Citation: Strippoli, R.; Niayesh-Mehr,

R.; Adelipour, M.; Khosravi, A.;

Cordani, M.; Zarrabi, A.; Allameh, A.

Contribution of Autophagy to

Epithelial Mesenchymal Transition

Induction during Cancer Progression.

Cancers 2024, 16, 807. https://

doi.org/10.3390/cancers16040807

Academic Editor: David A. Gewirtz

Received: 15 December 2023

Revised: 13 February 2024

Accepted: 13 February 2024

Published: 16 February 2024

Copyright: © 2024 by the authors.

Licensee MDPI, Basel, Switzerland.

This article is an open access article

distributed under the terms and

conditions of the Creative Commons

Attribution (CC BY) license (https://

creativecommons.org/licenses/by/

4.0/).

cancers

Review

Contribution of Autophagy to Epithelial Mesenchymal
Transition Induction during Cancer Progression
Raffaele Strippoli 1,2 , Reyhaneh Niayesh-Mehr 3, Maryam Adelipour 4, Arezoo Khosravi 5 , Marco Cordani 6,7 ,
Ali Zarrabi 8,9 and Abdolamir Allameh 3,*

1 Department of Molecular Medicine, Sapienza University of Rome, 00161 Rome, Italy;
raffaele.strippoli@uniroma1.it

2 National Institute for Infectious Diseases “Lazzaro Spallanzani”, I.R.C.C.S., 00149 Rome, Italy
3 Department of Clinical Biochemistry, Faculty of Medical Science, Tarbiat Modares University,

Tehran P.O. Box 14115-331, Iran; r.niayeshmehr@modares.ac.ir
4 Department of Clinical Biochemistry, School of Medicine, Ahvaz Jundishapur University of Medical Sciences,

Ahvaz 61357-15794, Iran; adelimaryam@rocketmail.com
5 Department of Genetics and Bioengineering, Faculty of Engineering and Natural Sciences, Istanbul Okan

University, Istanbul 34959, Türkiye; arezoo.khosravi@okan.edu.tr
6 Department of Biochemistry and Molecular Biology, Faculty of Biological Sciences, Complutense University

of Madrid, 28040 Madrid, Spain; mcordani@ucm.es
7 Instituto de Investigaciones Sanitarias San Carlos (IdISSC), 28040 Madrid, Spain
8 Department of Biomedical Engineering, Faculty of Engineering and Natural Sciences, Istinye University,

Istanbul 34396, Türkiye; ali.zarrabi@istinye.edu.tr
9 Department of Research Analytics, Saveetha Dental College and Hospitals, Saveetha Institute of Medical and

Technical Sciences, Saveetha University, Chennai 600077, India
* Correspondence: allameha@modares.ac.ir; Tel.: +98-21-82883877

Simple Summary: This manuscript focuses on the complex relationships between autophagy and
epithelial mesenchymal transition (EMT) in cancer. Autophagy, a cellular degradation process,
and EMT, a mechanism where epithelial cells acquire mesenchymal features, both play significant
roles in cancer development. This review aims to explore how these processes interact, particularly
how autophagy impacts cancer cell fate during EMT. The findings from this study are expected to
contribute to a better understanding of cancer biology and could potentially impact cancer treatment
strategies, as both autophagy and EMT are considered targets for therapy.

Abstract: Epithelial Mesenchymal Transition (EMT) is a dedifferentiation process implicated in many
physio-pathological conditions including tumor transformation. EMT is regulated by several extracel-
lular mediators and under certain conditions it can be reversible. Autophagy is a conserved catabolic
process in which intracellular components such as protein/DNA aggregates and abnormal organelles
are degraded in specific lysosomes. In cancer, autophagy plays a controversial role, acting in different
conditions as both a tumor suppressor and a tumor-promoting mechanism. Experimental evidence
shows that deep interrelations exist between EMT and autophagy-related pathways. Although
this interplay has already been analyzed in previous studies, understanding mechanisms and the
translational implications of autophagy/EMT need further study. The role of autophagy in EMT
is not limited to morphological changes, but activation of autophagy could be important to DNA
repair/damage system, cell adhesion molecules, and cell proliferation and differentiation processes.
Based on this, both autophagy and EMT and related pathways are now considered as targets for
cancer therapy. In this review article, the contribution of autophagy to EMT and progression of cancer
is discussed. This article also describes the multiple connections between EMT and autophagy and
their implication in cancer treatment.

Keywords: autophagy; epithelial mesenchymal transition; cell death; cell adhesion molecules; cell
proliferation; differentiation

Cancers 2024, 16, 807. https://doi.org/10.3390/cancers16040807 https://www.mdpi.com/journal/cancers

https://doi.org/10.3390/cancers16040807
https://doi.org/10.3390/cancers16040807
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https://doi.org/10.3390/cancers16040807
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Cancers 2024, 16, 807 2 of 31

1. Introduction: The Fate of Normal and Transformed Cells

The concept of cell fate pertains to the prospective identity of a cell or its progeny [1].
Distinct cell fates play a critical role in tissue development, organismal homeostasis mainte-
nance, and response to environmental disturbances [2]. Basically, a normal cell can manifest
one of five distinct cell fate types: proliferation, differentiation, quiescence (G0 phase),
senescence, and cell death (regardless of the mechanism of cell death). Complex regulatory
mechanisms, resulting from the interplay between intracellular regulatory networks and
external environmental stimuli, strongly govern cell fate decisions. These decisions often
occur in the G1 phase of the cell cycle [3–5].

Cellular transformation is caused by initial genetic alterations, which are followed
by subsequent changes that progressively drive the cell towards a malignant phenotype.
Cancer cells emerge as transformed derivatives of normal cells, exhibiting an extraordi-
nary capacity for rapid proliferation and dedifferentiation. This transformation entails
the progressive accumulation of DNA mutations in cancer-related genes, predominantly
occurring within proto-oncogenes and/or tumor suppressor genes [6,7]. These mutations
can ultimately lead to alterations in the cell’s morphology, as well as its biochemical and
molecular characteristics. In such cases, cells acquire the capacity to escape apoptosis,
develop resistance to anti-growth signals, achieve unlimited replicative potential, and
maintain continuous angiogenesis. Under these circumstances the cells can acquire the
capacity to invade neighboring tissues and metastasize [8]. Consequently, cancer-associated
modifications have the potential to perturb cellular fate decisions by impacting essential
cellular processes such as proliferation, differentiation, metabolism, and cell death [9,10].
Exogenous and endogenous agents, including ionizing radiation, chemical carcinogens,
oncoviruses, tobacco and alcohol consumption, as well as disorders that predispose indi-
viduals to DNA damage and cancer, are contributing factors [6,11].

When cells encounter DNA damage, they activate a network of intracellular pathways
to repair the damage and restore DNA integrity, collectively known as the DNA damage
response (DDR) [12]. Failure to repair DNA lesions can result in the activation of cell
death processes, primarily apoptosis, as the main pathway of cell death. If these pathways
are inactivated, they can contribute to genomic instability [13]. Ataxia telangiectasia mu-
tated (ATM) and ataxia telangiectasia and RAD3-related (ATR), belonging to the PIKK
(phosphoinositide 3-kinase related kinase) family, are recognized as key regulators of the
DDR [14]. Important functions of ATM and ATR include recognition of DNA damage and
regulation of DNA repair, cell cycle checkpoints, and apoptosis signaling pathways [15].
ATM predominantly responds to DNA double-strand breaks (DSBs), while ATR functions
as a sensor that responds to a wider range of DNA damages, including DNA single-strand
breaks (SSBs), DSBs, and DNA lesions during replication [14,16]. Some similar phospho-
rylation targets have been identified for both pathways. Upon activation of ATM/ATR
kinases, a signaling cascade is initiated, transmitting signals to downstream mediators
such as checkpoint kinase 1/2 (CHK1/CHK2), cell division cycle 25 (CDC25) protein, and
cyclin-dependent kinase (CDK). Subsequently, DDR pathway proteins like breast cancer
type 1/2 susceptibility protein (BRCA1/2) and p53 can undergo phosphorylation [14].
Evidence indicates that autophagy can play a significant role in the DDR pathway [17].
Studies have demonstrated that DNA damage can trigger autophagy, with various mech-
anisms attributed to this phenomenon [18]. For instance, certain DNA damage inducers
have been found to induce autophagy as well. One example is the activation of the ATM
pathway, which links DDR to autophagy induction by activating the AMP-activated pro-
tein kinase (AMPK) pathway and the transcription factor forkhead transcription factor O
subfamily member 3a (FOXO3a) that is involved in the regulation of ATM for DNA repair.
AMPK is capable of counteracting the inhibitory effect of mammalian target of rapamycin
complex 1 (mTORC1) on the autophagy pathway through phosphorylation of tuberous
sclerosis complex (TSC2). Moreover, AMPK can promote autophagosome formation by
activating unc-51-like autophagy activating kinase 1 (ULK1). Additionally, studies have
shown that FOXO3a plays a role in the transcription of genes related to autophagy [13,14].



Cancers 2024, 16, 807 3 of 31

Apoptosis and autophagy are important factors to control the balance of cell prolif-
eration and death and to save the organ from uncontrolled cell proliferation. Therefore,
the autophagic process causing intercellular lysosomal degradation is an important phe-
nomenon which contributes to cell fate decisions [19,20]. The impact of autophagy on
the fate of normal and cancer cells is mediated by different mechanisms. Lysosomal
degradation, cell survival, apoptosis induction, senescence and aging, regulation of cell
differentiation, and modulation of the carcinogenesis process can happen in response to
autophagy [21–24]. Specific outcomes of autophagy in cancer cells depend on cell type or
context, cellular conditions, stage of carcinogenesis, and interactions with other cellular
processes and signaling pathways [25]. Since the EMT process is recognized as a dediffer-
entiation process involved in cancer progression, this study aims to investigate the role
of autophagy and EMT processes in the development and treatment of cancer, as well as
explore different aspects of the interaction between EMT and autophagy.

2. Autophagy and Cancer
2.1. Role of Autophagy in Cancer Development and Progression

Macroautophagy, also known as autophagy, recycles damaged or unnecessary compo-
nents within cells. It involves initiation, phagophore formation, recognition of cargo, fusion
between autophagosome and lysosome, degradation of cargo, and autophagolysosome
breakdown. When cells experience stress or nutrient deprivation, a phagophore forms near
the target cargo and expands to become an autophagosome. Cargo receptors like sequesto-
some 1 (SQSTM1)/p62 identify and recruit the cargo, which is then degraded by lysosomal
enzymes in the autophagolysosome. This breakdown releases recycled molecules back into
the cell’s cytoplasm [26,27].

Autophagy is regulated by nutrient and energy-responsive signaling pathways. For
instance, mTOR (mammalian target of rapamycin) and Class III phosphoinositide 3-kinase
(PI3K)/Akt pathways inhibit autophagy through protein phosphorylation, while the AMP-
activated protein kinase (AMPK) pathway promotes autophagy [26]. ULK1/2, crucial
for autophagy induction, can be regulated by mTOR and AMPK. AMPK can induce ULK
activation by phosphorylating specific sites, such as S317 and S777. Additionally, mTOR can
inhibit autophagy by phosphorylating ULK, including the site S757, thereby inhibiting the
interaction between ULK and AMPK [28] (Figure 1). Transcription factors (TFs) like TFEB
control the expression of lysosomal and autophagy-related genes such as ATG9B, LC3, and
SQSTM1, and forkhead box protein O1 (FOXO1) activates autophagy-related genes such
as LC3b, Gabarapl1, PI3kIII, Ulk2, Atg12 l, Beclin1, Atg4b, and Bnip3. Additionally, post-
translational modifications like phosphorylation, acetylation, and ubiquitination regulate
protein activity and stability in autophagy [26,29].

The role of autophagy in cancer is complex, serving both as a tumor suppressor and a
pro-survival mechanism (Figure 2). Autophagy’s dual role is evident in cancer progression.
It acts as a tumor suppressor at early stages, preventing the accumulation of damaged
proteins and organelles, promoting cell death, and hindering cancer cell survival. However,
at later stages, especially with oncogenic K-RAS pathway activation, autophagy shifts to
a pro-survival mechanism, aiding cancer cells in resisting stress conditions like nutrient
deprivation, hypoxia, and chemotherapy-induced apoptosis. This pro-survival function
can contribute to tumor growth and therapy resistance. Additionally, autophagy can play a
role in degrading the extracellular matrix, promoting cancer cell motility, and facilitating
tumor cell invasion and metastasis [22,30].

Some studies have reported that defects in autophagy can contribute to tumorigenesis
by promoting genomic instability, inflammation, and metabolic dysregulation [31–33].

Autophagy performs several functions that help stabilize the genome, including main-
taining mitochondrial quality, reducing the accumulation of reactive oxygen species (ROS),
defending against carcinogenic pathogens, breaking down misfolded or overexpressed pro-
teins, and removing micronuclei and damaged nuclear parts. Autophagy also influences the
DNA damage response (DDR) and the processing of genomic lesions. Evidence suggests



Cancers 2024, 16, 807 4 of 31

that autophagy is closely linked to the DDR network, and that DNA damage can stimulate
autophagy in both pathological and nonpathological situations. The proper functioning of the
DNA repair machinery is contingent upon a highly efficient autophagic process. Autophagy,
in this context, plays a pivotal role in DNA repair. One crucial aspect is its contribution
to maintaining bioenergetic fitness. Autophagy provides metabolic precursors essential for
generating ATP. This ATP generation is particularly critical for supporting optimal DNA
repair processes. Moreover, autophagy actively participates in ensuring nucleotide home-
ostasis, a fundamental requirement for DNA synthesis. By regulating the availability and
balance of nucleotides, autophagy contributes to the integrity of the cellular genome, facili-
tating the accurate and efficient synthesis of DNA molecules [23,24]. According to Delaney
et al., monoallelic loss of Beclin-1 (BECN1) has been shown to promote genomic instability
in ovarian cancer. Knocking down BECN1 and microtubule-associated protein 1 light chain
3 beta (MAP1LC3B/LC3B), two frequently deleted autophagy genes in ovarian cancer, led to
genomic instability and increased migration rates in atypical ovarian cancer cells. In a mouse
model, haploinsufficiency of BECN1 was observed to allow and enhance genomic instability
in ovarian cancer. These findings suggest that autophagy deficiency, particularly monoallelic
loss of BECN1, can play a role in genome instability in cancer [25]. Nevertheless, in cases of
excessive or prolonged DNA damage, autophagy eventually induces senescence or cell death,
thereby inhibiting the proliferation of cells harboring genomic aberrations [33,34]. 

 

 

 
Cancers 2024, 16, 807. https://doi.org/10.3390/cancers16040807 www.mdpi.com/journal/cancers 

 
Figure 1. Schematic overview of the macroautophagy process and its key players in induction and 
nucleation. Macroautophagy involves several distinct stages: Induction: triggered by metabolic 
stress or treatment, involving the participation of the ULK1 protein complex. Nucleation: character-
ized by the formation of the phagophore or isolation membrane, primarily stimulated by the PI3K 
complex. Elongation: where the phagophore expands and develops into the autophagosome. Inte-
gration: occurs when the autophagosome containing cytosolic cargo fuses with the lysosome, result-
ing in the formation of the autolysosome. Degradation: takes place within the autolysosome, as ly-
sosomal hydrolases break down the contents and release primary components back into the cytosol. 

  

Figure 1. Schematic overview of the macroautophagy process and its key players in induction and
nucleation. Macroautophagy involves several distinct stages: Induction: triggered by metabolic stress
or treatment, involving the participation of the ULK1 protein complex. Nucleation: characterized by
the formation of the phagophore or isolation membrane, primarily stimulated by the PI3K complex.
Elongation: where the phagophore expands and develops into the autophagosome. Integration:
occurs when the autophagosome containing cytosolic cargo fuses with the lysosome, resulting in
the formation of the autolysosome. Degradation: takes place within the autolysosome, as lysosomal
hydrolases break down the contents and release primary components back into the cytosol.



Cancers 2024, 16, 807 5 of 31

Cancers 2024, 16, 807 2 of 6 
 

 

 

 
Figure 2. The potential impact of the autophagy mechanism on cancer. The effect of autophagy in 
cancer is highly contextual and stage-cell specific. Autophagy may eliminate damaged organelles 
such as mitochondria, thus removing a potential source of new DNA mutations, or alternatively 
may favor tumor cell survival under stress conditions. Autophagy can exert influence on the devel-
opment and progression of cancer, as it can either prevent or stimulate cancer development and 
progression. Additionally, it can affect cancer stem cell maintenance and drug resistance. 

  

Figure 2. The potential impact of the autophagy mechanism on cancer. The effect of autophagy in
cancer is highly contextual and stage-cell specific. Autophagy may eliminate damaged organelles
such as mitochondria, thus removing a potential source of new DNA mutations, or alternatively may
favor tumor cell survival under stress conditions. Autophagy can exert influence on the development
and progression of cancer, as it can either prevent or stimulate cancer development and progression.
Additionally, it can affect cancer stem cell maintenance and drug resistance.

Inflammation as a hallmark of cancer has been shown to be involved in various stages
of tumor progression. Autophagy has been implicated in regulating inflammation in cancer
by promoting the degradation of damaged cellular components and limiting the release of
pro-inflammatory signals. However, the relationship between autophagy and inflammation
in cancer is complex and context-dependent [35]. In addition, autophagy can enhance the
processing and presentation of tumor antigens, which stimulates anti-tumor immunity.
However, cancer cells may reduce autophagy to evade immune surveillance [36]. Mom-
mersteeg et al. investigated the role of autophagy in inflammation and the development of
Helicobacter pylori-associated gastric cancer. They found that this bacterium activates au-
tophagy, which can be dysregulated by a single nucleotide polymorphism in the autophagy
gene ATG16L1, leading to increased endoplasmic reticulum stress and inflammation. The
study suggests that dysregulation of autophagy and inflammation pathways by this genetic
variation could contribute to the development of this type of cancer [37].

Moreover, the crosstalk between autophagy and metabolism in cancer is bidirec-
tional and complex. Autophagy plays a crucial role in regulating cellular metabolism,
and metabolic changes in cancer cells can also influence autophagy. Jiao et al. indicated
that autophagy plays a role in regulating glycolytic metabolism in liver cancer cells by
targeting and breaking down hexokinase 2 (HK2). The degradation process involves the
ubiquitination of HK2 facilitated by the E3 ligase TNF receptor-associated factor 6 (TRAF6)
and subsequent recognition by the autophagy receptor protein SQSTM1/p62. Both in vitro
and in vivo experiments demonstrated that 3-bromopyruvate, a pyruvate analog targeting
HK2, decreased the growth of tumors with impaired autophagy. This study suggests that
targeting glycolysis through the TRAF6- and SQSTM1-mediated ubiquitination system may
be a potential therapeutic intervention for autophagy-impaired liver cancer [38]. Moreover,
Perera et al. revealed that the induction of autophagy in pancreatic ductal adenocarcinoma
(PDA) is a component of a broader transcriptional program. This program, mediated
by the MiT/TFE family of transcription factors (TFs), orchestrates lysosome biogenesis
and function, as well as nutrient scavenging, playing a crucial role in upregulating the
expression of a network of genes, promoting elevated levels of lysosomal catabolic function
crucial for the growth of PDA. Metabolite profiling indicates that MiT/TFE-dependent
activation of autophagy–lysosome pathways is specifically essential for sustaining intracel-



Cancers 2024, 16, 807 6 of 31

lular amino acid pools. These findings highlight the crucial role of autophagy in regulating
the metabolism in pancreatic cancer and identify transcriptional activation of clearance
pathways as a newly identified characteristic of highly aggressive malignancy [39].

2.2. Role of Autophagy in Cancer Stem Cell Maintenance

Cancer stem cells (CSCs) constitute a distinct minority subset of cells within tumors,
characterized by stem cell-like features. It is imperative to clarify that CSCs and cancer-
initiating cells are not synonymous; they represent different populations within the tumor
microenvironment. CSCs are pivotal contributors to tumor initiation, progression, and
resistance to therapy [23,40].

CSCs exhibit distinctive properties that significantly influence tumor behavior and
therapeutic responses. One key characteristic, clonogenicity, underscores their ability to
originate from a single cell and grow into a colony. Beyond clonogenicity, CSCs possess the
unique capacity for self-renewal and differentiation, making them both tumorigenic and
adaptable to various biological processes. This adaptability contributes to their substantial
impact on tumor progression, therapeutic resistance, and disease recurrence. CSCs engage
in sustained proliferation, invade normal tissue, promote angiogenesis, evade immune
surveillance, and resist conventional anticancer therapies. The intricate regulation of CSC
homeostasis involves critical transcription factors, including OCT4, SOX2, KLF4, NANOG,
and c-MYC. Additionally, intracellular signaling pathways such as Wnt/TCF, STAT3, and
NF-κB play pivotal roles in governing CSC phenotypes. The ATP-binding cassette (ABC)
transporter family expressed through activation of NF-kB SREBP2, SNAIL, and TWIST
transcription factors further contributes to the multi-drug resistance exhibited by CSCs [41].
To aid in the identification and isolation of these cells, cellular markers such as CD44, CD133,
and ALDH1 are commonly employed tools. Altogether, these characteristics and regulatory
mechanisms define the unique and influential role of CSCs in cancer biology [42].

In CSCs, autophagy appears to be upregulated and helps maintain their stem cell-like
properties. Autophagy can promote the survival of CSCs by providing them with energy
and nutrients during periods of stress or nutrient deprivation. Autophagy also helps CSCs
to resist chemotherapy and radiation therapy by promoting DNA repair and reducing
oxidative stress [43]. In this regard, Chen et al. suggested that the activation of autophagy
is vital for the self-renewal of CSCs in head and neck squamous cell carcinoma (HNSCC)
and the acquisition of CSC properties under adverse conditions. The results revealed that
adverse conditions, such as exposure to cisplatin, starvation, and hypoxia, can increase the
autophagy level and CSC properties of HNSCC cells. However, the CSC properties acquired
under adverse conditions were reduced when pretreated with autophagy inhibitors, includ-
ing 3-MA and chloroquine (CQ). The study also found that CSCs have stronger autophagic
activity than non-CSCs, and the inhibition of autophagy dampens the CSC properties of
HNSCC cells. Furthermore, the study identified the noncanonical FOXO3/SOX2 axis as
the intrinsic regulatory mechanism that controls the CSC phenotype [44]. Also, Shi et al.
indicated that the long noncoding RNA (lncRNA) TINCR regulates liver cancer stem cell
(LCSC) self-renewal through autophagy activation via the polypyrimidine tract binding
protein 1 (PTBP1) /ATG5 regulatory pathway. They found that TINCR is highly expressed
in hepatocellular carcinoma (HCC) tissues and LCSCs, and its expression is crucial for the
self-renewal and tumorigenesis of LCSCs. Gene ontology analysis uncovered that TINCR
plays a role in maintaining stemness through the regulation of autophagy. Knocking down
TINCR resulted in reduced expression of transcription factors POU5F1, SOX2, Nanog,
and surface marker CD44. Mechanistically, TINCR was observed to interact with PTBP1
proteins, subsequently enhancing the transcriptional activity of the autophagy-related gene
ATG5 [45].

Inconsistent with previous studies, other studies have shown an increase in the stem-
ness properties of CSCs with a reduction in autophagy. In this regard, Brunel et al. explored
the impact of silencing two autophagy-related genes (Beclin1 or ATG5) on the expression
of markers and functionalities associated with glioblastoma CSCs. The results showed



Cancers 2024, 16, 807 7 of 31

that downregulating autophagy increased the expression of CSCs markers and boosted
cell proliferation and clonogenicity [46]. In addition, Park et al. revealed that luminal and
triple-negative breast cancers (TNBCs) necessitate distinct treatment approaches due to
variations in their autophagy flux levels. Their study uncovered the inhibition of autophagy
flux in CSCs within TNBCs, coupled with the upregulation of miRNA-181a expression
in both TNBC CSCs and patient tissues. ATG5 and ATG2B were identified as targets of
miR-181a, playing a role in the early formation of autophagosomes [47].

Furthermore, Sharif et al. conducted a study demonstrating the role of autophagy in
the TP73/p73-dependent regulation of stemness within CSCs. The study revealed that
TP73/p73 positively regulates the growth and stemness of CSCs by modulating autophagy.
Specifically, TP73/p73 deficiency promotes autophagy in CSCs by activating the autophagy
machinery, resulting from reduced ATP levels caused by metabolic perturbations within
the proline regulatory axis. These findings suggest that autophagy may contribute to a
decrease in stemness maintenance in CSCs [48].

2.3. Autophagy as a Therapeutic Target in Cancer

Autophagy is believed to be a double-edged sword in cancer, exhibiting the potential
to either promote tumor cell survival or induce cell death, contingent on the specific context,
and its manipulation by drugs needs to be carefully considered to achieve therapeutic
benefits [49]. In this regard, a growing body of experimental studies and clinical trials
have attempted to demonstrate the efficacy of targeting autophagy as a therapeutic ap-
proach to overcome cancer. For instance, Yun et al. suggested that autophagy, induced
by temozolomide (TMZ) treatment, may contribute to resistance in glioblastoma multi-
forme (GBM). They discovered that DOC-2/DAB2 interacting protein (DAB2IP) loss causes
TMZ resistance in GBM via ATG9B, while DAB2IP sensitizes GBM to TMZ leading to
autophagy suppression through ATG9B expression regulation. In comparison to low-grade
glioma, GBM cells showed higher ATG9B expression, and enhanced knocking down of
ATG9B, which in turn decreased autophagy and resistance to TMZ. Furthermore, the study
demonstrated that DAB2IP negatively regulates ATG9B expression by blocking the Wnt/β-
catenin pathway. To prevent therapeutic resistance and enhance the benefit of TMZ, the
study tested effective combination strategies using a small molecule inhibitor blocking the
Wnt/β-catenin pathway along with TMZ. The combined treatment showed a synergistic
enhancement of TMZ efficacy in GBM cells, providing insight into a potential strategy to
overcome TMZ resistance [50]. Moreover, Chen et al. investigated the role of autophagy
in the treatment of HCC and demonstrated that the combination of hydroxychloroquine
(HCQ) as an autophagy inhibitory agent and sorafenib had a synergistic effect on sorafenib-
resistant HCC cells. This was achieved by downregulation of Toll-like receptor (TLR)-9.
TLR-9 increased HCC cells proliferation, tumor growth, oxidative markers, and autophago-
some formation. Therefore, TLR-9 modulation resulted in a decrease in autophagy-related
genes (ATG5 and Beclin-1), oxidative stress markers (SOD1), apoptosis-related genes (c-
caspase3), and finally, tumor growth. These findings suggest that targeting autophagy with
HCQ and downregulating TLR9 could increase the sensitivity of sorafenib-resistant HCC
cells to treatment. The modulation of autophagy may therefore be a promising strategy in
cancer therapy [51]. In addition, Li et al. investigated the role of autophagy in osimertinib
resistance in non-small cell lung cancer (NSCLC) and found that increased autophagy was
associated with resistance to the third-generation epidermal growth factor receptor-tyrosine
kinase inhibitor (EGFR-TKI). Suppression of autophagy improved osimertinib cytotoxicity
in both resistant and sensitive NSCLC cells, indicating a detrimental role of autophagy in
osimertinib efficacy. These findings highlight the potential of combination therapy with
an EGFR-TKI and an autophagy inhibitor as a promising strategy to overcome osimer-
tinib resistance in lung cancer [52]. Moreover, You et al. suggested a novel relationship
between breast cancer 1 (BRCA1) and autophagy in drug resistance. They investigated
the role of BRCA1 and autophagy in the drug resistance of epithelial ovarian cancer stem
cells (EOCSCs). Autophagy played a crucial role in preserving stemness and conferring



Cancers 2024, 16, 807 8 of 31

resistance to chemotherapy in EOCSCs. BRCA1 was identified as a regulator of drug
resistance in EOCSCs through autophagy, and inhibition of autophagy activity effectively
reduced resistance caused by BRCA1. Additionally, BRCA1 regulated cellular apoptosis
and cell cycle progression through autophagy, influencing drug sensitivity indirectly in
EOCSCs [53].

Targeting autophagy to treat cancer was evaluated in several clinical trials. Karacis et al.
in a phase 2 randomized clinical trial investigated whether the autophagy inhibitor, HCQ,
in combination with standard chemotherapy improved overall survival at 1 year among
patients with metastatic pancreatic cancer. The trial enrolled 112 patients, with 55 receiving
gemcitabine hydrochloride and nab-paclitaxel (GA) plus HCQ and 57 receiving GA alone.
The primary endpoint, overall survival at 12 months, was not improved by the addition of
HCQ, although there was an improvement in the overall response rate. The study suggests
that routine use of GA plus HCQ for metastatic pancreatic cancer without a biomarker is
not supported, but HCQ may have a role in the locally advanced setting [54]. In another
randomized phase 2 study, the efficacy of adding HCQ to preoperative chemotherapy was
assessed in patients with pancreatic adenocarcinoma. Patients were randomly assigned
to receive either GA alone or with HCQ for two cycles before resection. The study found
that the addition of HCQ resulted in greater histopathologic and biomarker responses,
as well as evidence of autophagy inhibition and immune activity. However, overall and
relapse-free survival did not differ between the two arms. The study concludes that
adding HCQ to chemotherapy may have potential clinical benefits in resectable pancreatic
adenocarcinoma [55]. In another phase 2 clinical trial, Arora et al. compared the efficacy and
safety of the histone deacetylase inhibitor, vorinostat, and HCQ to the multi-kinase inhibitor,
regorafenib, in patients with metastatic colorectal cancer [56]. The study found that the
median progression-free survival was inferior in the vorinostat/ HCQ arm compared to the
regorafenib arm, although both treatments were well-tolerated and showed improved anti-
tumor immunity. The study concludes that autophagy modulation using vorinostat/HCQ
has a favorable safety profile and may have clinical benefits in metastatic colorectal cancer.
Additionally, Xu et al. conducted a meta-analysis to evaluate the clinical value of autophagy
inhibitor-based therapy in cancer treatment. They identified seven clinical trials and found
that autophagy inhibitor-based therapy had higher overall response rate, progression-free
survival rate, and overall survival rate compared to therapy without inhibiting autophagy.
The study suggests that inhibiting autophagy may be a promising strategy for cancer
treatment [57].

3. Cell Transformation, EMT and Carcinogenesis

EMT is a partially reversible cell plasticity program that occurs under various physio-
logical and pathological conditions, playing a vital role in processes such as growth and
development, wound healing, tissue fibrosis, and tumorigenesis [58]. The EMT process in-
volves the alteration of normally arranged stationary compact epithelial cells into elongated
motile mesenchymal cells under the influence of EMT-inducing signals [59]. During tumor
development this process is associated with various outcomes, including tissue invasion,
metastasis, resistance to cancer treatment, poor survival, and an increased risk of tumor
recurrence [60]. The activation of EMT has been found to be essential for malignant pro-
gression in several types of cancers derived from epithelia, such as breast cancer, colorectal
cancer, HCC, lung cancer, prostate cancer, and pancreatic cancer [17,61,62].

3.1. Morphological, Biochemical and Molecular Changes during EMT

Epithelial and mesenchymal cells differ in their morphology, epithelial/mesenchymal
marker expression, tissue organization, and biological functions [63]. In normal epithelial
tissues, flat and polygonal epithelial cells form monolayer or multilayer continuous sheets,
serving as vital barriers for solutes and water [64]. Crucially, epithelial cells exhibit strong
apical-basal cell polarity, which plays a fundamental role in preserving cellular architecture
and facilitating essential biological functions like endocytosis, exocytosis, and vesicle



Cancers 2024, 16, 807 9 of 31

transport across the epithelium [64,65]. Various cellular junctions, such as tight junctions,
cadherin-based adherent junctions, gap junctions, desmosomes, and hemi-desmosomes,
play a crucial role in maintaining the cohesion of epithelial cells and their connection to the
underlying basement membrane [66,67]. Such cell–cell junctions are essential for preserving
cell polarity, tissue structural integrity, and upholding their barrier function [68,69]. The
key component of adherent junctions, located in the basolateral membrane and encoded by
the CDH1 gene, is Epithelial-cadherin (E-cadherin). The extracellular domain of E-cadherin
binds to adjacent epithelial cell cadherin, while its intracellular domain interacts with
β-catenin, α-catenin, and p120-catenin, forming the cadherin/catenin adhesion complex.
This complex participates in intracellular signaling as well as anchors to cortical actin
bundles [69]. On the other hand, desmosomes are associated with cytokeratin intermediate
filaments [70]. In addition to tight junctions, several multi-protein polarity complexes
play a role in regulating epithelial apico-basal polarization. These complexes include
Partitioning defective (PAR), Crumbs, and Scribble complexes, which exhibit a cortically
asymmetric distribution [62,67,71]. The mobility of individual cells within the epithelial
layer are restricted due to their epithelial morphology and their cellular junctions [63,72].

Unlike epithelial cells, mesenchymal cells exhibit distinct features such as irregular
morphology, am elongated spindle-like shape, less-rigid topography, anterior–posterior
polarity, and the presence of vimentin-based intermediate filaments instead of epithelial cy-
tokeratins [65,67]. Functional epithelial cell junctions are not observed in mesenchymal cells,
thereby resulting in a limited ability of these cells to form strong connections with surround-
ing mesenchymal cells [63]. In mesenchymal cells, several key factors contribute to their
ability to move and migrate. Firstly, there is a downregulation of cytokeratin and an upregu-
lation of vimentin filaments, which enhances the strength and flexibility of the cytoskeleton
and reduces its susceptibility to damage during migration [73–75]. Additionally, mesenchy-
mal cells produce actin-rich membrane protrusions through N-cadherin-mediated stress
fiber organization which facilitate various types of cell movement [74,76,77]. Moreover,
mesenchymal cells gain expression of α-smooth muscle actin (α-SMA), which favors the
contractility of the extracellular matrix (ECM) proteins in which cells are embedded [78].

The transition between epithelial and mesenchymal cell states, referred to as the
EMT process, has been observed in diverse cellular fate conversions, including cancer
progression [79]. EMT is associated with profound cellular changes at multiple levels,
encompassing dynamic morphological and biochemical alterations that result in functional
modifications in cell migration and invasion [62,67]. These changes include extensive
cytoskeletal remodeling and alterations in their proteins expression such as a switch from
cytokeratins to vimentin, the formation of actin stress fibers, enhanced production of
ECM-degrading enzymes, alterations in the expression of certain cell surface proteins, dis-
integration of epithelial cell junctions, loss of apical-basal polarity, transcriptional repression
of polarity complex proteins, and the acquisition of a fibroblastoid invasive phenotype [62].
EMT is often not a totally defined irreversible process. Indeed, during tumor transforma-
tion terms such as partial EMT (pEMT), hybrid epithelial/mesenchymal (E/M), and mixed
EMT have been used, suggesting that cells range across a continuum between the full ep-
ithelial towards the mesenchymal state [80]. Moreover, cellular and molecular markers that
reflect the characteristics of epithelial and mesenchymal cells, including specific parameters
involved in cell integrity and regulatory processes, can be used as markers for EMT [67].

The downregulation or loss of E-cadherin, a major hallmark of EMT, results in the
disintegration of adherence junctions. It also leads to the dissociation of membrane-bound
β-catenin from the cadherin complex and its translocation to the cell’s nucleus. Within the
nucleus, β-catenin regulates the expression of various genes, including c-myc, cyclin D1,
and genes associated with Wnt signaling [61,63,81]. Cadherin isoform switching, character-
ized by a change in the expression pattern of cadherin from E-cadherin to N-cadherin, is
an important phenomenon in EMT. Such changes significantly affect the motility of cells
undergoing EMT and lead to an increase in their ability to interact with stromal cells [82,83].
Cytokeratins (CK8, CK18, CK19), mucin-1, desmoplakin, and tight junction proteins such



Cancers 2024, 16, 807 10 of 31

as occludin, claudin, and zone of occlusion-1 (ZO-1) are also important markers which are
downregulated in epithelial cells undergoing EMT. Under these circumstances, there is an
upregulation of mesenchymal cell-specific markers including vimentin, α-SMA, fibroblast-
specific protein-1 (FSP-1), fibronectin, vitronectin, β1 and β3 integrins, and mesenchymal
cadherins such as N-cadherin [60,63,84].

Being that EMT induces a global reprogramming of the cell proteome, several EMT
transcription factors (EMT-TFs), epigenetic modifications, post-translational alterations,
and specific non-coding RNAs (ncRNAs) including lncRNAs, as well as microRNAs like
the miR-200 family, play a role in regulating specific cellular processes [63,85,86]. The key
EMT-TFs include the basic helix-loop-helix (bHLH) TFs Twist1 and Twist2, the Snail family
of zinc-finger TFs, Snail (SNAI1) and Slug (SNAI2), and the zinc finger E-box binding
homeobox (ZEB) family, specifically ZEB1 and ZEB2 [87]. Upon activation of specific
signaling cascades, EMT-TFs have the ability to repress the transcription of epithelial
markers. In particular, EMT-TFs can directly inhibit E-cadherin expression by binding
to E-boxes located on the CDH1 promoter [85,88]. In addition to the extensively studied
EMT-TFs, several non-canonical EMT-TFs have been identified, which may play a role
in coordinating the EMT process in specific cancers. These include Krüppel-like factor
8 (KLF8), placenta-related homeobox1 (PRRX1), and fork boxC2 (FOXC2) [85]. Several
signaling pathways contribute to the induction of the EMT process. These pathways include
transforming growth factor-β (TGF-β), bone morphogenetic protein (BMP), Wnt-β-catenin,
NOTCH, sonic hedgehog (Shh), nuclear factor kappa B (NF-κB), AKT-mTOR, integrins, and
receptor tyrosine kinases (RTKs) including epidermal growth factor (EGF) and fibroblast
growth factor (FGF) [89]. Among these factors, TGF-β is recognized as the most potent
inducer of EMT, exerting its effects through both Smad and non-Smad pathways, ultimately
leading to the upregulation of EMT-TFs [90,91].

3.2. Role of EMT in Tumor Invasion and Metastasis

The processes of EMT and its reversal, known as mesenchymal-to-epithelial transi-
tion (MET), have been identified as critical events in the metastatic cascade of epithelial
cancers [61,92].

Tumor cell invasion, which refers to the directed migration of tumor cells from the
tumor microenvironment into surrounding tissues by crossing the basement membrane,
is considered the initial stage in the metastatic cascade [93]. The ability of tumor cells to
invade neighbor cells and tissues is crucial for metastasis initiation. However, subsequent
steps such as intravasation, transport, extravasation, and colonization at secondary sites
are necessary to drive the metastatic cascade [94].

Cell invasion occurs by two main strategies, individual migration and collective
migration [27,68]. In single-cell invasion, cell adhesion to ECM components plays a crucial
role. However, in collective invasion, coordinated cell–cell interactions are essential [95].
Collective invasion employs a migration mechanism known as collective–amoeboid transi-
tion, wherein cells acquire an amoeboid phenotype [93,96]. During tumor invasion, single
tumor cells can exhibit two distinct modes of movement: mesenchymal and amoeboid
migration, which can be interchangeable [97]. Amoeboid migration is characterized by
membrane blebbing, weak adhesion or pushing movements, high myosin II activation,
and rapid motility. On the other hand, mesenchymal migration involves ECM degrada-
tion, strong adhesions, front-rear polarization, and the formation of actin-rich membrane
protrusions like lamellipodia and filopodia. Indeed, epithelial cells can adopt a migratory
phenotype by converting to a mesenchymal state through the activation of EMT. These
mesenchymal-like cells may be able to increase the speed of migration through complex
three-dimensional environments by acquiring amoeboid characteristics, referred to as
mesenchymal-to-amoeboid transition (MAT) [53,95,98,99]. In certain epithelial cancers,
such as HCC, prostate cancer, and breast cancer, direct epithelial-to-amoeboid transition
(EAT) has been observed as an additional migration pattern that enhances tumor cell
invasion and metastasis [95].



Cancers 2024, 16, 807 11 of 31

The aberrant activation of the EMT process is considered a significant event in initiat-
ing the invasion and dissemination of cancer cells [100]. Additionally, partial EMT has been
observed in the context of metastasis. During this state, cells are capable of collective mi-
gration and demonstrate an enhanced metastatic potential [9]. Multiple studies conducted
on various cancer models, including tumor cell lines, mouse models of cancer, and human
tumor samples, have confirmed that activating EMT is a crucial strategy for facilitating
the effective metastatic spread of tumor cells [101]. These studies reveal that epithelial
cancer cells can acquire a mesenchymal phenotype and express mesenchymal markers
such as α-SMA, FSP1, and vimentin. Typically, these cells are localized at the invasive front
of primary tumors and eventually undergo subsequent stages of the invasion–metastasis
cascade [102].

Evidence shows a connection between the process of EMT and protein hydrolases,
specifically matrix metalloproteinases (MMPs). At the invasion front, individual cells or cell
clusters possessing EMT properties can invade and disrupt the ECM by activating proteases
like MMPs [64]. A significant association has been identified between tumor aggressiveness
and increased expression of MMPs, particularly MMP-1, -2, and -9 in breast, lung, pan-
creatic, and prostate cancers [60,103,104]. ECM degradation by certain classes of MMPs is
considered a prerequisite for cell invasion [105]. Tumor cells undergoing EMT can produce
higher levels of MMP enzymes to enhance cell invasion and migration [60]. EMT-TFs have
the ability to induce MMPs, which play a crucial role in degrading the basement membrane
and ECM of surrounding tissues [62]. Previous studies have demonstrated that Twist and
ZEB1 can stimulate the formation of invadopodia [62,106]. Invadopodia are specialized
filopodia formed by invasive cancer cells, enabling them to degrade the ECM through MMP
secretion [107]. Additionally, an association has been observed between increased MMP
levels in the tumor microenvironment and the activation of EMT in epithelial cells. Various
types of epithelial cells, including those in ovarian, lung, prostate, lens, and breast tissues,
have exhibited MMP-dependent induction of EMT [64,108]. MMP-mediated degradation of
E-cadherin, as an important substrate for MMPs, leads to tissue conversion into single cells
and triggers EMT signaling. The extracellular domain of E-cadherin undergoes proteolytic
cleavage, giving rise to an 80 kDa fragment identified as soluble E-cadherin (sE-cad), which
is believed to be involved in functions such as inducing EMT and facilitating invasion [109].

EMT is a partly reversible process characterized by the transition from motile, multi-
polar, or spindle-shaped mesenchymal cells to planar arrays of polarized cells organized in
epithelia. Once tumor cells reach suitable metastatic sites, complete or partial EMT may
be followed by the MET process. MET involves the reorganization of the cytoskeleton,
restoration of epithelial cell-to-cell junctions, and establishment of apical-basal polarity
(Figure 2). These changes enable migrating mesenchymal cells to adopt a polarized epithe-
lial state, facilitating colonization at secondary sites [61,63,67]. For instance, a study utilizing
a mouse model of skin cancer demonstrated that the activation of Twist1 induces EMT and
facilitates the dissemination of cancer cells through the bloodstream. Conversely, in distant
tissues, the downregulation of Twist1, which triggers the MET process, is necessary for
the proliferation of disseminated cancer cells and the formation of macrometastases [110].
Thus, the dynamic nature of EMT-MET cellular processes can lead to alterations in the
phenotype of tumor cells in a spatiotemporal manner [62].

3.3. EMT as a Target in Cancer Therapy and Drug Resistance

In addition to the promotion of increased cell motility and invasiveness described
above, EMT has been demonstrated to play a role in other aspects of tumorigenesis, in-
cluding drug resistance or chemoresistance [62,111]. Since 1990, numerous studies using
different models (in vitro, in vivo, and clinical samples) have investigated the relationship
between EMT and drug resistance. There are several lines of studies in support of associ-
ation of EMT and drug resistance of cancer cells and underlying mechanisms in various
cancers, including lung, pancreatic, bladder, and breast cancers [112,113].



Cancers 2024, 16, 807 12 of 31

EMT-related TFs, such as Twist, Snail, Slug, and ZEB, play crucial roles in promoting
drug resistance in cancer cells. Several binding sites for these TFs have been identified
in the promoters of the ATP-binding cassette (ABC) transporter family, which includes
multidrug resistance (MDR) proteins. These transmembrane proteins actively participate
in drug efflux [114–116]. For instance, in invasive breast cancer cell lines, overexpression of
EMT-related TFs including Twist, Snail, and FOXC2 results in an increase in the promoter
activity and expression of ABC transporters, thereby enhancing resistance to doxorubicin
treatment [117]. Similarly, overexpression of Twist in human colorectal cancer cell lines
induces EMT and heightens resistance to oxaliplatin treatment by upregulating MDR1 [116].

Another well-known mechanism contributing to drug resistance in EMT is the inhi-
bition of drug-induced apoptosis signaling pathways [118]. For instance, a study demon-
strated that the expression of Slug, a member of the Snail TF superfamily, is significantly
higher in cancer cells with resistance to EGFR tyrosine kinase inhibitors and can promote
gefitinib resistance in NSCLC by suppressing Bim expression and inhibiting caspase-9
activity. This finding was supported by showing that silencing this TF restored the gefitinib-
mediated apoptosis [119].

EMT-inducing signaling pathways such as TGF-β, Wnt, and Hedgehog have also been
implicated in drug resistance [118]. In this connection, treatment of HCT116 human colon
cancer cells with doxorubicin resulted in EMT induction through the activation of TGF-β
signaling and increased MDR levels. Furthermore, by suppression in TGF-β signaling
through downregulating Smad4, the EMT process was reversed and the sensitivity of the
cells to doxorubicin was restored [120].

Cells undergoing EMT may exhibit similar characteristics to CSCs in terms of marker
expression, involvement of key signaling pathways such as Wnt, Hedgehog, and Notch,
as well as the development of a drug-resistant phenotype [118,121]. Wnt and Hedgehog,
for instance, may favor the expression of CSC markers such as CD34, CD44, Sca, and
cKIT [122,123]. Indeed, CSCs show resistance to several chemotherapy drugs due to over-
expression of drug efflux transporters, such as ABC transporters, slow-cycling (dormant)
nature, prevention of apoptosis, and expression of non-coding RNAs involved in drug
resistance [124].

Factors associated with the tumor microenvironment, including hypoxic conditions,
also play an important role in promoting EMT-related chemoresistance [118]. Under hy-
poxic conditions, the activation of hypoxia-inducible factor 1-alpha (HIF-1α) can induce
EMT in HCC cells and enhance drug resistance by upregulating MDR1 expression, sug-
gesting that HIF-1α suppression can enhance the efficacy of chemotherapy [125].

Relationships between the EMT process and resistance to other cancer treatments
such as radiotherapy, molecular targeted therapy, and immunotherapy further confirm
the role of EMT in drug resistance [126]. Based on this data, various therapeutic strategies
have been proposed, including targeting EMT-TFs and inhibitors of signaling pathways
involved in the EMT process, such as TGF-β/Smad signaling. Moreover, several small
molecules and microRNAs have been identified as EMT inhibitors that are able to reverse
the EMT phenotype and reduce tumor resistance to therapy. Long-term use of the EMT
inhibitors such as disulfiram and metformin raises concerns over the side effects and
toxicity, as well as the role of the MET process in cancer metastasis [118,126]. It is important
to note that intratumor heterogeneity and the plasticity of cancer cells during the EMT-MET
process can give rise to different resistance mechanisms [127,128]. According to Biddle
et al., depending on cellular states and plasticity, the EMT inhibitors can be classified into
different sub-groups [127].

These data indicate that EMT process and related factors can be used as target for
controlling cancer cells at early stages of tumorigenesis. However, targeting these cells
and molecules depends on different factors, particularly when used in combination with
conventional chemotherapy, immunotherapy, or other cancer treatment protocols.



Cancers 2024, 16, 807 13 of 31

4. Autophagy-EMT Interplay

As described in the previous section, autophagy is a highly conserved cellular pathway
that facilitates the elimination of harmful or defective biomolecules and organelles. It can
either stimulate or repress tumor formation depending on the type of tissue, tumor stage,
metabolic context, and microenvironmental inputs [129]. The EMT plays a key role in tumor
invasion and metastasis by enabling epithelial cells to acquire mesenchymal properties,
such as motility and the ability to spread and disseminate in distant organs [91] as well as
being implicated in the acquisition of chemoresistance [130]. Interestingly, autophagy and
EMT share a complex regulatory network and several stress-related signaling pathways.
Therefore, understanding their interrelations may open up novel therapeutic opportunities
in cancer treatment.

The dual role of autophagy during tumor development has been described in previous
sections. The use of autophagy as a cancer therapeutic target is highly debated. On one
hand, autophagy can be induced in cancer in response to chemotherapy damage, and
several pharmacological studies are underway to prevent autophagy, mainly by using CQ
or HCQ. On the other hand, further investigations are currently ongoing to inhibit mTOR
signaling, which can activate the tumor suppressor mechanism of autophagy [131].

EMT governs the most lethal aspects of cancer and is therefore an attractive target
for cancer therapy. Although specific targeting of EMT-related molecules in clinics is chal-
lenging, recent studies have identified various metabolic and autophagy-related pathways
involved in EMT. It has been proposed that using drugs that are FDA approved or currently
tested in clinical trials and are active in metabolism and/or autophagy could represent
a valid repurposing strategy to target EMT in cancer [132]. Metabolism-inhibiting drugs
or autophagy modulators may be used with standard chemo- or immunotherapy to treat
EMT-driven resistant and aggressive cancers.

Recent observations have unveiled complex interactions between autophagy and EMT.
Previous investigations have revealed that EMT-related molecules and signaling pathways
may activate autophagy. Several extracellular signals that induce EMT also activate au-
tophagy, such as the Wnt/β-catenin, TGF-β, HIF-1α, and Notch signaling pathways [133].
Intriguingly, autophagy is implicated in the regulation of EMT, mainly through the ac-
tivation of energy response pathways, triggering EMT-inducing signaling pathways or
controlling the degradation of EMT-related adhesion and cytoskeletal molecules as well as
EMT-TFs [134–137]. Due to its multifaceted function in tumor formation and development,
autophagy’s impact on EMT is debatable and highly dependent on the type of cell and
tissue, stage of tumor, and the metabolic and microenvironmental inputs that modulate
this process [138].

Autophagy has been shown to promote EMT in certain contexts. For example, au-
tophagy has been reported to promote EMT in breast cancer cells by activating the TGF-
β/Smad signaling pathway [90,135]. Autophagy can act as a pro-tumor process by provid-
ing the highly invasive and metastatic cancer cells with their energy needs [133,139]. In this
regard, it has been demonstrated that an EMT-like phenotype occurs alongside a greater
autophagy flux [140]. The pro-survival function of autophagy against cell apoptosis cues
resulting from alterations to adhesion and cytoskeleton remodeling may be the driving
factor for the metastatic process [138]. Thus, inhibiting autophagy in several types of
cultured cancer and non-cancerous cells may block EMT [141]. An enhancement in EMT
inhibition has been demonstrated in renal cancer cells when combining the autophagy
blocker CQ and the typical chemotherapy treatment [140]. In another study, it has been
reported that CQ reverses paclitaxel resistance and reduces metastatic potential in A549
lung cancer cells via ROS-mediated regulation of the β-catenin pathway [142].

Conversely, a number of studies suggest that autophagy may also interfere with metastatic
dissemination, acting as a tumor suppressor mechanism, and that cancer cells may be
prevented from acquiring an EMT-like phenotype by activating autophagy [143–145]. Re-
cent studies suggest that autophagy induction by mTOR inhibitors, bioactive molecules,
or environmental stresses could revert the EMT phenotype in several in vitro and in vivo



Cancers 2024, 16, 807 14 of 31

models [141,146–148]. A study by Catalano et al. demonstrated a molecular shift from a mes-
enchymal to an epithelial-like phenotype in GBM cell lines by overstimulation of autophagy
following energy starvation or mTOR inhibition. This phenotypic change drastically affected
migration and chemokine-mediated invasion, providing a further rationale for including
autophagy modulators in the current therapeutic regimen of GBM patients. At the molec-
ular level, a down-regulation of key EMT-TFs, such as Slug and Snail, was observed upon
autophagy induction, and consequently, a transcriptional and translational up-regulation of
N- and R-Cadherins expressed in the neural tissue [149].

In addition to its role in regulating EMT, autophagy has also been implicated in the
maintenance of stemness in cancer cells. CSCs have been shown to be in an EMT-like
state. Autophagy has been reported to promote the maintenance of stemness in CSCs by
suppressing some EMT-like features. In breast cancer cells, the inhibition of autophagy
leads to the induction of EMT and the loss of stem-like properties [43,150]. On the other
hand, the regulatory role of the EMT process on autophagy has been revealed through
inducing metabolic alterations or modulating the expression of autophagy-related genes
mediated by EMT-TFs [151–153].

In the following sections, we delve into the complex regulatory mechanisms and
the interplay of signaling pathways regulating autophagy and EMT in cancer, as well
as their significance during tumor progression and metastasis. We also explore how the
degradation of EMT-related markers by the autophagolysosomal system affects phenotypic
changes during EMT and its repercussions in cancer metastasis.

4.1. Common Signaling Pathways That Regulate Both Autophagy and EMT

Recent studies have revealed a complex interplay between signaling pathways regulat-
ing EMT and autophagy. The EMT process is regulated by various molecular and cellular
signaling pathways, including Wnt, TGF-β, and Notch signaling, which have also been
shown to regulate autophagy.

One key pathway that has been implicated in the interplay between EMT and au-
tophagy is the Wnt/β-catenin signaling pathway [154]. Wnt signaling is a critical regulator
of EMT and has been shown to promote the mesenchymal phenotype in cancer cells. In
addition, Wnt signaling has also been shown to activate autophagy through the inhibition
of mTOR signaling [141]. This suggests that the activation of Wnt signaling during EMT
may promote both the mesenchymal phenotype and autophagy, which could have impor-
tant implications for cancer progression. Certain growth factors, which are responsible for
triggering EMT-specific TFs [155,156], are additional EMT-inducing cues that originate in
the tumor microenvironment. It has been demonstrated that the TGF-β signaling pathway
promotes the mesenchymal phenotype in cancer cells and is a crucial regulator of EMT.
To put it another way, TGF-β signaling has been shown to promote autophagy while also
inducing EMT [157]. TGF-β activates the AMPK pathway and inhibits the mTOR pathway,
which together induce autophagy [158]. However, the role of EGF and platelet-derived
growth factor (PDGF) in autophagy has also been described. In melanoma models and
vascular smooth muscle cells, they can lead to ERK1/2- and mitogen-activated protein
kinase )MAPK(-dependent autophagy pathways upon starvation [159,160].

Another important pathway involved in the interplay between EMT and autophagy is
the nuclear factor erythroid 2-related factor 2 )NRF2(/Kelch-like ECH-associated protein1
)Keap1( pathway [161]. This pathway is important for controlling how cells react to
oxidative stress and is connected to both EMT and autophagy. The activation of NRF2
signaling during EMT has been shown to promote the mesenchymal phenotype in cancer
cells, and may also promote autophagy through the upregulation of autophagy-related
genes [162]. Conversely, the inhibition of NRF2 signaling has been shown to promote the
reversal of EMT and the inhibition of autophagy in cancer cells [163].

Tumor Necrosis Factor-α (TNFα), which may facilitate EMT induction via the NF-κB
signaling pathway stimulation [164], leads to the expression of the proinflammatory cy-
tokine interleukin 6 (IL6) gene, which, in turn, activates autophagy in melanoma cells [165].



Cancers 2024, 16, 807 15 of 31

It has been found that NF-κB can directly regulate the transcription of EMT-TF genes in
human breast cancer cell lines [166]. NF-κB also may modulate autophagy. By directly
stimulating the expression of genes or proteins involved in the autophagosome such as
BECN1, ATG5, and LC3, IKK/NF-κB signaling may cause autophagy [167]. However, in
tumors such as Ewing sarcoma, breast, and promyelocytic leukemia, NF-κB induced by
TNF-α may repress autophagy via activation of mTOR pathway [168,169].

HIF-1α, which induces EMT and a metastatic phenotype through the regulation of
ZEB1 and Snail in colorectal and gastric cancer cells [170,171], also plays a key role in
autophagy regulation through the p27-E2F1 signaling pathway and ATG regulation under
hypoxic conditions [172,173].

Moreover, the Beclin-1 signaling pathway has been implicated in the interplay between
autophagy and EMT in cancer [174]. In fact, Beclin-1 is a key regulator of autophagy, and
functions as a part of the PI3K complex that is required for the initiation of autophagy [175].
Beclin-1 interacts with other proteins, including Bcl-2, to regulate the activation of au-
tophagy. Several studies have suggested that Beclin-1 may also play a role in the regulation
of EMT in cancer. For example, one study found that the expression of Beclin-1 was de-
creased in breast and thyroid cancer cells undergoing EMT, and that the overexpression
of Beclin-1 inhibited the EMT process [176,177]. This suggests that Beclin-1 may act as a
negative regulator of EMT in cancer cells. Conversely, other studies have suggested that
the upregulation of Beclin-1 may promote the mesenchymal phenotype in cancer cells. For
example, one study found that the overexpression of Beclin-1 induced EMT in HCC cells,
and the PI3K/AKT/mTOR pathway was activated to mediate this process [178,179].

In addition to these pathways, several other molecular mechanisms have been impli-
cated in the interplay between EMT and autophagy. These include the Hippo signaling
pathway, which has been shown to regulate both EMT and autophagy in cancer cells, and
the Notch signaling pathway, which has been implicated in the regulation of both EMT
and autophagy in a variety of cell types [133,180,181]. Based on evidence, IL-6/STAT3
(signal transducer and activator of transcription-3) signaling and integrin-focal adhesion
signaling are other known signaling pathways involved in the regulation of both EMT and
autophagy processes in cancer [139].

The interplay between EMT and autophagy has also been shown to play a role in
regulating the immune response, particularly in the context of cancer. In fact, EMT has
been shown to contribute to immune evasion by cancer cells [182]. During EMT, cancer
cells downregulate the expression of major histocompatibility complex (MHC) class I
molecules that are recognized by the immune system [183,184]. The downregulation of
cell surface molecules such as E-cadherin can help cancer cells evade immune recognition
and attack. Autophagy, on the other hand, has been shown to play a role in regulating the
immune response by modulating the presentation of antigens by MHC class II molecules.
Autophagy can promote the degradation of intracellular pathogens and the generation
of antigenic peptides that can be presented by MHC class II molecules to activate CD4+T
cells, a critical component of the immune response [185]. Moreover, autophagy has been
shown to modulate the activation of dendritic cells, which are key regulators of the immune
response. In summary, the interplay between EMT and autophagy is involved in the
regulation of the immune response, particularly in the context of cancer. In order to design
strategies for manipulating EMT and autophagy to improve the immune response to cancer,
more study is required to completely understand the molecular mechanisms behind this
interplay. Figure 3 indicates an overview of signaling pathways that regulate the interplay
between autophagy and EMT.

4.2. Autophagy Degradation of EMT-Related Markers

Autophagolysosomes and chaperone-mediated autophagy degradation of EMT-related
molecules has been investigated, revealing the presence of a complex oncogenic interplay
highly regulated between EMT and autophagy [136,186]. A number of studies highlight
that the selective degradation of key EMT-associated factors such as epithelial cell adhesion



Cancers 2024, 16, 807 16 of 31

proteins represents one of the main ways by which autophagy might influence EMT [187].
A schematic demonstration of different potential interplays between EMT and autophagy
is depicted in Figure 4.

Cancers 2024, 16, 807 3 of 6 
 

 

 

 
Figure 3. Overview of the EMT/MET process in the metastasis of epithelial cancer cells. Accumulat-
ing genetic mutations leads to abnormal cell proliferation and primary tumor formation. Upon ac-
tivation of specific signaling pathways and transcription factors, epithelial cancer cells undergo ep-
ithelial-to-mesenchymal transition (EMT). During this process, epithelial cells lose normal cellular 
junctions and apical-basal polarity and acquire migratory and invasive properties. Epithelial cells 
undergoing EMT can enter the lymphatic system or blood vessels, which disseminate them to dis-
tant sites. There, they can exit from the circulation and undergo the mesenchymal-to-epithelial tran-
sition (MET) process to form secondary tumors (colonization). TGF-β, transforming growth factor-
β; EGF, epidermal growth factor; α-SMA, α-smooth muscle actin; FSP-1, fibroblast-specific protein-
1; MMP, matrix metalloproteinase. 

 

Figure 3. Overview of the EMT/MET process in the metastasis of epithelial cancer cells. Accumulating
genetic mutations leads to abnormal cell proliferation and primary tumor formation. Upon activation
of specific signaling pathways and transcription factors, epithelial cancer cells undergo epithelial-to-
mesenchymal transition (EMT). During this process, epithelial cells lose normal cellular junctions
and apical-basal polarity and acquire migratory and invasive properties. Epithelial cells undergoing
EMT can enter the lymphatic system or blood vessels, which disseminate them to distant sites.
There, they can exit from the circulation and undergo the mesenchymal-to-epithelial transition
(MET) process to form secondary tumors (colonization). TGF-β, transforming growth factor-β;
EGF, epidermal growth factor; α-SMA, α-smooth muscle actin; FSP-1, fibroblast-specific protein-1;
MMP, matrix metalloproteinase.

Autophagy can promote EMT by degrading E-cadherin, a key epithelial marker [188].
The loss of epithelial polarity and the development of a mesenchymal phenotype are fa-
vored by the degradation of E-cadherin by autophagy. Damiano et al. found that autophagy
decreases the E-cadherin protein levels by transporting it to the autophagosome via the au-
tophagic cargo adaptor SQSTM1/p62 [189]. According to Zhou et al., plant homeodomain
finger protein 8 (PHF8) has an oncogenic function in HCC by accelerating FIP200-dependent
autophagic degradation of E-cadherin, which leads to EMT and metastasis [190]. This study
sheds light on the significance of E-cadherin autophagic degradation in HCC and suggests
PHF8 as a novel viable target for HCC therapy. In another study, it has been reported that
E-cadherin protein expression was decreased upon TGF-β1 treatment in mouse kidney
proximal tubular epithelial cells concomitantly with the increase in LC3-II, the autophagy
marker. Interestingly, the use of inhibitors of the autophagy–lysosomal pathway, including



Cancers 2024, 16, 807 17 of 31

ammonium chloride or CQ, was able to rescue TGF-β1-mediated E-cadherin degradation.
In contrast, the treatment of the proteasome inhibitor MG132 was not able to prevent the
TGF-β1-induced decrease in E-cadherin [191]. These findings point to a role for autophagy
in E-cadherin degradation in TGF-β1-induced EMT. The NAD-dependent deacetylase
sirtuin-1 (SIRT1) was found to induce EMT by promoting E-cadherin degradation via au-
tophagy and facilitating melanoma metastasis. SIRT1 boosted the autophagic breakdown
of E-cadherin by deacetylating Beclin-1. Furthermore, autophagy inhibition could rescue
E-cadherin protein levels and repressed cell migration and invasion by preventing the
degradation of E-cadherin in SIRT1-overexpressing cells [192].

Cancers 2024, 16, 807 4 of 6 
 

 

 
Figure 4. Schematic illustration of the interplay between signaling pathways regulating EMT and 
autophagy. 

  

Figure 4. Schematic illustration of the interplay between signaling pathways regulating EMT
and autophagy.

Differently from SIRT1, inhibition of deacetylase 1 (HDAC1) by MS-275 was demon-
strated to promote EMT reversal and at the same time to induce autophagy [193,194].

According to Xu et al., E-cadherin stability could also be influenced by tripartite motif-
containing 29 (TRIM29), which has been shown to lead its autophagic degradation through
Beclin-1 in HTB-182 and NCL-H1915 lung squamous carcinoma cell lines. E-cadherin
degradation by TRIM29 could finally boost the EMT program, which enhances migration
and invasion in cellular models [195].

Although autophagic degradation of E-cadherin may enhance the activation of the
EMT program, other studies have shown the role of autophagy in regulating the degrada-
tion of EMT inducers, such as mediators of EMT-related signaling pathways, ECM, and
cytoskeleton-related proteins, as well as EMT-TFs, which may limit the metastatic potential
of cancer cells.

The Wnt/β-catenin signaling pathway is frequently up-regulated in colorectal
tumors [196,197]. β-catenin forms complexes with the TCF/LEF family of TFs to regulate
target gene expression [198]. A number of studies attribute a key role to the Wnt/β-catenin



Cancers 2024, 16, 807 18 of 31

pathway for the induction of the EMT program in different models and upon several stress
conditions [199,200]. During nutrient deprivation, β-catenin can be selectively targeted for
autophagy clearance following the formation of a β-catenin–LC3 complex which impedes
the β-catenin /TCF-driven transcription required for metabolic stress adaptation [201,202].
In GBM cells, autophagy has been reported to negatively regulate the Wnt/β-catenin
signaling pathway by promoting β-catenin delocalization intracellularly, mainly to sub-
membrane regions which, in turn, limits the nuclear translocation of β-catenin [203]. On
the other hand, Wnt/β-catenin may also repress autophagy and p62 expression, suggesting
the existence of a regulatory feedback mechanism [201].

The ECM glycoprotein fibronectin1 (FN1) is known as a key marker of EMT and
metastasis, which can facilitate tumorigenesis [204,205]. It has been demonstrated in
HNSCC that upregulation of FN1 is correlated with poor prognosis and a high tumor
grade [206]. In a human oral squamous carcinoma cell line (SCC-25), it was shown that
inducers of autophagy, such as rapamycin and Earl’s balanced salt solution (EBSS), lead
to increased degradation of FN1. Conversely, the use of autophagy inhibitors, including
bafilomycin A1 (Baf A1), 3-MA and CQ, leads to reduced degradation of FN1. X Liu et al.
reported the mechanism of p62/SQSTM1-mediated autophagy–lysosomal degradation of
FN1 in HNSCC [188].

Vimentin is a mesenchymal marker involved in cytoskeletal organization and focal
adhesion turnover and strongly correlates to tumorigenesis and EMT induction [207,208].
The autophagy adapter protein SQSTM1/p62 has been shown to be overexpressed in breast
cancer, and this protein is considered as a metastasis-related protein [209]. P62/SQSTM1
has been reported to bind to and stabilize vimentin, which in turn promotes cancer cell
invasion and metastasis. Notably, depletion of p62/SQSTM1 can downregulate vimentin
protein expression independent of the ubiquitin–proteasome pathway [210], suggesting a
possible role for the autophagy–lysosomal pathway in vimentin degradation.

4.3. Reciprocal Regulation between Autophagy and EMT-TFs

The main mechanism by which autophagy regulates EMT is the control of EMT-TF
degradation. The expression of EMT-TFs is tightly regulated. These TFs are constitutively
expressed in the early phases of life (i.e., during embryogenesis) whereas in adult life
their expression is strictly regulated and is induced by specific physio-pathologic stimuli.
EMT-TFs are the key drivers of tumor metastasis, and their high expression is associated
with a poor prognosis in cancer [85]. These factors have generally a brief half-life, and they
may undergo degradation by autophagy [133,211].

Twist1 induces the loss of E-cadherin-mediated cell–cell adhesion, facilitating EMT [212].
Zada et al. reported that starvation-induced autophagy led to Snail protein degradation,
thus counteracting EMT and limiting the metastatic potential in cancer cells. They also de-
scribed that Snail was physically associated and colocalized with LC3 and SQSTM1, and that
ATG7 knockdown inhibited autophagy-induced Snail degradation [136]. In a similar work,
autophagy has been described to degrade Snail under hypoxia conditions in human cardiac
microvascular endothelial cells, suggesting a cytoprotective role for autophagy to prevent
cardiac fibrosis [213]. According to Grassi et al., in a liver non-tumor cellular system, au-
tophagy may promote the turnover of Snail in a p62/SQSTM1-dependent manner, impairing
EMT progression. On the other hand, the authors reported that TGF-β-induced EMT also
affects the autophagic flux, suggesting that both processes participate in a complex interplay
to regulate the plasticity of hepatocytes [214]. In another study, inhibition of autophagy
activated the NF-κB/Snail pathway and induced EMT under the control of SQSTM1/p62 in
RAS mutated cancer cells [215]. It was shown that induction of autophagy in neuroblastoma
cells may reverse EMT, inhibiting migration and invasion by downregulating Snail and Slug.
Conversely, the genetic silencing of BECLIN1, an autophagy initiator, led to upregulation of
Snail and Slug and increased migration ability [149].

It has been reported that death-effector domain-containing DNA-binding protein
(DEDD), a key effector molecule for cell death signaling receptors, can interact with



Cancers 2024, 16, 807 19 of 31

PI3KC3/Beclin1 to activate autophagy in breast cancer cells, which induces the degra-
dation of Snail and Twist [187]. NOTCH1 intracellular C-terminal domain (NICD) is a
transcriptional regulator which takes part in the highly complex transcriptional network
regulating EMT mediators, including Snail, ZEB1, and N-cadherin [216] and its inhibition
suppresses cancer progression in different models [217,218]. In a very recent study, it has
been shown that activating the autophagy lysosomal pathway leads to the degradation
of NICD and Snail via physical and functional interactions with SQSTM1/p62 and LC3
in cancer cells. Hence, important EMT mediators such as NICD and Snail may be coordi-
nately regulated by autophagy, and using drugs inducing autophagy could prevent EMT
induction as a therapeutic strategy [219].

Thus, in these experimental systems, EMT is negatively regulated by autophagy.
As a result, autophagy inhibition can potentially enhance invasiveness and chemoresis-
tance, which is relevant when considering that autophagy induction is a promising tool in
cancer therapy.

However, in other experimental conditions, autophagy may promote EMT by affecting
the EMT-TFs. BECN1-induced autophagy was shown to accelerate EMT through increased
expression of Twist and vimentin, and was suggested with other autophagy modulators as
an independent prognostic biomarker in patients with gastric cancer, colorectal carcinoma,
and liver cancer [133,220,221]. Several studies have reported that autophagy plays a role in
regulating EM T by modulating the activity of EMT-inducing TFs, such as Snail, Twist, and
ZEB1. In particular, increased autophagy may favor EMT-TFs activity. Increased acetyl-
coenzyme A (acetyl-CoA) generated during autophagy may stabilize Snail by acetylation,
facilitating invasion and metastasis of KRAS-LKB1 co-mutated lung cancer cells [222]. Au-
tophagy has also been shown to promote the nuclear localization of Twist, by degrading its
negative regulator glycogen synthase kinase 3β (GSK3β) [223,224]. The nuclear localization
of Twist promotes the expression of EMT-related genes, leading to the induction of EMT.

Thus, EMT regulation by autophagy is contextual: according to different experimental
systems, autophagy may both inhibit or promote the induction of the EMT program
(Figure 5).

Cancers 2024, 16, 807 5 of 6 
 

 

 

 
Figure 5. Schematics showing how autophagy might influence EMT and mediators of EMT-related 
signaling pathways. 

  

Figure 5. Schematics showing how autophagy might influence EMT and mediators of EMT-related
signaling pathways.



Cancers 2024, 16, 807 20 of 31

On the other hand, the EMT process has also been shown to regulate autophagy. The
loss of epithelial polarity and the acquisition of a mesenchymal phenotype during EMT can
lead to metabolic changes that activate autophagy to maintain cellular homeostasis [151]. It
has been reported that EMT-TFs may play a role in regulating the autophagy process. Twist
TF, which is a key regulator of EMT, has been shown to induce autophagy by activating
the AMPK pathway and inhibiting the mTOR pathway [152]. Moreover, the EMT process
can also regulate autophagy by modulating the expression of autophagy master genes. It
was demonstrated that under energy stress, Slug is transcriptionally activated by FOXO3
and by interacting with FOXO3 increases the binding affinity of FOXO3 to its response
elements and promotes the expression of autophagy-associated genes such as PIK3CA and
unc-51-like autophagy activating kinase 1 (ULK1) in Hela cells [225]. However, Snail has
been reported to repress the expression of the autophagy-related gene ATG5, leading to the
inhibition of autophagy [153].

Overall, autophagy and EMT may interact at multiple crossroads and their interre-
lation appears to be contextual depending on the specific experimental system analyses.
This is a concern when the translational applications of these discoveries are considered
(Figure 6).

Cancers 2024, 16, 807 6 of 6 
 

 

 
Figure 6. The complex interplay between autophagy and EMT makes their connection context-de-
pendent; (A) autophagy induction prevents EMT induction, which is considered as a therapeutic 
strategy by decreasing the invasiveness and metastatic activity of cancer cells; while on the other 
hand, (B) autophagy may promote EMT by affecting the EMT-inducing transcription factors (EMT-
TFs) such as Twist or Snail, and thus could be considered as a cancer biomarker. 

Figure 6. The complex interplay between autophagy and EMT makes their connection context-
dependent; (A) autophagy induction prevents EMT induction, which is considered as a therapeutic
strategy by decreasing the invasiveness and metastatic activity of cancer cells; while on the other hand,
(B) autophagy may promote EMT by affecting the EMT-inducing transcription factors (EMT-TFs)
such as Twist or Snail, and thus could be considered as a cancer biomarker.

4.4. Clinical Relevance of Interplay between EMT and Autophagy

The exploration of the EMT-autophagy axis in cancer therapy is significantly illu-
minated by diverse studies, each highlighting the variability in treatment effectiveness
tied to this complex interplay. For instance, in colorectal cancer, the intricate relationship
between EMT and the emergence of drug-resistant cancer stem-like cells is established,
implicating a key molecular axis that governs chemotherapy resistance and metastasis [226].
Additionally, in colon cancer, the role of phosphorylated c-Fos in conferring resistance to
5-Fluorouracil through stem cell-related pathways presents a novel therapeutic target [227].



Cancers 2024, 16, 807 21 of 31

The potential of metabolism-specific inhibitors to address EMT-driven chemoresistance
underscores a strategic complement to conventional treatments [132]. Furthermore, in
breast cancer, the link between (N-myc and STAT interactor) NMI expression, autophagy,
and enhanced sensitivity to cisplatin through specific molecular pathways exemplifies the
nuanced influence of these biological processes on therapeutic outcomes [228]. Recent
studies have made significant strides in identifying prognostic biomarkers associated with
EMT and autophagy in various cancers. A study on endometrial cancer (EC) developed
a four-gene signature (SIRT2, SIX1, CDKN2A, and PGR) for predicting patient progno-
sis, emphasizing the role of EMT in cancer progression [229]. Similarly, colorectal cancer
(CRC) research identified 11 key autophagy-related genes as part of a prognostic model,
showcasing the potential of autophagy markers in predicting treatment outcomes [230].
Studies on GBM highlighted Epithelial membrane protein 3 (EMP3) as a significant factor
in promoting malignancy and as an independent prognostic factor for patient survival,
linking it to the EMT process [231]. In the case of human epidermal growth factor receptor
2 positive (HER2+) breast cancer, Gasdermin B (GSDMB) overexpression was found to
be associated with increased resistance to therapy and aggressive tumor behavior, indi-
cating its role in protective autophagy [232]. Emerging research in targeted therapies has
demonstrated promising strategies that modulate the EMT-autophagy pathway in cancer
treatment. For instance, a study has developed a targeted nano-system that induces ER
stress and autophagy in breast cancer, implying that enhancing autophagy can significantly
reduce metastasis and improve immune response [233]. Another research on melanoma
revealed that alteronol induces apoptosis and inhibits EMT, and its effects are potentiated
when combined with an autophagy inhibitor, suggesting a novel treatment approach [157].
Additionally, the complex roles of autophagy in melanoma, especially in the tumor mi-
croenvironment, have been highlighted, suggesting careful consideration of autophagy
manipulation in cancer therapy [234]. Lastly, a study on gastric cancer found that CD13
inhibition using Ubenimex overcomes cisplatin resistance by suppressing autophagy and
EMT, offering a potential new therapeutic strategy [235].

In conclusion, this research underscores a pivotal shift towards personalized cancer
treatments, informed by the nuanced interplay between EMT and autophagy. This evolving
understanding is crucial for refining cancer therapy, offering prospects for more effective,
patient-specific strategies. The significance of these context-dependent associations in
various cancers is becoming increasingly clear, highlighting the importance of tailoring
treatments to individual EMT-autophagy dynamics. Such an approach could lead to
enhanced therapeutic efficacy and reduced side effects, marking a promising direction for
future clinical research and strategy development in oncology.

5. Conclusions

The intricate interplay between autophagy and EMT has been spotlighted as a paramount
regulator in cancer progression, metastasis, and therapeutic resistance. While autophagy
traditionally serves as a cell survival mechanism during stress, its dual role in promoting
or inhibiting EMT reflects the adaptive and context-dependent nature of tumor cells. This
duality is also mirrored in the function of EMT-TFs, which depending on the cellular context,
can either promote or inhibit autophagy.

Recent findings have underscored the importance of understanding the reciprocal
regulation between EMT and autophagy. The ability of the autophagy pathway to se-
lectively degrade key EMT-related markers, such as E-cadherin, can influence cellular
adherence and migration properties. Conversely, EMT-TFs like Twist1, Snail, and Slug
can dictate autophagy rates, emphasizing a feedback mechanism that harmonizes cellular
transformation and survival processes.

The notion that autophagy can both suppress and facilitate EMT in different settings
underscores the importance of context. Factors like cellular environment, tumor type,
metabolic status, and specific stimulatory cues can sway the balance in favor of either EMT



Cancers 2024, 16, 807 22 of 31

promotion or inhibition. Similarly, EMT-TFs can act as arbiters, modulating autophagy in
response to cellular needs.

Importantly, therapeutic interventions targeting autophagy or EMT require a nuanced
understanding of this relationship. While inhibiting autophagy might seem beneficial in
contexts where it supports EMT and metastasis, such strategies could inadvertently bolster
tumor growth in scenarios where autophagy serves as a brake on EMT. This complexity
indicates that patient-specific factors, including tumor type, stage, and genetic makeup,
should guide therapeutic decisions.

In summary, the bidirectional relationship between autophagy and EMT represents
a dynamic axis in cancer biology. The intricate balance maintained by these processes
determines the course of tumorigenesis and metastasis. A deeper, more comprehensive
understanding of this relationship promises not only insights into fundamental tumor
biology but also offers a roadmap for devising targeted and effective therapeutic strategies.
Future research endeavors must prioritize unraveling this relationship in diverse cellular
contexts and exploring its therapeutic implications for better patient outcomes.

6. Future Directions

Understanding the role of autophagy in the progression of cancer cells remains a
pivotal area of exploration. The identification of how autophagy links with EMT in highly
proliferative cancer cells could significantly deepen our knowledge about autophagy’s
contribution to both the initiation and progression of cancer. This is particularly crucial as
specific EMT markers may serve as novel therapeutic targets in cancers where autophagy
regulation plays a key role. Future research should focus on identifying these markers and
investigating their potential as targets for intervention. This approach could pave the way
for more effective, targeted cancer therapies, enhancing our ability to combat this complex
and multifaceted disease.

Author Contributions: Conceptualization, A.A. and M.C.; methodology, M.A. and R.N.-M.; software,
M.A., R.N.-M., A.K. and A.Z. validation, R.S., A.A. and M.C.; resources, A.A. and M.C.; data curation,
R.S.; writing—original draft preparation, M.A., R.N.-M. and A.A.; writing—review and editing,
A.A., R.S. and M.C.; visualization, R.S.; supervision, A.A.; project administration, A.A. and M.C.;
funding acquisition, A.A. and M.C. All authors have read and agreed to the published version of
the manuscript.

Funding: This study was financially supported by research grant #4002451 provided to Prof. Ab-
dolamir Allameh by The Elite Research Committee of the NIMAD (National Institute for Medical
Research Development), the Ministry of Health and Medical Education, I.R. Iran. Marco Cordani
is supported with a Ramon y Cajal grant (RYC2021–031003-I) from the Spanish Ministry of Science
and Innovation, Agencia Estatal de Investigación (MCIN/AEI/10.13039/501100011033), and Euro-
pean UnionNextGeneration (EU/PRTR). Raffaele Strippoli was supported by a research grant from
the Italian ministry of University and Research (MIUR) P2022XZKBM financed by the European
Union NextGeneration.

Conflicts of Interest: The authors declare no conflicts of interest.

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	Introduction: The Fate of Normal and Transformed Cells 
	Autophagy and Cancer 
	Role of Autophagy in Cancer Development and Progression 
	Role of Autophagy in Cancer Stem Cell Maintenance 
	Autophagy as a Therapeutic Target in Cancer 

	Cell Transformation, EMT and Carcinogenesis 
	Morphological, Biochemical and Molecular Changes during EMT 
	Role of EMT in Tumor Invasion and Metastasis 
	EMT as a Target in Cancer Therapy and Drug Resistance 

	Autophagy-EMT Interplay 
	Common Signaling Pathways That Regulate Both Autophagy and EMT 
	Autophagy Degradation of EMT-Related Markers 
	Reciprocal Regulation between Autophagy and EMT-TFs 
	Clinical Relevance of Interplay between EMT and Autophagy 

	Conclusions 
	Future Directions 
	References