Person:
Molina Martín, María

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First Name
María
Last Name
Molina Martín
URI
https://hdl.handle.net/20.500.14352/77573
Affiliation
Universidad Complutense de Madrid
Faculty / Institute
Farmacia
Department
Microbiología y Parasitología
Area
Microbiología
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UCM identifierORCIDScopus Author IDWeb of Science ResearcherIDDialnet IDGoogle Scholar ID

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2015 - 201922020 - 20232
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Author: Jiménez Cid, Víctor × Subject: 579 ×

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Now showing 1 - 4 of 4
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    A global analysis of the reconstitution of PTEN function by translational readthrough of PTEN pathogenic premature termination codons
    (Human mutation, 2021) Luna, Sandra; Torices, Leire; Mingo, Janire; Amo, Laura; Ruiz‐Ibarlucea, Pablo; Erramuzpe, Asier; Cortés, Jesús M.; Tejada, María I.; Nunes‐Xavier, Caroline E.; López, José I.; Pulido, Rafael; Rodríguez Escudero, María Isabel; Jiménez Cid, Víctor; Molina Martín, María
    The PTEN tumor suppressor gene is mutated with high incidence in tumors and in thegermline of patients with cancer predisposition or with macrocephaly associatedwith autism.PTENnonsense mutations generating premature termination codons (PTC)and producing nonfunctional truncated PTEN proteins are frequent in association withhuman disease. However, there are no studies addressing the restoration of full‐lengthPTEN proteins from the PTC‐mutatedPTENgene by translational readthrough. Here,we have performed a global translational and functional readthrough analysis of thecomplete collection ofPTENPTC somatic or hereditary mutations found in tumors or inthegermlineofpatients(disease‐associated PTEN PTCome), and we set standards forthe analysis of the potential of readthrough functional reconstitution in disease‐relevant genes. Our analysis indicates that prevalent pathogenicPTENPTC mutationsare susceptible to PTEN functional restoration in response to readthrough‐inducingcompounds. Comprehensive readthrough analyses of disease‐associated PTComes willbe valuable tools for the implementation of readthrough‐based precision interventionsin specific groups of patients
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    Educating in antimicrobial resistance awareness: adaptation of the Small World Initiative program to service-learning.
    (FEMS Microbiology Letters, 2018) Valderrama Conde, María José; González Zorn, Bruno; Calvo De Pablo, Pilar; Díez Orejas, Rosalía María; Fernández-Acero Bascones, Teresa; Gil Serna, Jessica; Juan Ferré, Lucía De; Martín Brieva, Humberto; Molina Martín, María; Navarro García, Federico; Patiño Álvarez, Aurora Belén; Pla Alonso, Jesús; Prieto, Daniel; Rodríguez Fernández, Carmina; Román González, Elvira; Sanz Santamaría, Ana Belén; Silóniz Jiménez, María Isabel De; Suárez Rodríguez, Mónica; Vázquez Estévez, María Covadonga Inmaculada; Jiménez Cid, Víctor
    The Small World Initiative (SWI) and Tiny Earth are a consolidated and successful education programs rooted in the USA that tackle the antibiotic crisis by a crowdsourcing strategy. Based on active learning, it challenges young students to discover novel bioactive-producing microorganisms from environmental soil samples. Besides its pedagogical efficiency to impart microbiology content in academic curricula, SWI promotes vocations in research and development in Experimental Sciences and, at the same time, disseminates the antibiotic awareness guidelines of the World Health Organization. We have adapted the SWI program to the Spanish academic environment by a pioneering hierarchic strategy based on service-learning that involves two education levels (higher education and high school) with different degrees of responsibility. Throughout the academic year, 23 SWI teams, each consisting of 3-7 undergraduate students led by one faculty member, coordinated off-campus programs in 22 local high schools, involving 597 high school students as researchers. Post-survey-based evaluation of the program reveals a satisfactory achievement of goals: acquiring scientific abilities and general or personal competences by university students, as well as promoting academic decisions to inspire vocations for science- and technology-oriented degrees in younger students, and successfully communicating scientific culture in antimicrobial resistance to a young stratum of society.
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    A trans-kingdom T6SS effector induces the fragmentation of the mitochondrial network and activates innate immune receptor NLRX1 to promote infection
    (Nat. Commun., 2023) Sá-Pessoa, Joana; López-Montesino, Sara; Przybyszewska, Kornelia; Marshall, Helina; Ova, Adelia; Schroeder, Gunnar N; Barabas, Peter; Curtis, Tim; Bengoechea, Jose A; Rodríguez Escudero, María Isabel; Jiménez Cid, Víctor; Molina Martín, María
    Bacteria can inhibit the growth of other bacteria by injecting effectors using a type VI secretion system (T6SS). T6SS effectors can also be injected into eukaryotic cells to facilitate bacterial survival, often by targeting the cytoskeleton. Here, we show that the trans-kingdom antimicrobial T6SS effector VgrG4 from Klebsiella pneumoniae triggers the fragmentation of the mitochondrial network. VgrG4 colocalizes with the endoplasmic reticulum (ER) protein mitofusin 2. VgrG4 induces the transfer of Ca2+ from the ER to the mitochondria, activating Drp1 (a regulator of mitochondrial fission) thus leading to mitochondrial network fragmentation. Ca2+ elevation also induces the activation of the innate immunity receptor NLRX1 to produce reactive oxygen species (ROS). NLRX1-induced ROS limits NF-κB activation by modulating the degradation of the NF-κB inhibitor IκBα. The degradation of IκBα is triggered by the ubiquitin ligase SCFβ-TrCP, which requires the modification of the cullin-1 subunit by NEDD8. VgrG4 abrogates the NEDDylation of cullin-1 by inactivation of Ubc12, the NEDD8-conjugating enzyme. Our work provides an example of T6SS manipulation of eukaryotic cells via alteration of the mitochondria.
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    A functional dissection of PTEN N-terminus: implications in PTEN subcellular targeting and tumor suppressor activity.
    (PloS one, 2015) Gil, Anabel; Rodríguez Escudero, María Isabel; Stumpf, Miriam; Molina Martín, María; Jiménez Cid, Víctor; Pulido, Rafael
    Spatial regulation of the tumor suppressor PTEN is exerted through alternative plasma membrane, cytoplasmic, and nuclear subcellular locations. The N-terminal region of PTEN is important for the control of PTEN subcellular localization and function. It contains both an active nuclear localization signal (NLS) and an overlapping PIP2-binding motif (PBM) involved in plasma membrane targeting. We report a comprehensive mutational and functional analysis of the PTEN N-terminus, including a panel of tumor-related mutations at this region. Nuclear/cytoplasmic partitioning in mammalian cells and PIP3 phosphatase assays in reconstituted S. cerevisiae defined categories of PTEN N-terminal mutations with distinct PIP3 phosphatase and nuclear accumulation properties. Noticeably, most tumor-related mutations that lost PIP3 phosphatase activity also displayed impaired nuclear localization. Cell proliferation and soft-agar colony formation analysis in mammalian cells of mutations with distinctive nuclear accumulation and catalytic activity patterns suggested a contribution of both properties to PTEN tumor suppressor activity. Our functional dissection of the PTEN N-terminus provides the basis for a systematic analysis of tumor-related and experimentally engineered PTEN mutations.