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ORIGINAL RESEARCH
published: 01 September 2021

doi: 10.3389/fphys.2021.716473

Edited by: 
Trevor Chung-Ching Chen, 

 National Taiwan Normal University, 
Taiwan

Reviewed by: 
Rodolfo Paula Vieira,  

Brazil University,  
Brazil

Sven-Jean Tan, 
 Royal Melbourne Hospital, Australia

Leonardo Coelho Rabello de Lima, 
Centro Universitário Herminio Ometto 

de Araras, Brazil

*Correspondence: 
Thomas Yvert  

thomaspaul.yvert@universidadeuropea.es; 
tamara.iturriaga@gmail.com

Specialty section: 
This article was submitted to  

Exercise Physiology,  
a section of the journal  
Frontiers in Physiology

Received: 28 May 2021
Accepted: 03 August 2021

Published: 01 September 2021

Citation:
Iturriaga T, Yvert T, 

Sanchez-Lorente IM, Diez-Vega I, 
Fernandez-Elias VE, 
Sanchez-Barroso L, 

Dominguez-Balmaseda D, Larrosa M, 
Perez-Ruiz M and Santiago C (2021) 

Acute Impacts of Different Types of 
Exercise on Circulating α-Klotho 

Protein Levels.
Front. Physiol. 12:716473.

doi: 10.3389/fphys.2021.716473

Acute Impacts of Different Types of 
Exercise on Circulating α-Klotho 
Protein Levels
Tamara Iturriaga 1, Thomas Yvert 1*, Isabel M. Sanchez-Lorente 1, Ignacio Diez-Vega 1,2, 
Valentin E. Fernandez-Elias 1, Lara Sanchez-Barroso 3,4, Diego Dominguez-Balmaseda 1, 
Mar Larrosa 4, Margarita Perez-Ruiz 1,5 and Catalina Santiago 1

1 Faculty of Physical Activity, Sport Sciences and Physiotherapy, Universidad Europea de Madrid, Madrid, Spain, 
2 Departamento de Enfermería y Fisioterapia, Facultad de Ciencias de la salud, Universidad de Leon, Ponferrada, Spain, 
3 Facultad de Enfermería, Fisioterapia y Podología, Universidad Complutense de Madrid, Madrid, Spain, 4 Faculty of 
Biomedical and Health Sciences, Universidad Europea de Madrid, Madrid, Spain, 5 Servicio de Medicina Física y 
Rehabilitación, Hospital General Universitario Gregorio Marañón, Instituto de Investigación Sanitaria Gregorio Marañón, 
Madrid, Spain

Introduction: Elevated plasma α-klotho (αKl) protects against several ageing phenotypes 
and has been proposed as a biomarker of a good prognosis for different diseases. The 
beneficial health effects of elevated plasma levels of soluble αKl (SαKl) have been likened 
to the positive effects of exercise on ageing and chronic disease progression. It has also 
been established that molecular responses and adaptations differ according to exercise 
dose. The aim of this study is to compare the acute SαKl response to different exercise 
interventions, cardiorespiratory, and strength exercise in healthy, physically active men 
and to examine the behavior of SαKl 72 h after acute strength exercise.

Methods: In this quasi-experimental study, plasma SαKl was measured before and after 
a cardiorespiratory exercise session (CR) in 43 men, and strength exercise session (ST) 
in 39 men. The behavior of SαKl was also examined 24, 48, and 72 h after ST.

Results: Significant differences (time × group) were detected in SαKl levels (p = 0.001; 
d = 0.86) between CR and ST. After the ST intervention, SαKl behavior varied significantly 
(p = 0.009; d = 0.663) in that levels dropped between pre- and post-exercises (p = 0.025; 
d = 0.756) and were also significantly higher compared to pre ST values at 24 h (p = 0.033; 
d = 0.717) and at 48 h (p = 0.015; d = 0.827).

Conclusions: SαKl levels increased in response to a single bout of cardiorespiratory 
exercise; while they decreased immediately after strength exercise, levels were elevated 
after 24 h indicating different klotho protein responses to different forms of exercise.

Keywords: klotho, biomarker, physical condition, endurance exercise, strength exercise

INTRODUCTION

The αKlotho (αKl) gene was discovered in 1997 by Kuro-o et  al. (1997). In a study in mice, these 
authors found that a mutation in the αKl gene caused typical symptoms of rapid ageing such as 
sarcopenia, low bone mineral density, and skin atrophy (Kuro-o et  al., 1997). More recent studies 
have focused on the molecular mechanisms of action of this protein (Xu and Sun, 2015), and its 

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usefulness as a prognostic biomarker for several diseases including 
cardiovascular disease in patients with chronic kidney disease 
(Neyra and Hu, 2016), lung diseases (Kureya et  al., 2016; Pako 
et al., 2017), cancer (Kuro-o, 2019), and some autoimmune diseases 
(Guzmán-Silahua et  al., 2017). These studies have been consistent 
in revealing that the lower levels of αKl are linked to a worse 
disease prognosis. Low αKl levels have been also related to premature 
ageing (Felipe Salech et  al., 2012), systemic inflammation (Krick 
et  al., 2018), endothelial cell damage (Matsubara et  al., 2014), 
impaired cell regeneration and proliferation (Kuro-o, 2009; Welc 
et al., 2020), oxidative stress (Yamamoto et al., 2005), and abnormal 
bone mineral metabolism (Razzaque, 2012).

Exercise is an effective tool to treat and prevent many 
causes of morbidity and mortality associated with ageing 
(Cordero et  al., 2014) and chronic diseases (Ostman et  al., 
2017; Paneroni et  al., 2017; Qiu et  al., 2017). Depending on 
the training modality and dose, the adaptations produced 
vary widely (Egan and Zierath, 2013). Recently, exercise has 
been proposed as a good strategy to improve blood levels 
of SαKl as it seems to have increasing effects on muscle 
mass and decreasing ones on fat mass (Amaro-Gahete et  al., 
2019). Other studies have shown a direct relationship between 
physical fitness, as measured through maximal oxygen 
consumption, and SαKl levels, such that the plasma levels 
of protein are higher in both young and older people who 
are physically fitter (Matsubara et  al., 2014; Amaro-Gahete 
et  al., 2018). Avin et  al. even highlighted the similarity 
between the beneficial effects of high SαKl levels and exercise, 
namely improved resistance to oxidative stress, along with 
increased tissue regeneration, bone mass, angiogenesis, and 
endothelial cell protection (Avin et  al., 2014). Changes in 
plasma αKl levels could be  explained by the role of the 
klotho gene in molecular signaling pathways in muscle cells, 
acutely regulating the removal of reactive oxygen species 
(ROS) and chronically regulating the inflammatory process 
(Yamamoto et  al., 2005; Li et  al., 2016; Ji et  al., 2018), 
consistent with its proposed mechanisms of action in anti-
ageing effects. We also propose that exercise, dosage, intensity, 
and probably modality may be  important in the response 
of SαKl to exercise. Preliminary results have indicated that 
an acute session of moderate-high intensity cardiorespiratory 
exercise (>70% VO2max) produces a sustained increase in blood 
levels of SαKl (Mostafidi et al., 2016; Santos-Dias et al., 2017), 
possibly lasting up to 7 days after the exercise session (Tan 
et  al., 2018). In addition, several weeks of cardiorespiratory 
training seems to affect plasma SαKl concentrations irrespective 
of training intensity (low, moderate, or high; Avin et  al., 
2014; Matsubara et  al., 2014; Saghiv et  al., 2019). In contrast, 
an acute low-intensity intervention (40–55% VO2max) was 
found to elicit no change in this biomarker in both young 
and older individuals (Avin et  al., 2014).

Most investigations that have addressed the effects of 
exercise on levels of this protein have mainly focused on 
cardiorespiratory exercise. These studies have shown that 
individuals who regularly practice any activity with a high 
cardiorespiratory component have greater plasma levels of 
SαKl (Saghiv et  al., 2015a; Mostafidi et  al., 2016). 

However, few studies have examined the effects of strength 
training on SαKl (Semba et  al., 2012, 2015; Saghiv et  al., 
2017a) and the impacts of acute vs. chronic strength training 
interventions have not yet been explored. To date, however, 
there is a sufficient knowledge of molecular mechanisms 
triggered by strength training to suggest that this form of 
exercise could have a positive effect on SαKl. For example, 
it is known that strength exercise induces the release of 
insulin-like growth factor 1 (IGF-1; Adams, 1998) in the 
muscle cell, where it induces protein synthesis producing 
adaptations such as muscle fiber growth (Egan and Zierath, 
2013). To elicit these adaptations, exercise programs have 
been designed to prioritize eccentric efforts able to induce 
controlled muscle damage, such as plyometric training, thus 
triggering molecular pathways that lead to adaptations that 
are beneficial for both general and muscle health. Further, 
as does cardiorespiratory exercise, this metabolic activity 
generates ROS, but at a later time point (24–48 h after a 
training session). The controlled muscular damage that gives 
rise to ROS in the first hours of strength training is necessary 
for protein metabolism (Egan and Zierath, 2013). The buildup 
of ROS, before or after depending on the type of trigger 
produces sufficient oxidative stress to cause the deterioration 
of muscle cell. It is, at this point, that the role of SαKl 
protein seems critical. There are two possible mechanisms 
of cell resistance to oxidative stress mediated by SαKl: the 
first would be  IGF-1 receptor inhibition diminishing ROS 
production and, the second, Akt inhibition, would prevent 
the phosphorylation of FOXO (Forkhead box O) to activate 
the enzymes such as superoxide dismutase (SOD2; Kuro-o, 
2009; Papaconstantinou, 2009; Daneshgar and Dai, 2020).

Given this described association between SαKl and exercise 
in molecular terms along with the beneficial effects of both 
factors on some chronic conditions, this study sought to compare 
the effects of cardiorespiratory and strength exercise on levels 
of this protein. While it seems that both types of exercise 
could be  used as a tool to increase SαKl levels, the behavior 
of the protein after a strength intervention remains unknown. 
The aims of the present study were: (i) to compare the acute 
effects of cardiorespiratory vs. strength exercise on SαKl levels 
in healthy physically active men and (ii) to monitor SαKl 
levels over a 72-h period after a bout of strength exercise.

MATERIALS AND METHODS

Design and Sample
Our first aim was addressed in a quasi-experimental study 
with pre–post measurements, and our second aim in a 
single-arm trial. The study protocol adhered to the “Ethical 
Guidelines of the Declaration of Helsinki,” as last amended 
in 2013, and was approved by the Regional Clinical Research 
Ethics Committee of the Community of Madrid (CEIm-R. 
Reference number: 47/764390.9/17). All participants gave their 
written informed consent. Through a non-probabilistic 
convenience sampling approach, two independent groups of 
physically active men who had training experience in different 

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sports modalities were selected to establish two study groups: 
acute cardiorespiratory (CR) and acute strength (ST) exercise. 
Inclusion criteria were: (i) men aged 18–55 years, (ii) 
non-smokers, (iii) cardiorespiratory or strength training at 
least three times a week for 6 months or longer, and (iv) no 
musculoskeletal injuries sustained in the past 6 months. 
Exclusion criteria were: (i) a fitness level below a maximal 
oxygen consumption (V02max) of 40 ml/kg/min, (ii) exercise 
intervention not completed and/or blood samples not collected, 
and (iii) no informed consent given. According to these 
inclusion/exclusion criteria, 46 men from athletics and triathlon 
clubs were selected for the CR group and 45 men from 
different sports centers whose training was mainly strength-
based for the ST group. Three subjects in the CR group 
decided not to participate after reading the informed consent 
form. The remaining 43 men in this group underwent 
preliminary physical fitness and body composition tests. In 
all 43 subjects, V02max was above 40 ml/kg/min, and these 
individuals were selected for the acute cardiorespiratory exercise 
intervention. All completed the intervention and provided 
all required pre- and post-intervention blood samples. All 
45 subjects selected for the ST group decided, and they would 
participate in the study, and therefore, performed the pretest. 
Six of these individuals were excluded because of a V02max 
below 40 ml/kg/min, leaving 39 subjects in the acute strength 
exercise group. All completed the intervention and sampling 
protocol. Subjects in this ST group were also scheduled for 
additional sampling at 24, 48, and 72 h after the session to 
assess the behavior post-exercise of SαKl levels. The recruitment, 
tracking and analysis procedures are detailed in the flow 
chart (Figure  1).

Study Variable
Plasma SαKl
A blood sample was collected from the antecubital vein into 
a separating gel vacuum tube, centrifuged, and stored at −80°C 
until analysis using an enzyme-linked immunosorbent assay 
(ELISA) kit (Human Soluble Test Kit α-Klotho Immuno-
Biological Laboratories Co., Ltd., Japan). Assays were run in 
duplicate as double parallel tubes following the manufacturer’s 
recommendations. This procedure has an intra-assay coefficient 
of variation (CV) of 3.1% and an inter-assay CV of 6.9%, 
with a sensitivity of 6.15 pg/ml (Yamazaki et  al., 2010). The 
CV was ≤1.9% in all the samples.

Interventions
The CR intervention consisted of a 10-min warm-up at 55% 
of estimated V02max, a steady treadmill run at 75% of V02max 
lasting 30 min, and a cool down of 10 min of slow walking 
(Saghiv et al., 2015b). Blood samples were collected just before 
the start of the exercise intervention and just after the end 
of the intervention (Figure  2).

The main objective of the ST intervention was to induce 
controlled muscle damage through eccentric contractions at 
an intensity of >70% of the rate of perceived exertion (RPE) 
of each subject. The intervention consisted of a warm-up 
on a cycle ergometer for 10 min followed by a set of plyometric 
exercises: 100 jumps from a 60 cm box with dumbbells in 
each hand representing 10% of body weight; as soon as 
contact was made with the ground after each jump, the 
weights were dropped and a vertical jump was completed 
at maximum power. The session was structured as five sets 

FIGURE 1  |  Flow chart detailing the recruitment, tracking, and analysis of the study participants.

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of 20 jumps with 2 min rest intervals between sets and 10 s 
of rest between each jump and took approximately 1 hour 
to complete (Howatson et  al., 2012). Blood samples were 
collected at five time points: just before starting the exercise 
(Pre), just after finishing it (Post), and over the following 
3 days (24, 48, and 72 h; Figure 2). No other form of exercise 
was performed over the blood sampling period and the blood 
samples were taken between 9 and 11 AM for all 
the participants.

Baseline Subject Characteristics
This information is highly measured and analyzed to establish 
baseline parameters for comparison between both groups.

The demographic and clinical data collected were age in 
years, hours per week of exercise, musculoskeletal injuries in 
the last 6 months, and any pre-existing diseases.

Physical Fitness
This variable was recorded as VO2max on a treadmill ergo-
spirometer (analyzer: ULTIMA series, MEDGRAPHICS, 
Cardiorespiratory diagnostic; treadmill: Venus 200/75. h/p/
cosmos. Nussdorf-Traunstein, Germany) in an incremental 
protocol consisting of 3 min of warm-up at 7.7 km/h, followed 
by an increase of 0.3 km/h every 30 s until exhaustion, applying 
maximality criteria according to the procedure described by 
Casajús et  al. (2009).

Body Composition
Height and weight measured using a stadiometer and 
analogue scales (Ano Sayol SL, Barcelona, Spain, and Asimed 
T2, Barcelona, Spain, respectively). A Dual X-Ray 
Densitometry (DEXA) system (Hologic QDR Discovery, 
Bedford, MA, United  States) was used for the 8-min “full-
body” test (Plank, 2005). The variables recorded were: body 
mass index (BMI), body adipose index (BAI) as a percentage 
(%), appendicular skeletal muscle mass (ASM) in arms 
and legs as a whole, and visceral fat area (VFA) in square 
centimeters (cm2).

Statistical Analysis
For a final study population of 82 subjects, descriptive statistics 
are provided as the mean, standard deviation and confidence 
interval (95% CI) of each variable, reflecting the characteristics 
of the sample. For comparisons between the two interventions, 
a mixed ANCOVA (2×2) was used with age and V02max as 
covariates, as these two factors may affect SαKl levels (Avin 
et  al., 2014; Amaro-Gahete et  al., 2018). Post-hoc comparisons 
were carried out with Bonferroni correction. In the ST group, 
SαKl behavior was examined through repeated-measures ANOVA, 
comparing differences (at Post, 24, 48, and 72 h) with baseline 
levels (Pre) using a priori test of simple within-subject contrasts. 
The effect size was reported as Cohen’s d (d) and interpreted 
according to Cohen’s recommendations (Cohen, 1988). The 
accuracy of the SαKl values recorded was determined through 
CVs calculated for duplicates of each sample. All the statistical 
tests were performed using the package SPSS 20.1 for Windows. 
Significance was set at p < 0.05.

RESULTS

Participants had similar demographic and physiological 
characteristics (Table  1). Baseline SαKl values were 
1018.44 ± 237.24 pg/ml, and the mean CV between duplicates 
of all the samples was 1.74% (duplicate measures with a CV 
higher than 10% were not accepted).

When comparing the two exercise interventions, a significant 
time × group (t × g) interaction was found with a large effect 
size [F(1,78) = 14.476; p = 0.001; d = 0.86]. There was no significant 
time (t) effect [F(1,78) = 0.051; p = 0.821; d = 0.06] and no group 
(g) effect [F(1,78) = 2.409; p = 0.125; d = 0.35; Table  2], and non 
significant difference in Pre SαKl levels between CR and ST 
[F(1,78) = 0.033; p = 0.857; d = 0.59]. However, a significant 
difference in Post SαKl levels between the CR and ST groups 
was observed with a moderate effect size [F(1,78) = 8.995; 
p = 0.004; d = 0.7]. Further, in the CR group, a significant (Pre–
Post) increase in SαKl levels was produced with a large effect 
size [F(1,78) = 25.432; p = 0.001; d = 0.87] while in the ST group, 

FIGURE 2  |  Experimental design: acute cardiorespiratory (CR) and strength training (ST) interventions, and plasma SαKI determinations.

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levels dropped slightly, yet not significantly, after exercise and 
the effect size was small [F(1,78) = 1.712; p = 0.195; d = 0.37; 
Figure  3].

When the SαKl response to strength exercise was monitored 
over 72 h, significant changes were produced [F(4,152) = 4.182; 
p = 0.009; d = 0.663]. Thus, there was a significant decrease Pre- 
vs. Post-acute ST exercise (p = 0.025; d = 0.756) and significant 
increase between Pre vs. 24 h (p = 0.033; d = 0.717) and Pre vs. 
48 h (p = 0.015; d = 0.827; Figure  4).

DISCUSSION

To our knowledge, our study is the first to compare the 
immediate effects of an acute cardio-respiratory or strength 
exercise session on plasma SαKl levels, despite several randomized 
controlled trials of the klotho response to acute cardiorespiratory 
exercise (Saghiv et  al., 2015a; Santos-Dias et  al., 2017; 
Tan et al., 2018). Further, the literature contains only descriptive 

studies of this response to strength training as the main exercise 
component (i.e., weightlifters; long-distance runners vs. sprinters; 
Saghiv et al., 2017a,b) or studies correlating protein levels with 
limb strength (Semba et  al., 2012, 2015; Saghiv et  al., 2015a).

Our study is also the first to analyze the time course of 
plasma SαKl after strength exercise. A significant increase in 
protein levels has been described immediately after the end 
of an acute cardiorespiratory exercise session (Saghiv et  al., 
2015a,b; Santos-Dias et al., 2017), and a recent study has shown 
that levels remain elevated compared to baseline up to 7 days 
after the intervention (Tan et  al., 2018). In contrast, only one 
study conducted in a mouse model has examined SαKl levels 
over the days following acute strength exercise (Welc et al., 2020).

Our results indicate that in healthy active men, plasma 
SαKl levels increase in response to acute cardiorespiratory 
exercise but decrease immediately after the end of acute strength 
exercise, and then rise to above pre-exercise levels within 24 h. 
The effect of acute exercise on SαKl levels in healthy active 
men has been scarcely addressed. Some authors have reported 
comparable results to those observed in our CR group for a 
similar exercise intensity and participant age (Saghiv et  al., 
2015a; Santos-Dias et  al., 2017; Tan et  al., 2018). Our results 
are also consistent with reports of a significant immediate 
increase in SαKl levels after a session of predominantly 
cardiorespiratory exercise (Saghiv et  al., 2015a,b; Santos-Dias 
et  al., 2017). Moreover, increased SαKl levels have also been 
observed after cardiorespiratory exercise programs lasting from 
12 to 16 weeks in young people and those over 60 years of 
age (Avin et  al., 2014; Matsubara et  al., 2014).

As so far only descriptive studies have been carried out in 
humans, the effect of strength exercise on SαKl levels remains 
unclear. Significantly lower levels of SαKl have been reported 
in weightlifters and sprinters compared to inactive subjects or 
athletes practicing other disciplines (Saghiv et al., 2015a, 2017a,b). 
In contrast, in older adults (>65 years), protein levels have 
been positively correlated with upper limb strength (Semba 
et  al., 2012) but not with lower limb strength (Semba et  al., 
2015). In our ST group, we observed a decrease in SαKl values 
at the end of the acute exercise session contrary to that found 
in the CR group. The only literature we  found to be  in accord 
with these results is an intervention comparable to a strength 
training bout of exercise in a mouse model, in which SαKl 
levels were noted to fall after exercise (Welc et  al., 2020). 
Further studies are needed in humans to confirm that an 
acute session of strength exercise causes an immediate decrease 
in SαKl levels.

It has been well-established that SαKl levels remain elevated 
in healthy individuals aged 44–51 years for at least 7 days after 
acute high-intensity cardiorespiratory exercise (Tan et al., 2018). 
Interestingly, it has also been shown in mice SαKl levels 
gradually recover following a strength exercise session 
(Welc et  al., 2020). These last authors described a similar 
behavior pattern of the protein in a murine model as observed 
here. Thus, it seems that SαKl synthesis is inhibited or slowed 
down after strength exercise, yet induced after 24 h. Again, 
further studies in humans are needed to confirm the behavior 
over time of SαKl protein after a strength training session. It 

TABLE 1  |  Characteristics of the study participants.

Mean ± SD   p

Total (n = 82) CR (n = 43) ST (n = 39)

Age (years) 29.9 ± 9 35.8 ± 8.14 23.3 ± 3.9 0.001
Weight (kg) 72.9 ± 8.7 70.6 ± 8.1 75.5 ± 8.8 0.010
Height (cm) 176.8 ± 6.8 175.4 ± 6.2 178.3 ± 7.2 0.051
BMI (kg/m2) 23.2 ± 2.1 22.8 ± 2.2 23.6 ± 1.9 0.063
BAI (%) 18.7 ± 3.5 19.1 ± 4.1 18.4 ± 2.6 0.070
VFA (cm2) 57.8 ± 24 64.6 ± 29.5 50.4 ± 12.5 0.007
ASM (kg) 8.3 ± 0.7 8.2 ± 0.7 8.3 ± 0.7 0.564
VO2max (ml/kg/min) 56.9 ± 5.2 58.2 ± 4.9 55.6 ± 5.1 0.023

Results shown as the mean and standard deviation (mean ± SD). Significance set at 
p < 0.05. BMI: body mass index; BAI: body adipose index; VFA: visceral fat area; 
ASM: appendicular skeletal muscle mass.

FIGURE 3  |  Plasma SαKI levels determined before and after the exercise 
intervention in the CR and ST groups.

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should be  considered that SαKl is intracellularly secreted in 
muscle fiber cells among others (Kuro-o et  al., 1997; Avin 
et  al., 2014). Avin et  al. (2014) proposed cross-talk between 
skeletal muscle activity and SαKl expression to gain strength, 
whereby biochemical events originating within the muscle, such 
as ROS regulation, could be  important determinants for the 
regulation of SαKl itself. Thus, some authors propose that the 
participation of SαKl could be  adjusted depending on the 
molecular demands provoked by the exercise stimulus (Egan 
and Zierath, 2013; Daneshgar and Dai, 2020).

A session of exercise whose main component is 
cardiorespiratory prompts an immediate increase in 
mitochondrial metabolism, which triggers the rapid buildup 
of ROS (Egan and Zierath, 2013). A plausible hypothesis is 
that the significant accumulation of the protein is produced 
just before the end of a bout cardiorespiratory exercise in an 
effort to regulate these ROS levels. On the other hand, we should 
also consider that the controlled muscle damage produced by 
the eccentric component of strength training maintains, during 

the initial stages sufficient levels of ROS to activate protein 
metabolism (Egan and Zierath, 2013). In view of this observation, 
it could be  that in this type of exercise, low levels of SαKl 
are maintained to stimulate the protein repair mechanism and 
do not increase until there is a significant accumulation of 
ROS (Papaconstantinou, 2009; Figure 5). Nevertheless, additional 
basic science studies are needed to verify these hypotheses.

Knowledge of the SαKl response to exercise is of interest, 
as this tool is being ever more used in clinical practice. 
The increase in SαKl induced by cardiorespiratory exercise 
coincides with a beneficial effect of this type of exercise on 
the cardiovascular system, and with the protective role of 
SαKl against cardiovascular disease in general and endothelial 
damage in particular (Matsubara et  al., 2014). In addition, 
strength training with an eccentric component helps to combat 
the loss of muscle mass and functionality in general and 
may improve the course of disease (Hody et  al., 2019). 
Besides, this type of exercise generates adaptations that also 
benefit the immune system. Muscle is considered as an 
immunogenic organ. When a muscle contracts, certain 
pro-inflammatory or anti-inflammatory interleukins are 
released, which are responsible for cell communication between 
the different organs and tissues through the bloodstream 
depending on the metabolic demands (Coffey and Hawley, 
2007). Hence, knowing the acute effects of different exercise 
modalities on plasma αKl concentrations, and that strength 
exercise leads to an increase in its levels after 24 h may help 
us to develop exercise strategies designed to improve the 
levels of this protein, which is now emerging as a marker 
of a good prognosis for some diseases (Kuro-o, 2019).

Our study has several limitations. According to a theoretical 
model of oxidative stress as a possible explanation for the 
behavior of SαKl levels, it would be  of interest to consider 
other biomarkers such as SOD or malondialdehyde to better 
understand these responses to both types of exercise. Further, 
as we  stated above, it is well-documented that plyometric 
exercise often results in significantly muscle damage (Miyama 
and Nosaka, 2004; Howatson et al., 2012). However, an important 
limitation of our study is that no muscle damage or muscle 
fatigue markers (e.g., delayed onset muscle soreness, creatine 
kinase, and muscle function) for none of CR and ST groups 
were included in the study. Moreover, the male only study 
design is a limitation to be  able to generalize the results. 
Future studies that include both men and women would 
be  necessary to see if there are differences in the response to 
SαKl between the sexes. Another limitation of the present 
study, stands in the differences in the time points of the blood 
sample analysis between CR and ST group. SaKl were only 
measured at baseline and immediately after session for the 
CR group, while it were measured at baseline and immediately 
after the session, as well as 1, 2, and 3 days after session for 
the ST group.

In conclusion, the effect of an acute exercise intervention 
on SαKl levels in healthy physically active men seems to depend 
on the type of exercise executed. In our study, this determined 
that plasma levels of the klotho protein increased after acute 
cardiorespiratory exercise yet diminished immediately after an 

TABLE 2  |  Behavior of SαKl levels over time in the study groups.

SαKl (pg/
ml)

Mean ± SD
  p(t)   p(g) p(txg)

Pre Post

CR (n = 43) 982.28 ± 221.6 1172.28 ± 238.14
0.821 0.125 0.001

ST (n = 39) 1058.30 ± 250.16 1001.97 ± 231.78

Results shown as the mean and standard deviation (mean ± SD). Significance set at 
p < 0.05.

FIGURE 4  |  Plasma SαKI levels monitored after the strength exercise 
intervention. *Significant difference vs. baseline (p < 0.05).

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acute strength exercise session, only to increase with respect 
to pre-exercise levels 24 h later.

DATA AVAILABILITY STATEMENT

The original contributions presented in the study are included 
in the article/supplementary material, further inquiries can 
be  directed to the corresponding author.

ETHICS STATEMENT

The studies involving human participants were reviewed and approved 
by the Ethics Committee of the Community of Madrid (CEIm-R. 
Reference number: 47/764390.9/17). The patients/participants 
provided their written informed consent to participate in this study.

AUTHOR CONTRIBUTIONS

TI and TY prepared the first draft of the manuscript. TI, 
IS-L, DD-B, LS-B, and VF-E recruited the sample and collected 
data. TI and ID-V analyzed data. CS, ML, and MP-R conceived 
and designed the study. CS and MP-R initiated the overall 
project. All authors made substantial contributions to revision 
of the document prior to submission. All authors read and 
approved the final version of the manuscript.

ACKNOWLEDGMENTS

The authors would like to thank Eneko Larumbe and Maria Fernandez 
del Valle for the edits and review of the manuscript and statistical 
analyses and all the students and workers of different faculties of 
Universidad Europea de Madrid who took part in this study.

FIGURE 5  |  SαKI as a regulator of exercise-activated molecular signaling pathways. (A) Following a bout of strength exercise, plasma SαKI levels fall so that the 
signaling pathway PI3K-Akt-mTOR is activated through IGF-1 induction with the main objective of protein synthesis. (B) Plasma SαKI levels rise in response to 
elevated ROS produced by the exercise stimulus just after completing the session in the case of cardiorespiratory exercise and starting 24 h after its completion in 
the case of strength exercise. ROS levels are regulated through the activation by FOXO of enzymes such as SOD2. FOXO: Forkhead box O; IGF-1: insulin growth 
factor type 1; IGF-1R: insulin growth factor type 1 receptor; ROS: reactive oxygen species; PI3K: phosphoinositide 3-kinase; Akt: serine/threonine kinase; mTOR: 
target mechanism of rapamycin kinase.

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	Acute Impacts of Different Types of Exercise on Circulating α-Klotho Protein Levels
	Introduction
	Materials and Methods
	Design and Sample
	Study Variable
	Plasma SαKl
	Interventions
	Baseline Subject Characteristics
	Physical Fitness
	Body Composition
	Statistical Analysis

	Results
	Discussion
	Data Availability Statement
	Ethics Statement
	Author Contributions

	References