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Article

Associations of VEGF-A-Related Variants with Adolescent Cardiometabolic and Dietary Parameters

by
Maria Kafyra
1,
Ioanna Panagiota Kalafati
1,2,
Ioanna Gavra
1,
Sophie Siest
3,4,† and
George V. Dedoussis
1,*,†
1
Department of Nutrition and Dietetics, School of Health Science and Education, Harokopio University, 17671 Athens, Greece
2
Department of Nutrition and Dietetics, School of Physical Education, Sport Science and Dietetics, University of Thessaly, 42132 Trikala, Greece
3
Interactions Gène-Environnement en Physiopathologie Cardio-Vasculaire (IGE-PCV), Université de Lorraine, 54000 Nancy, France
4
Santorini Conferences (SCs) Association—For Research Innovation in Health, 54470 Bernecourt, France
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Nutrients 2023, 15(8), 1884; https://doi.org/10.3390/nu15081884
Submission received: 13 March 2023 / Revised: 7 April 2023 / Accepted: 12 April 2023 / Published: 13 April 2023
(This article belongs to the Special Issue Dietary Pattern, Food Intake, and Health: What Is Still Missing in the Current Evidence?)
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Abstract

:
Previous research has allowed the identification of variants related to the vascular endothelial growth factor-A (VEGF-A) and their association with anthropometric, lipidemic and glycemic indices. The present study examined potential relations between key VEGF-A-related single-nucleotide polymorphisms (SNPs), cardiometabolic parameters and dietary habits in an adolescent cohort. Cross-sectional analyses were conducted using baseline data from 766 participants of the Greek TEENAGE study. Eleven VEGF-A-related SNPs were examined for associations with cardiometabolic indices through multivariate linear regressions after adjusting for confounding factors. A 9-SNP unweighted genetic risk score (uGRS) for increased VEGF-A levels was constructed to examine associations and the effect of its interactions with previously extracted dietary patterns for the cohort. Two variants (rs4416670, rs7043199) displayed significant associations (p-values < 0.005) with the logarithms of systolic and diastolic blood pressure (logSBP and logDBP). The uGRS was significantly associated with higher values of the logarithm of Body Mass Index (logBMI) and logSBP (p-values < 0.05). Interactions between the uGRS and specific dietary patterns were related to higher logDBP and logGlucose (p-values < 0.01). The present analyses constitute the first-ever attempt to investigate the influence of VEGF-A-related variants on teenage cardiometabolic determinants, unveiling several associations and the modifying effect of diet.

1. Introduction

Vascular endothelial growth factor A (VEGF-A) is involved in various biological functions, primarily as a major contributor to angiogenesis induction which extends its activities to cell proliferation, migration and even differentiation [1,2,3]. Due to its versatile roles in endothelial function [4], its involvement in activating the cortisol–adrenocorticotrophic hormone (ACTH) stress axis, its promotion of aldosterone [5] production as well as its multifactorial influence on energy homeostasis [2,6,7], insulin resistance [2,8] and cardiac function [9], VEGF-A is involved in various reciprocal relationships influencing cardiovascular and cardiometabolic risk factors such as glucose sensitivity, lipidemic profile, obesity and blood pressure.
Altered VEGF-A expression is observed in the presence of disturbed cardiometabolic states, denoting a requited relationship between the biomarker’s levels and disrupted cardiometabolic profile. For example, VEGF-A is known to be involved in glucose homeostasis, where both its over- and under-expression can affect glucose tolerance [8], as well as lipid metabolism, through its regulation of lipases and the creation of chylomicrons [7]. In a similar manner, VEGF-A is highly expressed in the adipose tissue, where an increase in the number of adipocytes signifies increased VEGF-A and subsequent angiogenesis and further cell proliferation and differentiation [1].
Circulating VEGF-A levels have been conclusively demonstrated as greatly heritable [10]. The past decades have marked the conduct of large meta-analyses of multiple genome-wide association studies (GWAS), revealing key variants significantly associated with the marker’s levels. More specifically, Debette and Visvikis-Siest et al. brought four key single-nucleotide polymorphisms (SNPs) to light, collectively explaining 48.7% of VEGF-A variation [10]. Subsequent studies have unveiled additional VEGF-A-related SNPs, which have, in turn, been further associated with adult cardiometabolic indices [11,12] and even the presence of neurodegenerative disorders such as Alzheimer’s disease [13]. Selected VEGF-A-associated SNPs have even been directly linked to the presence of hypercholesterolemia and metabolic syndrome in adults [14,15]. In addition, the interplay between VEGF-A SNPs and dietary components has also been associated with multiple metabolic syndrome determinants [16,17]. An example of the importance of the interplay between VEGF-A, anthropometric indices and dietary compounds was recently highlighted in the finding that the effect of VEGF- A variants on circulating iron levels might depend on anthropometric indices [(i.e., Body Mass Index (BMI)] [18].
The present study constitutes the continuation of our team’s previous research aiming at exploring the effect of the interplay between genetic makeup and lifestyle habits on adolescent anthropometric, lipidemic and glycemic indices. In this context, the present findings concern the first-ever attempt to investigate the role of key VEGF-A-related variants exclusively on the cardiometabolic profile of adolescents, using data from the Greek TEENAGE Study. We hereby present the results of the analyses on selected target variants, the subsequent examinations of their cumulative effect in the form of an unweighted genetic risk score (uGRS) and its respective interactions with previously extracted dietary patterns on the teenagers’ cardiometabolic indices.

2. Materials and Methods

2.1. The TEENAGE Study

The present analyses constitute the next step in the research of our team’s Gutenberg Chair 2018 project, where building on our previous findings [19], we hereby present the subsequent examinations between genetic makeup and teenage cardiometabolic profile in the TEENAGE Study. The latter (TEENs of Attica: Genes and Environment) refers to the cross-sectional collection of various data from adolescent students conducted during the years 2008–2010 in Attica, Greece. The project was approved by the Institutional Review Board of Harokopio University of Athens, as well as the Greek Ministry of Education and Religious Affairs. All nodes conducted within the study took place adhering to the guidelines of the Declaration of Helsinki.
Details of the study protocol and characteristics have been previously extensively described elsewhere [20,21,22]. The TEENAGE desired target population were children and adolescents of 13–15 years of age attending the primary three classes of public secondary schools in the Attica region, coming from all groups and backgrounds [22]. Schools and participants were invited to be involved in the study from the pool of the teenage population of the GENDAI study [23]. The latter constituted a previous study also conducted and approved by Harokopio University of Athens, including children attending fifth and sixth grade of 1440 schools from a wide range of neighborhoods of different socioeconomic status across the Attica region [23]. Overall, 857 out of 1440 teenagers attending the participating schools were recruited for the purposes of the TEENAGE study [20,21]. The volunteers were recruited to the study after undergoing a briefing session on the study aims, their voluntary inclusion and the confidentiality measures surrounding their data [20,21]. Verbal consent by all adolescent participants and their respective guardians’ written consent was collected prior to study enrollment.
After enrollment in the study, all children and adolescents participated in a baseline, in-person session with healthcare professionals, where anthropometric, dietary, biochemical and lifestyle data were collected. Measurements of body and height were conducted for each individual in a barefoot state and with light clothes on, and the BMI was calculated as weight (kg)/height2 (m2). Waist circumference was measured in centimeters using a non-extensible soft tape, and body fat was evaluated by measuring the triceps and subscapular skinfolds. Dietary intake was assessed via conduct of a 24 h recall for the day prior to recruitment and the completion of a questionnaire for meal patterns and eating behavior. A second recall was conducted via telephone in the 10 days after the baseline session. Physical activity habits were assessed via the completion of a relative checklist for two non-consecutive days [20,21,22].
Moreover, DNA samples were collected for each participant and were further genotyped via the use of the Illumina HumanOmniExpress BeadChips (Illumina, San Diego, CA, USA) at the Wellcome Trust Sanger Institute, Hinxton, UK [20]. The imputation of the genotyped data was conducted using the Haplotype Reference Consortium (HRC) panel [20,24].
For the purposes of the present study, we used anthropometric, biochemical and genetic data from an initial pool of 766 participants with available data. We investigated associations between 11 VEGF-A-associated SNPs and various cardiometabolic indices. Pulse pressure (PP) was calculated to allow for comparisons with the previous findings, based on the available data for systolic and diastolic blood pressure (SBP and DBP, respectively) and via using the following formula:
P u l s e   P r e s s u r e   ( P P ) = S y s t o l i c   B l o o d   P r e s s u r e   ( S B P , m m H g ) D i a s t o l i c   B l o o d   P r e s s u r e   ( D B P , m m H g )
Furthermore, we proceeded to construct an unweighted genetic risk score (uGRS) for VEGF-A using the target SNPs identified by Choi et al. For the purposes of the present analyses, we used the SNPs with the available data in the TEENAGE cohort (i.e., 9 out of 10 variants). The uGRS was constructed by scoring the risk alleles positively associated with the VEGF-A levels. We subsequently examined its respective relations with the cardiometabolic indices and further split the uGRS into two groups of high and low genetic risk for higher levels of VEGF based on the sample median value. Additionally, we proceeded to investigate the potential effect of interactions between the uGRS and the previously identified dietary patterns for the TEENAGE cohort [19] on the various indices.

2.2. Statistical Analyses

In the present analyses, we set out to investigate the potential impact of 11 VEGF-A-related target SNPs on cardiometabolic indices using available data from the Greek TEENAGE study (Table 1). Based on our team’s previously published findings [10,11], we chose to examine the rs4416670, rs6921438, rs10738760 and rs6993770 variants, which have been shown to collectively explain 48.7% of VEGF-A variability and have been further associated with multiple cardiometabolic indices in healthy populations [10]. We additionally included 7 more SNPs identified by Choe et al. as strongly associated with circulating VEGF-A levels, with available data in the TEENAGE cohort [11].
We used a threshold of 0.7 for the imputation INFO score for all SNPs included in the analyses. Quality control for sample and SNP exclusion criteria consisted of: (i) sample call rate at 95%; (ii) Hardy–Weinberg Equilibrium (HWE) exact p < 0.0001; and (iii) genotyping call rate at 99%. Before testing for associations, an assessment of the cardiometabolic variables’ distribution was carried out via the use of the Shapiro–Wilk and Kolmogorov–Smirnov tests. All variables not presenting a normal distribution were log-transformed. Hypothesis testing between cohort subgroups took place using the Mann–Whitney test. We investigated potential relations between the 11 target SNPs and the cardiometabolic parameters using linear regression analyses. Associations were examined after adjusting for 3 different models of confounding factors, namely: (i) Model 1, which consisted of adjustment for age and sex; (ii) Model 2, which further included exercise level; and (iii) Model 3, additionally incorporating the adjustment for the five previously extracted dietary patterns [19]. Multiple linear regression results for each SNP are presented as betas [regression coefficients (β)] and p-values. The threshold for statistical significance was set at 0.05. The adjusted threshold for multiple testing was set at 0.005 (0.05/11 components examined).
Following the associations explored for each SNP separately, we further used multiple linear regressions to examine the associations between the uGRS and the metabolic indices, as well as the potential effect of the interactions between the uGRS and the formerly extracted dietary patterns. Multiple linear regression results are presented as estimates [beta coefficients (β)] and standard error (SE). In the case of examining the interactions, the adjusted threshold for statistical significance was set at 0.01 (i.e., 0.05/5 components examined). All phenotypic analyses were conducted using the R Statistical Package [25], and genetic analyses were carried out with the Plink whole-genome association analysis toolset, version 1.9 [26].

3. Results

3.1. Population Characteristics

The characteristics of the population used have been previously described elsewhere [19]. This overall healthy population of 349 boys and 417 girls presented a median age of 13.30 years old (Table 2). The girls displayed an overall better cardiometabolic profile compared to boys, with the latter showing statistically significantly higher levels of SBP, PP, glucose and C-reactive protein (CRP) (p-value < 0.001). Additionally, girls demonstrated statistically significantly higher levels of high-density cholesterol (HDL) (p-value < 0.001). BMI, triglycerides, total cholesterol, SBP, while low-density cholesterol did not display any statistically significant differences between the two groups.

3.2. Associations between the 11 VEGF-A-Related SNPs and the Cardiometabolic Indices

Cross-sectional associations between the 11 SNPs and the various indices were assessed in participants with available data. Table 3 shows the multivariate linear regressions conducted for each of the 11 SNPs after adjustment for age and sex (Model 1), age, sex and exercise (Model 2) and age, sex, exercise and dietary pattern (Model 3). Our analyses showed statistically significant associations for two out of the eleven examined SNPs, namely the rs7043199 and the rs4416670 variants, with the latter having been found to explain 1,5% of the variance of VEGF-A levels in adults [7]. More specifically, the presence of the C allele of the latter was related, with a lower log of systolic blood pressure (logSBP) across all models (Model 1: β = −0.007, p-value = 0.002, Model 2: β = −0.007, p-value = 0.002, Model 3: β = −0.07, p-value = 0.0035). Another statistically significant but positive relation for logSBP was demonstrated for the A allele of the rs7043199 variant after adjusting for Model 2 (Model 2: β = 0.009, p-value = 0.004). The same SNP also displayed a statistically significant and positive association with log diastolic blood pressure (logDBP) after adjustment for Model 3 (Model 3: β = 0.0138, p-value = 0.0046).

3.3. Associations between the 9-SNP uGRS and the Cardiometabolic Indices

In the effort to examine the potential effect of uGRS in the formation of the investigated indices, we separated the 9-SNP uGRS into the two categories of “low” and “high” risk based on the sample median, where logBMI displayed statistically significant differences between the two groups (Figure 1), with individuals in the higher category presenting greater logBMI (p-value < 0.05), indicating that higher risk for increased VEGF-A levels is also associated with elevated logBMI. People in the higher percentile of uGRS also presented statistically significantly higher values of logSBP compared to the ones in the lower group (p-value < 0.05), also denoting that elevated risk for increased VEGF-A levels is further associated with increased logSBP. To boot, individuals with higher versus lower uGRS did display statistically significantly lower levels of logHDL (p-value < 0.05), highlighting an inverse association between increased risk for VEGF-A and levels of logHDL.
Furthermore, the creation of the 9-SNP uGRS was followed by association testing for all cardiometabolic indices explored via linear regressions after adjusting for age and sex (Model 1), age, sex and exercise (Model 2) and age, sex, exercise and dietary patterns (Model 3). Similar to the results deriving from the within-group comparisons and as shown in Table 4, significant associations were observed between higher uGRS values and increased levels of logBMI across all models (Model 1: β = 0.0044, p-value = 0.003, Model 2: β = 0.0043, p-value = 0.005, Model 3: β = 0.004, p-value = 0.009). Additionally, a statistically significant, positive association was also observed between the uGRS and logSBP, again after adjusting for all models (Model 1: β = 0.002, p-value = 0.03, Model 2: β = 0.019, p-value = 0.047, Model 3: β = 0.002, p-value = 0.037). The score was further negatively associated with logHDL levels after adjustment for age and sex (Model 1: β = −0.005, p-value = 0.032), an association which was not maintained after correcting for the additional confounders (exercise and dietary patterns).

3.4. Interactions between the uGRS and Dietary Patterns

After calculating the 9-SNP uGRS, we carried on to examine the potential associations between the cardiometabolic indices and their interactions with the five previously extracted patterns of food choices in the teenagers, namely the “Western Breakfast”, the “Legumes and Good Fat”, the “Homemade Meal”, the “Chickens and Sugars”, and the “Eggs and Fibers” patterns [19]. Table 5 shows the multivariate linear regressions carried out for each examined index and the interaction between the uGRS and each of the dietary patterns after adjusting for age, sex, uGRS and each dietary pattern (Model 1) and age, sex, and exercise. uGRS and each dietary pattern (Model 2).
As shown in the table, after evaluation based on the adjusted threshold (p = 0.01), the interaction between the uGRS and the “Western Breakfast” was associated with higher levels of logDBP (Model 1: β = 0.0060, p-value = 4.28 × 10−5, Model 2: β = 0.00568, p-value = 0.000239), suggesting that increased risk for high VEGF-A and adherence to a western-diet-like pattern is associated with elevated logDBP. A different nominally statistically significant, positive association was found for the interaction between the uGRS and consumption of the “Eggs and Fibers” pattern and increased levels of logGlucose after adjusting for age, sex, and exercise (Model 2: β = 0.00883, p-value = 0.0132), potentially indicating that elevated risk for increased VEGF-A and increased consumption of fiber-rich foods or eggs is associated with increased levels of logGlucose.

4. Discussion

The present study sought to conduct the first-ever attempt to investigate the role of VEGF-A-related variants on adolescent cardiometabolic profile, as well as their potential interplay with dietary habits. In this population of Greek teenagers, two VEGF-A-related SNPs, namely the rs7043199 and the rs4416670 variants, presented significant relations with blood pressure indices. Moreover, the 9-SNP uGRS constructed out of risk variants for higher VEGF-A levels was associated with higher levels of logBMI and logSBP but lower levels of logHDL. Furthermore, the exploration of associations between the uGRS and the teenagers’ dietary patterns revealed a significant relationship between the adherence to the “Western Breakfast” pattern and higher logDBP, as well as a nominal association for the “Eggs and Fibers” pattern and higher logGlucose.
In our sample, the negatively associated with VEGF-A levels C allele of the rs4416670 SNP was also negatively associated with logSBP levels. Debette et Visvikis-Siest et al. previously showed a positive relationship between the allele and increased pulse pressure in a healthy population [10]; this could potentially be attributed to the relationship between lower levels of SBP, which would subsequently signify greater values of pulse pressure. On the contrary, the A allele of the rs7043199 variant, which was previously negatively associated with VEGF-A [10,11], was hereby linked with higher levels of logSBP and logDBP. Although not as statistically strong (p-value = 0.004), this observed effect could possibly be attributed to the yet-to-be-fully elucidated pleiotropic influence of the variant, the role of which has been previously investigated for overall risk for other disorders related to cardiometabolic profile, namely ischemic heart disease [27] and osteoporosis [28].
To the best of our knowledge, VEGF-A has not been extensively and exclusively examined in adolescents, and the present constitutes the first attempt to construct a uGRS for teenagers using VEGF-A-associated variants. The present 9-SNP uGRS was linked to higher levels of logSBP (Model 1: β = 0.002, p-value = 0.03, Model 2: β = 0.019, p-value = 0.047, Model 3: β = 0.002, p-value = 0.037) and individuals with high GRS presented greater values compared to the ones with low GRS (p-value = 0.027), showing that increased genetic predisposition to higher levels of VEGF-A is associated with higher blood pressure in adolescents. This finding is aligned with the well-known relationship between VEGF-A and hypertension, as the current literature has shown that the inhibition of VEGF-A receptors signifies higher levels of circulating VEGF-A, which have, in turn, been associated with a greater risk for hypertension [29,30,31]. In a similar manner and supporting the reciprocal relationship between the VEGF family and hypertension, Zorena et al. showed that adolescents with type 1 diabetes and hypertension displayed greater levels of VEGF compared to healthy individuals or patients with type 1 diabetes but without hypertension [32].
Although this is an overall healthy population with most adolescents presenting normal weight, the accumulating effect of the nine examined SNPs from Choi et al. displayed a statistically significant, positive association with higher logBMI values. In addition to the already underlined positive relationship between VEGF-B and VEGF-C levels and obesity presence [33,34], the current literature further highlights the role of VEGF-A in obesity control [2,35,36]. In the presence of obesity and fat cell proliferation, VEGF-A expression increases as it participates in angiogenesis, cell differentiation and thermogenesis in the white and brown adipose tissues. In this context, VEGF-A contributes to the subsequent increase in energy expenditure and attempts to suppress further diet-induced increase and ameliorate insulin resistance in a compensatory effect [2,35,36]. However, as the increase in adipocytes progresses, VEGF-A is produced more, and angiogenesis is further promoted in the white adipose tissue, thus allowing for further obesity establishment. This cascade of events creates a reciprocal circle where obesity presence induces VEGF-A expression and vice versa. For that reason, the effect of VEGF-A on increased weight can be described as reciprocal and context-dependent, being mainly influenced by the potential pre-existence of increased body weight [1,35]. Hereby, the positive association between the uGRS and logBMI was steadily maintained after adjustments for all three models of confounding factors (Model 1: β = 0.0044, p-value = 0.003, Model 2: β = 0.0043, p-value = 0.005, Model 3: β = 0.004, p-value = 0.009) and adolescents with high versus low genetic risk also presented higher values of logBMI, suggesting an aggravating effect in BMI as a genetic risk for higher VEGF-A increases. In a similar context to the present, Novikova et al. showed that compared to individuals of normal weight, adolescents with obesity presented a 12-fold increase in corresponding VEGF-A levels [37]. To boot, Loebig et al. showed a similar positive association in healthy young men (aged 18–30 years old) under normal blood sugar conditions, where higher levels of VEGF-A were consistently associated with increased weight [38]. VEGF-A was also related to abdominal obesity in a sample of young individuals, as demonstrated by Guzman-Guzman et al. when investigating relations with parameters of the metabolic syndrome [39]. Our present findings show that increased predisposition to higher levels of VEGF-A is related to higher BMI; however, according to the aforementioned, it should be noted that the reciprocity of the relationship remains significant, as increased VEGF-A levels can generally be observed due to increased BMI, thus potentially aggravating the positive predisposing genetic effect.
Another significant relation was observed between the uGRS and lower levels of logHDL (Model 1: β = 0.005, p-value = 0.032). Although this association was not maintained after correction for multiple confounding factors, when looking at individuals with higher versus lower genetic risk for increased VEGF-A, the former did present lower values of logHDL. When looking into potential associations between VEGF-A variants and HDL, both Debette et Visvikis-Siest and Stathopoulou et al. showed that the negatively associated with VEGF-A A allele of rs6921438 SNP was related to lower HDL levels in healthy populations [10,12]. The present finding denoting a positive association between increased VEGF-A and lower HDL levels can, thus, potentially be explained by the general overview of the role of elevated VEGF-A in worse lipidemic profile, rather than the direct effect of VEGF-A on HDL per se [40].
Furthermore, taking the biomarker’s role in metabolism into account [2,6,7], we further attempted to unravel the meaning of the interplay between genetic predisposition for higher VEGF-A levels and multiple cardiometabolic indices by examining the potentially modifying role of dietary habits. In our sample, the interaction between the uGRS and the consumption of the “Western Breakfast” was associated with higher levels of logDBP (Model 1: β = 0.0060, p-value = 4.28 × 10−5, Model 2: β = 0.00568, p-value = 0.000239). This finding can be explained by the fact that the “Western Breakfast” pattern consists of food groups with high-fat content, namely cheese, dairy and processed meat [19], which have already been shown to associate with increased blood pressure in the literature [41]. Hojhabrimanesh et al. showed similar significant associations between a “Western” dietary pattern and overall and systolic blood pressure in Iranian adolescents, as well as a positive but not statistically significant association for diastolic pressure [42]. Although the pattern was not unilaterally associated with blood pressure measurements in our team’s previous analyses [19], and an increased predisposition to higher VEGF-A appears to bring its aggravating effect to the forefront and vice versa. This could be partly attributed to the positive effect of the Western diet and red meat-derived protein, which has been previously shown to elevate VEGF-A expression among patients with breast cancer [43].
Furthermore, although the 9-SNP uGRS was not alone associated with glucose in our sample, it did present a nominally significant interaction with the protein-rich “Eggs and Fibers” dietary pattern (consisting of non-refined cereals, vegetables and eggs) in increasing logGlucose levels (Model 2: β = 0.00883, p-value = 0.0132). The involvement of VEGF-A in glucose homeostasis is well-known [8], as low levels of the biomarker are linked to insulin resistance, while its overexpression is associated with impaired insulin production and increased glucose levels [2,8]. Consequently, research in adolescent cohorts to date mainly surrounds diabetic individuals or related complications [30,44] and has yet to yield significant results in healthy populations. Although fiber intake is generally regarded as having protective effects in the production of inflammatory biomarkers [45], the present finding could possibly refer to the reciprocal effect of dietary carbohydrate and protein intake on aggravating the genetic risk for VEGF-A levels and subsequent influence the elevated glucose levels.
Moreover, similar gene–diet interactions have also been explored in individuals with metabolic syndrome in studies examining target SNPs for VEGF-A rather than using a holistic genetic risk score approach. Ghazizadeh et al. showed that individuals with the AA genotype for the rs10738760 variant, which was also included in the present uGRS, and higher adherence to foods with increased sugar and saturated fatty acids, among others, presented a greater risk for metabolic syndrome [16]. It was further demonstrated that the presence of the same A allele can significantly interact with even favorable dietary components (e.g., PUFAs) in ultimately elevating the risk for worse glycemic and lipidemic profile and, thus, metabolic syndrome [16]. Taking it one step further, Chedid et al. showed a significant association between BMI and the rs10738760 polymorphism in decreasing iron levels, an effect shown to be more prominent in individuals with obesity [18]. Finally, a different relation concerned the observed associations between the presence of the 9-SNP-uGRS rs6921438 and rs6993770 included SNPs and micronutrient contents, namely high manganese, low zinc, and low iron intakes in patients with metabolic syndrome [46,47,48].
The strengths of the present study concern its hypothesis of investigating demonstrated effects of known VEGF-A variants on the cardiometabolic profile of healthy adolescents for the first time. Various associations presented hereby underline the effect of the SNPs in this age group and further highlight the complementary and modifying effect of diet in this vulnerable and crucial for future development life stage. The limitations of the study are summarized as follows: (i) the limited but substantial number of participants compared to larger cohorts examining VEGF-A-related variants; (ii) the overall health status of the population used, which might not have promoted the identification of distinct associations with cardiometabolic risk factors, as for example in the case of patients with obesity or disrupted glucose metabolism and; (iii) the restricted variance of the populations’ habits explained by the previously extracted dietary patterns (46.69%) [19].

5. Conclusions

The results from the present study suggest that well-identified VEGF-A-related variants in adults affect the parameters of adolescent cardiometabolic profiles. Our findings highlight the complexity of the mechanisms in which VEGF-A-related variants affect cardiometabolic risk factors both directly but also potentially through pleiotropic effects. Assessment of the role of diet showed that interaction between genetic makeup and dietary habits could significantly influence the variation of glycemic and blood pressure indices in this age group. In this spectrum, our findings promote the enhancement of our understanding of VEGF-A influence and its individual interaction with dietary aspects. We hereby lay the ground for future GWAS studies to be held that include larger adolescent sample sizes, allowing for the establishment of corresponding effect sizes and the subsequent construction of weighted GRSs for VEGF-A in teenagers. The latter would broaden our abilities in evaluating this reciprocal relationship and even allow for the use of the risk scores as tools of individual and clinical utility in assessing the risk for adolescent cardiometabolic disorders.

Author Contributions

Conceptualization, M.K., S.S. and G.V.D.; methodology, M.K., S.S. and G.V.D.; validation, M.K.; formal analysis, M.K. and I.P.K.; investigation, S.S. and G.V.D.; resources, S.S. and G.V.D.; data curation, M.K., I.P.K. and I.G.; writing—original draft preparation, M.K.; writing—review and editing, M.K., I.P.K. and S.S.; visualization, M.K., S.S. and G.V.D.; supervision, S.S. and G.V.D.; project administration, S.S. and G.V.D.; funding acquisition, S.S. and G.V.D. All authors have read and agreed to the published version of the manuscript.

Funding

The TEENAGE study received funding from the European Social Fund-ESF of the European Union and the National Strategic Reference Framework (NSRF)- Research Funding Program: Heracleitus II through its Operational Program “Education and Lifelong Learning”. The present research was financed from the project “La Région Grand Est, France-GUTENBERG chair 2018, grant number 18CP-1413”.

Institutional Review Board Statement

The TEENAGE study received approval from the Institutional Review Board of Harokopio University of Athens, as well as the Greek Ministry of Education, Lifelong Learning and Religious Affairs.

Informed Consent Statement

All participants in the TEENAGE study provided verbal consent in combination with their parents’ written consent before enrolling in the study.

Data Availability Statement

Access to the study data is available upon request due to participants’ privacy and ethical restrictions.

Acknowledgments

This work makes part of the VEGF Consortium (https://www.santoriniconference.org/ accessed on 11 March 2023).

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. di Somma, M.; Vliora, M.; Grillo, E.; Castro, B.; Dakou, E.; Schaafsma, W.; Vanparijs, J.; Corsini, M.; Ravelli, C.; Sakellariou, E.; et al. Role of VEGFs in metabolic disorders. Angiogenesis 2020, 23, 119–130. [Google Scholar] [CrossRef] [PubMed]
  2. Elias, I.; Franckhauser, S.; Bosch, F. New insights into adipose tissue VEGF-A actions in the control of obesity and insulin resistance. Adipocyte 2013, 2, 109–112. [Google Scholar] [CrossRef]
  3. Abhinand, C.S.; Raju, R.; Soumya, S.J.; Arya, P.S.; Sudhakaran, P.R. VEGF-A/VEGFR2 signaling network in endothelial cells relevant to angiogenesis. J. Cell Commun. Signal. 2016, 10, 347–354. [Google Scholar] [CrossRef] [PubMed]
  4. Guangqi, E.; Cao, Y.; Bhattacharya, S.; Dutta, S.; Wang, E.; Mukhopadhyay, D. Endogenous Vascular Endothelial Growth Factor-A (VEGF-A) Maintains Endothelial Cell Homeostasis by Regulating VEGF Receptor-2 Transcription. J. Biol. Chem. 2012, 287, 3029–3041. [Google Scholar] [CrossRef]
  5. Gennari-Moser, C.; Khankin, E.V.; Escher, G.; Burkhard, F.; Frey, B.M.; Karumanchi, S.A.; Frey, F.J.; Mohaupt, M.G. Vascular endothelial growth factor-A and aldosterone: Relevance to normal pregnancy and preeclampsia. Hypertension 2013, 61, 1111–1117. [Google Scholar] [CrossRef]
  6. Pi, X.; Xie, L.; Patterson, C. Emerging Roles of Vascular Endothelium in Metabolic Homeostasis. Circ. Res. 2018, 123, 477–494. [Google Scholar] [CrossRef] [PubMed]
  7. Zhou, Y.; Zhu, X.; Wang, H.; Duan, C.; Cui, H.; Shi, J.; Shi, S.; Yuan, G.; Hu, Y. The Role of VEGF Family in Lipid Metabolism. Curr. Pharm. Biotechnol. 2022, 24, 253–265. [Google Scholar] [CrossRef] [PubMed]
  8. Staels, W.; Heremans, Y.; Heimberg, H.; De Leu, N. VEGF-A and blood vessels: A beta cell perspective. Diabetologia 2019, 62, 1961–1968. [Google Scholar] [CrossRef]
  9. Braile, M.; Marcella, S.; Cristinziano, L.; Galdiero, M.R.; Modestino, L.; Ferrara, A.L.; Varricchi, G.; Marone, G.; Loffredo, S. VEGF-A in Cardiomyocytes and Heart Diseases. Int. J. Mol. Sci. 2020, 21, 5294. [Google Scholar] [CrossRef] [PubMed]
  10. Debette, S.; Visvikis-Siest, S.; Chen, M.-H.; Ndiaye, N.-C.; Song, C.; Destefano, A.; Safa, R.; Nezhad, M.A.; Sawyer, D.; Marteau, J.-B.; et al. Identification of cis- and trans-Acting Genetic Variants Explaining Up to Half the Variation in Circulating Vascular Endothelial Growth Factor Levels. Circ. Res. 2011, 109, 554–563. [Google Scholar] [CrossRef] [PubMed]
  11. Choi, S.H.; Ruggiero, D.; Sorice, R.; Song, C.; Nutile, T.; Smith, A.V.; Concas, M.P.; Traglia, M.; Barbieri, C.; Ndiaye, N.C.; et al. Six Novel Loci Associated with Circulating VEGF Levels Identified by a Meta-analysis of Genome-Wide Association Studies. PLoS Genet. 2016, 12, e1005874. [Google Scholar] [CrossRef]
  12. Stathopoulou, M.G.; Bonnefond, A.; Ndiaye, N.C.; Azimi-Nezhad, M.; El Shamieh, S.; Saleh, A.; Rancier, M.; Siest, G.; Lamont, J.; Fitzgerald, P.; et al. A common variant highly associated with plasma VEGFA levels also contributes to the variation of both LDL-C and HDL-C. J. Lipid Res. 2013, 54, 535–541. [Google Scholar] [CrossRef] [PubMed]
  13. Petrelis, A.M.; Stathopoulou, M.G.; Kafyra, M.; Murray, H.; Masson, C.; Lamont, J.; Fitzgerald, P.; Dedoussis, G.; Yen, F.T.; Visvikis-Siest, S. VEGF-A-related genetic variants protect against Alzheimer’s disease. Aging 2022, 14, 2524–2536. [Google Scholar] [CrossRef] [PubMed]
  14. Salami, A.; El Shamieh, S. Association between SNPs of Circulating Vascular Endothelial Growth Factor Levels, Hypercholesterolemia and Metabolic Syndrome. Medicina 2019, 55, 464. [Google Scholar] [CrossRef]
  15. Kim, Y.R.; Hong, S.-H. The Protective Effects of the VEGF−2578C>A and −1154G>A Polymorphisms Against Hypertension Susceptibility. Genet. Test. Mol. Biomark. 2015, 19, 476–480. [Google Scholar] [CrossRef] [PubMed]
  16. Ghazizadeh, H.; Esmaeily, H.; Sharifan, P.; Parizadeh, S.M.R.; Ferns, G.A.; Rastegar-Moghaddam, A.; Khedmatgozar, H.; Ghayour-Mobarhan, M.; Avan, A. Interaction between a genetic variant in vascular endothelial growth factor with dietary intakes in association with the main factors of metabolic syndrome. Gene Rep. 2020, 21, 100813. [Google Scholar] [CrossRef]
  17. Hoseini, Z.; Azimi-Nezhad, M.; Ghayour-Mobarhan, M.; Avan, A.; Eslami, S.; Nematy, M.; Mirhafez, S.R.; Ghazavi, H.; Ferns, G.A.; Safarian, M. VEGF gene polymorphism interactions with dietary trace elements intake in determining the risk of metabolic syndrome. J. Cell. Biochem. 2018, 120, 1398–1406. [Google Scholar] [CrossRef]
  18. Chedid, P.; Salami, A.; Ibrahim, M.; Visvikis-Siest, S.; El Shamieh, S. The association of vascular endothelial growth factor related SNPs and circulating iron levels might depend on body mass index. Front. Biosci. 2022, 27, 27. [Google Scholar] [CrossRef]
  19. Kafyra, M.; Kalafati, I.P.; Kumar, S.; Kontoe, M.S.; Masson, C.; Siest, S.; Dedoussis, G.V. Dietary Patterns, Blood Pressure and the Glycemic and Lipidemic Profile of Two Teenage, European Populations. Nutrients 2021, 13, 198. [Google Scholar] [CrossRef]
  20. Ntalla, I.; Panoutsopoulou, K.; Vlachou, P.; Southam, L.; Rayner, N.W.; Zeggini, E.; Dedoussis, G.V. Replication of Established Common Genetic Variants for Adult BMI and Childhood Obesity in Greek Adolescents: The TEENAGE Study. Ann. Hum. Genet. 2013, 77, 268–274. [Google Scholar] [CrossRef]
  21. Ntalla, I.; Yannakoulia, M.; Dedoussis, G.V. An Overweight Preventive Score associates with obesity and glycemic traits. Metabolism 2016, 65, 81–88. [Google Scholar] [CrossRef] [PubMed]
  22. Ntalla, I.; Giannakopoulou, M.; Vlachou, P.; Giannitsopoulou, K.; Gkesou, V.; Makridi, C.; Marougka, M.; Mikou, G.; Ntaoutidou, K.; Prountzou, E.; et al. Body composition and eating behaviours in relation to dieting involvement in a sample of urban Greek adolescents from the TEENAGE (TEENs of Attica: Genes & Environment) study. Public Health Nutr. 2014, 17, 561–568. [Google Scholar] [CrossRef] [PubMed]
  23. Yannakoulia, M.; Ntalla, I.; Papoutsakis, C.; Farmaki, A.-E.; Dedoussis, G.V. Consumption of Vegetables, Cooked Meals, and Eating Dinner is Negatively Associated with Overweight Status in Children. J. Pediatr. 2010, 157, 815–820. [Google Scholar] [CrossRef] [PubMed]
  24. McCarthy, S.; Das, S.; Kretzschmar, W.; Delaneau, O.; Wood, A.R.; Teumer, A.; Kang, H.M.; Fuchsberger, C.; Danecek, P.; Sharp, K.; et al. A reference panel of 64,976 haplotypes for genotype imputation. Nat. Genet. 2016, 48, 1279–1283. [Google Scholar] [CrossRef]
  25. Ihaka, R.; Gentleman, R. R: A Language for Data Analysis and Graphics. J. Comput. Graph. Stat. 1996, 5, 299–314. [Google Scholar] [CrossRef]
  26. Purcell, S.; Neale, B.; Todd-Brown, K.; Thomas, L.; Ferreira, M.A.R.; Bender, D.; Maller, J.; Sklar, P.; de Bakker, P.I.W.; Daly, M.J.; et al. PLINK: A Tool Set for Whole-Genome Association and Population-Based Linkage Analyses. Am. J. Hum. Genet. 2007, 81, 559–575. [Google Scholar] [CrossRef]
  27. Yeung, S.L.A.; Lam, H.S.H.S.; Schooling, C.M. Vascular Endothelial Growth Factor and Ischemic Heart Disease Risk: A Mendelian Randomization Study. J. Am. Heart Assoc. 2017, 6, e005619. [Google Scholar] [CrossRef] [PubMed]
  28. Keller-Baruch, J.; Forgetta, V.; Manousaki, D.; Zhou, S.; Richards, J.B. Genetically Decreased Circulating Vascular Endothelial Growth Factor and Osteoporosis Outcomes: A Mendelian Randomization Study. J. Bone Miner. Res. 2020, 35, 649–656. [Google Scholar] [CrossRef]
  29. Robinson, E.S.; Khankin, E.V.; Karumanchi, S.A.; Humphreys, B.D. Hypertension Induced by Vascular Endothelial Growth Factor Signaling Pathway Inhibition: Mechanisms and Potential Use as a Biomarker. Semin. Nephrol. 2010, 30, 591–601. [Google Scholar] [CrossRef]
  30. Pandey, A.K.; Singhi, E.K.; Arroyo, J.P.; Ikizler, T.A.; Gould, E.R.; Brown, J.; Beckman, J.A.; Harrison, D.G.; Moslehi, J. Mechanisms of VEGF (Vascular Endothelial Growth Factor) Inhibitor–Associated Hypertension and Vascular Disease. Hypertension 2018, 71, e1–e8. [Google Scholar] [CrossRef]
  31. Mäki-Petäjä, K.M.; McGeoch, A.; Yang, L.L.; Hubsch, A.; McEniery, C.M.; Meyer, P.A.; Mir, F.; Gajendragadkar, P.; Ramenatte, N.; Anandappa, G.; et al. Mechanisms Underlying Vascular Endothelial Growth Factor Receptor Inhibition-Induced Hypertension: The HYPAZ Trial. Hypertension 2021, 77, 1591–1599. [Google Scholar] [CrossRef]
  32. Zorena, K.; Myśliwska, J.; Myśliwiec, M.; Rybarczyk-Kapturska, K.; Malinowska, E.; Wiśniewski, P.; Raczyńska, K. Association between vascular endothelial growth factor and hypertension in children and adolescents type I diabetes mellitus. J. Hum. Hypertens. 2010, 24, 755–762. [Google Scholar] [CrossRef] [PubMed]
  33. Zafar, M.I.; Mills, K.; Ye, X.; Blakely, B.; Min, J.; Kong, W.; Zhang, N.; Gou, L.; Regmi, A.; Hu, S.Q.; et al. Association between the expression of vascular endothelial growth factors and metabolic syndrome or its components: A systematic review and meta-analysis. Diabetol. Metab. Syndr. 2018, 10, 62. [Google Scholar] [CrossRef] [PubMed]
  34. Mazidi, M.; Rezaie, P.; Kengne, A.; Stathopoulou, M.G.; Azimi-Nezhad, M.; Siest, S. VEGF, the underlying factor for metabolic syndrome; fact or fiction? Diabetes Metab. Syndr. 2017, 11 (Suppl. S1), S61–S64. [Google Scholar] [CrossRef]
  35. Herold, J.; Kalucka, J. Angiogenesis in Adipose Tissue: The Interplay Between Adipose and Endothelial Cells. Front. Physiol. 2021, 11, 624903. [Google Scholar] [CrossRef]
  36. Sun, K.; Asterholm, I.W.; Kusminski, C.M.; Bueno, A.C.; Wang, Z.V.; Pollard, J.W.; Brekken, R.A.; Scherer, P.E. Dichotomous effects of VEGF-A on adipose tissue dysfunction. Proc. Natl. Acad. Sci. USA 2012, 109, 5874–5879. [Google Scholar] [CrossRef]
  37. Novikova, V.; Gritsinskaya, V.; Petrenko, Y.V.; Gurova, M.; Gurina, O.; Varlamova, O.; Blinov, A.; Strukov, E.; Smirnova, N.; Kuprienko, N.; et al. Level of erythropoietin, sVCAM-1 and VEGF in blood of obese adolescents. Abstracts 2021, 106, A87–A88. [Google Scholar] [CrossRef]
  38. Loebig, M.; Klement, J.; Schmoller, A.; Betz, S.; Heuck, N.; Schweiger, U.; Peters, A.; Schultes, B.; Oltmanns, K.M. Evidence for a Relationship between VEGF and BMI Independent of Insulin Sensitivity by Glucose Clamp Procedure in a Homogenous Group Healthy Young Men. PLoS ONE 2010, 5, e12610. [Google Scholar] [CrossRef]
  39. Guzmán-Guzmán, I.P.; Zaragoza-García, O.; Vences-Velázquez, A.; Castro-Alarcón, N.; Muñoz-Valle, J.F.; Parra-Rojas, I. Concentraciones circulantes de MCP-1, VEGF-A, sICAM-1, sVCAM-1, sE-selectina y sVE-cadherina: Su relación con componentes del síndrome metabólico en población joven [Circulating levels of MCP-1, VEGF-A, sICAM-1, sVCAM-1, sE-selectin and sVE-cadherin: Relationship with components of metabolic syndrome in young population]. Med. Clin. 2016, 147, 427–434. [Google Scholar] [CrossRef]
  40. Dabravolski, S.A.; Khotina, V.A.; Omelchenko, A.V.; Kalmykov, V.A.; Orekhov, A.N. The Role of the VEGF Family in Atherosclerosis Development and Its Potential as Treatment Targets. Int. J. Mol. Sci. 2022, 23, 931. [Google Scholar] [CrossRef] [PubMed]
  41. Schwingshackl, L.; Schwedhelm, C.; Hoffmann, G.; Knüppel, S.; Iqbal, K.; Andriolo, V.; Bechthold, A.; Schlesinger, S.; Boeing, H. Food Groups and Risk of Hypertension: A Systematic Review and Dose-Response Meta-Analysis of Prospective Studies. Adv. Nutr. Int. Rev. J. 2017, 8, 793–803, Correction in Adv Nutr. 2018, 9, 163–164. [Google Scholar] [CrossRef] [PubMed]
  42. Hojhabrimanesh, A.; Akhlaghi, M.; Rahmani, E.; Amanat, S.; Atefi, M.; Najafi, M.; Hashemzadeh, M.; Salehi, S.; Faghih, S.; Akhlaghi, M. A Western dietary pattern is associated with higher blood pressure in Iranian adolescents. Eur. J. Nutr. 2017, 56, 399–408. [Google Scholar] [CrossRef]
  43. Shokri, A.; Pirouzpanah, S.; Foroutan-Ghaznavi, M.; Montazeri, V.; Fakhrjou, A.; Nozad-Charoudeh, H.; Tavoosidana, G. Dietary protein sources and tumoral overexpression of RhoA, VEGF-A and VEGFR2 genes among breast cancer patients. Genes Nutr. 2019, 14, 22. [Google Scholar] [CrossRef] [PubMed]
  44. Chiarelli, F.; Spagnoli, A.; Basciani, F.; Tumini, S.; Mezzetti, A.; Cipollone, F.; Cuccurullo, F.; Morgese, G.; Verrotti, A. Vascular endothelial growth factor (VEGF) in children, adolescents and young adults with Type 1 diabetes mellitus: Relation to glycaemic control and microvascular complications. Diabet. Med. 2000, 17, 650–656. [Google Scholar] [CrossRef]
  45. Swann, O.G.; Breslin, M.; Kilpatrick, M.; O’Sullivan, T.A.; Mori, T.A.; Beilin, L.J.; Oddy, W.H. Dietary fibre intake and its association with inflammatory markers in adolescents. Br. J. Nutr. 2021, 125, 329–336. [Google Scholar] [CrossRef] [PubMed]
  46. Lu, C.-W.; Lee, Y.-C.; Kuo, C.-S.; Chiang, C.-H.; Chang, H.-H.; Huang, K.-C. Association of Serum Levels of Zinc, Copper, and Iron with Risk of Metabolic Syndrome. Nutrients 2021, 13, 548. [Google Scholar] [CrossRef]
  47. Wong, M.M.H.; Chan, K.Y.; Lo, K. Manganese Exposure and Metabolic Syndrome: A Systematic Review and Meta-Analysis. Nutrients 2022, 14, 825. [Google Scholar] [CrossRef]
  48. Ma, J.; Zhou, Y.; Wang, D.; Guo, Y.; Wang, B.; Xu, Y.; Chen, W. Associations between essential metals exposure and metabolic syndrome (MetS): Exploring the mediating role of systemic inflammation in a general Chinese population. Environ. Int. 2020, 140, 105802. [Google Scholar] [CrossRef]
Nutrients 15 01884 g001a 550Nutrients 15 01884 g001b 550Nutrients 15 01884 g001c 550
Figure 1. Violin plots depicting the distribution of (A) logBMI, (B) logSBP and (C) logHDL between the two groups of the 9-SNP VEGF-A unweighted GRS (low versus high), separated by the sample median (p-values < 0.05).
Figure 1. Violin plots depicting the distribution of (A) logBMI, (B) logSBP and (C) logHDL between the two groups of the 9-SNP VEGF-A unweighted GRS (low versus high), separated by the sample median (p-values < 0.05).
Nutrients 15 01884 g001aNutrients 15 01884 g001bNutrients 15 01884 g001c
Table
Table 1. List of the VEGF-A-related single-nucleotide polymorphisms (SNPs) (n = 11) investigated for cardiometabolic associations in the TEENAGE cohort.
Table 1. List of the VEGF-A-related single-nucleotide polymorphisms (SNPs) (n = 11) investigated for cardiometabolic associations in the TEENAGE cohort.
Consortial Summary StatisticsTEENAGE Cohort
SNPGeneChrPositionAllelesMAFEffect AlleleDirection of Effect for VEGFEAF Ref.
rs114694170MEF2C, MEF2C-AS155:88884379T/C0.02 (C)TNegative (beta = −0.15)0.96[6]
rs6921438SCIRT, LOC10013235466:43957870G/A/C0.44 (A)ANegative (beta = −0.72)0.39[6,7]
rs1740073LINC02537, SCIRT, C6orf22366:43979661T/A/C0.20 (T)TPositive (beta = 0.09)0.35[6]
rs4416670SCIRT66:43982716T/A/C0.47 (C)CNegative (beta = −0.13)0.44[7]
rs6993770ZFPM2-AS1,ZFPM288:105569300A/T0.36 (T)TNegative (beta = 0.17)0.31[6,7]
rs7043199VLDLR-AS199:2621145T/A0.11 (A)ANegative (beta = −0.10)0.19[6]
rs10738760VLDLR, KCNV299:2691186A/G0.41 (G)GNegative (beta = −0.28)0.46[7]
rs2375981VLDLR, KCNV299:2692583 C/A/G/T0.41 (G)CPositive (beta = 0.21)0.44[6]
rs74506613/proxy rs10761741 usedJMJD1C1010:63306426G/T0.37 (T)TPositive (beta = 0.08)0.47[6]
rs4782371ZFPM11616:88502423T/A/C/G0.41 (G)TNegative (beta = −0.07)0.36[6]
rs2639990ZADH21818:75203596T/C0.10 (C)TPositive (beta = 0.11)0.10[6]
SNP: Single-Nucleotide Polymorphism, Chr: Chromosome, bp: base pairs, MAF: Minor Allele Frequency (as shown in GWAS Catalog), Ref.: Reference.
Table
Table 2. Descriptive characteristics of the TEENAGE Study.
Table 2. Descriptive characteristics of the TEENAGE Study.
AllBoysGirls
nMedian (IQR)nMedian (IQR)nMedian (IQR)p-Value *
Age (years)76613.30 (1.31)34913.36 (1.38)41713.26 (1.25)<0.001
BMI (kg/m2)76620.88 (4.38)34920.85 (4.45)41720.93 (4.37)0.517
Triglycerides (mg/dL)61156.00 (24)28355.00 (25)32857.00 (24)0.090
Total Cholesterol (mg/dL)611157.00 (33)283156.49 (25.18) **328157.50 (31)0.210
SBP (mmHg)743119.00 (16)335120.67 (11.93) **408118.00 (15)0.001
DBP (mmHg)74370.00 (12)33571.00 (12)40870.00 (12)0.825
PP74347.00 (13)33549.23 (10.61) **40846 (12)<0.001
LDL (mg/dL)61154.00 (16)28390.57 (21.78) **32888.40 (26)0.651
HDL (mg/dL)61189.20 (27)28353.00 (16)32856.00 (17)0.001
Glucose (mg/dL), 61180.00 (12)28381.00 (11)32879.00 (12)<0.05
CRP (mg/dL)5400.30 (1)2540.45 (1)2860.20 (0)<0.001
BMI: Body Mass Index, SBP: Systolic Blood Pressure, DBP: Diastolic Blood Pressure, PP: Pulse Pressure, HDL: High-density lipoprotein cholesterol, LDL: Low-density lipoprotein cholesterol, CRP: C-reactive protein. * Hypothesis testing took place via use of the Mann–Whitney test. ** The variable summary statistics are shown as mean ± standard deviation (SD).
Table
Table 3. Associations between the 11 VEGF-A-related SNPs and cardiometabolic indices in the TEENAGE cohort.
Table 3. Associations between the 11 VEGF-A-related SNPs and cardiometabolic indices in the TEENAGE cohort.
Model 1Model 2Model 3
Betap-ValueBetap-ValueBetap-Value
LogBMI
rs1146941700.010090.34240.013170.23850.012390.2707
rs6921438−0.006310.1131−0.00530.2038−0.004750.2564
rs17400730.0055310.17850.0036640.38260.0027840.5088
rs4416670−0.006980.06125−0.003890.3099−0.003630.3452
rs6993770−0.006490.1252−0.008660.04606−0.008580.0483
rs7043199−0.012650.01352−0.012020.02304−0.011850.02551
rs107387600.0031470.42080.0023410.55880.002030.6125
rs23759810.0034260.38830.0028370.48460.0024720.5432
rs107617410.0030550.44670.0034550.39780.0030620.4544
rs47823710.004420.28330.0031580.45760.0029530.4892
rs2639990−0.002970.6463−0.002320.7241−0.00210.7516
logTriglycerides
rs1146941700.0089070.72740.028280.29780.0290.292
rs69214380.0010280.91840.013190.20070.013280.2003
rs17400730.0062610.54730.0025730.80580.002530.8107
rs44166701.83 × 10−50.99840.005130.58270.0048980.6018
rs69937700.0060580.5595−0.003070.7726−0.003320.7567
rs7043199−0.016810.1822−0.017870.1588−0.019380.1304
rs10738760−0.023820.01482−0.02010.04157−0.02010.04306
rs2375981−0.019950.04558−0.016750.09515−0.016960.09375
rs107617410.0041580.6738−0.002540.7989−0.001980.844
rs4782371−0.000710.94480.001890.85710.0019440.8546
rs2639990−0.014280.3776−0.013090.4196−0.01380.4033
logCholesterol
rs114694170−0.003140.7859−0.007830.5438−0.008960.4916
rs6921438−0.000510.91110.0002540.9586−9.61 × 10−50.9844
rs17400730.0007670.87060.0002250.9639−0.000330.947
rs44166700.0018490.65640.0040520.36020.0043030.3322
rs69937700.00420.37090.0028850.5670.0027290.5901
rs7043199−0.000660.908−9.11 × 10−50.9879−0.001070.8596
rs10738760−0.002560.5642−0.003550.4489−0.003510.4558
rs2375981−0.003570.4299−0.004460.3497−0.004240.3768
rs10761741−0.006420.1503−0.008560.0695−0.00870.06685
rs47823710.0033280.47360.0016010.74780.0021730.6649
rs2639990−0.003370.645−0.005210.4986−0.003150.6864
logSBP
rs1146941700.0048560.46020.010950.13220.010020.1704
rs6921438−0.005280.03273−0.005710.03214−0.006140.02126
rs17400730.0062110.014560.0070360.0084350.0071130.007929
rs4416670−0.007070.002172−0.007440.002407−0.007160.003524
rs6993770−0.0050.05437−0.004890.07711−0.0050.07093
rs70431990.0073570.021040.0095940.0043380.0094460.005093
rs10738760−0.001050.6643−0.000180.9445−0.00020.9368
rs2375981−0.000480.84640.0004750.85490.0006760.7948
rs107617410.0043940.075590.0035740.17110.0036340.1643
rs4782371−0.00170.5082−0.001480.5885−0.000990.7192
rs2639990−0.000270.9467−0.001810.6667−0.001120.7913
logDBP
rs114694170−0.005380.5747−0.000230.9829−0.000730.945
rs6921438−0.006170.08685−0.008040.03627−0.008450.0283
rs17400730.0055990.13110.0067550.079750.0069830.07167
rs4416670−0.005560.09872−0.006860.05272−0.006610.06318
rs6993770−0.006210.101−0.00430.281−0.004430.2685
rs70431990.011910.010330.013590.0050510.01380.004611
rs107387606.32 × 10−60.99860.0016390.65750.0016420.6579
rs2375981−0.000220.95080.0017810.63390.0020480.5851
rs107617410.0053850.1350.0064350.087010.0065010.0848
rs47823710.0005050.89280.0020550.60270.0027890.4824
rs26399900.0042130.46710.0030250.61630.0035980.5553
logPP
rs1146941700.021690.17990.030110.08770.028920.1044
rs6921438−0.004290.4814−0.001360.8342−0.001660.7989
rs17400730.0083540.18260.0082060.20630.0079790.223
rs4416670−0.012320.03026−0.010750.07144−0.01040.08316
rs6993770−0.00030.9623−0.003130.6417−0.00310.6466
rs7043199−0.001190.87980.0023930.770.0014660.859
rs10738760−0.00210.7244−0.001560.8026−0.001420.8201
rs2375981−0.000330.9559−0.000170.97869.90 × 10−50.9875
rs107617410.0050410.40810.0009310.88320.0008390.8954
rs4782371−0.006630.2943−0.008460.2027−0.008440.2076
rs2639990−0.005710.5596−0.008650.3943−0.007330.4765
logGlucose
rs1146941700.019150.42590.018440.4880.014990.5762
rs6921438−0.006840.4689−0.010780.2855−0.012270.2245
rs17400730.009420.33610.0070990.48790.0067080.5143
rs44166700.0008320.92350.0003460.96980.0002230.9806
rs6993770−0.010430.2856−0.005690.5839−0.006790.5148
rs70431990.0084240.47820.0084280.49730.0062930.6144
rs107387600.0068660.4570.0038220.69270.0026420.7852
rs23759810.0071880.4450.0043440.65880.0035120.722
rs107617410.0034650.70950.0046640.63220.0063170.5187
rs4782371−0.014970.1213−0.009680.3456−0.009540.3557
rs2639990−0.001270.9336−0.00420.7913−0.003590.8233
logLDL
rs114694170−0.00820.6443−0.020020.3046−0.021870.2661
rs6921438−0.005020.4711−0.004180.573−0.004190.5718
rs17400730.0009880.8914−0.000910.9035−0.00220.7704
rs44166700.0019870.75580.0062260.35290.0068930.3039
rs6993770−0.002810.6968−0.005810.4461−0.005510.4718
rs70431990.0067250.44310.0060130.50940.0053370.5605
rs10738760−0.010290.1306−0.011860.09438−0.011450.1071
rs2375981−0.012740.06626−0.014250.04787−0.013720.05769
rs10761741−0.005190.4493−0.007940.2667−0.00910.2047
rs47823710.011350.11150.0077830.30150.0082570.2758
rs2639990−0.003880.7136−0.007130.517−0.007440.5042
logHDL
rs1146941700.0011510.9449−0.000310.9867−0.001110.9524
rs69214380.0022310.73320.000560.9363−0.000140.9837
rs17400730.0020990.75720.0055970.43030.006060.3951
rs44166700.0024020.68870.0001270.984−0.000210.9737
rs69937700.011510.088930.01480.039530.014270.04781
rs7043199−0.007110.3875−0.004290.6186−0.005850.4992
rs107387600.014090.027290.012490.062060.012230.06815
rs23759810.012610.052750.011390.094540.011290.09822
rs10761741−0.010290.1098−0.010980.1037−0.009750.15
rs4782371−0.007620.2552−0.00720.3117−0.00680.3417
rs2639990−0.003880.7136−0.007130.517−0.007440.5042
logCRP
rs114694170−0.03790.6541−0.042370.6554−0.035210.711
rs6921438−0.04180.1947−0.044140.2017−0.040390.241
rs1740073−0.004330.8972−0.01810.606−0.024660.482
rs4416670−0.01940.511−0.015280.6242−0.01620.6012
rs6993770−0.017180.6107−0.003390.9251−0.00480.8941
rs70431990.026660.50290.0033780.93530.0004550.9913
rs107387600.023190.46580.022420.50160.023710.4762
rs23759810.028670.37470.026030.4410.025720.4462
rs107617410.02370.45880.014150.67350.012070.7179
rs4782371−0.040920.2165−0.036580.3002−0.036890.2958
rs2639990−0.055230.2803−0.056470.2884−0.051930.3325
Model 1: Adjusted for age and sex, Model 2: Adjusted for age, sex and exercise, Model 3: Adjusted for age, sex, exercise and dietary patterns. BMI: Body Mass Index, SBP: Systolic Blood Pressure, DBP: Diastolic Blood Pressure, PP: Pulse Pressure, LDL: Low-density cholesterol, HDL: High-density cholesterol, CRP: C-reactive protein.
Table
Table 4. Associations between the 9-SNP uGRS and selected cardiometabolic indices in the TEENAGE cohort.
Table 4. Associations between the 9-SNP uGRS and selected cardiometabolic indices in the TEENAGE cohort.
Model 1Model 2Model 3
EstimateSEp-ValueEstimateSEp-ValueEstimateSEp-Value
logBMI
9-SNP uGRS for VEGF-A0.0044450.0014940.003050.0043490.0015530.0052770.00409370.00156780.009281
logTriglycerides
9-SNP uGRS for VEGF-A0.0058920.0038540.1270.0042600.0039150.27710.0046500.0039940.2450
logCholesterol
9-SNP uGRS for VEGF-A−0.00019790.00174790.90992−0.0007160.0018590.70024−0.00076850.00189170.68474
logSBP
9-SNP uGRS for VEGF-A0.0020060.0009240.03030.00198400.00099740.0472030.00209830.00100450.037205
logDBP
9-SNP uGRS for VEGF-A0.0018910.0013510.1619630.0022110.0014410.125690.0023650.0014550.10458
LogPP
9-SNP uGRS for VEGF-A0.0024250.0022680.28540.0015990.0024130.507790.00155230.00244390.52558
LogGlucose
9-SNP uGRS for VEGF-A0.00090570.00364480.8040.0019520.0038400.6110.00284150.00389890.4665
logLDL
9-SNP uGRS for VEGF-A0.0030380.0026880.25890.0023000.0028180.41480.0017330.0028630.5454
LogHDL
9-SNP uGRS for VEGF-A−0.0053360.0024930.03279−0.0049990.0026310.05812−0.0044550.0026730.09630
LogCRP
9-SNP uGRS for VEGF-A0.0014370.0123970.90778−0.00016630.01310080.98988−0.0016310.0132500.90207
Model 1: Adjusted for age and sex, Model 2: Adjusted for age, sex and exercise, Model 3: Adjusted for age, sex, exercise and dietary patterns. BMI: Body Mass Index; SBP: Systolic Blood Pressure; DBP: Diastolic Blood Pressure; PP: Pulse Pressure; LDL: Low-density cholesterol; HDL: High-density cholesterol; CRP: C-reactive protein; SE: Standard Error.
Table
Table 5. Associations between the 9-SNP uGRS for VEGF-A and dietary patterns in the TEENAGE cohort.
Table 5. Associations between the 9-SNP uGRS for VEGF-A and dietary patterns in the TEENAGE cohort.
Model 1 *Model 2 *
EstimateSEp-ValueEstimateSEp-Value
logBMI
uGRS*Western Breakfast0.00062590.00165440.705320.00096230.00166990.564684
uGRS*Legumes and Good Fat0.00043620.00141150.75742−0.00029510.00150270.844375
uGRS*Homemade Meal−0.0018360.0013020.15906−0.0018940.0013260.153652
uGRS*Chicken and Sugars−0.0019550.0014420.17566−0.0015080.0015770.339236
uGRS*Eggs and Fibers−0.0006870.0012040.568400.00043250.00146160.767393
logTriglycerides
uGRS*Western Breakfast−0.0039760.0041210.335−0.0033940.0041470.4135
uGRS*Legumes and Good Fat−0.0030840.0036430.398−0.0029930.0037010.4192
uGRS*Homemade Meal−0.00036730.00315210.907−0.00042490.00310420.8912
uGRS*Chicken and Sugars−0.0005620.0035270.8730.0004460.0037230.9047
uGRS*Eggs and Fibers0.00047140.00291630.872−8.952 × 10−73.645 × 10−30.9998
logCholesterol
uGRS*Western Breakfast−0.00031200.00186730.86737−0.00035950.00196520.85495
uGRS*Legumes and Good Fat4.399 × 10−41.654 × 10−30.790380.00061900.00176040.72529
uGRS*Homemade Meal0.00225440.00142470.114210.00245940.00146790.09455
uGRS*Chicken and Sugars0.00058820.00159970.713240.00114190.00176680.51840
uGRS*Eggs and Fibers−0.00244290.00131710.064231−0.00356540.00172210.0390
logSBP
uGRS*Western Breakfast0.00198350.00101710.051640.00217910.00107160.042500
uGRS*Legumes and Good Fat0.00098000.00086940.26010.0011120.0009660.250296
uGRS*Homemade Meal−0.00040480.00082490.6238−0.00065340.00085080.442827
uGRS*Chicken and Sugars0.00037760.00089870.67450.00034590.00100810.731659
uGRS*Eggs and Fibers−0.00118550.00073410.1068−0.00180730.00093540.053889
logDBP
uGRS*Western Breakfast0.00607530.00147364.28 × 10−50.0056870.0015370.000239
uGRS*Legumes and Good Fat0.00090390.00127130.4773440.0014830.0013960.28856
uGRS*Homemade Meal−0.00089810.00120640.45691−0.0010970.0012290.37234
uGRS*Chicken and Sugars1.822 × 10−51.316 × 10−30.9889600.0012290.0014570.39932
uGRS*Eggs and Fibers0.00018760.00107520.86156−0.00095240.00135590.48273
logPP
uGRS*Western Breakfast−0.0043750.0025010.08081−0.0031790.0026020.22237
uGRS*Legumes and Good Fat0.00067450.00213550.752210.00017650.00233930.93989
uGRS*Homemade Meal0.00015850.00202810.93772−5.986 × 10−52.067 × 10−30.97691
uGRS*Chicken and Sugars0.00067360.00220940.76055−0.0016620.0024420.49637
uGRS*Eggs and Fibers−0.0032350.0018010.07296−0.0025870.0022690.2548
logGlucose
uGRS*Western Breakfast−0.00023710.00389920.952−0.00068820.00406710.866
uGRS*Legumes and Good Fat−0.0040750.0034410.237−0.0025750.0036280.478
uGRS*Homemade Meal−0.00352280.00297730.237−0.0039460.0030390.195
uGRS*Chicken and Sugars0.0035500.0033170.2850.0039220.0036340.281
uGRS*Eggs and Fibers5.869 × 10−32.745 × 10−30.03300.0088300.0035500.0132
logLDL
uGRS*Western Breakfast−0.00038450.00287330.8936−0.00082170.00297910.7828
uGRS*Legumes and Good Fat0.0011020.0025450.66520.0018570.0026690.4870
uGRS*Homemade Meal0.0022290.0021940.31030.0026170.0022300.2412
uGRS*Chicken and Sugars0.00245630.00245630.94680.00087950.00267570.7425
uGRS*Eggs and Fibers−0.0040270.0020240.0472−0.0059500.0026060.0229
logHDL
uGRS*Western Breakfast0.00070580.00266750.791450.0010020.0027890.71958
uGRS*Legumes and Good Fat0.00046280.00235290.84413−7.341 × 10−52.485 × 10−30.97644
uGRS*Homemade Meal0.0037190.0020320.067870.0036930.0020800.07649
uGRS*Chicken and Sugars0.0018800.0022750.409030.0023210.0024960.3529
uGRS*Eggs and Fibers−0.00033720.00188610.85819−0.00070870.00244720.77227
logCRP
uGRS*Western Breakfast−0.0097970.0130820.45430−0.00727810.01363450.59379
uGRS*Legumes and Good Fat0.0028830.0113930.80035−0.00319470.01199860.79019
uGRS*Homemade Meal0.0107950.0098230.272390.0110240.0100100.27144
uGRS*Chicken and Sugars0.0041400.0109790.70632−0.00065920.01200810.95625
uGRS*Eggs and Fibers−0.0062200.0089950.489630.00100380.0116440.93135
* Model 1: Adjusted for age, sex, uGRS and each dietary pattern, Model 2: Adjusted for age, sex, and exercise. uGRS and each dietary pattern. BMI: Body Mass Index; SBP: Systolic Blood Pressure; DBP: Diastolic Blood Pressure; PP: Pulse Pressure; LDL: Low-density cholesterol; HDL: High-density cholesterol; CRP: C-reactive protein; SE: Standard Error.
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Kafyra, M.; Kalafati, I.P.; Gavra, I.; Siest, S.; Dedoussis, G.V. Associations of VEGF-A-Related Variants with Adolescent Cardiometabolic and Dietary Parameters. Nutrients 2023, 15, 1884. https://doi.org/10.3390/nu15081884

AMA Style

Kafyra M, Kalafati IP, Gavra I, Siest S, Dedoussis GV. Associations of VEGF-A-Related Variants with Adolescent Cardiometabolic and Dietary Parameters. Nutrients. 2023; 15(8):1884. https://doi.org/10.3390/nu15081884

Chicago/Turabian Style

Kafyra, Maria, Ioanna Panagiota Kalafati, Ioanna Gavra, Sophie Siest, and George V. Dedoussis. 2023. "Associations of VEGF-A-Related Variants with Adolescent Cardiometabolic and Dietary Parameters" Nutrients 15, no. 8: 1884. https://doi.org/10.3390/nu15081884

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