Figures
Abstract
Leptin is a hormone synthesized by adipocytes and other tissues, including the placenta, and it regulates food intake and energy expenditure, reproductive and immune functions. To investigate the role of leptin in neonatal immunity, we measured serum leptin and cytokine (IFN-γ, TNF-α, IL-2, IL-4, IL-10, IL-12) levels in the cord blood (cb) of 510 healthy neonates, 14 small for gestational age (SGA), 312 appropriately grown for gestational age (AGA) and 184 large for gestational age (LGA). Median serum leptin concentration in the whole sample was 11 ng/ml. In 11.2% neonates (1 SGA, 32 AGA, 24 LGA), leptin levels were >90th percentile (median 39 ng/ml). In 33.3% of those (3.72% of total sample) with the highest leptin levels (median 46 ng/ml), significantly elevated levels of serum IFN-γ were also found (mean 27.11 pg/ml, range 17.5–38.5 pg/ml). In neonates with leptin levels ∼50th percentile (median 12 ng/ml) or <10th percentile (median 1 ng/ml), serum IFN-γ levels were negligible. All other cytokines measured, were < the assays’ detection limits. To investigate whether leptin can independently influence cytokine gene expression by cb T-cells and monocytes (Mc), we cultured cb T-cells or Mc, isolated from randomly selected AGA neonates or adult peripheral blood, with leptin. This resulted in upregulation of IL-2, IFN-γ and IL-4 gene expression in cb and adult T-cells and IL-10 expression mainly in cb-Mc. Significantly higher expression of IFN-γ occurred in female cb-T-cells cultured with leptin, compared with male cb-T-cells. In conclusion, the concurrent presence of high concentrations in both leptin and IFN-γ in cb of healthy infants, and leptin’s ability to directly upregulate cytokine gene expression in cb T and Mc cells, indicate that abnormally high leptin levels can independently influence the immune system of healthy newborns, and may mediate gender differences in the development of a Th1 polarized immune response.
Citation: Mouzaki A, Panagoulias I, Raptis G, Farri-Kostopoulou E (2012) Cord Blood Leptin Levels of Healthy Neonates Are Associated with IFN-γ Production by Cord Blood T-Cells. PLoS ONE 7(7): e40830. https://doi.org/10.1371/journal.pone.0040830
Editor: Nick Gay, University of Cambridge, United Kingdom
Received: December 2, 2011; Accepted: June 15, 2012; Published: July 16, 2012
Copyright: © 2012 Mouzaki et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: The authors have no support or funding to report.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Leptin, a 16 kDa non-glycosylated polypeptide product of the obese (ob) gene [1], is an adipocyte-derived hormone that participates in the regulation of energy homeostasis [2], neuroendocrine function [3], angiogenesis [4], [5], bone formation [6] and reproduction [7]. The central action of leptin, is mediated by binding to its hypothalamic receptors [8], [9]. Leptin is structurally similar to long-chain helical cytokines [10], [11] and it signals through its receptor, OB-R [11], which is a member of the cytokine receptor superfamily. Leptin is mainly expressed in the adipose tissue, but also in the placenta, bone marrow, stomach, brain, muscle and fetal tissues [12], [13]. In pregnancy, leptin regulates fetal growth, placental angiogenesis and mobilization of maternal fat [13]. Serum leptin levels in pregnant women are significantly higher than in non-pregnant women [14]. The human placenta expresses high amounts of leptin mRNA and protein in early, mid, and late gestation [14], [15]. Adipocytes have not been found in placental tissue [16].
There is no correlation between maternal leptin levels and fetal weight, whereas several studies have reported that umbilical cord blood leptin levels correlate with fetal insulin, birth weight, ponderal index, length and head circumference [17], [18], [19]. The higher leptin levels in umbilical veins compared with umbilical arteries, and the marked fall during the neonatal period, indicate that the human placenta is a major source of leptin in the fetal circulation [20].
There is growing evidence that leptin regulates the maturation of the fetal and neonatal immune system: Mice lacking leptin or its functional receptor have a number of defects in both cell-mediated and humoral immunity [21], [22]. Similarly, humans with congenital leptin deficiency have a much higher incidence of infection-related death during childhood [23]. In the latter, administration of exogenous leptin reverses their abnormal immunophenotype, T-cell hyporesponsiveness and Th2 cytokine production [24].
Leptin affects both the endocrine and immune systems, and there is functional connection and anatomical contiguity between adipocytes and lymphoid cells [25]. In innate immunity, leptin seems to promote the activation of monocytes, dendritic cells and macrophages, and stimulates them to produce pro-inflammatory cytokines [26], [27] or the anti-inflammatory cytokine IL-10 [28], [29]. In NK cells, leptin is involved in all processes of cell development, differentiation, proliferation, activation, and cytotoxicity [30]. Leptin has been also shown to modulate the adaptive immunity by enhancing T-cell survival, promoting the proliferation of naive but not memory T-cells, and stimulating the production of the Th0/Th1 cytokines IL-2 and IFN-γ [31].
The pro-Th1 immunomodulatory effects of leptin have been linked to enhanced susceptibility to autoimmune or inflammatory diseases, mainly in experimental models [32], [33], [34], [35]. In addition, leptin was shown to inhibit the proliferation of human PBMC-derived natural T regulatory cells [36]. In human autoimmune patients, elevated serum leptin levels occur in certain diseases and may play a causal role in the disease progress [37], [38], [39] although a direct link of leptin to human autoimmune disease pathogenesis has not been yet established [28], [40].
To investigate the role of leptin in neonatal immunity, we measured leptin levels in cord blood of healthy newborns and tested for a possible correlation with cytokine levels. In addition, we studied whether leptin has a direct effect on the expression of pro- and anti-inflammatory cytokine genes in cord blood mononuclear cells, and purified cord blood T-cells and monocytes.
We observed that in a small percentage of neonates leptin levels were very high, and in those neonates IFN-γ levels were also significantly elevated. Culture with leptin, upregulated cytokine gene expression in T-cells and monocytes. In addition, we observed that higher expression of IFN-γ occurred in T-cells derived from the cord blood of female neonates.
Results
Data of Study Subjects
The demographic characteristics of the 510 neonates are shown in Table 1. The anthropometric characteristics of the mothers are shown in Table 2 and of the neonates in Table 3. Group statistics showed that in each group of infants (SGA, AGA, LGA) male and female neonates had similar somatometric characteristics and PI at birth.
Leptin Levels of the Neonates
Serum leptin levels of the neonates are shown in Table 4 and a detailed analysis of median leptin levels vs birth weight of the neonates (presented as total, males and females/weight group) is shown in Figure 1. Leptin was detected in all samples. The median cord blood leptin concentration was 11 ng/ml (range 1–204 ng/ml). There was no significant correlation between the anthropometric characteristics of the mothers (Table 2) and cord blood leptin levels of the newborns (multiple linear regression analyses among 510 term or near-term pregnancies).
Median serum leptin levels in 7 weight categories (g); each includes leptin values for the total sample, male and female infants. The table shows the min. and max. leptin values (ng/ml) and the number of subjects (n) per weight group (total, males, females).
Mean serum leptin levels were 20% higher in females (16.39 ng/ml) than males (13.1 ng/ml) in the total sample. The range of leptin levels in females was much wider, with a maximum reaching 204 ng/ml, compared to a maximum of 49 ng/ml in males. Leptin levels correlated weakly with neonatal birth weight (r = 0.14, P<0.05) and length (r = 0.13, P<0.05). The correlations were relatively stronger for males (r = 0.18, P<0.05 for leptin vs weight and r = 0.19, P<0.05 for leptin vs length) than females (r = 0.12, P<0.05 for leptin vs weight, no significant correlation for leptin vs length).
The 90th percentile (28 ng/ml) was considered as the upper limit of normal leptin levels in neonates.
Figure 2 shows the leptin (ln) mean differences between SGA, AGA and LGA neonates. Leptin (ln) differences between AGA and LGA neonates were statistically significant (P<0.005). LGA neonates had higher leptin levels (mean 2.57 ng/ml) than AGA neonates (mean 2.36 ng/ml). LGA males had statistically significant higher mean leptin levels than AGA males (P<0.05). There were no statistically significant differences between AGA and SGA neonates or LGA and SGA neonates.
Values show mean ± SD. Statistically significant differences are indicated by asterisks (*, P<0.05; **, P<0.01, compared with the Kruskal-Wallis test). The table shows the min. and max. values (ng/ml) and the number of subjects (n) per group (total, males, females).
Analysis of Neonates with High Leptin Levels
In 11.2% neonates (1 SGA, 32 AGA, 24 LGA), leptin levels were well above the 90th percentile, with a median of 39 ng/ml. In a proportion of these neonates (33.3%, 3.72% of the total sample) leptin levels reached max. values (median 46 ng/ml, mean 58.11 ng/ml). To study this group further, we defined 3 groups within our study population (Fig. 3): Group A, consisting of neonates with leptin levels >90th percentile, group B, consisting of neonates with leptin levels around the 50th percentile (median 12 ng/ml, mean 12.41 ng/ml) and group C, consisting of neonates with leptin levels below the 10th percentile (median 1 ng/ml, mean 6.45 ng/ml).
The black circle includes 19 neonates with mean leptin levels over the 90th percentile (group A), the red circle includes 17 neonates with mean leptin levels around the 50th percentile (group B) and the orange circle includes 20 neonates with mean leptin level below the 10th percentile.
Cord blood serum samples were selected from these 3 groups for further analysis. The anthropometric characteristics of the neonates from which these samples were derived are described in Table 5. The leptin levels of groups A, B and C are shown in Figure 4A.
(A) Cord blood leptin levels (ng/ml) in serum of study groups A (n = 19), B (n = 17) and C (n = 20) in the total sample, males and females (mean ± SD). (B) Cytokine serum levels (pg/ml) in groups A, B and C (mean ± SD). (B insert) IFN-γ serum levels in male and female neonates of group A. Statistically significant differences are indicated by asterisks (**, P<0.005, compared with t-test).
Serum Cytokine Levels of Groups A, B and C
The cytokines IL-2, IFN-γ, IL-4, IL-10, IL-12 and TNF-α, were measured in the sera of groups A, B and C (Figure 4B). In group A, significantly elevated levels of serum IFN-γ were found (mean 27.11 pg/ml, range 17.5–38.5 pg/ml). Group A female neonates had higher serum levels of IFN-γ than males (30.5±5.5 pg/ml vs 22.5±3.5 pg/ml, P<0.005) (Figure 4B, insert). IFN-γ in groups B and C was in trace amounts (0–4.44 pg/ml). In all 3 groups, the levels of IL-2, IL-4, IL-10, IL-12 and TNF-α were below or around the detection limits of the assays employed for their detection (M&M).
Leptin levels correlated with IFN-γ levels (r = 0.356, P<0.01 for leptin vs IFN-γ) (Figure 5). There was no correlation between leptin and the other cytokines tested (Supplementary Table S1). To confirm the correlation between leptin and IFN-γ and investigate whether any of the other cytokines interfere with leptin and vice versa, we run a multivariable analysis using the General Linear Model (cf. M&M). The analysis (Supplementary Table S2) confirmed that only the interaction between IFN-γ and leptin was statistically significant (P<0.001).
There was no correlation between leptin and the other cytokines tested. Correlation is significant at the P<0.01 level (2-tailed).
Effect of Rleptin on Cytokine Gene Expression in Cord Blood Mononuclear Cells (CBMC) vs Adult PBMC
Figure 6 depicts the results from RT-PCR performed on CBMC and adult PBMC cultured for 8h in plain culture medium (CM) ± mitogens (P/I) ± rleptin (leptin), run under exactly the same PCR conditions and normalized according to β2 microglobulin expression levels (M&M). After 8h of culture in CM, CBMC expressed none of the cytokine genes tested (IL-2, IFN-γ, IL-4, IL-10) whereas adult PBMC expressed IL-10. Both cb and adult mononuclear cells expressed all the cytokine genes tested when cultured with P/I, but cb cells at significantly lower levels. Culture with rleptin induced the expression of IL-2, IFN-γ and IL-4 genes in both cb and adult cells at comparable levels, and of IL-10 in CBMC. IFN-γ expression was significantly higher in CBMC from female neonates cultured with rleptin.
The cells were cultured for 8h in plain culture medium (CM) or with mitogens (P/I) or with recombinant leptin (leptin). The levels of expression were normalized according to β2m expression levels. Statistically significant differences are indicated by asterisks (***, P<0.001, compared with 2-way ANOVA).
Figure 7 shows the type-1 cytokine (IL-2, IFN-γ) over type-2 cytokine (IL-4, IL-10) gene expression ratio (Fig. 7A), Th1 (IFN-γ) over Th2 (IL-4) gene expression ratio (Fig. 7B), and Th1 (IFN-γ) over IL-10 gene expression ratio (Fig. 7C) in adult PBMC and CBMC cultured with P/I or rleptin. Type-1/type-2, Th1/Th2 and Th1/IL-10 ratios were significantly higher in cb female samples cultured with rleptin than in cb male samples, and comparable to adult levels.
A, type-1 (IL-2+ IFN-γ) over type-2 (IL-4+ IL-10) gene expression ratios; B, Th1 (IFN-γ) over Th2 (IL-4) gene expression ratios; C, Th1 (IFN-γ) over IL-10 gene expression ratios. Results are given as mean ±%CV; asterisks indicate statistical significance (***, P<0.001, compared with 2-way ANOVA).
Effect of Rleptin on Cytokine Gene Expression in Purified Cord Blood or Adult Peripheral Blood T-cells and Monocytes
Table 6 depicts the results from RT-PCR performed on purified cb and adult CD3+ T-cells and CD14+ monocytes cultured ± leptin and processed in parallel. Culture with rleptin induced IL-2, IFN-γ and IL-4 gene expression in T-cells and IL-10 gene expression in monocytes, in different sample proportions. Leptin induced the expression of the cytokine genes in a higher number of female than male cb T or Mc cultures. The values obtained for gene intensities were comparable, with the exception of IFN-γ that was significantly higher in female cb T-cells than male cb T-cells.
Phenotypic analysis showed that cb CD3+ T-cells consisted of 35.6±5% T helper cells (CD3+CD4+) of which 90.5±7% were naive (CD45RA+), and 42.4±15.1% T cytotoxic cells (CD3+CD8+) of which 89.5±10% were naive. Phenotypic analysis of adult CD3+ T-cells showed that they consisted of 47±6% T helper cells of which 42±7% were naive, and 24±7% T cytotoxic cells of which 75±15% were naive. Gender differences were not observed in the phenotypic sub-analyses (not shown).
Leptin induced IL-10 expression in 60% of male and 70% of female cb-Mc samples. Cb-Mc did not express IL-10 after 8h culture, whereas 30% of adult-derived Mc expressed IL-10 after 8h culture. Leptin did not superinduce IL-10 in the IL-10-positive adult Mc samples, but induced IL-10 in 20% of the IL-10-negative adult Mc samples.
Discussion
In a relatively large sample of healthy newborns born to healthy mothers, we found no significant correlation between cord blood leptin levels and anthropometric characteristics of the mothers. Male and female neonates had similar somatometric characteristics and PI at birth. Overall, leptin levels correlated with birth weight and length; the correlations were relatively stronger for males than females, in accordance to [41]. Leptin levels were also higher in females than males; nevertheless, the difference between mean leptin levels in male neonates (13.1±9.37 ng/ml) and female neonates (16.39±19.6 ng/ml) in the whole sample did not reach statistical significance, due to the large SD values in the females. This was reflected in all groups for female neonates i.e. SGA, AGA and LGA. The number of SGA infants included in this study was much smaller than AGA and LGA infants, because we set strict inclusion criteria for neonates, free of any risk factors (M&M), and for these reasons our findings in leptin levels between SGA and AGA or LGA populations did not reach statistical significance. Significantly lower leptin levels have been recorded for SGA infants, compared to AGA, in a study cohort of 190 infants (29 SGA, 161 AGA), that included 52% pre-term and low birth weight infants, of which 22% were SGA [42].
Interestingly, although leptin levels were higher in LGA vs AGA neonates, in accordance to [43], only 9.6% of AGA neonates had leptin levels below the 10th percentile compared to 16.3% of LGA neonates. Overall, a higher proportion of LGA neonates had lower leptin levels than AGA neonates. If leptin levels in cord blood reflect the rate of leptin synthesis by fetoplacental tissues, then leptin may be a factor that regulates growth of the fetus and nutrient partitioning so, in this sense, higher adiposity in LGA healthy infants may result from lower leptin production [44].
In a small proportion of neonates (3.72% of the total sample), with the highest leptin levels (group A, median serum leptin concentration 46 ng/ml), IFN-γ serum levels at birth were elevated (range 17.5–38.5 pg/ml) whereas the rest of the cytokines tested were very low (below or around the detection limits of the assays, cf. M&M). In addition, group A female neonates had significantly higher serum levels of IFN-γ than males. We did not observe increased levels of any of the cytokines tested in the sera of neonates with average (group B) or very low (group C) leptin levels. Elevated serum levels of pro-inflammatory cytokines and, in particular IFN-γ have not been reported for healthy term or near-term infants; rather, elevated cord blood serum levels of IFN-γ and other pro-inflammatory cytokines have been observed in premature infants that developed respiratory distress syndrome soon after birth, as we have shown recently [45].
The medical records of group A newborns and maternal notes were reviewed for any additional information about their intrauterine and perinatal period. It was confirmed that these newborns were free from any environmental or genetic risk factor and no intrauterine or perinatal infection were recorded; 15 were delivered normally and 4 by elective caesarean section.
Experiments carried out to delineate the direct effect of leptin on cord blood-derived mononuclear cells, purified T-cells and monocytes, in comparison with the same cell types derived from healthy adults, showed that activation of the cells by P/I resulted in significantly lower expression of the cytokine genes in CBMC compared to adult PBMC. In addition, cb monocytes did not express any of the cytokine genes tested when cultured for 8h in plain CM, whereas PBMC-derived monocytes expressed IL-10. These results support the conclusions of published reports showing that neonatal immunity is relatively impaired compared to adult immunity [46], [47], [48], [49], [50]. In contrast, CBMC were activated by leptin to express IL-2, IFN-γ, IL-4 and IL-10 genes at comparable levels to adult PBMC.
When CBMC were analysed for cytokine gene expression separately for female and male neonates, a difference was observed in the expression levels of IFN-γ that was significantly higher in female CBMC and in purified female cb T-cells. This was an intriguing finding in the light of recent research demonstrating that IFN-γ acts directly on adipocytes inducing them to release inflammatory chemokines and cytokines [51], [52].
Experiments with purified T-cells and monocytes showed that leptin induced the expression of IL-2, IFN-γ and IL-4 genes in T-cells and IL-10 in monocytes in both CBMC and PBMC samples. Nevertheless, quantitative differences were observed, i.e. cb monocytes responded better to leptin in culture than PBMC monocytes, and a higher proportion of female cb T-cells responded to leptin than male cb or PBMC T-cells. These data cannot be explained by the naive/memory T-cell dichotomy proposed earlier [31], because the phenotypic analysis performed to describe the cb and adult T-cells analyzed in this study, showed that all adult T-cell samples contained a substantial proportion of naive T helper and cytotoxic cells, and, also, gender differences were not observed in the phenotypic sub-analyses. We therefore suggest that the effect of leptin on T-cells is more complicated than previously thought, and future experiments with highly purified T-cell populations isolated from cord blood or adult PBMC will enable us to understand better the biochemical and molecular pathways involved in leptin’s effect on neonatal and adult adaptive immunity.
In Figure 8 we propose a model that shows the cross-regulation of leptin and cytokine production in cord blood. The significantly increased IFN-γ expression of female CBMC or T-cells when cultured with rleptin, indicate that high leptin levels in the neonate may create a Th1 polarization that, in females, may contribute to a propensity to develop T-cell-mediated autoimmunity later in life, as others have shown for hormones [53] or the expression levels of the nuclear receptor peroxisome-proliferator-activated receptor-α in T-cells [54]. To note, the max. values of serum leptin in group A neonates were measured in females, with a maximum reaching 204 ng/ml, whereas the max. value for males was 49 ng/ml. On the other hand, the production of IFN-γ by cord blood cells may protect infants from allergic conditions [46] or susceptibility to the infections of childhood [47].
Leptin is produced by adipocytes (and other tissues including the placenta), binds to its receptor (OB-R) on T-cells and monocytes [29], and directly activates them to express cytokines. T-cells express the Th0/Th1 cytokine genes IFN-γ and IL-2 and the Th2 cytokine gene IL-4, that mediate effector functions [57], and monocytes express IL-10, a main anti-inflammatory cytokine that limits the immune response and prevents damage to the host [58]. In infants with very high leptin levels, leptin stimulation of IFN-γ production by T-cells overrides IL-10 production by monocytes [59]; in this milieu, a Th1 response predominates; in addition, IFN-γ may enhance cytokine stimulation of leptin synthesis by adipocytes [51], [52], [60], [61], [62] and perpetuate the Th1 polarization.
On follow up, interviews were carried out by phone with the parents, or those who had parental responsibility, to enquire about the health status of group A children. It was reported that all group A children were healthy and fully immunized. Their weight and height were between the 50th – 75th percentiles on the growth charts. Detailed follow up of the children, originally entered in the study as neonates, may reveal more aspects of leptin’s role.
Materials and Methods
Study Subjects
Five hundred and ten (510) healthy infants of singleton pregnancies were studied. Selection criteria included uncomplicated perinatal period and term or near term birth (gestational age over 36 weeks and with a birth weight >2,150 g). Three hundred and twelve (312) were AGA infants and 184 were LGA. Fourteen (14) SGA infants with no further abnormalities were also included. These SGA neonates were symmetrical, born at term or near term by normal delivery and they did not need admission to special care unit. They were bottle fed and stayed on the postnatal ward to establish feeds for 3 days.
From the medical records 10 of them were born to multigravida mothers and 4 to primigravida. Maternal booking bloods were negative for infections. Membranes ruptured <18 hours and mother was free of any infection (afebrile, GBS negative, uncomplicated postnatal period). Placenta appeared anatomically normal. Babies never needed resuscitation at birth or screening for sepsis. Babies were discharged home under the care of the community midwife. No subsequent readmissions were recorded in the following 28 days. Other SGA infants were not included in the study because they were regarded as high risk neonates.
Infants with anomalies or who required intensive care were also excluded. Infants whose mothers suffered from any medical complication (including diabetes), who were on any medication (with the exception of iron supplements and vitamins), abused alcohol, drugs or smoked during their pregnancy were excluded.
Birth weight was recorded at birth, using a standard electrical scale by the attending midwife. Height and head circumference were determined within the first 24h of life by a single examiner. Ponderal index (PI) was calculated as an additional postnatal variable for intrauterine growth. PI was calculated as the ratio of the birth weight in grams times 100 to cubed value of the length in cm. The intrauterine status of the infants was categorized as SGA (birth weight below the 10th percentile), AGA (birth weight between 10th and 90th percentiles) and LGA (birth weight higher than the 90th percentile) [55]. Newborn gestational age was determined according to Ballard’s scoring system, assuming two weeks as a reasonable error of the estimated gestational age based upon the first day of the last menstrual period and supported by ultrasound measurements.
Twenty healthy adult volunteers served as controls. They were 12 F, age 27–34 years, BMI 17.3–21.7, serum leptin (ng/ml): mean ± SD 8.8±5.0, median 7.4, and 8M, age 25–56 years, BMI 23.6–26.1, serum leptin (ng/ml): mean ± SD 6.4±1.9, median 7.3.
Adult controls and the women before labor provided written informed consent for the use of their peripheral blood samples or their childrens’ cord blood samples for the purpose of this research, or, if they were unable to read or write, independently witnessed verbal consent was obtained. The study was submitted to and approved by the internal review board and scientific advisory committee of Patras University Hospital, as part of a general application for studies on «the role of cytokines and hormones in the pathogenesis of autoimmune diseases», entailing the use of the study subjects’ clinical data to be used (unamed) in the sections of «Patients, Materials & Methods» and of the blood samples to be used in in vitro experiments to be described in the resulting publications. The Hospital abides by the Helsinki declaration on ethical principles for medical research involving human subjects.
Determination of Serum Leptin and Cytokine Concentrations
The umbilical cord was clamped immediately and umbilical cord blood samples were obtained from the vein, just after an uncomplicated delivery (normal or by elective cesarean section). The serum was separated, aliquoted and stored at −80°C. Serum leptin and cytokine IL-12 levels were measured by ELISA (R&D systems, Minneapolis, USA). The detection limits of the assays were 7.8 pg/ml for leptin and 5 pg/ml for IL-12. Cytokine IFN-γ, TNF-α, IL-2, IL-4 and IL-10 levels were measured by a cytometric bead array (CBA) assay (BD Biosciences, San Diego, USA) for the detection of individual cytokines in sera (flex sets) and analyzed on a BD FACSArray Bioanalyzer. The detection limits of the assays were 1.8 pg/ml for IFN-γ, 1.2 pg/ml for TNF-α, 11.2 pg/ml for IL-2, 1.4 pg/ml for IL-4 and 0.13 pg/ml for IL-10. All samples were analyzed in duplicate.
Cell Isolation, Phenotyping and RT-PCR
Blood samples, cord blood (15–25 ml) from 40 neonates and peripheral blood (10 ml) from 20 adults, were collected in heparinized tubes. Mononuclear cells were isolated by centrifugation over a Ficoll-Paque gradient (Biochrom AG, Berlin, Germany). For isolation of T-cells and monocytes, mononuclear cells were washed 4x with ice-cold RPMI1640 culture medium (Gibco BRL, Gaithersburg, MD) and CD3+ T-cells or CD14+ monocytes were isolated using antibody-coated magnetic bead kits for the isolation of untouched human T-cells or monocytes from PBMC, at a concentration of 106 cells/ml, 2 beads/cell (Dynabeads®, Invitrogen, Biotech ASA, Oslo, Norway). The CD3+ T-cells and CD14+ monocytes were tested by FACS for purity (all samples were >95% pure) with the mouse anti-human monoclonal antibodies: CD3-PE-Cy5 (Beckman Coulter, France) and CD14-FITC (BD Biosciences/Pharmingen, San Diego, CA, USA). CD3+ T-cells were phenotyped further to estimate their content of naive (CD45RA+) T-cells, in the T helper (CD4+) and T cytotoxic (CD8+) cell subsets. The antibodies used were mouse anti-human monoclonal CD4-FITC (BC), CD8-FITC (BC), CD45RA-PE (BD). CD3+ T-cells and CD14+ monocytes were cultured at a concentration of 106 cells/ml for 8h either in plain culture medium (CM) or with the mitogens phorbol myristate acetate (20 ng/ml) and ionomycine (2 µΜ) (P/I) or with recombinant (r) leptin (800 ng/ml) [28]. At the end of the culture period, total RNA was isolated from the cells. One (1) µg of total RNA/sample was reverse transcribed to cDNA using random primers, and RT-PCR was performed at 35 cycles to determine cytokine gene expression levels with specific primers for IL-2, IL-4, IFN-γ and IL-10, using β2 microglobulin mRNA as an endogenous control [56]. The results were quantified by measuring the intensity of the PCR products after agarose gel analysis by the use of the Scion Image program. The levels of expression were normalized according to β2m expression levels. All measurements were done in triplicate.
Statistical Analysis
Serum leptin values were not normally distributed and the data are presented as median (range). The data were normalized by log-transformation and Spearman’s correlations were used to evaluate any relationship among the variables of interest. The rest of the data were normally distributed and are presented as mean ± SD. The differences in baseline characteristics (gestational age, maternal age, ethnicity and gender) were examined by two-way analysis of variance. The differences in newborn’s anthropometric measures and cord blood serum leptin concentration (after ln transformation as appropriate) were examined using a two-way analysis of covariance. Multiple linear regression analysis was used to examine relationships between somatometric and demographic characteristics of the mothers and cord blood leptin levels of the newborns, and between cord blood leptin and cytokine levels. All corrections for multiple comparisons were done with the Bonferroni procedure. Confirmation of correlations was done using the General Linear Model. The Statistical Package for Social Sciences (SPSS), version 17, was used for statistical analysis.
Supporting Information
Table S1.
Matrix representing the correlation between all variables (cytokines and leptin)#. #Spearman’s r for non parametric values. **Correlation is significant at the P<0.01 level (2-tailed).
https://doi.org/10.1371/journal.pone.0040830.s001
(DOCX)
Table S2.
Tests of Between-Subjects Effects#. #Corrected model showing that only the interaction between the IFN-γ and leptin is statistically significant (p<0.001). a, R Squared = 0.242 (Adjusted R Squared = 0.214); b, R Squared = 0.000 (Adjusted R Squared = 0.000); c, R Squared = 0.126 (Adjusted R Squared = 0.093); d, R Squared = 0.032 (Adjusted R Squared = −0.004); e, R Squared = 0.469 (Adjusted R Squared = 0.499).
https://doi.org/10.1371/journal.pone.0040830.s002
(DOC)
Acknowledgments
We thank Dr. E.B. Odeka, University of Manchester, for reviewing the manuscript, Mr. A. Letsios, Techological & Educational Institute of Athens, and Ms. M. Perez-Botella, University of Central Lancashire, for reviewing the statistical analysis, and Dr. E. Jelastopulu, University of Patras, for her help with data presentation at an earlier stage of the study.
Author Contributions
Conceived and designed the experiments: AM. Performed the experiments: IP GR. Analyzed the data: AM IP GR. Contributed reagents/materials/analysis tools: AM IP GR EF-K. Wrote the paper: AM IP GR EF-K.
References
- 1. Zhang Y, Proenca R, Maffei M, Barone M, Leopold L, et al. (1999) Positional cloning of the mouse obese gene and its human homologue. Nature 372: 425–432.
- 2. Morton GJ, Cummings DE, Baskin DG, Barsh GS, Schwartz MW (2006) Central nervous system control of food intake and body weight. Nature 443: 289–295.
- 3. Haynes WG, Morgan DA, Walsh SA, Mark AL, Sivitz WI (1997) Receptor-mediated regional sympathetic nerve activation by leptin. J Clin Invest 100: 270–278.
- 4. Sierra-Honigmann MR, Nath AK, Murakami C, García-Cardeña G, Papapetropoulos A, et al. (1998) Biological action of leptin as an angiogenic factor. Science 281: 1683–1686.
- 5. Bouloumie A, Drexler HC, Lafontan M, Busse R (1998) Leptin, the product of ob gene, promotes angiogenesis. Circ Res 83: 1059–1066.
- 6. Ducy P, Amling M, Takeda S, Priemel M, Schilling AF, et al. (2000) Leptin inhibits bone formation through a hypothalamic relay: a central control of bone mass. Cell 100: 197–207.
- 7. Chehab FF, Lim ME, Lu R (1996) Correction of the sterility defect in homozygous obese female mice by treatment with the human recombinant leptin. Nat Genet 12: 318–320.
- 8. Campfield LA, Smith FJ, Guisez Y, Devos R, Burn P (1995) Recombinant mouse OB protein: evidence for a peripheral signal linking adiposity and central neural networks. Science 269: 546–549.
- 9. Friedman J, Halaas J (1998) Leptin and the regulation of body weight in mammals. Nature 395: 763–770.
- 10. Madej T, Boguski MS, Bryant SH (1995) Threading analysis suggests that the obese gene product may be a helical cytokine. FEBS Let 373: 13–18.
- 11. Tartaglia LA, Dembski M, Weng X, Deng N, Culpepper J, et al. (1995) Identification and expression cloning of a leptin receptor, OB-R. Cell 83: 1263–1271.
- 12. Considine RV (2001) Regulation of leptin production. Rev Endocr Metabol Disord 2: 357–363.
- 13. Hoggard N, Haggarty P, Thomas L, Lea RG (2001) Leptin expression in placental and fetal tissues: does leptin have a functional role? Biochem Soc Trans 29: 57–63.
- 14. Masuzaki H, Ogawa Y, Sagawa N, Hosoda K, Matsumoto T, et al. (1997) Nonadipose tissue production of leptin: Leptin as a novel placenta-derived hormone in humans. Nat Med 3: 1029–1033.
- 15. Henson M, Swan K, O’Neil J (1998) Expression of placental leptin and leptin receptor transcripts in early pregnancy and at term. Obstet Gynecol 92: 1020–1028.
- 16.
Page K (1993) The physiology of the human placenta. UCL Press Limited London, England p.16–25.
- 17. Schubring C, Kiess W, Englaro P, Rascher W, Blum W (1996) Leptin concentrations in amniotic fluid, venous and arterial cord blood and maternal serum: high leptin synthesis in the fetus and inverse correlation with placental weight. Eur J Pediatr 155: 830.
- 18. Ong KKL, Ahmed ML, Sherriff A, Woods KA, Watts A, et al. (1999) Cord blood leptin is associated with size at birth and predicts infancy weight gain in humans. ALSPAC Study Team. Avon Longitudinal Study of Pregnancy and Childhood. J Clin Endocrinol Metab 84: 1145–1148.
- 19. Lepercq J, Lahlou N, Timsit J, Girard J, Hauguelde-Mouzon S (1999) Macrosomia revisited: ponderal index and leptin delineate subtypes of fetal overgrowth. Am J Obstet Gynecol 181: 621–625.
- 20. Yura S, Sagawa N, Mise H, Mori T, Masuzaki H, et al. (1998) Positive umbilical venous-arterial difference of leptin level and its rapid decline after birth. Am J Obstet Gynecol 178: 926–930.
- 21. Mandel MA, Mahmoud AA (1978) Impairment of cell-mediated immunity in mutation diabetic mice (db/db). J Immunol 120: 1375–1377.
- 22. Chandra RK (1980) Cell-mediated immunity in genetically obese (C57BL/6J ob/ob) mice. Am J Clin Nutr 33: 13–16.
- 23. Ozata M, Ozdemir IC, Licinio J (1999) Human leptin deficiency caused by a missense mutation: multiple endocrine defects, decreased sympathetic tone, and immune system dysfunction indicate new targets for leptin action, greater central than peripheral resistance to the effects of leptin, and spontaneous correction of leptin-mediated defects. J Clin Endocrinol Metab 84: 3686–3695.
- 24. Farooqi IS, Matarese G, Lord GM, Keogh JM, Lawrence E, et al. (2002) Beneficial effects of leptin on obesity, T cell hyporesponsiveness, and neuroendocrine/metabolic dysfunction of human congenital leptin deficiency. J Clin Invest 110: 1093–1103.
- 25. Conde J, Scotece M, Gómez R, Gómez-Reino JJ, Lago F, et al. (2010) At the crossroad between immunity and metabolism: focus on leptin. Expert Rev Clin Immunol 6: 801–808.
- 26. Mattioli B, Straface E, Quaranta MG, Giordani L, Viora M (2005) Leptin promotes differentiation and survival of human dendritic cells and licenses them for Th1 priming. J Immunol 174: 6820–6828.
- 27.
Fernández-Riejos P, Najib S, Santos-Alvarez J, Martín-Romero C, Pérez-Pérez A, et al. (2010) Role of leptin in the activation of immune cells. Mediators Inflamm 2010: art. ID 568343.
- 28. Chatzantoni K, Papathanassopoulos P, Gourzoulidou E, Mouzaki A (2004) Leptin and its soluble receptor in plasma of patients suffering from remitting-relapsing multiple sclerosis (MS). In vitro effects of leptin on type-1 and type-2 cytokine secretion by peripheral blood mononuclear cells, T-cells and monocytes of MS patients. J Autoimmun 23: 169–177.
- 29. Mouzaki A, Panagoulias I, Dervilli Z, Zolota V, Spadidea P, et al. (2009) Expression patterns of leptin receptor (OB-R) isoforms and direct in vitro effects of recombinant leptin on OB-R, leptin expression and cytokine secretion by human hematopoietic malignant cells. Cytokine 48: 203–211.
- 30. Tian Z, Sun R, Wei H, Gao B (2002) Impaired natural killer (NK) cell activity in leptin receptor deficient mice: leptin as a critical regulator in NK cell development and activation. Biochem Biophys Res Commun 298: 297–302.
- 31. Lord GM, Matarese G, Howard JK, Baker RJ, Bloom SR, et al. (1998) Leptin modulates the T cell immune response and reverses starvation-induced immunosuppression. Nature 394: 897–901.
- 32. Matarese G, Sanna V, Lechler RI, Sarvetnick N, Fontana S, et al. (2002) Leptin accelerates autoimmune diabetes in female NOD mice. Diabetes 51: 1356–1361.
- 33. Matarese G, Di Giacomo A, Sanna V, Lord GM, Howard JK, et al. (2001) Requirement for leptin in the induction and progression of autoimmune encephalomyelitis. J Immunol 166: 5909–5916.
- 34. Matarese G, Sanna V, Di Giacomo A, Lord GM, Howard JK, et al. (2001) Leptin potentiates experimental autoimmune encephalomyelitis in SJL female mice and confers susceptibility to males. Eur J Immunol 31: 1324–1332.
- 35. Taleb S, Herbin O, Ait-Oufella H, Verreth W, Gourdy P, et al. (2007) Defective leptin/leptin receptor signaling improves regulatory T cell immune response and protects mice from atherosclerosis. Arterioscler Thromb Vasc Biol 27: 2691–2698.
- 36. De Rosa V, Procaccini C, Calì G, Pirozzi G, Fontana S, Zappacosta S, et al. (2007) A key role of leptin in the control of regulatory T cell proliferation. Immunity 26: 241–255.
- 37. Garcia-Gonzalez A, Gonzalez-Lopez L, Valera-Gonzalez IC, Cardona-Muñoz EG, Salazar-Paramo M, et al. (2002) Serum leptin levels in women with systemic lupus erythematosus. Rheumatol Int 22: 138–141.
- 38. Popa C, Netea MG, de Graaf J, van den Hoogen FHJ, Radstake TRDJ, et al. (2009) Circulating Leptin and Adiponectin Concentrations During Tumor Necrosis Factor Blockade in Patients with Active Rheumatoid Arthritis. J Rheumatol 36: 724–730.
- 39. Matarese G, Carrieri PB, Montella S, De Rosa V, La Cava A (2010) Leptin as a metabolic link to multiple sclerosis. Nat Rev Neurol 6: 455–461.
- 40. Rey LK, Wieczorek S, Akkad DA, Linker RA, Chan A, et al. (2011) Polymorphisms in genes encoding leptin, ghrelin and their receptors in German multiple sclerosis patients. Mol Cell Probes 25: 255–259.
- 41. Karakosta P, Chatzi L, Plana E, Margioris A, Castanas E, et al. (2011) Leptin levels in cord blood and anthropometric measures at birth: a systematic review and meta-analysis. Paediatr Perinat Epidemiol 25: 150–163.
- 42. Martos-Moreno GA, Barrios V, Saenz de Pipaon M, Pozo J, Dorronsoro I, et al. (2009) Influence of prematurity and growth restriction on the adipokine profile, IGF1, and ghrelin levels in cord blood: relationship with glucose metabolism. Eur J Endocrinol 161: 381–389.
- 43. Mazaki-Tovi S, Kanety H, Pariente C, Hemi R, Schiff E, et al. (2005) Cord blood adiponectin in large-for-gestational age newborns. Am J Obstet Gynecol 193: 1238–1242.
- 44. Forhead A, Fowden AL (2009) The hungry fetus? Role of leptin as a nutritional signal before birth. J Physiol 587: 1145–1152.
- 45. Varvarigou AA, Thomas I, Rodi M, Economou I, Mantagos S, et al. (2012) Respiratory distress syndrome (RDS) in premature infants is underscored by the magnitude of Th1 cytokine polarization. Cytokine 58: 355–360.
- 46. Pfefferle PI, Sel S, Ege MJ, Büchele G, Blümer N, et al. (2008) Cord blood allergen-specific IgE is associated with reduced IFN-gamma production by cord blood cells: the Protection against Allergy-Study in Rural Environments (PASTURE) Study. J Allergy Clin Immunol 122: 711–716.
- 47. Van Den Biggelaar AHJ, Holt PG (2010) Neonatal immne function and vaccine responses in children born in low-income versus high-income countries. Clin Exp Immunol 160: 42–47.
- 48. Mahdi M, Marodi L (2010) Monocytes in neonatal immunity. NeoReviews 11: 558–565.
- 49. Canto E, Rodriguez-Sanchez JL, Vidal S (2003) Distinctive response of naive lymphocytes from cord blood to primary activation via TCR. J Leukocyte Biol 74: 998–1007.
- 50. Zaghouani H, Hoeman CM, Adkins B (2010) Neonatal immunity: faulty T-helpers and the shortcomings of dendritic cells. Trends Immunol 30: 585–591.
- 51. Rocha VZ, Folco EJ, Sukhova G, Shimizu K, Gotsman I, et al. (2008) Interferon-γ, a Th1 Cytokine, Regulates Fat Inflammation. A Role for Adaptive Immunity in Obesity. Circ Res 103: 467–476.
- 52. Wong N, Fam BC, Cempako GR, Steinberg GR, Walder K, et al. (2011) Deficiency in Interferon-γ Results in Reduced Body Weight and Better Glucose Tolerance in Mice. Endocrinology 152: 3690–3699.
- 53. Bao M, Yang Y, Jun HS, Yoon JW (2002) Molecular mechanisms for gender differences in susceptibility to T cell-mediated autoimmune diabetes in nonobese diabetic mice. J Immunol 168: 5369–5375.
- 54. Dunn SE, Ousman SS, Sobel RA, Zuniga L, Baranzini SE, et al. (2007) Peroxisome proliferator–activated receptor (PPAR)α expression in T cells mediates gender differences in development of T cell-mediated autoimmunity. J Exp Med 204: 321–330.
- 55. Landmann E, Reiss I, Misselwitz B, Gortner L (2006) Ponderal index for discrimination between symmetric and asymmetric growth restriction: Percentiles for neonates from 30 weeks to 43 weeks of gestation. J Matern Fetal Neonatal Med 19: 157–160.
- 56. Mouzaki A, Theodoropoulou M, Gianakopoulos I, Vlaha V, Kyrtsonis MC, et al. (2002) Expression patterns of Th1 and Th2 cytokine genes in childhood idiopathic thrombocytopenic purpura (ITP) at presentation and their modulation by intravenous immunoglobulin G (IVIg) treatment: their role in prognosis. Blood 100: 1774–1779.
- 57. Zhu J, Paul WE (2010) Heterogeneity and plasticity of T helper cells. Cell Res 20: 4–12.
- 58. Couper KN, Blount DG, Riley EM (2008) IL-10: The Master Regulator of Immunity to Infection. J Immunol 180: 5771–5777.
- 59. Chomarat P, Rissoan MC, Banchereau J, Miossec P (1993) Interferon gamma inhibits interleukin 10 production by monocytes. JEM 177: 523–527.
- 60. Gerhardt CC, Romero IA, Cancello R, Camoin L, Strosberg AD (2001) Chemokines control fat accumulation and leptin secretion by cultured human adipocytes. Mol Cell Endocrinol 175: 81–92.
- 61. Trujillo ME, Sullivan S, Harten I, Schneider SH, Greenberg AS, et al. (2004) Interleukin-6 regulates human adipose tissue lipid metabolism and leptin production in vitro. J Clin Endocrinol Metab 89: 5577–82.
- 62. Simons PJ, van den Pangaart PS, van Roomen CPAA, Aerts JMFG, Boon L (2005) Cytokine-mediated modulation of leptin and adiponectin secretion during in vitro adipogenesis: Evidence that tumor necrosis factor-α- and interleukin-1β-treated human preadipocytes are potent leptin producers. Cytokine 32: 94–103.