Abstract
OBJECTIVE
To analyze the relationship between maternal adiponectin (mAdiponectin) and cord blood adiponectin (cbAdiponectin) multimeric forms (high molecular weight [HMW], medium molecular weight [MMW], and low molecular weight [LMW]) in a cohort of gestational diabetes mellitus (GDM) and normal glucose–tolerant (NGT) pregnant women.
RESEARCH DESIGN AND METHODS
A total of 212 women with a singleton pregnancy, 132 with NGT and 80 with GDM, and their offspring were studied. Maternal blood was obtained in the early third trimester and cord blood was obtained at delivery. Total adiponectin and the multimeric forms of adiponectin were determined in cord blood and maternal serum. Spearman rank correlation and stepwise linear correlation analysis were used to assess the relationship between cbAdiponectin levels and clinical and analytical parameters.
RESULTS
No differences in cbAdiponectin concentration or its multimeric forms were observed in the offspring of diabetic mothers compared with NGT mothers. The HMW-to-total adiponectin ratio was higher in cord blood than in maternal serum, whereas the MMW- and LMW-to-total adiponectin ratio was lower. Cord blood total and HMW adiponectin levels were positively correlated with birth weight and the ponderal index (PI), whereas cord blood MMW adiponectin was negatively correlated with the PI. In addition, cbAdiponectin and its multimeric forms were correlated with mAdiponectin concentrations. In the multivariate analysis, maternal multimeric forms of adiponectin emerged as independent predictors of cbAdiponectin, its multimers, and their distribution.
CONCLUSIONS
cbAdiponectin concentrations are independently related to mAdiponectin levels and unrelated to the diagnosis of GDM. Maternal multimeric forms of adiponectin are independent predictors of the concentrations of cbAdiponectin and its multimeric forms at delivery.
Adiponectin is one of the most abundant adipose tissue–specific proteins that is supposed to play a role in the modulation of glucose and lipid metabolism in insulin-sensitive tissues (1). After post-translational modifications, adiponectin is secreted into the bloodstream in three different multimeric forms: a trimeric or low molecular weight form (LMW-Ad), a hexameric or medium molecular weight form (MMW-Ad), and a high molecular weight form (HMW-Ad) (2,3). The amount and distribution of these molecular forms can determine the activity of adiponectin in different tissue (2–4).
The last half of pregnancy is characterized by an insulin-resistant state, and an inverse relationship between adiponectin levels and insulin resistance has been reported (5). Lower adiponectin levels have been observed in gestational diabetes mellitus (GDM) and in obese pregnant women when compared with uncomplicated pregnancies (5–8). Considering the fundamental role of adiponectin in insulin metabolism and the importance of glucose and insulin in fetal growth, maternal adiponectin (mAdiponectin) may play a regulatory role in fetal growth. Unfortunately, the results published to date have yielded inconsistent results (5,9–11). Adiponectin is also present during fetal life and it is detectable in cord serum at as early as 24 weeks of pregnancy (12). Its levels increase markedly during the gestation progresses until delivery, and adiponectin levels in neonates are several fold higher than those reported in adults (13). These findings suggest a role for fetal adiponectin in the modulation of intrauterine growth. However, the role of adiponectin during fetal life is not well known.
A crosstalk between mAdiponectin and fetal metabolism has been proposed. Nevertheless, studies have failed to find a relationship between mAdiponectin and fetal adiponectin (11,13–15). Most of the clinical studies published to date have evaluated total cord blood adiponectin (cbAdiponectin) in the peripartum period, so it has not been possible to establish a long-term modulation of fetal adiponectin production by mAdiponectin levels. We hypothesize that mAdiponectin could influence fetal adiponectin levels during the third trimester of pregnancy, given that the multimeric forms are a key element of this regulation. For this purpose, we have measured mAdiponectin levels in the late second trimester or early third trimester and cbAdiponectin levels at delivery, analyzing the relationship between mAdiponectin and cbAdiponectin levels, its multimeric adiponectin distribution, and its relationship with clinical and metabolic features.
RESEARCH DESIGN AND METHODS
This is a prospective case-control study conducted at the Joan XXIII University Hospital. The study protocol was approved by the Research Ethics Board of the center and all subjects gave written informed consent. Three hundred and seventy-seven pregnant Caucasian women were recruited at the time of antepartum screening for GDM. All of the women who participated underwent a 3-h, 100-g oral glucose tolerance test (OGTT) and were monitored from the time of inclusion to delivery. Serum and plasma samples were kept in a GDM biobank collection. According to the OGTT, women with two or more values above the threshold proposed by the National Diabetes Data Group (16) were considered to have GDM, and women who had all the values below the threshold were classified in the normal glucose–tolerant (NGT) group. In this study we included 212 women that fulfilled the following criteria at the end of pregnancy: 1) a singleton pregnancy, 2) accurate gestational age confirmed by an ultrasound examination before 20 weeks of gestation, 3) the absence of fetal anomalies identified at birth, 4) cord blood sample obtained at delivery, and 5) normal glucose tolerance or GDM diagnosed before 30 weeks of pregnancy. Women with only one value above the threshold after OGTT were excluded from the study. Women with preexisting diabetes, inflammatory or chronic diseases, or current use of drugs known to affect carbohydrate metabolism were also excluded.
GDM women were given an individualized diet with 40% carbohydrates and they were instructed to self-monitor blood glucose six times a day (fasting and 1-h postprandial). Insulin therapy was recommended when fasting glucose levels were repeatedly >95 mg/dL and/or 1-h postprandial values were repeatedly >140 mg/dL. According to these criteria, 51 women were treated only with diet, and 29 women required the addition of insulin.
Clinical and demographic data
Upon inclusion, demographic and historical information was collected by an interviewer-administered questionnaire that included patient demographics, personal medical and obstetrical history, and information regarding the current pregnancy, with special attention to risk factors for GDM. Maternal anthropometric measurements of height and weight were obtained using a medical scale. At the end of pregnancy, data concerning weight gain, gestational age at delivery, and neonatal anthropometry were also collected. BMI was calculated using the formula BMI = weight (kg)/height (m2). Increase in BMI was calculated by the formula BMI gain = final BMI − pregravid BMI. Neonatal length and weight were determined using a measuring board and a calibrated scale. The ponderal index (PI) was calculated using the formula PI = birth weight (g)/[body length (cm)3 ] × 100.
Laboratory measurements
The 100-g OGTT was performed in the morning after overnight fast. Venous blood samples were drawn at baseline and 60, 120, and 180 min after ingestion of a standard 100-g glucose load. Glucose levels were determined in an ADVIA 2400 (Siemens AG, Munich, Germany) autoanalyzer using the standard enzyme methods. Fasting plasma insulin and C-peptide were determined by immunoassay in an ADVIA Centaur System (Siemens AG). This assay shows a cross-reactivity of <0.1% to intact human proinsulin and the primary circulating split form des 31,32 proinsulin. Homeostasis model assessment of insulin resistance (HOMA-IR) was determined according to the following equation: fasting plasma glucose (mmol/L) × fasting plasma insulin (μU/mL)/22.5 (17).
Serum adiponectin levels were determined using a human ELISA kit (Multimeric Adiponectin ELISA Kit; Bühlmann, Schönenbuch, Switzerland). The intra- and interassay coefficient of variations (CVs) were <15%, and assay sensitivity was 0.08 ng/mL. We calculated the ratio of HMW-to-total adiponectin levels (SA) for mAdiponectin and cbAdiponectin concentrations, mSA and cbSA, respectively. In addition, the ratio of MMW- and LMW-to-total adiponectin levels was calculated for maternal (mMMW/Total and mLMW/Total, respectively) and cord blood (cbMMW/Total and cbLMW/Total) determinations.
Statistics
All statistical analysis was performed using SPSS 13.0 software (SPSS, Chicago, IL). Normally distributed data were expressed as the mean ± SD, whereas variables with a skewed distribution were represented as the median (interquartile range). Categorical variables were reported by number (percentages). Student t test analysis was used to compare the mean value of normally distributed continuous variables. For variables with skewed distributions, we used the Mann-Whitney U test. To analyze the differences in nominal variables between groups, we performed the χ2 test. Spearman rank correlation coefficient was used to analyze the bivariate correlation between adiponectin levels and clinical or metabolic parameters. To evaluate the effect of clinical and metabolic variables on the relationship observed between mAdiponectin and cbAdiponectin, we conducted partial correlations. Finally, stepwise multiple regression analysis including mAdiponectin levels and metabolic and clinical variables that could be associated with cbAdiponectin was performed to determine whether mAdiponectin or its isoforms were independently associated with umbilical adiponectin. P < 0.05 was considered significant.
RESULTS
Maternal outcome
The main clinical and metabolic characteristics of the population included in the study are presented in Table 1. The increase in BMI at the end of pregnancy was significantly greater in the NGT group (P < 0.001), whereas no difference in prepregnancy BMI had been observed between groups. A history of GDM in a previous pregnancy was more frequent in the GDM than in the NGT group, whereas no differences were observed in previous delivery of a macrosomic infant or Caesarean section. Fasting insulin (fInsulin) levels and HOMA-IR index were higher in the GDM group.
Table 1.
Whole group | NGT (n = 132) | GDM (n = 80) | P | |
---|---|---|---|---|
Maternal characteristics | ||||
Age (years) | 31.54 ± 4.99 | 31.33 ± 4.86 | 31.88 ± 5.19 | NS |
Gestational age (weeks) | 27 (26.25–29.00) | 27.46 ± 1.40 | 27.51 ± 1.41 | NS |
Parity (n) | 1.00 (0.00–2.00) | 1.00 (0.00–1.00) | 1.00 (0.00–2.00) | NS |
Prepregnancy BMI (kg/m2) | 25.10 ± 5.06 | 24.83 ± 5.13 | 25.56 ± 4.94 | NS |
ΔBMI total (kg/m2) | 4.37 ± 2.12 | 4.79 ± 2.06 | 3.67 ± 2.05 | <0.001 |
Tobacco use n (%) | 36 (17.0) | 21 (15.9) | 15 (18.75) | NS |
Previous GDM n (%)* | 18 (15.52) | 4 (5.8) | 14 (29.8) | 0.001 |
Previous macrosomia n (%)* | 14 (9.07) | 9 (13.0) | 5 (10.6) | NS |
Previous Caesarean section n (%)* | 19 (16.38) | 9 (13.0) | 10 (21.8) | NS |
Glucose (mg/dL) | 82.69 ± 9.59 | 80.69 ± 7.23 | 85.99 ± 11.89 | <0.001 |
Glucose 60’ (mg/dL) | 175.85 ± 38.48 | 154.07 ± 23.46 | 211.79 ± 30.71 | <0.001 |
Glucose 120’ (mg/dL) | 143.26 ± 37.68 | 119.81 ± 21.71 | 181.96 ± 23.98 | <0.001 |
Glucose 180’ (mg/dL) | 109.47 ± 34.34 | 95.42 ± 26.72 | 132.65 ± 33.04 | <0.001 |
A1C (%) | — | — | 4.86 ± 0.39 | |
mTotal-Ad (µg/mL)† | 5.44 ± 2.32 | 5.80 ± 2.37 | 4.85 ± 2.11 | <0.01 |
mHMW-Ad (µg/mL) | 28.01 (1.73–3.92) | 3.27 ± 1.72 | 2.45 ± 1.42 | <0.01 |
mMMW-Ad (µg/mL) | 1.19 ± 0.55 | 1.24 ± 0.56 | 1.12 ± 0.53 | NS |
mLMW-Ad (µg/mL) | 1.11 (0.73–1.58) | 1.29 ± 0.84 | 1.12 ± 0.76 | NS |
mSA | 0.539 ± 0.114 | 0.5440 ± 0.115 | 0.533 ± 0.108 | NS |
mMMW/Total | 0.237 ± 0.095 | 0.230 ± 0.091 | 0.248 ± 0.101 | NS |
mLMW/Total | 0.228 ± 0.115 | 0.226 ± 0.112 | 0.2316 ± 0.122 | NS |
fInsulin (mUI/L) | 8.76 (6.11–14.15) | 7.73 (5.83–13.28) | 10.03 (7.01–15.12) | 0.03 |
HOMA-IR | 1.77 (1.19–2.94) | 1.50 (1.12–2.74) | 2.08 (1.42–3.53) | 0.010 |
Gestational age at delivery (weeks) | 39 (38–40) | 39.37 ± 1.57 | 39.00 ± 1.43 | NS |
Fetal characteristics | ||||
Birth weight (g) | 3,271.48 ± 484.10 | 3,275.91 ± 485.50 | 3,255.67 ± 493.87 | NS |
Ponderal index (kg/m3) | 2.70 ± 0.24 | 2.70 ± 0.24 | 2.69 ± 0.25 | NS |
cbTotal-Ad (µg/mL) | 17.34 ± 6.44 | 17.58 ± 6.31 | 16.94 ± 6.70 | NS |
cbHMW-Ad (µg/mL) | 12.35 ± 5.13 | 12.50 ± 5.04 | 12.03 ± 5.31 | NS |
cbMMW-Ad (µg/mL) | 3.19 ± 1.77 | 3.25 ± 1.78 | 3.09 ± 1.73 | NS |
cbLMW-Ad (µg/mL) | 2.06 (1.086–3.294) | 2.42 ± 1.71 | 2.354 ± 1.94 | NS |
cbSA | 0.702 ± 0.112 | 0.7045 ± 0.117 | 0.700 ± 0.104 | NS |
cbMMW/Total | 0.191 ± 0.086 | 0.194 ± 0.104 | 0.195 ± 0.096 | NS |
cbLMW/Total | 0.133 ± 0.098 | 0.1337 ± 0.094 | 0.130 ± 0.105 | NS |
Cord blood insulin (mU/mL) | 4.47 (2.65–8.03) | 4.34 (2.47–6.89) | 5.36 (3.12–10.72) | 0.010 |
A1C, glycosylated hemoglobin; NS, not significant.
*Only women with a previous pregnancy included in the analysis.
†mAdiponectin was measured early in the third trimester.
Adiponectin and multimeric forms
Total mAdiponectin (mTotal-Ad) and HMW mAdiponectin (mHMW-Ad) levels were higher in the NGT group compared with the GDM group, whereas no differences were observed in the remaining multimeric forms or in their distribution (see Table 1). In the GDM group, the women treated with insulin showed lower mSA values and mHMW-Ad concentrations compared with the group treated only with diet (0.563 ± 0.091 vs. 0.485 ± 0.118, P = 0.002, and 2.93 ± 1.28 vs. 2.22 ± 1.55 µg/mL, P = 0.032, respectively). No other differences were observed between the GDM patients treated only with diet compared with those treated with insulin.
Fetal outcome
One hundred and five of the neonates were male and one hundred and seven were female. No differences were observed in the distribution between NGT and GDM groups. Mean birth weight (BW) and PI were similar in both groups (Table 1).
No differences were observed in total cbAdiponectin, the multimeric forms or cbSA, cbMMW/Total, and cbLMW/Total between NGT and GDM patients. Only cord blood insulin concentration was higher in infants of GDM mothers (Table 1). No differences in total cbAdiponectin levels and cbAdiponectin distribution were observed between the GDM patients treated only with diet and those treated with insulin.
Relationship between mAdiponectin and cbAdiponectin levels
Total adiponectin levels and each of its isoforms were higher in cord blood than in the mother (P < 0.001 for all, see Table 1). Also, the SA was higher in cord blood, but MMW-Ad- and LMW-Ad-to-total adiponectin ratios were lower than in maternal serum (P < 0.001 for all, see Table 1). Similar results were observed when we analyzed the NGT and the GDM groups separately. Hence, the bivariate and multivariate analyses were performed with the whole group.
Bivariate correlation analysis
mAdiponectin with metabolic and clinical variables.
mTotal-Ad and mHMW-Ad levels were negatively correlated with prepregnancy BMI (r = −0.183, P < 0.01, for both), fInsulin (r = −0.340, P < 0.001; and r = −0.376, P < 0.001, respectively) and HOMA-IR (r = −0.325, P < 0.001; and r = 0.367, P < 0.001, respectively). mSA was also negatively correlated with fasting glucose (r = −0.186, P < 0.01), fInsulin (r = −0.284, P < 0.001), HOMA-IR (r = −0.295, P < 0.001), PI (r = −0.200, P < 0.01), and cord blood insulin concentrations (r = −0.140, P < 0.05). Maternal MMW-Ad (mMMW-Ad) was positively correlated with gain in BMI (r = 0.165, P < 0.05) and PI (r = 0.193, P < 0.01), whereas the mMMW/Total was correlated with fInsulin (r = 0.262, P < 0.001), HOMA-IR (r = 0.245, P < 0.001) and PI (r = 0.210, P < 0.01). mLMW/Total concentrations were only marginally related with fasting glucose levels (r = 0.158, P < 0.05).
cbAdiponectin with metabolic and clinical variables.
Cord blood total adiponectin (cbTotal-Ad) and cord blood HMW (cbHMW) were related with the gain in BMI (r = 0.250, P < 0.01; and r = 0.163, P < 0.05, respectively), BW (r = 0.154, P < 0.05; and r = 0.165, P < 0.05), and PI (r = 0.228, P = 0.001; and r = 0.221, P = 0.001). Cord blood MMW adiponectin (cbMMW-Ad) was negatively correlated with PI (r = −0.185, P < 0.01) and, finally, cord blood LMW adiponectin (cbLMW-Ad) was weakly associated with fasting glucose levels (r = 0.184, P < 0.05). A scatterplot figure of the relationship between cbTotal-Ad and PI is available as Supplementary Fig. 1.
mAdiponectin and cbAdiponectin bivariate correlations.
The most significant correlations observed between mAdiponectin and cbAdiponectin and their multimeric forms are presented in Table 2. These associations persisted after controlling for possible confounding factors such as gestational age, maternal prepregnancy BMI, PI, HOMA-IR, and the diagnosis of GDM (Table 2).
Table 2.
cbTotal-Ad |
cbHMW-Ad |
cbMMW-Ad |
cbLMW-Ad |
|||||
---|---|---|---|---|---|---|---|---|
Unadjusted | Adjusted§ | Unadjusted | Adjusted§ | Unadjusted | Adjusted§ | Unadjusted | Adjusted§ | |
mTotal | 0.268‡ | 0.252† | 0.225† | 0.230† | — | — | 0.271‡ | 0.294‡ |
mHMW | 0.221† | 0.188* | 0.225† | 0.210† | — | — | 0.146* | 0.155* |
mMMW | 0.298‡ | 0.282‡ | 0.280‡ | 0.266‡ | 0.251‡ | 0.219† | ||
mLMW | 0.179* | 0.154* | — | — | — | — | 0.452‡ | 0.474† |
§Partial correlation coefficients adjusted for gestational age, prepregnancy BMI, PI, HOMA-IR, and GDM. cbMMW-Ad was correlated in the unadjusted analysis with mMMW-Ad, r = 0.251‡, but not with mTotal-Ad. cbMMW-Ad was correlated in the adjusted analysis with mMMW-Ad, r = 0.219†, but not with mTotal-Ad. cbLMW-Ad was correlated in the unadjusted analysis with mLMW-Ad, r = 0.452‡, but not with mMMW-Ad. cbLMW-Ad was correlated in the adjusted analysis with mLMW-Ad, r = 0.474†, but not with mMMW-Ad.
‡P < 0.001.
†P < 0.01.
*P < 0.05.
In this subset of correlations, when GDM and NGT were studied separately, we observed that the correlation coefficients between MMW-Ad and LMW-Ad were similar in both groups, but there were some differences in the strength of correlations between total adiponectin and HMW-Ad adiponectin. The correlation coefficient for total adiponectin was higher in the GDM group (r = 0.335, P < 0.01, vs. r = 0.193, P < 0.05), and for the HMW isoform it was only significant in the GDM group (r = 0.294, P < 0.01).
Multivariate regression analysis
To analyze the relationship between cord blood and mAdiponectin levels, a stepwise multiple linear regression analysis was performed with dependent variable cbTotal-Ad concentrations. Variables considered for selection in the model included mTotal-Ad, PI, maternal age, gestational age at delivery, GDM, neonatal sex, cord blood insulin, HOMA-IR, pregestational BMI, and gain in BMI. The final regression model identified PI and mTotal-Ad as positive independent determinants and maternal age as a negative determinant of cbTotal-Ad levels (Table 3).
Table 3.
Dependent variable | Variables included in the model | B (95% CI) | P |
---|---|---|---|
cbTotal-Ad (model adjusted r2 = 0.121; P < 0.001)* | mTotal-Ad | 0.743 (0.385–1.101) | <0.001 |
PI | 6.312 (2.802–9.823) | <0.001 | |
Age | −0.186 (−0.357 to −0.015) | 0.033 | |
cbTotal-Ad (model-adjusted r2 = 0.147; P < 0.001)† | mMMW-Ad | 3.397 (1.835–4.958) | <0.001 |
PI | 4.920 (1.316–8.524) | 0.008 | |
mLMW-Ad | 1.194 (0.156–2.231) | 0.024 | |
cbHMW-Ad (model-adjusted r2 = 0.100; P < 0.001)† | mMMW-Ad | 2.399 (1.100–3.688) | <0.001 |
PI | 3.615 (0.641–6.589) | 0.017 | |
cbMMW-Ad (model-adjusted r2 = 0.089; P < 0.001)† | mMMW-Ad | 1.038 (0.575–1.502) | <0.001 |
mHMW-Ad | −0.225 (−0.379 to −0.070) | 0.005 | |
cbLMW-Ad (model-adjusted r2 = 0.236; P < 0.001)† | mLMW-Ad | 1.075 (0.788–1.362) | <0.001 |
*Model 1 covariates considered for selection: PI, maternal age, gestational age at delivery, GDM, neonatal sex, cord blood insulin, HOMA-IR, prepregnancy BMI, and gain in BMI.
†Model 2 covariates considered for selection: PI, maternal age, gestational age at delivery, GDM, neonatal sex, cord blood insulin, HOMA-IR, prepregnancy BMI, gain in BMI, mHMW-Ad, mMMW-Ad, and mLMW-Ad.
We repeated this multiple regression analysis with the introduction of the maternal multimeric forms of adiponectin and the exclusion of total adiponectin in order to determine which of these forms was responsible for the association. mHMW-Ad, PI, and LMW-Ad were positive, independent predictors of cbTotal-Ad (see Table 3).
To further analyze the relationship between maternal and cord blood multimeric forms of adiponectin, we repeated the last multiple regression model with dependent variables cbHMW-Ad, cbMMW-Ad, and cbLMW-Ad, respectively, in place of cbTotal-Ad (Table 3). mMMW-Ad emerged as a positive, independent predictor for both dependent variables cbHMW-Ad and cbMMW-Ad, whereas mHMW-Ad was also a negative, independent predictor of cMMW-Ad. mLMW-Ad was a positive predictor of cbLMW-Ad, and PI was a positive, independent predictor of cbHMW-Ad, the dominant multimeric form in cord blood.
As multimeric form distribution was also different in cord blood compared with maternal serum, we also explored the independent relationship between the ratios of each multimer in cord blood with maternal and neonatal parameters. Stepwise multiple linear regression analyses were performed with dependent variable cbSA, cbMMW/Total, and cbLMW/Total ratios in each model. For cbSA as a dependent variable, mLMW/Total emerged as a negative, independent variable (B = −0.273 [95% CI −0.412 to −0.134]; P < 0.001) and gestational week at delivery as a positive, independent variable (B = 0.014 [0.004–0.024; P = 0.006]). On the other hand, when cbMMW/Total was introduced in the model as a dependent variable, the mMMW/Total ratio was positively associated (B = 0.224 [0.098–0.351; P = 0.001]), whereas gestational week at delivery (B = −0.010 [−0.017 to 0.002; P = 0.013]) was negatively related. Finally, when cbLMW/Total was introduced in the model as a dependent variable, mLMW-Ad (B = 0.031 [0.013–0.048; P = 0.001]) and the mLMW/Total ratio (B = 0.181 [0.013–0.319; P = 0.010]) were the two variables associated with it.
CONCLUSIONS
In this study, we have shown similar concentrations of total adiponectin and its multimeric forms in cord blood of offspring of GDM and NGT mothers as well as similar multimeric form distribution. We also report that the differences in adiponectin levels observed between GDM and NGT pregnant women are restricted to the mHMW-Ad and are present despite similar BMI. Also, our data provide a comprehensive examination regarding the relationship of adiponectin and circulating multimeric forms in cord blood with maternal levels and some clinical and metabolic parameters. Here, we report that umbilical and mAdiponectin concentrations differ not only in total adiponectin and multimeric form levels but also in the distribution of multimeric forms. Likewise, we describe a close relationship between maternal and umbilical adiponectin levels.
Recently, Mazaki-Tovi et al. (6,8) analyzed adiponectin levels and its multimeric forms during pregnancy, but little is known about the distribution of the multimeric forms of adiponectin in cord blood. In our study, similar total adiponectin levels were observed between offspring of GDM and NGT women, as has been reported (18). We also failed to find any difference between both groups in any of the multimeric forms or in their distribution. In contrast, other authors (19,20) have found lower adiponectin levels in cord blood of offspring of GDM compared with control subjects, and this finding was unrelated to gestational age and BW. We have no explanation for this discrepancy, but as cbAdiponectin levels seem to be more closely related to adiposity than BW (18), differences in this parameter could be a possible explanation, and considering that we would remark that in our study, BW and PI were similar in both groups, probably due to the effect of treatment. These data suggest that maternal glucose tolerance status, at least when treated, does not play a relevant role in fetal adiponectin secretion.
We also confirm that cbAdiponectin levels are rather higher than in maternal serum, in agreement with previous observations (21), with the HMW-Ad being the predominant form and the MMW-Ad form being the second in abundance. Interestingly, we also describe a different distribution in the multimeric forms in cord blood than in the maternal serum. Thus, a higher proportion of the SA with a lower ratio of the remaining isoforms was the profile depicted in cord blood in contrast with maternal distribution. This may be important concerning the biological effects of adiponectin, because it has become apparent that not only the absolute amount of adiponectin but also the distribution of the multimeric forms seem to play a role in its biological activity (2–4). In addition, it is interesting that as gestational age progresses, there is an increase in the cbSA ratio while the cbMMW/Total ratio decreases, probably indicating a change in the pattern of adiponectin secretion by fetal tissues as the fetus grows. It is well known that when adiponectin isoforms appear in circulation, they do not interconvert (22), and at the end of pregnancy, there seems to be a decline of adiponectin secretion by nonadipose tissues (23), whereas there is an increase of adiponectin secretion from adipose tissue that produces predominantly HMW-Ad.
The progressive increase in adiponectin levels from week 24 of pregnancy until delivery would suggest a role of this adipokine in the regulation of fetal growth and fat deposition. It has been observed in experimental models that adiponectin is a potent stimulator of adipogenesis (24). Our results support this hypothesis, as we observe that cbTotal-Ad and cbHMW-Ad are positively related with PI and BW, whereas cbMMW-Ad is only inversely related to PI. One is tempted to hypothesize that HMW-Ad stimulates fetal growth and MMW-Ad inhibits it.
The association between mAdiponectin levels and fetal growth are less clear. A negative correlation with BW has been reported by some authors (9,14), but not others (11). We failed to find a relationship, but mSA was inversely related to PI, whereas mMMW-Ad was positively related. These data would suggest an inverse effect of both the mSA and mMMW-Ad on fetal growth. A low mSA is associated with a higher insulin resistance state that could contribute to a metabolically altered environment that favors an increased fetoplacental availability of nutrients and fetal overgrowth.
Interestingly, we observed a relationship between mAdiponectin and umbilical adiponectin levels in the bivariate correlate that persisted after adjustment for factors known to be associated with mAdiponectin levels. In the GDM group, the mHMW isoform had stronger correlation coefficients with cord blood total and HMW adiponectin than the NGT group, so despite similar cbAdiponectin levels in both groups, we cannot rule out that the impaired glucose metabolism may have a role in the crosstalk between mAdiponectin and fetal adiponectin production. Furthermore, in the regression model, mAdiponectin multimers and PI were found to be independent predictors of cbAdiponectin levels. This finding contrasts with previous reports in which no relationship between mAdiponectin and umbilical adiponectin is observed (11,13–15). A possible explanation of these discrepancies may lie in the study design and the population evaluated. We assessed mAdiponectin levels in the early third trimester, before any therapeutic intervention had been started, which allowed us to evaluate a long-term effect on fetal growth and on cbAdiponectin concentrations. As far as we are aware, in other published studies, mAdiponectin levels were obtained in the peripartum period, just before (11,13,14) or after delivery (15). As fetal adiponectin levels increase and mAdiponectin concentration decreases as the pregnancy progresses, differences in the time of extraction could be a possible explanation for the discordant data. Thus, our data would suggest that mAdiponectin early in the third trimester may be one of the factors implicated in the modulation of fetal adiponectin secretion, and that the multimeric forms and their distribution are the most implicated.
This analysis must be interpreted within the context of certain limitations. First, in our study, we have included only Caucasian women and so we cannot extrapolate to other ethnicities. Also, HOMA-IR has limitations as a measure for insulin resistance. However, we noted that the previously observed inverse associations between insulin resistance and mTotal-Ad and mHMW-Ad were also observed in this study. Nevertheless, this study represents one of the first investigations into the specific relationships of HMW-Ad, MMW-Ad, and LMW-Ad in umbilical serum with mAdiponectin levels and metabolic parameters and should lead to further studies.
In conclusion, we report that adiponectin multimeric distribution in cord blood is different than in adult life and is not different in the offspring of GDM and NGT mothers. We also describe that total adiponectin circulating levels and the multimeric forms of adiponectin in cord blood are independently related to PI and the multimeric forms of mAdiponectin, suggesting a crosstalk between mAdiponectin levels and fetal adiponectin production.
Supplementary Material
Acknowledgments
This work was supported by grants FIS PS09/02152, Fondos FEDER, and CIBER de Diabetes y Enfermedades Metabólicas Asociadas CIBERDEM (CB07/08/0012). M.B. is grateful to the Fundació Santiago Dexeus Font for the Maternal and Foetal Medicine grant. V.C.-M. is supported by a fellowship from the Juan de la Cierva programme and Grant JCI-2010-06395. CIBERDEM de Diabetes y Enfermedades Metabólicas Asociadas (CB07708/0012) is an initiative of the Instituto de Salud Carlos III.
No potential conflicts of interest relevant to this article were reported.
Parts of this study were presented at the 47th Annual Meeting of the European Association for the Study of Diabetes, Lisbon, Portugal, 12–16 September 2011.
M.B. held the outpatient clinic, researched data, and wrote and edited the manuscript. I.S. contributed to the study concept and design, recruited patients, discussed the study results, and reviewed the final manuscript. J.V. contributed to writing and reviewing the final manuscript. V.C.-M. conducted measurements and reviewed the manuscript. R.M.M. reviewed the manuscript. G.A. helped in the outpatient clinic and contributed to the manuscript. F.T. reviewed the manuscript. A.M. held the outpatient clinic, contributed to the study concept and design, recruited patients, discussed the study results, and reviewed the final manuscript.
The authors are grateful to Miriam Campos and Lluís Gallart from the biobank at Joan XXIII Hospital for their help in laboratory work.
Footnotes
This article contains Supplementary Data online at http://care.diabetesjournals.org/lookup/suppl/doi:10.2337/dc11-0788/-/DC1.
References
- 1.Brochu-Gaudreau K, Rehfeldt C, Blouin R, Bordignon V, Murphy BD, Palin MF. Adiponectin action from head to toe. Endocrine 2010;37:11–32 [DOI] [PubMed] [Google Scholar]
- 2.Waki H, Yamauchi T, Kamon J, et al. Impaired multimerization of human adiponectin mutants associated with diabetes. Molecular structure and multimer formation of adiponectin. J Biol Chem 2003;278:40352–40363 [DOI] [PubMed] [Google Scholar]
- 3.Wang Y, Lam KSL, Yau MH, Xu A. Post-translational modifications of adiponectin: mechanisms and functional implications. Biochem J 2008;409:623–633 [DOI] [PubMed] [Google Scholar]
- 4.Kobayashi H, Ouchi N, Kihara S, et al. Selective suppression of endothelial cell apoptosis by the high molecular weight form of adiponectin. Circ Res 2004;94:e27–e31 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 5.Cseh K, Baranyi E, Melczer Z, Kaszás E, Palik E, Winkler G. Plasma adiponectin and pregnancy-induced insulin resistance. Diabetes Care 2004;27:274–275 [DOI] [PubMed] [Google Scholar]
- 6.Mazaki-Tovi S, Romero R, Kusanovic JP, et al. Adiponectin ultimers in maternal plasma. J Matern Fetal Neonatal Med 2008;21:796–815 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 7.Retnakaran R, Hanley AJ, Raif N, Connelly PW, Sermer M, Zinman B. Reduced adiponectin concentration in women with gestational diabetes: a potential factor in progression to type 2 diabetes. Diabetes Care 2004;27:799–800 [DOI] [PubMed] [Google Scholar]
- 8.Mazaki-Tovi S, Romero R, Vaisbuch E, et al. Maternal serum adiponectin multimers in gestational diabetes. J Perinat Med 2009;37:637–650 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 9.Ong GK, Hamilton JK, Sermer M, et al. Maternal serum adiponectin and infant birthweight: the role of adiponectin isoform distribution. Clin Endocrinol (Oxf) 2007;67:108–114 [DOI] [PubMed] [Google Scholar]
- 10.López-Bermejo A, Fernández-Real JM, Garrido E, et al. Maternal soluble tumour necrosis factor receptor type 2 (sTNFR2) and adiponectin are both related to blood pressure during gestation and infant’s birthweight. Clin Endocrinol (Oxf) 2004;61:544–552 [DOI] [PubMed] [Google Scholar]
- 11.Chan TF, Yuan SS, Chen HS, et al. Correlations between umbilical and maternal serum adiponectin levels and neonatal birthweights. Acta Obstet Gynecol Scand 2004;83:165–169 [DOI] [PubMed] [Google Scholar]
- 12.Kajantie E, Hytinantti T, Hovi P, Andersson S. Cord plasma adiponectin: a 20-fold rise between 24 weeks gestation and term. J Clin Endocrinol Metab 2004;89:4031–4036 [DOI] [PubMed] [Google Scholar]
- 13.Sivan E, Mazaki-Tovi S, Pariente C, et al. Adiponectin in human cord blood: relation to fetal birth weight and gender. J Clin Endocrinol Metab 2003;88:5656–5660 [DOI] [PubMed] [Google Scholar]
- 14.Wang J, Wang SH, Shang LX, et al. Relationship of adiponectin and resistin levels in umbilical and maternal serum with fetal macrosomia. J Obstet Gynaecol Res 2010;36:533–537 [DOI] [PubMed] [Google Scholar]
- 15.Weyermann M, Beermann Ch, Brenner H, Rothenbacher D. Adiponectin and leptin in maternal serum, cord blood, and breast milk. Clin Chem 2006;52:2095–2102 [DOI] [PubMed] [Google Scholar]
- 16.National Diabetes Data Group. Classification and diagnosis of diabetes mellitus and other categories of glucose intolerance. Diabetes 1979;28:1039–1057 [DOI] [PubMed] [Google Scholar]
- 17.Matthews DR, Hosker JP, Rudenski AS, Naylor BA, Treacher DF, Turner RC. Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia 1985;28:412–419 [DOI] [PubMed] [Google Scholar]
- 18.Basu S, Laffineuse L, Presley L, Minium J, Catalano PM, Hauguel-de Mouzon S. In utero gender dimorphism of adiponectin reflects insulin sensitivity and adiposity of the fetus. Obesity (Silver Spring) 2009;17:1144–1149 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 19.Cortelazzi D, Corbetta S, Ronzoni S, et al. Maternal and foetal resistin and adiponectin concentrations in normal and complicated pregnancies. Clin Endocrinol (Oxf) 2007;66:447–453 [DOI] [PubMed] [Google Scholar]
- 20.Pirc LK, Owens JA, Crowther CA, Willson K, De Blasio MJ, Robinson JS. Mild gestational diabetes in pregnancy and the adipoinsular axis in babies born to mothers in the ACHOIS randomised controlled trial. BMC Pediatr 2007;7:18–25 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 21.Pinar H, Basu S, Hotmire K, et al. High molecular mass multimer complexes and vascular expression contribute to high adiponectin in the fetus. J Clin Endocrinol Metab 2008;93:2885–2890 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 22.Pajvani UB, Du X, Combs TP, et al. Structure-function studies of the adipocyte-secreted hormone Acrp30/adiponectin. Implications fpr metabolic regulation and bioactivity. J Biol Chem 2003;278:9073–9085 [DOI] [PubMed] [Google Scholar]
- 23.Corbetta S, Bulfamante G, Cortelazzi D, et al. Adiponectin expression in human fetal tissues during mid- and late gestation. J Clin Endocrinol Metab 2005;90:2397–2402 [DOI] [PubMed] [Google Scholar]
- 24.Fu Y, Luo N, Klein RL, Garvey WT. Adiponectin promotes adipocyte differentiation, insulin sensitivity, and lipid accumulation. J Lipid Res 2005;46:1369–1379 [DOI] [PubMed] [Google Scholar]
Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.