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Association of Adiponectin Gene Polymorphism With Birth Weight in Korean Neonates

Published online by Cambridge University Press:  03 April 2013

Kyoung Ae Kong
Affiliation:
Clinical Trial Center, Ewha Womans University Medical Center, Seoul, South Korea
Young Ju Suh
Affiliation:
Department of Clinical Research, School of Medicine, Inha University, Incheon, South Korea
Su Jin Cho
Affiliation:
Department of Pediatrics, School of Medicine, Ewha Womans University, Seoul, South Korea
Eun Ae Park
Affiliation:
Department of Pediatrics, School of Medicine, Ewha Womans University, Seoul, South Korea
Mi Hye Park
Affiliation:
Department of Obstetrics and Gynecology, School of Medicine, Ewha Womans University, Seoul, South Korea
Young Ju Kim*
Affiliation:
Department of Obstetrics and Gynecology, School of Medicine, Ewha Womans University, Seoul, South Korea
*
address for correspondence: Young Ju Kim, Department of Obstetrics and Gynecology, School of Medicine, Ewha Womans University, 911-1 Mok-6 dong, Yangcheon-ku, Seoul 158-710, Republic of Korea. E-mail: [email protected]

Abstract

Adiponectin has been associated with insulin resistance and type 2 diabetes mellitus and possibly fetal growth. Our aim was to assess the association between the single nucleotide polymorphisms (SNPs) of the adiponectin gene (ADIPOQ) and the birth sizes. We investigated four SNPs of ADIPOQ (rs182052, rs2241766, rs1501299, and rs266729) and birth height and weight in 237 healthy full-term neonates. The neonates with the rs182052 G allele had a greater birth weight (p = .043 in the dominant model) and a higher ponderal index (p = .028 in the additive model). The rs2241766 G allele was associated with a greater birth weight (p = .016 in the recessive model). In a logistic regression analysis, the homozygotes for the rs182052 G allele and those for the rs2241766 G allele showed a significant association with a greater birth weight above 90 percentile (OR 2.75, 95% CI 1.13–6.70 and OR 5.15, 95% CI 1.66–15.99, respectively). In conclusion, we found an association between rs182052 and rs2241766 and birth weight and ponderal index among healthy neonates and suggested that adiponectin might have some roles in fetal growth.

Type
Articles
Copyright
Copyright © The Authors 2013 

Adiponectin is a 30-kDa protein secreted from adipocytes, and its serum levels are decreased in individuals with obesity, type 2 diabetes mellitus (T2DM), and conditions commonly associated with insulin resistance (Rasouli & Kern, Reference Rasouli and Kern2008). Low serum adiponectin concentrations are also found in subjects with hypertension, atherosclerosis, coronary artery disease, or ischemic stroke (Lu et al., Reference Lu, Huang, Chang, Huang, Chi, Su and Yang2008; Rasouli & Kern, Reference Rasouli and Kern2008). It has been suggested that adiponectin plays a role in the regulation of insulin sensitivity and glucose and lipid metabolism, and further in the development of insulin resistance, T2DM, and atherosclerosis (Rasouli & Kern, Reference Rasouli and Kern2008; Yamauchi & Kadowaki, Reference Yamauchi and Kadowaki2008). Not only does thiazolidinedione, an insulin sensitizer, increase circulating adiponectin level in humans, but administration of recombinant adiponectin improves insulin sensitivity in mice (Lu et al., Reference Lu, Huang, Chang, Huang, Chi, Su and Yang2008; Rasouli & Kern, Reference Rasouli and Kern2008).

Adiponectin has also been suggested to have an important role in fetal growth. Cord blood adiponectin level was significantly higher than that of adults or adolescents. And, unlike with adults, cord adiponectin level was positively associated with birth size in many studies (Kadowaki et al., Reference Kadowaki, Waguri, Nakanishi, Miyashita, Nakayama, Suehara and Fujita2006; Kotani et al., Reference Kotani, Yokota, Kitamura, Matsuda, Naito and Kuroda2004; Mantzoros et al., Reference Mantzoros, Rifas-Shiman, Williams, Fargnoli, Kelesidis and Gillman2009). Cord blood adiponectin level was lower among small for gestational age (Kamoda et al., Reference Kamoda, Saitoh, Saito, Sugiura and Matsui2004). The key endocrine regulators on fetal growth are insulin and insulin-like growth factors (IGFs), and adiponectin has been known to have an effect on them as an insulin sensitizer (Briana & Malamitsi-Puchner, Reference Briana and Malamitsi-Puchner2010; Inami et al., Reference Inami, Okada, Fujita, Makimoto, Hosono, Minato and Yamamoto2007; Mantzoros et al., Reference Mantzoros, Petridou, Alexe, Skalkidou, Dessypris, Papathoma and Trichopoulos2004). Moreover, adiponectin in fetal life may have important implications for later health. Fetal growth and insulin resistance could affect growth and development of insulin resistance with metabolic consequences in later life (Nathanielsz, Reference Nathanielsz and Nathanielsz1999).

Adiponectin concentrations are under strong genetic control with heritability between 30% and 50% (Siitonen et al., Reference Siitonen, Pulkkinen, Lindstrom, Kolehmainen, Eriksson, Venojarvi and Uusitupa2011). Some adiponectin gene (ADIPOQ) polymorphisms are reported to be associated with conditions such as insulin resistance or T2DM through serum adiponectin level (Melistas et al., Reference Melistas, Mantzoros, Kontogianni, Antonopoulou, Ordovas and Yiannakouris2009; Siitonen et al., Reference Siitonen, Pulkkinen, Lindstrom, Kolehmainen, Eriksson, Venojarvi and Uusitupa2011) and there may be an effect on fetal growth, although research is sparse. Therefore, we set out to investigate the association between the common single nucleotide polymorphisms (SNPs) of the ADIPOQ and birth sizes in South Korea.

Materials and Methods

Study Population and Data Collection Procedures

The study subjects were a total of 237 healthy full-term neonates born as singletons at Ewha Womans University Hospital, Seoul, South Korea, between July 2006 and December 2008. Their mothers were recruited among women who had received prenatal care at the hospital and agreed to participate in this study. Informed consent was obtained from the mothers. Information on maternal age and parity was obtained from a self-reported questionnaire completed during the first prenatal visit. We acquired information on infant sex, birth weight, birth length, and gestational age from medical records. Gestational age was determined according to the date of onset of the mother's last menstrual period and by the ultrasonographic estimation. Ponderal index (kg/m3) was calculated as the weight (kg) divided by height cubed (m3). Neonates whose mother had hypertension, diabetes mellitus, or other diseases causing fetal growth restriction, or had received medications related to fetal growth, and those with congenital anomalies were excluded. Cord blood samples were taken immediately after delivery and aliquoted and stored at -70 degree Celsius until assayed. This study was approved by the institutional review board on human subjects at Ewha Womans University, Seoul, South Korea.

Genotyping Analysis

We selected four SNPs of ADIPOQ, which have not only been reported to be associated with adiponectin level and metabolic consequences such as diabetes and metabolic syndrome but also to be polymorphic, with the minor allele frequencies found in more than 20% of the Korean population. After DNA was extracted from whole blood using the DNeasy Blood & Tissue kit (Qiagen, Hilden, Germany), these genotypes of ADIPOQ (rs182052, rs2241766, rs1501299, and rs266729) were screened using the TaqMan fluorogenic 5′ nuclease assay (ABI, Foster City, CA, USA). The final volume of polymerase chain reaction (PCR) was 5 uL, containing 10 ng of genomic DNA and 2.5 uL TaqMan Universal PCR Master Mix, with 0.13 uL of 40× Assay Mix. Thermal cycle conditions were as follows: 50 degree Celsius for 2 minutes to activate the uracil N-glycosylase and to prevent contamination, 95 degree Celsius for 10 minutes to activate the DNA polymerase, followed by 45 cycles of 95 degree Celsius for 15 seconds and 60 degree Celsius for 1 minute. All PCR were performed using 384-well plates by a Dual 384-Well GeneAmp PCR System 9700 (ABI, Foster City, CA, USA) and the endpoint fluorescent readings were performed on an ABI PRISM 7900 HT Sequence Detection System (ABI, Foster City, CA, USA).

Statistical Analysis

The consistency of the genotype frequencies of each polymorphism with the Hardy–Weinberg equilibrium was assessed with the χ2 test. The results are expressed as mean and standard deviation for continuous variables and as frequency and percentage for categorical variables.

The general associations between each polymorphism and birth size were assessed using general linear models with adjustment for sex, gestational age, and birth order. We further tested these associations under dominant, recessive, and additive genetic models only if the general association test was significant. The dominant genetic model compares neonates with one or more polymorphic alleles to those with homozygous wild-type alleles (Aa and AA vs. aa). The recessive genetic model compares neonates with a homozygous variant allele to those with one or more wild-type allele (AA vs. Aa or aa). The additive genetic model assumes that there is a linear gradient in birth size among three genotypes. Multiple tests for three genetic models of each SNP were adjusted by the Bonferroni correction (p value multiplied by 3, the number of models).

In addition, we categorized neonates into three groups according to sex-specific percentile (<10 percentile as smaller birth size, >90 percentile as larger birth size, and 10–90 percentile) for birth weight, birth length, and ponderal index at birth. The cut points (10th and 90th percentiles) of height were 49.0 and 53.0 cm among boys and 48.0 cm and 52.0 cm among girls. Those of birth weight were 2,940 and 3,840 g among boys and 2,750 and 3,730 g among girls. Those of ponderal index were 24.0 and 29.4 kg/m3 among boys and 24.2 and 29.8 kg/m3 among girls. Multinomial logistic regression was used to estimate the odds ratios (ORs) and 95% confidence intervals (CIs) of the risk associated with the variant allele for the smaller or larger birth sizes (height, weight, and ponderal index) in dominant and recessive models of each ADIPOQ polymorphism.

Pairwise linkage disequilibrium between each SNP was estimated using Haploview (Barrett et al., Reference Barrett, Fry, Maller and Daly2005). Haplotype reconstruction analysis was done using PHASE (Stephens et al., Reference Stephens, Smith and Donnelly2001). We also performed general linear model and multinomial logistic regression analyses on haplotypes. We adjusted for sex, gestational age, and birth order of neonates as covariates in all analyses. All statistical analyses were performed using the SAS package (version 9.2, SAS institute, Cary, NC).

Results

The genotype distributions of the four SNPs and the success rates for genotyping are described in Table 1. The genotype distributions did not differ from those expected for a population in the Hardy–Weinberg equilibrium using the χ2 test. There was significant linkage disequilibrium between the rs266729 and rs182052 (D′ = 1, R 2 = 0.349) and between rs2241766 and rs1501299 polymorphisms in the population (D′ = 1, R 2 = 0.183). The main haplotypes for rs266729/rs182052 were the C/G (53.6%), C/A (23.2%), and G/A (23.2%) types, and those for rs2241766/rs1501299 were the T/G (39.8%), G/G (32.4%), and T/T (27.8%) types in the population. Among subjects, homozygous diplotypes of C/A from the rs266729/rs182052 haplotypes (CA/CA) were 6.8%, heterozygous diplotype (CA/X) 29.5%, and diplotypes without the C/A haplotype (X/X) 63.7%. For the diplotypes of T/G from rs2241766/rs1501299 haplotypes, homozygous (TG/TG), heterozygous (TG/X), non-T/G diplotypes (X/X) were 15.6%, 43.5%, and 41.4%, respectively.

TABLE 1 Genotype Distributions of Adiponectin Gene SNPs in the Study

SNP = single nucleotide polymorphism; Position = position relative to ATG start; H.W. = Hardy–Weinberg equilibrium.

The characteristics of the subjects are presented in Table 2. Among 237 neonates, 114 were boys (48.1%) and 123 were girl (51.9%). Forty-three percent were first born and 29% were born with cesarean section. Their gestational age ranged from 37.1 to 41.6 weeks, with a mean of 39.4 weeks. The mean and standard deviation values of birth height and weight were 49.9 ± 1.6 cm and 3,291 ± 351 g. There were four neonates with birth weight greater than 4 kg and no low birth weight infant (below 2.5 kg).

TABLE 2 Baseline Characteristics of Neonates in the Study (n = 237)

Note: SD = standard deviation.

The association between each SNP and birth sizes is shown in Table 3. Two adiponectin SNPs (rs182052 and rs2241766) were significantly associated with birth weight and ponderal index at birth. The neonates homozygous for the common G allele of rs182052 had a greater birth weight (GG: 3,393 ± 387 g, GA: 3,241 ± 327 g, AA: 3,278 ± 336 g, p = .043 in the dominant genetic model) and a higher ponderal index (GG: 27.1 ± 2.6 kg/m3, GA: 26.5 ± 2.0 kg/m3, AA: 26.0 ± 1.9 kg/m3, p = .028 in the additive model) than those with the A allele. The variant G allele of rs2241766 was also associated with greater birth weight (TT: 3,257 ± 359 g, TG: 3,294 ± 317 g, GG: 3,513 ± 421 g, p = .016 in the recessive model and p = .059 in the additive model). No adiponectin SNPs in this study were significantly associated with birth height.

TABLE 3 Associations of Adiponectin Gene SNPs with Birth Sizes

P values by general linear models with adjustment for sex, gestational age, and birth order; Ddominant model (one or more polymorphic alleles versus homozygous wild-type alleles, Aa and AA versus aa); Rrecessive model (homozygous variant allele versus one or more wild-type allele, AA versus Aa or aa); Aadditive model (a linear gradient among three genotypes). P values in dominant, recessive, and additive models were adjusted using the Bonferroni method.

SNP = single nucleotide polymorphism; SD = standard deviation.

In the multinomial logistic regression analysis, the variant A allele of ADIPOQ rs182052 showed a significantly lower odds ratio for greater birth weight above 90 percentile (Table 4; OR 0.36, 95% CI 0.15–0.89 in the dominant genetic model) and a borderline significantly lower odds ratio for the higher ponderal index above 90 percentile (OR 0.42, 95% CI 0.17–1.01, p = .052 in the dominant model) relative to the common G allele. In other words, the neonates homozygous for the common G allele of rs182052 had a significant association with greater birth weight above 90 percentile (OR 2.75, 95% CI 1.13–6.70) and a borderline significant association with a higher ponderal index above 90 percentile (OR 2.40, 95% CI 0.99–5.79), compared with those with the GA or AA genotype. The homozygotes for the variant G allele of rs2241766 were significantly associated with greater birth weight above 90 percentile (OR 5.15, 95% CI 1.66–15.99 in the recessive model).

TABLE 4 Logistic Regression Analysis of Adiponectin Gene SNPs for Birth Sizes

Dominant model = one or more polymorphic alleles versus homozygous wild-type alleles (Aa and AA versus aa); Recessive model = homozygous variant allele versus one or more wild-type allele (AA versus Aa or aa). P* = sex-specific percentile; OR** = odds ratio of the variant allele relative to wild-type allele for larger or smaller birth size in multinomial logistic regression analysis with adjustment for sex, gestational age, and birth order.

OR 2.75 (95% CI 1.13–6.70) of the common G allele for greater birth weight (>90p) relative to the variant A allele; OR 2.40 (95% CI 0.99–5.79) of the common G allele for higher ponderal index.

In the haplotype analysis, the C/A haplotype from rs266729/rs182052 haplotypes was significantly associated with birth weight. The neonates with the C/A haplotype had a lower birth weight (C/A carrier: 3,225 ± 305 g, non-C/A carrier: 3,328 ± 371 g, p = .048) and a lower ponderal index (C/A carrier: 26.0 ± 2.0 kg/m3, non-C/A carrier: 26.8 ± 2.2 kg/m3, p = .014). The presence of the C/A haplotype showed a significantly lower odds ratio for greater birth weight above 90 percentile (OR 0.26, 95% CI 0.07–0.92) relative to the absence of the C/A haplotype. The other haplotypes were not significantly associated with birth sizes.

Discussion

In this study, we suggested that ADIPOQ SNP rs182052 and rs2241766 were probably associated with birth weight and ponderal index at birth. Neonates with the SNP rs182052 common G allele had greater birth weight and higher ponderal index and rs2241766 variant G allele had greater birth weight. This is the first report that showed a significant association of ADIPOQ SNP rs182052 and rs2241766 of neonates with birth sizes.

Since the first report about an association of the ADIPOQ SNP rs182052 and serum adiponectin level by Woo et al. (Reference Woo, Dolan, Deka, Kaushal, Shen, Pal and Martin2006), the variant A allele of this SNP has been shown to be associated with lower serum adiponectin level, insulin resistance syndrome-related phenotypes such as higher BMI, thicker skin fold thickness, higher fasting insulin, lower homeostasis model assessment of insulin sensitivity, and diabetic nephropathy (Bostrom et al., Reference Bostrom, Freedman, Langefeld, Liu, Hicks and Bowden2009; Ong et al., Reference Ong, Li, Tso, Xu, Cherny, Sham and Lam2010; Richardson et al., Reference Richardson, Schneider, Fourcaudot, Rodriguez, Arya, Dyer and Jenkinson2006; Wassel et al., Reference Wassel, Pankow, Jacobs, Steffes, Li and Schreiner2010). The association of ADIPOQ rs182052 with birth sizes was first reported in this study. The SNP rs182052 lies in the first intron of human adiponectin gene. Although introns are the non-protein-coding regions within a gene, they have recently been demonstrated to have an effect on messenger RNA (mRNA) degradation or translation suppression (Wassel et al., Reference Wassel, Pankow, Jacobs, Steffes, Li and Schreiner2010). Also, this SNP might be involved in any change in a binding site of the transcription factor. The first intron of ADIPOQ contains a gene expression enhancer element, which CCAAT/enhancer-binding proteins (C/EBPα), a major transcription factor for adiponectin, bind to and could increase the activity of the adiponectin promoter (Ong et al., Reference Ong, Li, Tso, Xu, Cherny, Sham and Lam2010; Qiao et al., Reference Qiao, Maclean, Schaack, Orlicky, Darimont, Pagliassotti and Shao2005).

The reports about the association between the ADIPOQ rs2241766 and serum adiponectin level are more inconsistent. Some report a higher adiponectin level in the variant G allele (Jang et al., Reference Jang, Chae, Koh, Hyun, Kim, Jeong and Lee2008; Siitonen et al., Reference Siitonen, Pulkkinen, Lindstrom, Kolehmainen, Eriksson, Venojarvi and Uusitupa2011) and others report no association between them (Chung et al., Reference Chung, Chae, Hyun, Paik, Kim, Jang and Lee2009; Kim et al., Reference Kim, Kang, Hur, Lee, Han, Kwak and Lee2008). ADIPOQ rs2241766 is associated with T2DM, coronary artery disease, or carotid artery plaque in T2DM (Al-Daghri et al., Reference Al-Daghri, Al-Attas, Alokail, Alkharfy and Hussain2011; Kim et al., Reference Kim, Kang, Hur, Lee, Han, Kwak and Lee2008; Siitonen et al., Reference Siitonen, Pulkkinen, Lindstrom, Kolehmainen, Eriksson, Venojarvi and Uusitupa2011). The rs2241766 is located at exon 2 and is one of the most common polymorphisms of ADIPOQ. However, it causes synonymous mutation (GGT→GGG, Gly→Gly), that is, it does not make any change in amino acid sequences in adiponectin. So, the associations with some diseases or biologic functions were often explained by the possible linkage disequilibrium with other functional SNPs (Al-Daghri et al., Reference Al-Daghri, Al-Attas, Alokail, Alkharfy and Hussain2011; Melistas et al., Reference Melistas, Mantzoros, Kontogianni, Antonopoulou, Ordovas and Yiannakouris2009). It is also suggested that this silent mutation may affect ADIPOQ expression by modifying mRNA splicing or stability (Al-Daghri et al., Reference Al-Daghri, Al-Attas, Alokail, Alkharfy and Hussain2011; Melistas et al., Reference Melistas, Mantzoros, Kontogianni, Antonopoulou, Ordovas and Yiannakouris2009; Yang et al., Reference Yang, Tsou, Lee, Tseng, Chen, Peng and Chuang2003). Yang et al. (Reference Yang, Tsou, Lee, Tseng, Chen, Peng and Chuang2003) showed the difference in allele-specific expression, with higher mRNA level transcribed by the G allele and lower level by the T allele of this SNP in the adipose tissue of heterozygous subjects. However, it is still not clear how this polymorphism could be associated with adiponectin level and other phenotypic variants or diseases.

The associations with genotypic variations of adiponectin and birth sizes have not been studied enough so far. As far as we know, there are only two studies that examined these genetic links. A study in Brazil showed that the variant A allele of SNP rs17300539 (-11,391) in the promoter region of ADIPOQ was associated with being born large for gestational age and with higher adiponectin levels at the age of 23–25 years (Bueno et al., Reference Bueno, Espineira, Fernandes-Rosa, de Souza, de Castro, Moreira and Antonini2010). Saito et al. (Reference Saito, Kamoda, Nishimura, Miyazono, Kanai, Kato and Noguchi2012) reported that the neonates with the variant G allele of SNP rs266729 (-11,377) in the vicinity of rs17300539 in the ADIPOQ promoter region had significantly greater birth weights and higher cord adiponectin levels. They suggested that the effect of the SNP rs266729 on birth weight is based on its relation to adiponectin level. In our study, the C/A haplotype from rs266729/rs182052 was associated with birth sizes, but this was similar to the rs182052 A allele, and the SNP rs266729 in the promoter region was not associated with birth sizes. The ADIPOQ SNP rs1501299 is also not associated with birth sizes in spite of the significant result of SNP rs2241766. The haplotypes, including SNPs rs1501299 and rs2241766, are associated with insulin resistance, metabolic syndrome, and T2DM (Chung et al., Reference Chung, Chae, Hyun, Paik, Kim, Jang and Lee2009; Jang et al., Reference Jang, Chae, Koh, Hyun, Kim, Jeong and Lee2008; Melistas et al., Reference Melistas, Mantzoros, Kontogianni, Antonopoulou, Ordovas and Yiannakouris2009), but other studies have showed different associations with diseases between these two SNPs, similar to our study (Al-Daghri et al., Reference Al-Daghri, Al-Attas, Alokail, Alkharfy and Hussain2011; Kim et al., Reference Kim, Kang, Hur, Lee, Han, Kwak and Lee2008; Siitonen et al., Reference Siitonen, Pulkkinen, Lindstrom, Kolehmainen, Eriksson, Venojarvi and Uusitupa2011). These discrepancies in studies might be attributed to the variation of the linkage disequilibrium structures among the populations (Al-Daghri et al., Reference Al-Daghri, Al-Attas, Alokail, Alkharfy and Hussain2011).

Although we did not have cord adiponectin level, it is reasonable to speculate that the effects of ADIPOQ polymorphisms on birth sizes were mediated by adiponectin level. The neonates with ADIPOQ SNP rs182052 G allele or rs2241766 G allele were likely to be associated with increase in birth weight and ponderal index through the higher concentration of cord adiponectin.

Among adults, the circulating adiponectin level decreases with obesity (Kotani et al., Reference Kotani, Yokota, Kitamura, Matsuda, Naito and Kuroda2004; Rasouli & Kern, Reference Rasouli and Kern2008). But blood adiponectin levels of neonates are two or three times higher than those of adults and were positively associated with birth weight and fat mass (Inami et al., Reference Inami, Okada, Fujita, Makimoto, Hosono, Minato and Yamamoto2007; Kadowaki et al., Reference Kadowaki, Waguri, Nakanishi, Miyashita, Nakayama, Suehara and Fujita2006; Kotani et al., Reference Kotani, Yokota, Kitamura, Matsuda, Naito and Kuroda2004; Mantzoros et al., Reference Mantzoros, Rifas-Shiman, Williams, Fargnoli, Kelesidis and Gillman2009; Saito et al., Reference Saito, Kamoda, Nishimura, Miyazono, Kanai, Kato and Noguchi2012). This may be caused by a lack of negative feedback on adiponectin production, related to the relatively smaller fat mass, low proportion of visceral fat, different cell population (Briana & Malamitsi-Puchner, Reference Briana and Malamitsi-Puchner2010; Kotani et al., Reference Kotani, Yokota, Kitamura, Matsuda, Naito and Kuroda2004; Saito et al., Reference Saito, Kamoda, Nishimura, Miyazono, Kanai, Kato and Noguchi2012), and multiple fetal tissues producing adiponectin (Briana & Malamitsi-Puchner, Reference Briana and Malamitsi-Puchner2010; Kadowaki et al., Reference Kadowaki, Waguri, Nakanishi, Miyashita, Nakayama, Suehara and Fujita2006; Kotani et al., Reference Kotani, Yokota, Kitamura, Matsuda, Naito and Kuroda2004).

Higher adiponectin concentration among neonates than among adults, and lower adiponectin level in gestational diabetic mothers and their newborns suggests the important role of adiponectin in intrauterine growth and development and energy metabolism (Kiess et al., Reference Kiess, Petzold, Töpfer, Garten, Blüher, Kapellen and Kratzsch2008). The important endocrine regulators on fetal growth are insulin and IGFs (Inami et al., Reference Inami, Okada, Fujita, Makimoto, Hosono, Minato and Yamamoto2007; Mantzoros et al., Reference Mantzoros, Petridou, Alexe, Skalkidou, Dessypris, Papathoma and Trichopoulos2004) and adiponectin could be speculated to have a regulatory effect on fetal growth through enhancing insulin and IGF sensitivity and modulating their actions (Briana & Malamitsi-Puchner, Reference Briana and Malamitsi-Puchner2010; Inami et al., Reference Inami, Okada, Fujita, Makimoto, Hosono, Minato and Yamamoto2007; Kadowaki et al., Reference Kadowaki, Waguri, Nakanishi, Miyashita, Nakayama, Suehara and Fujita2006; Kotani et al., Reference Kotani, Yokota, Kitamura, Matsuda, Naito and Kuroda2004; Mantzoros et al., Reference Mantzoros, Petridou, Alexe, Skalkidou, Dessypris, Papathoma and Trichopoulos2004). It also suggests that lower cord adiponectin concentration could be associated with weight gain in early childhood and a predisposition to insulin resistance or other metabolic consequences in later life (Kamoda et al., Reference Kamoda, Saitoh, Saito, Sugiura and Matsui2004; Mantzoros et al., Reference Mantzoros, Rifas-Shiman, Williams, Fargnoli, Kelesidis and Gillman2009; Yang, Reference Yang2009). However, the relationship between cord adiponectin level, birth sizes, and insulin sensitivity is still not clear (Briana & Malamitsi-Puchner, Reference Briana and Malamitsi-Puchner2010; Jaquet et al., Reference Jaquet, Deghmoun, Chevenne, Czernichow and Levy-Marchal2006; Kotani et al., Reference Kotani, Yokota, Kitamura, Matsuda, Naito and Kuroda2004; Wang et al., Reference Wang, Wang, Shang, Dong, Wang, Zhang and Ye2010) and the cord adiponectin level was even considered as the mere reflection of fetal growth itself. Recently, it has been suggested that the low adiponectin level among obese adults is not a cause, but a consequence of obesity and adipose tissue-specific insulin resistance, and mediates insulin resistance in peripheral tissues and metabolic sequences (Lu et al., Reference Lu, Huang, Chang, Huang, Chi, Su and Yang2008; Yang, Reference Yang2009). The links between birth weight, insulin resistance, and adiponectin need further delineation, and the genetic association between adiponectin polymorphisms and fetal growth also needs more study.

The limitation of our study is that we did not have cord adiponectin level and other serum biomarkers to explain the mechanism of the association between birth sizes and ADIPOQ polymorphism. Four SNPs in our study could not sufficiently cover the entire adiponectin gene so we might have missed some important regions and their effects. Also, we applied the correction for multiple comparisons across the genetic models but not across SNPs. In consideration of low replication in genetic association, we could only suggest but not confirm these associations in our study results and call for the replication studies. Nevertheless, we could show the probable association between ADIPOQ SNP rs182052 and rs2241766 and birth weight and ponderal index at birth among healthy neonates with a small proportion of macrosomia and no low birth weight babies, no neonates with mothers who had diabetes or other diseases, and those with congenital anomaly or neonatal complications as we wanted to know the effect on birth sizes itself among healthy neonates rather than on other diseases or conditions affecting birth sizes.

In conclusion, we found the association between the ADIPOQ SNP rs182052 common G allele and the rs2241766 variant G allele and greater birth weight and higher ponderal index at birth among healthy neonates for the first time and suggest that adiponectin might have some role in fetal growth.

Acknowledgments

This work was supported by Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education Science and Technology (2011-0004200) and the Ewha Global Top5 Grant (2013) of Ewha Womans University.

References

Al-Daghri, N. M., Al-Attas, O. S., Alokail, M. S., Alkharfy, K. M., & Hussain, T. (2011). Adiponectin gene variants and the risk of coronary artery disease in patients with type 2 diabetes. Molecular Biology Reports, 38, 37033708.CrossRefGoogle ScholarPubMed
Barrett, J. C., Fry, B., Maller, J., & Daly, M. J. (2005). Haploview: Analysis and visualization of LD and haplotype maps. Bioinformatics, 21, 263265.Google Scholar
Bostrom, M. A., Freedman, B. I., Langefeld, C. D., Liu, L., Hicks, P. J., & Bowden, D. W. (2009). Association of adiponectin gene polymorphisms with type 2 diabetes in an African American population enriched for nephropathy. Diabetes, 58, 499504.Google Scholar
Briana, D. D., & Malamitsi-Puchner, A. (2010). The role of adipocytokines in fetal growth. Annals of the New York Academy of Sciences, 1205, 8287.Google Scholar
Bueno, A. C., Espineira, A. R., Fernandes-Rosa, F. L., de Souza, R. M., de Castro, M., Moreira, A. C., . . . Antonini, S. R. (2010). Adiponectin: Serum levels, promoter polymorphism, and associations with birth size and cardiometabolic outcome in young adults born large for gestational age. European Journal of Endocrinology, 162, 5360.Google Scholar
Chung, H. K., Chae, J. S., Hyun, Y. J., Paik, J. K., Kim, J. Y., Jang, Y., . . . Lee, J. H. (2009). Influence of adiponectin gene polymorphisms on adiponectin level and insulin resistance index in response to dietary intervention in overweight-obese patients with impaired fasting glucose or newly diagnosed type 2 diabetes. Diabetes Care, 32, 552558.Google Scholar
Inami, I., Okada, T., Fujita, H., Makimoto, M., Hosono, S., Minato, M., . . . Yamamoto, T. (2007). Impact of serum adiponectin concentration on birth size and early postnatal growth. Pediatric Research, 61, 604606.Google Scholar
Jang, Y., Chae, J. S., Koh, S. J., Hyun, Y. J., Kim, J. Y., Jeong, Y. J., . . . Lee, J. H. (2008). The influence of the adiponectin gene on adiponectin concentrations and parameters of metabolic syndrome in non-diabetic Korean women. Clinica Chimica Acta, 391, 8590.Google Scholar
Jaquet, D., Deghmoun, S., Chevenne, D., Czernichow, P., & Levy-Marchal, C. (2006). Low serum adiponectin levels in subjects born small for gestational age: Impact on insulin sensitivity. International Journal of Obesity, 30, 8387.CrossRefGoogle ScholarPubMed
Kadowaki, K., Waguri, M., Nakanishi, I., Miyashita, Y., Nakayama, M., Suehara, N., . . . Fujita, T. (2006). Adiponectin concentration in umbilical cord serum is positively associated with the weight ratio of fetus to placenta. Journal of Clinical Endocrinology and Metabolism, 91, 50905094.CrossRefGoogle ScholarPubMed
Kamoda, T., Saitoh, H., Saito, M., Sugiura, M., & Matsui, A. (2004). Serum adiponectin concentrations in newborn infants in early postnatal life. Pediatric Research, 56, 690693.Google Scholar
Kiess, W., Petzold, S., Töpfer, M., Garten, A., Blüher, S., Kapellen, T., . . . Kratzsch, J. (2008). Adipocytes and adipose tissue. Best Practice and Research. Clinical Endocrinology and Metabolism, 22, 135153.CrossRefGoogle ScholarPubMed
Kim, S. H., Kang, E. S., Hur, K. Y., Lee, H. J., Han, S. J., Kwak, J. Y., . . . Lee, H. C. (2008). Adiponectin gene polymorphism 45T>G is associated with carotid artery plaques in patients with type 2 diabetes mellitus. Metabolism: Clinical and Experimental, 57, 274279.Google Scholar
Kotani, Y., Yokota, I., Kitamura, S., Matsuda, J., Naito, E., & Kuroda, Y. (2004). Plasma adiponectin levels in newborns are higher than those in adults and positively correlated with birth weight. Clinical Endocrinology, 61, 418423.Google Scholar
Lu, J. Y., Huang, K. C., Chang, L. C., Huang, Y. S., Chi, Y. C., Su, T. C., . . . Yang, W. S. (2008). Adiponectin: A biomarker of obesity-induced insulin resistance in adipose tissue and beyond. Journal of Biomedical Science, 15, 565576.Google Scholar
Mantzoros, C., Petridou, E., Alexe, D. M., Skalkidou, A., Dessypris, N., Papathoma, E., . . . Trichopoulos, D. (2004). Serum adiponectin concentrations in relation to maternal and perinatal characteristics in newborns. European Journal of Endocrinology, 151, 741746.Google Scholar
Mantzoros, C. S., Rifas-Shiman, S. L., Williams, C. J., Fargnoli, J. L., Kelesidis, T., & Gillman, M. W. (2009). Cord blood leptin and adiponectin as predictors of adiposity in children at 3 years of age: A prospective cohort study. Pediatrics, 123, 682689.CrossRefGoogle ScholarPubMed
Melistas, L., Mantzoros, C. S., Kontogianni, M., Antonopoulou, S., Ordovas, J. M., & Yiannakouris, N. (2009). Association of the +45T>G and +276G>T polymorphisms in the adiponectin gene with insulin resistance in nondiabetic Greek women. European Journal of Endocrinology, 161, 845852.Google Scholar
Nathanielsz, P. W. (1999). Heart disease, obesity and diabetes. In Nathanielsz, P. W. (Ed.), Life in the womb: The origin of health and disease (pp. 137163). Ithaca, NY: Promethean Press.Google Scholar
Ong, K. L., Li, M., Tso, A. W., Xu, A., Cherny, S. S., Sham, P. C., . . . Lam, K. S. (2010). Association of genetic variants in the adiponectin gene with adiponectin level and hypertension in Hong Kong Chinese. European Journal of Endocrinology, 163, 251257.CrossRefGoogle ScholarPubMed
Qiao, L., Maclean, P. S., Schaack, J., Orlicky, D. J., Darimont, C., Pagliassotti, M., . . . Shao, J. (2005). C/EBPalpha regulates human adiponectin gene transcription through an intronic enhancer. Diabetes, 54, 17441754.Google Scholar
Rasouli, N., & Kern, P. A. (2008). Adipocytokines and the metabolic complications of obesity. Journal of Clinical Endocrinology and Metabolism, 93, S64S73.Google Scholar
Richardson, D. K., Schneider, J., Fourcaudot, M. J., Rodriguez, L. M., Arya, R., Dyer, T. D., . . . Jenkinson, C. P. (2006). Association between variants in the genes for adiponectin and its receptors with insulin resistance syndrome (IRS)-related phenotypes in Mexican Americans. Diabetologia, 49, 23172328.Google Scholar
Saito, M., Kamoda, T., Nishimura, K., Miyazono, Y., Kanai, Y., Kato, Y., . . . Noguchi, E. (2012). Association of adiponectin polymorphism with cord blood adiponectin concentrations and intrauterine growth. Journal of Human Genetics, 57, 109114.CrossRefGoogle ScholarPubMed
Siitonen, N., Pulkkinen, L., Lindstrom, J., Kolehmainen, M., Eriksson, J. G., Venojarvi, M., . . . Uusitupa, M. (2011). Association of ADIPOQ gene variants with body weight, type 2 diabetes and serum adiponectin concentrations: The Finnish Diabetes Prevention Study. BMC Medical Genetics, 12, 5.Google Scholar
Stephens, M., Smith, N. J., & Donnelly, P. (2001). A new statistical method for haplotype reconstruction from population data. American Journal of Human Genetics, 68 (4), 978989.CrossRefGoogle ScholarPubMed
Wang, J., Wang, S. H., Shang, L. X., Dong, X., Wang, X., Zhang, F., . . . Ye, Y. Y. (2010). Relationship of adiponectin and resistin levels in umbilical and maternal serum with fetal macrosomia. Journal of Obstetrics and Gynaecology Research, 36, 533537.Google Scholar
Wassel, C. L., Pankow, J. S., JacobsD. R., Jr. D. R., Jr., Steffes, M. W., Li, N., & Schreiner, P. J. (2010). Variants in the adiponectin gene and serum adiponectin: The Coronary Artery Development in Young Adults (CARDIA) Study. Obesity (Silver Spring), 18, 23332338.Google Scholar
Woo, J. G., Dolan, L. M., Deka, R., Kaushal, R. D., Shen, Y., Pal, P., . . . Martin, L. J. (2006). Interactions between noncontiguous haplotypes in the adiponectin gene ACDC are associated with plasma adiponectin. Diabetes, 55, 523529.Google Scholar
Yamauchi, T., & Kadowaki, T. (2008). Physiological and pathophysiological roles of adiponectin and adiponectin receptors in the integrated regulation of metabolic and cardiovascular diseases. International Journal of Obesity, 32, S13S18.Google Scholar
Yang, W. S. (2009). Cord blood adipocytokines beyond adiposity in neonates? Pediatrics and Neonatology, 50, 245246.Google Scholar
Yang, W. S., Tsou, P. L., Lee, W. J., Tseng, D. L., Chen, C. L., Peng, C. C., . . . Chuang, L. M. (2003). Allele-specific differential expression of a common adiponectin gene polymorphism related to obesity. Journal of Molecular Medicine, 81, 428434.CrossRefGoogle ScholarPubMed
Figure 0

TABLE 1 Genotype Distributions of Adiponectin Gene SNPs in the Study

Figure 1

TABLE 2 Baseline Characteristics of Neonates in the Study (n = 237)

Figure 2

TABLE 3 Associations of Adiponectin Gene SNPs with Birth Sizes

Figure 3

TABLE 4 Logistic Regression Analysis of Adiponectin Gene SNPs for Birth Sizes