Nutritional programming by maternal obesity: insights into the development of non‐alcoholic fatty liver disease

Obesity has become an urgent global health concern. Individuals with obesity are at higher risk in developing numerous diseases including diabetes, metabolic syndrome and fatty liver disease. According to the World Health Organization (WHO, 2016), 39% of adults aged 18 years and over worldwide were overweight, 13% of them were obese, and these numbers had tripled over the past three decades. While obese adults are spotted for health concerns, childhood obesity has also become a serious health problem as obese children tend to remain so later in life. Increasing evidence suggests a link between maternal diet and childhood obesity. This is referred to as nutritional programming whereby maternal diet during pregnancy exerts lifelong effects on the developing fetus including predisposition to diseases. Of note, numerous studies have demonstrated maternal obesity (MO), resulting from diets comprising high fats, predisposes children and adolescents to the development of non-alcoholic fatty liver disease (NAFLD) (Brumbaugh et al. 2014). NAFLD is characterized by an excess fat deposition in the liver in the absence of significant alcohol consumption. It is the most prevalent form of chronic liver disease in children and adolescents; however, the underlying mechanisms by which NAFLD develops and progresses remain unknown. Given the devastating impact of NAFLD on the paediatric population, it is imperative to understand the effect of MO on the development of the disease. In a recent article by Lomas-Soria et al. (2018) in The Journal of Physiology, a cross-sectional study was conducted to investigate the effects of MO on the development of NAFLD in young adult rat offspring. This study in particular was designed in part to address previous results showing programming by MO displays a bias between sexes whereby disease severity is often more pronounced in male than female offspring. To elucidate the underlying cause of these observed differences, Lomas-Soria et al. (2018) examined the effects of MO on female and male F1 rat livers independently by analysing liver metabolites, structure and transcriptome changes. This study was performed on F1 progeny from mothers who were fed with either a high-fat or a control diet. To ensure F1 progeny homogeneity, Lomas-Soria and colleagues weaned all the F1 rats at postnatal day (PND) 21 and subjected them to experimental analyses at PND110. Measurements of liver metabolites and structure revealed clear differences in phenotypes between male and female F1 livers arising from MO. Livers of male MO F1 presented significantly increased levels of weight, total fat and triglycerides compared to controls whereas livers of female MO F1 showed only an increase in triglyceride levels that is much less pronounced than in male MO F1. These results reflect a previous study by Lomas-Soria and colleagues where they showed that male MO F1 displayed more severe phenotypes compared to female MO F1 at a younger age (PND36). To help understand the differences between male and female MO F1 phenotypes, the authors examined gene expression profiles of male and female MO F1 and control F1 rat livers by RNA-seq analysis. They found a complete separation in the gene expression profiles between male MO F1 and control F1 as opposed to female MO F1 where there is a significant overlap in gene expression profiles with the control F1. A closer look into the distribution of differentially expressed genes (DEGs) revealed that 1317 genes were down-regulated and 48 were up-regulated in MO F1 males when compared to controls and only 24 were down-regulated and 46 were up-regulated in MO F1 females when compared to controls. These novel findings illustrate a sex-dependent MO programming in the F1 liver transcriptome. While the current study provides novel insights into the effects of MO on F1 genetic expression, an interesting question arose as to whether the observed sexual dimorphism in DEGs is exclusively a consequence of MO. Sexual dimorphism has long been considered to arise during early development. Due to an imbalance in X and Y chromosomes, a number of sex-biased gene expressions can be observed throughout development (Rigby et al. 2015). In mammals, a sophisticated sex-determination system is adopted to ensure successful production of morphologically and physiologically distinct sexes. This system involves neatly regulated hierarchies which use sex-specific transcription factors to produce sex-biased gene expression. In addition to sex-specific gonadal tissues, evidence has also suggested sexual dimorphism in somatic tissues (Rigby et al. 2015). For example, Zhang et al. (2011) conducted a genome-wide scale study using human liver samples collected from 224 subjects and found that close to 4% of total genes in liver (1249/33250) had sex-biased expression. In addition, 70% of these genes were found to have higher expression in females. Therefore, according to this finding, it will be interesting to determine whether any of these genes have homologues that overlap with the DEGs found in the MO F1 rats reported by Lomas-Soria et al. (2018). Results from this study will have the potential to narrow down the genetic targets of F1 influenced by MO, which may further strengthen the current evidence of sexual dimorphism in the NAFLD F1 rats. Another factor that may also be implicated in MO programmed NAFLD in the F1 progeny is the difference in hormonal state between sexes. A study by Hogg et al. (2011) demonstrated that maternal exposure to androgens resulted in subclinical fatty liver in young adult sheep while oestrogens provided a protective role in the liver. Moreover, Villa et al. (2012) suggested that oestrogen receptor signalling plays an important role in regulating fat metabolism in the mouse liver. They found that oestrogen receptor oscillates in phase with the oestrous cycle and that a proper oestrous cycle is necessary to prevent fat deposition in the liver. These studies suggest a need to investigate whether hormones contribute a regulating role in the

• Publication year

  2018

• Venue

  Journal of Physiology

• Publication date

  2018-09-09

• Fields of study

  Medicine, Chemistry

• Identifiers
  DOI 10.1113/JP276965PMID 30160306PMCID PMC6187035
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

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