Josep C. Jimenez-Chillaron

Intergenerational Transmission of Glucose Intolerance and Obesity by In Utero Undernutrition in Mice

OBJECTIVE—Low birth weight (LBW) is associated with increased risk of obesity, diabetes, and cardiovascular disease during adult life. Moreover, this programmed disease risk can progress to subsequent generations. We previously described a mouse model of LBW, produced by maternal caloric undernutrition (UN) during late gestation. LBW offspring (F1-UN generation) develop progressive obesity and impaired glucose tolerance (IGT) with aging. We aimed to determine whether such metabolic phenotypes can be transmitted to subsequent generations in an experimental model, even in the absence of altered nutrition during the second pregnancy. RESEARCH DESIGN AND METHODS—We intercrossed female and male F1 adult control (C) and UN mice and characterized metabolic phenotypes in F2 offspring. RESULTS—We demonstrate that 1) reduced birth weight progresses to F2 offspring through the paternal line (C♀-C♂ = 1.64 g; C♀-UN♂ = 1.57 g, P < 0.05; UN♀-C♂ = 1.64 g; UN♀-UN♂ = 1.60 g, P < 0.05), 2) obesity progresses through the maternal line (percent body fat: C♀-C♂ = 22.4%; C♀-UN♂ = 22.9%; UN♀-C♂ = 25.9%, P < 0.05; UN♀-UN♂ = 27.5%, P < 0.05), and 3) IGT progresses through both parental lineages (glucose tolerance test area under curve C♀-C♂ = 100; C♀-UN♂ = 122, P < 0.05; UN♀-C♂ = 131, P < 0.05; UN♀-UN♂ = 151, P < 0.05). Mechanistically, IGT in both F1 and F2 generations is linked to impaired β-cell function, explained, in part, by dysregulation of Sur1 expression. CONCLUSIONS—Maternal undernutrition during pregnancy (F0) programs reduced birth weight, IGT, and obesity in both first- and second-generation offspring. Sex-specific transmission of phenotypes implicates complex mechanisms including alterations in the maternal metabolic environment (transmaternal inheritance of obesity), gene expression mediated by developmental and epigenetic pathways (transpaternal inheritance of LBW), or both (IGT).

The role of nutrition on epigenetic modifications and their implications on health

Nutrition plays a key role in many aspects of health and dietary imbalances are major determinants of chronic diseases including cardiovascular disease, obesity, diabetes and cancer. Adequate nutrition is particularly essential during critical periods in early life (both pre- and postnatal). In this regard, there is extensive epidemiologic and experimental data showing that early sub-optimal nutrition can have health consequences several decades later. The hypothesis that epigenetic mechanisms may link such nutritional imbalances with altered disease risk has been gaining acceptance over recent years. Epigenetics can be defined as the study of heritable changes in gene expression that do not involve alterations in the DNA sequence. Epigenetic marks include DNA methylation, histone modifications and a variety of non-coding RNAs. Strikingly, they are plastic and respond to environmental signals, including diet. Here we will review how dietary factors modulate the establishment and maintenance of epigenetic marks, thereby influencing gene expression and, hence, disease risk and health.

An Unbiased Assessment of the Role of Imprinted Genes in an Intergenerational Model of Developmental Programming

Environmental factors during early life are critical for the later metabolic health of the individual and of future progeny. In our obesogenic environment, it is of great socioeconomic importance to investigate the mechanisms that contribute to the risk of metabolic ill health. Imprinted genes, a class of functionally mono-allelic genes critical for early growth and metabolic axis development, have been proposed to be uniquely susceptible to environmental change. Furthermore, it has also been suggested that perturbation of the epigenetic reprogramming of imprinting control regions (ICRs) may play a role in phenotypic heritability following early life insults. Alternatively, the presence of multiple layers of epigenetic regulation may in fact protect imprinted genes from such perturbation. Unbiased investigation of these alternative hypotheses requires assessment of imprinted gene expression in the context of the response of the whole transcriptome to environmental assault. We therefore analyse the role of imprinted genes in multiple tissues in two affected generations of an established murine model of the developmental origins of health and disease using microarrays and quantitative RT–PCR. We demonstrate that, despite the functional mono-allelicism of imprinted genes and their unique mechanisms of epigenetic dosage control, imprinted genes as a class are neither more susceptible nor protected from expression perturbation induced by maternal undernutrition in either the F1 or the F2 generation compared to other genes. Nor do we find any evidence that the epigenetic reprogramming of ICRs in the germline is susceptible to nutritional restriction. However, we propose that those imprinted genes that are affected may play important roles in the foetal response to undernutrition and potentially its long-term sequelae. We suggest that recently described instances of dosage regulation by relaxation of imprinting are rare and likely to be highly regulated.

Expression of the Splicing Factor Gene SFRS10 is Reduced in Human Obesity and Contributes to Enhanced Lipogenesis

Alternative mRNA splicing provides transcript diversity and may contribute to human disease. We demonstrate that expression of several genes regulating RNA processing is decreased in both liver and skeletal muscle of obese humans. We evaluated a representative splicing factor, SFRS10, downregulated in both obese human liver and muscle and in high-fat-fed mice, and determined metabolic impact of reduced expression. SFRS10-specific siRNA induces lipogenesis and lipid accumulation in hepatocytes. Moreover, Sfrs10 heterozygous mice have increased hepatic lipogenic gene expression, VLDL secretion, and plasma triglycerides. We demonstrate that LPIN1, a key regulator of lipid metabolism, is a splicing target of SFRS10; reduced SFRS10 favors the lipogenic β isoform of LPIN1. Importantly, LPIN1β-specific siRNA abolished lipogenic effects of decreased SFRS10 expression. Together, our results indicate that reduced expression of SFRS10, as observed in tissues from obese humans, alters LPIN1 splicing, induces lipogenesis, and therefore contributes to metabolic phenotypes associated with obesity.

To catch up or not to catch up: is this the question? Lessons from animal models.

Purpose of reviewLow birth weight and accelerated postnatal catch-up growth during early life are independent risk factors for adult disease, including diabetes, obesity, and cardiovascular disease. As they are intimately linked, it is difficult to determine the independent contributions of birth weight and catch-up growth per se. This review focuses on evidence derived from animal models of disease, in which it is possible to dissect more clearly the independent roles of intrauterine growth retardation, low birth weight, and catch-up growth in mediating disease risk. Recent findingsRecent data from rats, mice and birds show that accelerated postnatal growth is a trigger for the development of adult disease and, ultimately, can affect longevity. SummaryUnderstanding the mechanisms and relative contribution of low birth weight and early postnatal catch-up growth to late onset of disease is critical to establish appropriate interventions to prevent or delay adult disease.

Transgenerational epigenetic inheritance of diabetes risk as a consequence of early nutritional imbalances.

In todays world, there is an unprecedented rise in the prevalence of chronic metabolic diseases, including obesity, insulin resistance and type 2 diabetes (T2D). The pathogenesis of T2D includes both genetic and environmental factors, such as excessive energy intake and physical inactivity. It has recently been suggested that environmental factors experienced during early stages of development, including the intrauterine and neonatal periods, might play a major role in predisposing individuals to T2D. Furthermore, several studies have shown that such early environmental conditions might even contribute to disease risk in further generations. In this review, we summarise recent data describing how parental nutrition during development increases the risk of diabetes in the offspring. We also discuss the potential mechanisms underlying transgenerational inheritance of metabolic disease, with particular emphasis on epigenetic mechanisms.

Reduction of islet amylin expression and basal secretion by adenovirus-mediated delivery of amylin antisense cDNA

Reduction of amylin content and secretion in rat islets was attempted by transduction with an adenovirus bearing a 0.2-kb fragment of rat amylin cDNA inserted in the antisense orientation (AdCMV-

Fatty Acid Transport Protein 1 (FATP1) Localizes in Mitochondria in Mouse Skeletal Muscle and Regulates Lipid and Ketone Body Disposal

aLamylin). Exposure of islets to AdCMV-

GNIP1 E3 ubiquitin ligase is a novel player in regulating glycogen metabolism in skeletal muscle

aLamylin at a multiplicity of infection (moi) of 200 (1.2 × 107 pfu/ml) reduced amylin mRNA levels by 37 ± 5% (p <0.005), whereas infection with an adenovirus expressing the reporter gene of β-galactosidase (AdCMV-lacz) did not modify amylin expression. Transduction with the antisense construct was specifically associated with the decrease (30 ± 6%; p <0.001) in the amylin content. Insulin content was unaltered in AdCMV-

Epigenetic programming at the Mogat1 locus may link neonatal overnutrition with long-term hepatic steatosis and insulin resistance

aLamylin islets compared to AdCMV-lacz-transduced or untransduced cells. Basal amylin secretion (2.8 mM glucose) was 36 ± 3% (p <0.005) lower in AdCMV-