Early life energy expenditure deficits drive obesity in a mouse model of Alström syndrome

Alström syndrome is an extremely rare multi-system disorder for which early-onset childhood obesity is one of the cardinal features. Similar to humans with Alström syndrome, animal models with Alms1 loss of function mutations develop obesity, strongly supporting the notion that ALMS1/Alms1 is required for the regulatory control of energy balance across species. To determine which component(s) of energy balance are reliant on functional Alms1, we performed comprehensive energy balance phenotyping of the tvrm102 mouse model of Alström syndrome. We found that that adiposity gains occurred early and rapidly in male mice but much later in females. Rapid increases in body fat in males were, at least in part, due to a marked reduction in energy expenditure during early life and not due to any genotype-specific influence over energy intake. Energy intake did increase in a genotype-specific manner when mice were provided a palatable, high-energy diet, although this was not necessary for the initial establishment of obesity. Interestingly, the energy expenditure deficit observed in male Alms1-/-mice did not persist as mice age, suggesting that loss of Alms1 either causes a developmental delay in the mechanisms controlling early life energy expenditure, or that there is activation of compensatory mechanisms after obesity is established. Future studies will tease out how ALMS1/Alms1 modulates energy expenditure in early life and how sex moderates this process.

Abstract MP212: Integrated Genomics Analysis Identifies Recessive Ciliopathy Mutations In Primary Endocardial Fibroelastosis: A Rare Neonatal Cardiomyopathy

Background: Among neonatal cardiomyopathies, primary endocardial fibroelastosis (pEFE) remains a mysterious disease of the endomyocardium, affecting 1/5000 live births and accounting for 25% of the entire pediatric dilated cardiomyopathy (DCM) population with a devastating course and grave prognosis. Objective: We aimed to investigate potential genetic contributions to pEFE etiology. Methods: We performed integrative genomic analysis in 8 infants with confirmed pathological diagnosis of pEFE using whole exome sequencing (WES), RNA-seq and functional genomics studies. Patient-derived fibroblasts, neonatal rat ventricular myocytes and neonatal rat cardiac fibroblasts were used for cellular assays. Real-time cell migration and proliferation analyses were performed using xCELLigence technology. Results: Whole exome sequencing detected novel and deleterious de novo single nucleotide variants, or inherited homozygous rare variants in 11 cilia-related genes in seven out of the eight affected probands. In particular, a novel homozygous variant [c.1938delA] in ALMS1 was identified in a female proband, pEFE4. This variant resulted in a frameshift introducing a premature stop codon and complete absence of the ALMS1 protein in the proband fibroblasts and explanted heart. Loss of function mutations of ALMS1 have been implicated in Alstrom syndrome [OMIM 203800], a rare recessive ciliopathy. RNA-sequencing of the proband’s dermal fibroblasts revealed significantly dysregulated cellular signaling and function, including the induction of epithelial mesenchymal transition (EMT), potentially mediated by TGFβ signaling activation. The proband fibroblasts exhibited enhanced migration activity. Herein, we present the unique pathological features of pEFE compared to DCM and utilize integrated WES with RNA-seq analysis to elucidate the molecular mechanisms by which the novel causal ALMS1 variant contributes to the unique pathology of pEFE in a female infant with Alstrom syndrome. Conclusions: Our report provides insights into pEFE etiology and suggests, for the first time to our knowledge, ciliopathy as a potential underlying mechanism for this poorly understood and incurable form of neonatal cardiomyopathy.

Recessive ciliopathy mutations in primary endocardial fibroelastosis: a rare neonatal cardiomyopathy in a case of Alstrom syndrome

Among neonatal cardiomyopathies, primary endocardial fibroelastosis (pEFE) remains a mysterious disease of the endomyocardium that is poorly genetically characterized, affecting 1/5000 live births and accounting for 25% of the entire pediatric dilated cardiomyopathy (DCM) with a devastating course and grave prognosis. To investigate the potential genetic contribution to pEFE, we performed integrative genomic analysis, using whole exome sequencing (WES) and RNA-seq in a female infant with confirmed pathological diagnosis of pEFE. Within regions of homozygosity in the proband genome, WES analysis revealed novel parent-transmitted homozygous mutations affecting three genes with known roles in cilia assembly or function. Among them, a novel homozygous variant [c.1943delA] of uncertain significance in ALMS1 was prioritized for functional genomic and mechanistic analysis. Loss of function mutations of ALMS1 have been implicated in Alstrom syndrome (AS) [OMIM 203800], a rare recessive ciliopathy that has been associated with cardiomyopathy. The variant of interest results in a frameshift introducing a premature stop codon. RNA-seq of the proband’s dermal fibroblasts confirmed the impact of the novel ALMS1 variant on RNA-seq reads and revealed dysregulated cellular signaling and function, including the induction of epithelial mesenchymal transition (EMT) and activation of TGFβ signaling. ALMS1 loss enhanced cellular migration in patient fibroblasts as well as neonatal cardiac fibroblasts, while ALMS1-depleted cardiomyocytes exhibited enhanced proliferation activity. Herein, we present the unique pathological features of pEFE compared to DCM and utilize integrated genomic analysis to elucidate the molecular impact of a novel mutation in ALMS1 gene in an AS case. Our report provides insights into pEFE etiology and suggests, for the first time to our knowledge, ciliopathy as a potential underlying mechanism for this poorly understood and incurable form of neonatal cardiomyopathy. Key message Primary endocardial fibroelastosis (pEFE) is a rare form of neonatal cardiomyopathy that occurs in 1/5000 live births with significant consequences but unknown etiology. Integrated genomics analysis (whole exome sequencing and RNA sequencing) elucidates novel genetic contribution to pEFE etiology. In this case, the cardiac manifestation in Alstrom syndrome is pEFE. To our knowledge, this report provides the first evidence linking ciliopathy to pEFE etiology. Infants with pEFE should be examined for syndromic features of Alstrom syndrome. Our findings lead to a better understanding of the molecular mechanisms of pEFE, paving the way to potential diagnostic and therapeutic applications.

Impaired Ca2+ signaling due to steatosis mediates hepatic insulin resistance in Alstrom Syndrome mice that is reversed by GLP-1 analog treatment

Ca2+ signaling plays a critical role in the regulation of hepatic metabolism by hormones including insulin. Changes in cytoplasmic Ca2+ regulate synthesis and post-translational modification of key signaling proteins in the insulin pathways. Emerging evidence suggests that hepatocyte intracellular Ca2+ signaling is altered in lipid-loaded liver cells isolated from obese rodent models. The mechanisms of altered Ca2+-insulin and insulin-Ca2+ signaling pathways in obesity remain poorly understood. Here we show that the kinetics of insulin-initiated intracellular (initial) Ca2+ release from endoplasmic reticulum is significantly impaired in steatotic hepatocytes from obese Alström syndrome mice. Furthermore, exenatide, a GLP-1 analog, reversed lipid-induced inhibition of intracellular Ca2+ release kinetics in steatotic hepatocytes, without affecting the total content of intracellular Ca2+ released. Exenatide reversed the lipid-induced inhibition of intracellular Ca2+ release, at least partially, via lipid reduction in hepatocytes which then restored hormone-regulated cytoplasmic Ca2+ signaling and insulin sensitivity. This data provides additional evidence for the important role of Ca2+ signaling pathways in obesity-associated impaired hepatic lipid homeostasis and insulin signaling. It also highlights a potential advantage of GLP-1 analogs when used to treat type 2 diabetes associated with hepatic steatosis.

Liver Fibrosis and Steatosis in Alström Syndrome: A Genetic Model for Metabolic Syndrome

Alström syndrome (ALMS) is an ultra-rare monogenic disease characterized by insulin resistance, multi-organ fibrosis, obesity, type 2 diabetes mellitus (T2DM), and hypertriglyceridemia with high and early incidence of non-alcoholic fatty liver disease (NAFLD). We evaluated liver fibrosis quantifying liver stiffness (LS) by shear wave elastography (SWE) and steatosis using ultrasound sonographic (US) liver/kidney ratios (L/K) in 18 patients with ALMS and 25 controls, and analyzed the contribution of metabolic and genetic alterations in NAFLD progression. We also genetically characterized patients. LS and L/K values were significantly higher in patients compared with in controls (p < 0.001 versus p = 0.013). In patients, LS correlated with the Fibrosis-4 Index and age, while L/K was associated with triglyceride levels. LS showed an increasing trend in patients with metabolic comorbidities and displayed a significant correlation with waist circumference, the homeostasis model assessment, and glycated hemoglobin A1c. SWE and US represent promising tools to accurately evaluate early liver fibrosis and steatosis in adults and children with ALMS during follow-up. We described a new pathogenic variant of exon 8 in ALMS1. Patients with ALMS displayed enhanced steatosis, an early increased age-dependent LS that is associated with obesity and T2DM but also linked to genetic alterations, suggesting that ALMS1 could be involved in liver fibrogenesis.