Objective

Weaning in mammals is associated with a shift in the metabolism, driven by the differences in the macronutrient composition of milk and post-weaning diet. Milk has a higher fat content compared with the carbohydrate-enriched solid food. Malnutrition during this stage could affect this transition with long-term adverse effects. The role of micronutrients during this transition is not well understood.

Methods

We used mice lacking a functional vitamin D receptor (VDR) to study the role of vitamin D signalling in the metabolic transition during weaning.

Results

We demonstrate that after weaning, VDR knockout mice exhibit systemic energy deprivation and higher lipolysis in inguinal white adipose tissue, probably due to increased norepinephrine signalling via protein kinase A (PKA) and extracellular signalling-regulated kinase (ERK) pathways. The energy deprivation in vdr−/− mice is associated with defective liver glycogenolysis, characterized by increased expression of protein phosphatase-1 alpha and decreased glycogen phosphorylase activity. However, restoration of serum calcium and phosphate levels by a rescue diet is sufficient to restore energy metabolism in vdr−/− mice. Interestingly, maintaining a high-fat-containing milk-based diet post-weaning could prevent the onset of energy deprivation, liver glycogen storage defect, and adipose atrophy in these mice.

Conclusion

Our data show that vitamin D-signalling is essential for the adaptation of mice to the dietary shift from high-fat-containing milk to post-weaning carbohydrate-enriched diets. It also reveals a novel macronutrient–micronutrient interaction that shapes the metabolic flexibility of the individual based on the dietary composition of nutrients.

Background

The global prevalence of obesity and type 2 diabetes, particularly among children, is rising, yet the long-term impacts of early-life fecal microbiota transplantation (FMT) on metabolic health remain poorly understood.

Objectives

To investigate how early-life FMT from children to young, sex-matched mice influences metabolic outcomes and adipose tissue function in later, adult life.

Methods

Germ-free mice were colonized with fecal microbiota from either lean children or children with obesity. The impacts on brown adipose tissue (BAT), white adipose tissue (WAT), glucose metabolism, and gut health were analyzed in male and female mice. Microbial communities and metabolite profiles were characterized using sequencing and metabolomics.

Results

Male mice receiving FMT from obese donors exhibited marked BAT whitening and impaired amino acid and glucose metabolism. In contrast, female recipients developed hyperglycemia, accompanied by gut barrier dysfunction and WAT impairment. Distinct microbial and metabolite profiles were associated with these phenotypes: Collinsella and trimethylamine in females; and Paraprevotella, Collinsella, Lachnospiraceae NK4A136, Bacteroides, Coprobacillus, and multiple metabolites in males. These phenotypic effects persisted despite changes in host environment and diet.

Conclusions

Early-life FMT induced long-lasting effects on the metabolic landscape, profoundly affecting adipose tissue function and systemic glucose homeostasis in adulthood. Donor dietary habits correlated with the fecal microbial profiles observed in recipient mice. These findings highlight the critical need for identifying and leveraging beneficial exposures during early development to combat obesity and diabetes.

Objective

We previously established the scaffold protein 14-3-3ζ as a critical regulator of adipogenesis and adiposity, but whether 14-3-3ζ exerted its regulatory functions in mature adipocytes or in adipose progenitor cells (APCs) remained unclear.

Methods

To decipher which cell type accounted for 14-3-3ζ-regulated adiposity, adipocyte- (Adipoq14-3-3ζKO) and APC-specific (Pdgfra14-3-3ζKO) 14-3-3ζ knockout mice were generated. To further understand how 14-3-3ζ regulates adipogenesis, Tandem Affinity Purification (TAP)-tagged 14-3-3ζ-expressing 3T3-L1 preadipocytes (TAP-3T3-L1) were generated with CRISPR-Cas9, and affinity proteomics was used to examine how the nuclear 14-3-3ζ interactome changes during the initial stages of adipogenesis. ATAC-seq was used to determine how 14-3-3ζ depletion modulates chromatin accessibility during differentiation.

Results

We show a pivotal role for 14-3-3ζ in APC differentiation, whereby male and female Pdgfra14-3-3ζKO mice displayed impaired or potentiated weight gain, respectively, as well as fat mass. Proteomics revealed that regulators of chromatin remodeling, like DNA methyltransferase 1 (DNMT1) and histone deacetylase 1 (HDAC1), were significantly enriched in the nuclear 14-3-3ζ interactome and their activities were impacted upon 14-3-3ζ depletion. Enhancing DNMT activity with S-Adenosyl methionine rescued the differentiation of 14-3-3ζ-depleted 3T3-L1 cells. ATAC-seq revealed that 14-3-3ζ depletion impacted the accessibility of up to 1,244 chromatin regions corresponding in part to adipogenic genes, promoters, and enhancers during the initial stages of adipogenesis. Finally, 14-3-3ζ-regulated chromatin accessibility correlated with the expression of key adipogenic genes.

Conclusion

Our study establishes 14-3-3ζ as a crucial epigenetic regulator of adipogenesis and highlights the usefulness of deciphering the nuclear 14-3-3ζ interactome to identify novel pro-adipogenic factors and pathways.

Objective

Metabolic dysfunction-associated steatotic liver disease (MASLD) is a growing global health concern, with limited effective treatments. KCNMA1 potassium channel has been implicated in the pathogenesis of various metabolic diseases. However, whether and how KCNMA1 regulates MASLD have been elusive.

Methods

Global, hepatic stellate cells (HSCs)-specific, and hepatocyte-specific Kcnma1 knockout mice were fed either a standard chow or a high-fat diet (HFD). Serum and liver tissues were collected and analyzed by biochemical assay, histology, qPCR and western blotting. HSCs conditioned medium (CM) treatment hepatocytes experiment model and three-dimensional (3D) hepatocytes-HSCs spheroids were employed to study lipid accumulation in hepatocytes. A Cytokine Antibody Array was used to analyze the cytokine profile.

Results

Our study demonstrated that global Kcnma1 deletion prevented diet-induced hepatic steatosis and improved insulin sensitivity. Further analyses using HSC-specific and hepatocyte-specific Kcnma1 knockout MASLD mouse models revealed that the protective effect against hepatic steatosis was predominantly mediated by Kcnma1 deletion in HSCs, rather than in hepatocytes. CM transfer experiment and 3D spheroid studies show Kcnma1 deletion effectively prevents lipid accumulation in hepatocytes. Mechanically, Kcnma1-deficient HSCs secrete Amphiregulin (AREG) to regulate lipid metabolism in hepatocytes via epidermal growth factor receptor (EGFR) signaling. Of clinical significance, AREG levels were notably reduced in the liver tissue of MASLD patients, while injection of recombinant AREG protein significantly ameliorated MASLD in mice.

Conclusions

Our study uncovers a novel mechanism in which Kcnma1 deletion in HSCs enhances AREG secretion, thereby reducing lipid accumulation in hepatocytes through the AREG/EGFR signaling, ultimately inhibiting the progression of MASLD.

Objective

The cellular composition and functionality of adipose tissue are key determinants of metabolic diseases associated with adipose tissue dysregulation, such as obesity. We hypothesized that distinct subpopulations with unique gene expression profiles and functional characteristics exist within human adipocytes.

Methods

Dedifferentiated adipocytes (DFAT), obtained by ceiling culture of human adipocytes, were analyzed using single-cell RNA sequencing (10x Genomics). Clustering analysis identified one subpopulation with a particular gene signature containing muscle cell genes which was further characterized by bulk-sequencing and analyzed alongside different cohorts of human adipose tissue.

Results

This subpopulation, named cluster 7 (C7), was isolated by FACS using two specific surface markers: cluster of differentiation 36 (CD36) and melanoma cell adhesion molecule (MCAM/CD146). Upon differentiation into adipocytes, the FACS-isolated CD36+/CD146+ cells (C7∗) showed an increased oxygen consumption rate compared to CD36-/CD146-cells (control cells) and non-sorted cells. Bulk RNA-sequencing revealed important pathways regulated in the differentiated C7∗ subpopulation that may contribute to its increased metabolic activity. Furthermore, the relative abundance of this specific cluster varied across eleven different human donors, demonstrating an inverse correlation between the proportion of C7∗ cells and the body mass index (BMI) of the respective donor. Importantly, a subset of genes regulated within this subpopulation also correlates with clinically relevant metabolic parameters, including weight, BMI, glycated hemoglobin, and plasma insulin, when analyzed alongside the gene expression of a large cohort of human subcutaneous adipose tissue (1759 donors).

Conclusion

Our results not only characterize DFAT cells derived from human adipose tissue, but also identify a specific subpopulation with increased energy expenditure that may play a role in body weight control. Future efforts to identify possible therapeutic targets or to promote the enrichment or activation of these energy-burning cells in adipose tissue might be useful in the field of cardiometabolic diseases.

Objective

Macrophage accumulation in metabolically active tissues during obesity is common in both animals and humans, but the lipid signaling mechanisms that trigger macrophage inflammation remain unclear. This study investigates the role of Ces1d, an unconventional lipase, in regulating macrophage inflammation under nutritional stress.

Methods

A myeloid-specific Ces1d knockout (LysM-Cre-Ces1d ^{floxed/floxed}, KO) mouse model was used for the studies. For in vitro tests, bone marrow-derived macrophages (BMDMs) from control (Ces1d ^{floxed/floxed}, WT) and KO mice were assessed for migration, polarization, and activation. For in vivo experiments, WT and KO mice were induced to obesity via a high-fat diet (HFD) and subjected to metabolic characterization. Adipose tissue, liver, and serum samples were analyzed histologically and biochemically. Endogenous macrophages and T cells from adipose tissue were isolated and analyzed for functional interactions by flow cytometry.

Results

Ces1d expression changes during the differentiation of monocytes into macrophages in both mice and humans. Loss of Ces1d causes larger lipid droplets, with increased accumulation of triacylglycerol (TAG) and diacylglycerol (DAG), and impaired lipid signaling in KO macrophages. Lipid dysregulation in macrophages triggers pro-inflammatory activation, enhancing migration, activation, and polarization toward an M1-like phenotype. The pro-inflammatory macrophages further promote CD3+CD8+ T cell accumulation in obese adipose tissue, which contributes to worsened metabolic disorders, including more severe fatty liver, increased local inflammation in adipose tissue, and impaired systemic glucose tolerance in KO mice on a high-fat diet.

Conclusions

This study demonstrates Ces1d is a crucial factor in maintaining lipid homeostasis in macrophages. Loss of Ces1d leads to metabolic dysregulation in macrophages and other immune cells during obesity.

Objectives

Sucrose-rich diets promote hepatic de novo lipogenesis (DNL) and steatosis through interactions with the gut microbiota. However, the role of sugar-microbiota dynamics in the absence of dietary fat remains unclear. This study aimed to investigate the effects of a high-sucrose, zero-fat diet (ZFD) on hepatic steatosis and host metabolism in conventionally raised (CONVR) and germ-free (GF) mice.

Methods

CONVR and GF mice were fed a ZFD, and hepatic lipid accumulation, gene expression, and metabolite levels were analyzed. DNL activity was assessed by measuring malonyl-CoA levels, expression of key DNL enzymes, and activation of the transcription factor SREBP-1c. Metabolomic analyses of portal vein plasma identified microbiota-derived metabolites linked to hepatic steatosis. To further examine the role of SREBP-1c, its hepatic expression was knocked down using antisense oligonucleotides in CONVR ZFD-fed mice.

Results

The gut microbiota was essential for sucrose-induced DNL and hepatic steatosis. In CONVR ZFD-fed mice, hepatic fat accumulation increased alongside elevated expression of genes encoding DNL enzymes, higher malonyl-CoA levels, and upregulation of SREBP-1c. Regardless of microbiota status, ZFD induced fatty acid elongase and desaturase gene expression and increased hepatic monounsaturated fatty acids. Metabolomic analyses identified microbiota-derived metabolites associated with hepatic steatosis. SREBP-1c knockdown in CONVR ZFD-fed mice reduced hepatic steatosis and suppressed fatty acid synthase expression.

Conclusions

Sucrose-microbiota interactions and SREBP-1c are required for DNL and hepatic steatosis in the absence of dietary fat. These findings provide new insights into the complex interplay between diet, gut microbiota, and metabolic regulation.

Objective

We previously identified tetraspanin 7 (Tspan7) as a candidate gene influencing body weight in an obesity-related gene screening study. However, the mechanisms underlying its involvement in body weight regulation remained unclear. This study aims to investigate the role of TSPAN7 from a metabolic perspective.

Methods

We utilized genetically modified mice, including adipose tissue-specific Tspan7-knockout and Tspan7-overexpressing models, as well as human adipose-derived stem cells with TSPAN7 knockdown and overexpression. Morphological, molecular, and omics analyses, including proteomics and transcriptomics, were performed to investigate TSPAN7 function. Physiological effects were assessed by measuring blood markers associated with lipid regulation under metabolic challenges, such as high-fat feeding and aging.

Results

We show that TSPAN7 is involved in regulating lipid droplet formation and stabilization. Tspan7-knockout mice exhibited an increased proportion of small-sized adipocytes and a reduced visceral-to-subcutaneous fat ratio. This shift in fat distribution was associated with improved insulin sensitivity and altered branched-chain amino acid metabolism, as evidenced by increased expression of the branched-chain α-keto acid dehydrogenase complex subunit B in Tspan7-modified mice. Mechanistically, TSPAN7 deficiency promoted subcutaneous fat expansion, alleviating metabolic stress on visceral fat, a major contributor to insulin resistance.

Conclusions

TSPAN7 influences lipid metabolism by modulating adipose tissue remodeling, particularly under metabolic challenges, such as high-fat diet exposure and aging. Its modulation enhances subcutaneous fat storage capacity while mitigating visceral fat accumulation, leading to improved insulin sensitivity. These findings position TSPAN7 as a potential target for therapeutic interventions aimed at improving metabolic health and preventing obesity-related diseases.

Objective

The capacity of the liver to serve as a peripheral sensor in the regulation of food intake has been debated for over half a century. The anatomical position and physiological roles of the liver suggest it is a prime candidate to serve as an interoceptive sensor of peripheral tissue and systemic energy state. Importantly, maintenance of liver ATP levels and within-meal food intake inhibition is impaired in human subjects with obesity and obese pre-clinical models. Previously, we have shown decreased hepatic mitochondrial energy metabolism (i.e., oxidative metabolism & ADP-dependent respiration) in male liver-specific, heterozygous PGC1a mice results in increased short-term diet-induced weight gain with increased within meal food intake. Herein, we tested the hypothesis that decreased liver mitochondrial energy metabolism impairs meal termination following nutrient oral pre-loads.

Methods

Liver mitochondrial respiratory response to changes in ΔG_ATP and adenine nucleotide concentration following fasting were examined in male liver-specific, heterozygous PGC1a mice. Further, food intake and feeding behavior during basal conditions, following nutrient oral pre-loads, and following fasting were investigated.

Results

We observed male liver-specific, heterozygous PGC1a mice have reduced mitochondrial response to changes in ΔG_ATP and tissue ATP following fasting. These impairments in liver energy state are associated with larger and longer meals during chow feeding, impaired dose-dependent food intake inhibition in response to mixed and individual nutrient oral pre-loads, and greater acute fasting-induced food intake.

Conclusions

These data support previous work proposing liver-mediated food intake regulation through modulation of peripheral satiation signals.

Objective

Acidic extracellular microenvironments, resulting from enhanced glycolysis and lactic acid secretion by immune cells, along with metabolic acidosis may interfere with the insulin signaling pathway and contribute to the development of insulin resistance. In the present study, we investigated the role of G protein-coupled receptor GPR65, an extracellular pH sensing protein, in modulating insulin resistance.

Methods

We measured GPR65 expression in the adipose tissue (AT) of subjects with varying metabolic health states. We utilized whole-body and hematopoietic cell-specific GPR65 knockout (KO) mice to investigate the mechanism underlying the associations between GPR65, inflammatory response, and insulin resistance.

Results

Elevated GPR65 expression was observed in the AT of subjects with obesity, compared to their lean counterparts, and was inversely correlated with insulin resistance. In GPR65 KO mice, improved insulin sensitivity and decreased hepatic lipid content were observed, attributed to concomitant increases in mitochondrial activity and fatty acid β-oxidation in liver. GPR65 KO mice also exhibited increased Akt phosphorylation in skeletal muscle, suppressed proinflammatory gene expression in AT, and decreased serum cytokine levels, collectively suggesting the anti-inflammatory effects of GPR65 depletion. This was further confirmed by observations of decreased macrophage chemotaxis towards AT in vitro, and depressed inflammatory signaling pathway activation in bone marrow-derived dendritic cells from GPR65 KO mice. Additionally, hematopoietic lineage-specific GPR65 KO mice exhibited improved whole body insulin sensitivity in clamp studies, demonstrating GPR65 signaling in immune cells mediates this effect.

Conclusions

Our data suggests that macrophage-specific GPR65 signaling contributes to inflammation and the development of insulin resistance.

Objective

Interleukin-6 (IL-6) is a pleiotropic cytokine involved in immune regulation and energy metabolism. Its diurnal secretion influences core circadian components, emphasizing its critical role in circadian biology. Despite known sex differences in immune, circadian, and metabolic processes, how IL-6 integrates these processes remains poorly understood.

Methods

IL6 knockout (KO) and control mice of both sexes were phenotyped for circadian and metabolic traits under standard (STD) and high-fat diet (HFD), fasting, and time-restricted feeding. Molecular analyses in muscle, liver, and hypothalamus assessed clock gene expression and IL-6 signaling pathway. Circulating sex steroid hormones were quantified to examine their contribution to the observed sex-specific phenotypes.

Results

IL-6 deficiency disrupts circadian locomotor and metabolic rhythms in a sex- and diet-dependent manner. Males exhibit impaired light-driven circadian rhythms under STD conditions and metabolic misalignment under HFD, whereas females display greater circadian resilience under STD conditions but increased vulnerability to circadian disruption during HFD. Additionally, IL-6 emerges as a novel regulator of the food-entrainable oscillator (FEO), linking food anticipatory activity and metabolic cycles under both STD and HFD in a sex-dependent manner.

Conclusions

These findings identify IL-6 as a critical mediator of circadian-metabolic plasticity, shaping sex- and diet-specific trade-offs between circadian stability and metabolic homeostasis. Our study highlights IL-6 as a potential therapeutic target for mitigating circadian misalignment-associated metabolic disorders, with implications for the timed modulation of IL-6 signaling.

Objective

Parkinson’s disease (PD) is recognized as a systemic condition, with clinical features potentially modifiable by dietary intervention. Diets high in saturated fats and refined sugars significantly increase PD risk and exacerbate motor and non-motor symptoms, yet precise metabolic mechanisms are unclear. Our objective here was to investigate the interplay between diet and PD-associated phenotypes from a metabolic perspective.

Methods

We explored PARK7 KO mice under chronic glycative stress induced by prolonged high-fat high-sucrose (HFHS) diet. We investigated metabolic consequences by combining classical metabolic phenotyping (body composition, glucose tolerance, indirect calorimetry, functional assays of isolated mitochondria) with metabolomics profiling of biospecimens from mice and PD patients.

Results

We found this obesogenic diet drives loss of fat and muscle mass in early-onset PD mice, with a selective vulnerability of glycolytic myofibers. We show that PD mice and early-onset familial PD patients are under pervasive glycative stress with pathological accumulation of advanced glycation end products (AGEs), including N-α-glycerinylarginine (α-GR) and N-α-glycerinyllysine (α-GK), two previously unknown glycerinyl-AGE markers.

Conclusions

Our results offer the first proof for a direct link between diet, accumulation of AGEs and genetics of PD. We also expand the repertoire of clinically-relevant glycative stress biomarkers to potentially define at-risk patients before neurological or metabolic symptoms arise, and/or to monitor disease onset, progression, and effects of interventions.

The activation of branched chain amino acid (BCAA) catabolism has garnered interest as a potential therapeutic approach to improve insulin sensitivity, enhance recovery from heart failure, and blunt tumor growth. Evidence for this interest relies in part on BT2, a small molecule that promotes BCAA oxidation and is protective in mouse models of these pathologies. BT2 and other analogs allosterically inhibit branched chain ketoacid dehydrogenase kinase (BCKDK) to promote BCAA oxidation, which is presumed to underlie the salutary effects of BT2. Potential “off-target” effects of BT2 have not been considered, however. We therefore tested for metabolic off-target effects of BT2 in Bckdk^−/− animals. As expected, BT2 failed to activate BCAA oxidation in these animals. Surprisingly, however, BT2 strongly reduced plasma tryptophan levels and promoted catabolism of tryptophan to kynurenine in both control and Bckdk^−/− mice. Mechanistic studies revealed that none of the principal tryptophan catabolic or kynurenine-producing/consuming enzymes (TDO, IDO1, IDO2, or KATs) were required for BT2-mediated lowering of plasma tryptophan. Instead, using equilibrium dialysis assays and mice lacking albumin, we show that BT2 avidly binds plasma albumin and displaces tryptophan, releasing it for catabolism. These data confirm that BT2 activates BCAA oxidation via inhibition of BCKDK but also reveal a robust off-target effect on tryptophan metabolism via displacement from serum albumin. The data highlight a potential confounding effect for pharmaceutical compounds that compete for binding with albumin-bound tryptophan.