Previous studies have demonstrated increased risk of hepatic steatosis in patients following pancreatic resection, which might be linked to decreased pancreatic function. Here, we evaluated liver fat content, circulating pancreatic hormones, amino acids, and more, before and 1 year after either total pancreatectomy or pancreaticoduodenectomy. At 1-year follow-up, we found increased liver fat content in more than half (63%) of the participants, evaluated both by liver histology and magnetic resonance imaging. The participants were characterized by hyperaminoacidemia, which correlated negatively with remnant endocrine pancreatic function. These findings further elucidate the relationship between glucagon, circulating amino acids, and hepatic metabolism.

Diabetic cardiomyopathy (DCM) describes the abnormality of myocardial structure and function caused by diabetes, and Yes-associated protein (Yap) is linked to various cardiovascular diseases, modulating remodeling and cardiac function in hearts, but its role in DCM is unclear. How Yap affects myocardial structure and function in mice with type 2 diabetes mellitus and the underlying pathways were investigated. High glucose or high glucose plus palmitic acid levels enhance Yap activity, thereby promoting miR-22-3p expression and inhibiting sirtuin 1 (Sirt1) expression. The Yap-miR-22-3p-Sirt1 axis plays critical roles in the cause of DCM. The molecular pathways investigated offer promising targets for therapeutic intervention against DCM and provide new insights into the development of innovative treatment strategies to combat cardiac dysfunction in patients with diabetes.

We report five new cases of neonatal or early childhood-onset diabetes caused by biallelic pathogenic variants in IL2RA. Autoimmune diabetes was the presenting feature in most individuals and occurs in 64% of all reported cases of immunodeficiency 41. Patients typically presented in infancy with diabetic ketoacidosis, low C-peptide, and GAD antibody positivity, highlighting an autoimmune etiology. The diabetes phenotype was consistent across cases but not linked to variant type or location. IL2RA should be included in genetic testing for neonatal diabetes and considered in children with diabetes plus immune dysregulation.

Type 1 diabetes (T1D) is the most common chronic autoimmune disease in children, driven by a breakdown in self-tolerance and T cell-mediated immune attack of pancreatic β-cells. There are no biomarkers to effectively diagnose autoimmunity before disease onset and clinical symptom development. Here, we applied deep multiparametric immunophenotyping to compare immune landscapes in 38 patients with new-onset T1D, 24 siblings, and 18 healthy control participants (HCs). Patients with T1D underwent clinical and metabolic evaluations. Immune populations in fresh whole-blood samples were analyzed using a panel of 26 antibodies, detecting 39 different cell populations. Memory regulatory T cells (memory Tregs) were significantly increased in patients with T1D (P < 0.05) and their siblings (P < 0.01) compared with HCs but not between patients with T1D and siblings. Memory Tregs were associated with disease status and age in multivariable analysis. There was a positive correlation between age and memory Tregs in the HC and sibling groups but not in patients with T1D. Baseline memory Treg levels in siblings resembled those of patients with T1D. These findings highlight the existence of an age-independent, disease-specific immune fingerprint that could serve as a minimally invasive biomarker for early diagnosis and personalized immunotherapy. Further studies using functional and single-cells analysis are needed to confirm memory Tregs as a pathogenic trait.

Gestational diabetes mellitus (GDM) is a heterogeneous condition diagnosed solely through glucose. It is characterized by profound perturbations in the metabolome, with specific metabolic profiles linked to adverse birth outcomes. Metabolomics can reveal population heterogeneity in health and disease. Here, we used nontargeted metabolomics to systematically profile the circulating metabolome in 2,050 pregnant women during midpregnancy, identifying 30 metabolites that define the GDM metabolic signature (mGDM). Participants were stratified into four groups by distinct glycemic and metabolic profiles, namely normoglycemic non-mGDM, hyperglycemic non-mGDM, normoglycemic mGDM, and hyperglycemic mGDM, and associations with subsequent adverse birth outcomes were assessed. Compared with normoglycemic non-mGDM, normoglycemic mGDM demonstrated nearly a twofold increased risk of preterm birth (odds ratio [OR] 1.93, 95% CI 1.02-3.65) and large for gestational age (OR 2.11, 95% CI 1.53-2.92). Conversely, the hyperglycemic non-mGDM group did not show elevated risks in adverse birth outcomes versus the normoglycemic group. The hyperglycemic mGDM profile was associated with higher risks of preterm birth (OR 2.37, 95% CI 1.04-5.39), large for gestational age (OR 2.28, 95% CI 1.50-3.47), congenital malformations (OR 1.87, 95% CI 1.03-3.39), and neonatal intensive care unit (NICU) admissions (OR 1.69, 95% CI 1.09-2.61). We observed a stepwise increase in adverse outcome risk across the four-level metabolic-glycemic categories (P for trend < 0.001 for large for gestational age, 0.013 for preterm birth, and 0.018 for NICU admission). Taken together, our study outlines the metabolic profile of GDM and reveals clinically relevant heterogeneity in adverse pregnancy outcomes by metabolic signature. Integrating blood glucose and metabolomics may improve risk stratification and advance precision maternal care.

Chronic low-grade inflammation underlies many microvascular complications of diabetes, including diabetic kidney disease (DKD). Lipoxins (LXs), an endogenously produced family of lipid mediators, resolve inflammation and protect against renal scarring as occurs in DKD. This study examined the mechanism by which LXs protect against DKD, focusing on the regulation of VCAM-1 and the recruitment of macrophages to the diabetic glomerulus. LXA4 and two fourth-generation mimetics were assessed in diabetic ApoE knockout mice, followed by in vitro studies in the main renal cell populations, including podocytes, proximal tubular, mesangial, and glomerular endothelial cells. LXs attenuated albuminuria, mesangial expansion, and collagen and fibronectin deposition as both a preventive and delayed intervention in experimental DKD. LXs also consistently attenuated the TNF-α-induced expression of VCAM-1 in all the human and mouse renal cell populations examined. Further analysis identified that the renoprotection was in part mediated by an epigenetic modification of the VCAM-1 gene through H3K4 monomethylation, which did not appear to be dependent on NF-κB activation in human glomerular endothelial cells. LXs protect against DKD by modulating glomerular endothelial cell inflammation and via a novel LX-mediated epigenetic mechanism regulating the VCAM-1 promoter in these cells.

Adipose tissue (AT) lipolysis insulin resistance results in excess free fatty acid (FFA) release. We tested the hypothesis that the ability of insulin to suppress AT lipolysis is unrelated to the ability of niacin to suppress lipolysis, because niacin acts through a different proximal signaling pathway. Ten volunteers (5 women and 5 men) with upper-body obesity and/or type 2 diabetes mellitus (T2DM) underwent two study visits with overnight intravenous infusions of niacin (1.4 mg/min) or saline, followed by a hyperinsulinemic-euglycemic clamp. FFA-palmitate Ra was measured using [U-13C] and [2H9]palmitate infusions; abdominal AT biopsies were performed before and during the insulin clamp. The suppression of FFA-palmitate Ra by insulin on the saline control day and by niacin after an overnight infusion were highly correlated (r = -0.93, P < 0.001). Fasting AT Akt (pAktS473/474-to-panAkt ratio, P = 0.01) and perilipin 1 (PLN1) (pPLN1S552-to-panPLN1 ratio, P = 0.02) phosphorylation were less during niacin treatment than in the saline control study. Because the suppression of lipolysis by insulin and niacin are highly correlated within individuals and because niacin and insulin act through different proximal signaling pathways, we propose dysregulated AT lipolysis in obesity/T2DM is due to dysfunction(s) in distal lipolysis proteins rather than isolated "insulin resistance."

Pancreatic β-cells play a central role in type 2 diabetes mellitus (T2DM), yet the interactions between β-cells and stromal components within the islet microenvironment remain poorly defined. We investigated the contribution of pancreatic fibroblasts to β-cell dysfunction and T2DM progression. We used single-cell sequencing technology and in vitro experiments to investigate the mechanisms by which bariatric surgery ameliorates T2DM. We introduce the novel concept of a "metabolic synapse" to describe the interaction between pancreatic fibroblasts and β-cells. Our findings reveal that pancreatic fibroblasts secrete excessive glutamate in the early stages of T2DM. Elevated glutamate concentrations within the islet microenvironment subsequently activate N-methyl-d-aspartic acid receptors (NMDARs), triggering PANoptosis in pancreatic β-cells and accelerating T2DM progression. Consistent with this, significant changes in NMDAR expression were observed in human pancreatic samples from patients with T2DM. These findings uncover a previously unrecognized fibroblast-β-cell communication pathway in the islet niche, provide mechanistic insights into T2DM pathogenesis, and highlight the glutamate-NMDAR axis as a potential therapeutic target for nonsurgical intervention.

Adipokines serve crucial functions in diabetic kidney disease (DKD) pathogenesis. Growth differentiation factor 5 (GDF5) is highly expressed in adipose tissue, but its specific role in DKD is unknown. In this study, we observed elevated GDF5 expression in both patients with DKD and db/db mice, suggesting a potential association between GDF5 and DKD progression. Elevated plasma GDF5 levels are associated with an increased risk of incident chronic kidney disease in patients with type 2 diabetes. In animal studies, adipose-specific overexpression of GDF5 increased circulating GDF5 and exacerbated renal injury in db/db mice, characterized by increased tubulointerstitial injury and inflammation infiltration. Conversely, adipose-specific knockdown reduced circulating GDF5 and alleviated renal injury. In vitro studies demonstrated that GDF5 induces partial epithelial-mesenchymal transition in renal tubular epithelial cells via activation of the SMAD1/5/8 signaling pathway, as evidenced by reduced E-cadherin expression and increased Snail1 levels. Notably, the supernatant from GDF5-treated injured HK-2 cells was found to enhance the secretion of proinflammatory cytokines by macrophages. These findings suggest that adipose-derived GDF5 acts as a novel mediator contributing to tubulointerstitial injury in DKD.

Weight cycling has been demonstrated, in humans and animal models, to increase cardiometabolic disease and disrupt glucose homeostasis. Both obesity itself and weight cycling cause adipose tissue inflammation and metabolic dysfunction. Studies show that even after weight loss, increased numbers of lipid-associated macrophages and memory T cells persist in adipose tissue and become more inflammatory on weight regain. This suggests that the immune system retains an obesogenic memory, which may contribute to the elevated inflammation and metabolic dysfunction associated with weight cycling. We show that blocking the CD70-CD27 axis, critical for the formation of immunologic memory, decreases the number of memory T cells and T-cell clonality within adipose tissue after weight loss and weight cycling. Furthermore, although CD70-/- mice have metabolic responses to stable obesity similar to those of wild-type mice, they are protected from the worsened glucose tolerance associated with weight cycling. Our data are the first to support mitigating the metabolic consequences of weight cycling through an immunomodulatory mechanism. We propose a new avenue of therapeutic intervention targeting memory T cells to minimize the adverse consequences of weight cycling. These findings are timely, given the increasing use of weight-loss drugs, which may lead to more instances of human weight cycling.

In response to the lockdowns and travel bans during the coronavirus disease 2019 pandemic, Peter C. Butler at the University of California, Los Angeles (UCLA), started a virtual islet biology seminar series. After the authors of this article joined him as co-organizers, this initiative became the Islet Research Seminar Series (IRSS). Like islets of Langerhans adapt to their changing environment, the islet biology community quickly embraced this new format. The IRSS evolved into a lasting scientific forum that convenes weekly and is attended by islet biologists from the U.S., Canada, Europe, and Israel. The series covers a range of topics in islet biology, with presentations from scientists representing all career stages. It has proven particularly valuable for trainees and early-stage investigators in exposing them to a variety of topics in islet biology without travel required and facilitating more spontaneous interactions with senior scientists than at in-person meetings. While the online format is not meant to replace live scientific conferences, we believe that the IRSS plays a unique role in keeping the islet biology community connected and abreast of the most recent scientific discoveries in our field. The success of this platform stands as a testament to the scientific community to adapt and thrive through challenges. This article is dedicated to Peter C. Butler, UCLA, who initiated the IRSS.

Pancreatic islet cells differentiate from a common progenitor pool through tightly regulated transcriptional and epigenetic programs. ISL1, a LIM homeodomain transcription factor, is essential for islet development, but its molecular functions remain poorly defined. Here, we demonstrate that ISL1 is critical for maintaining endocrine cell identity and enabling terminal differentiation, particularly of α- and β-cells. Using conditional Isl1 deletion in endocrine precursors, combined with single-cell RNA sequencing and chromatin profiling (H3K27ac and H3K27me3), we reveal disruption of the transcriptional and epigenetic landscape in Isl1-deficient islets. Loss of Isl1 results in the failure to establish α-cell identity, loss of δ- and γ-cell lineages, and the persistence of immature β-cells with impaired functional profiles in Isl1CKO mice. Longitudinal single-cell analysis shows that Isl1CKO endocrine cells exhibit sustained progenitor-like states and defective β-cell maturation. These defects are accompanied by activation of stress and diabetes-associated transcriptional programs, along with sex-specific responses that may influence disease onset and progression. Mechanistically, ISL1 represses intermediate progenitor programs and facilitates chromatin remodeling necessary for endocrine lineage commitment and terminal maturation. Our findings highlight a previously underappreciated role for ISL1 in preserving endocrine cell fate and function and offer insight into how its dysregulation may contribute to diabetes.

Skeletal muscle glucose transporter 4 (GLUT4) translocation to the plasma membrane determines glucose uptake in response to insulin and exercise and is disrupted in insulin resistance, making its experimental measurement critical. Confocal light microscopy is widely used for this purpose because of its ability to provide quantitative, high-resolution spatial information from small tissue amounts. However, conventional immunofluorescence colocalization microscopy lacks sensitivity and specificity in the detection of GLUT4 translocation. We validated the use of exofacial epitope-specific GLUT4 antibodies to quantify sarcolemmal GLUT4 translocation in fixed, nonpermeabilized adult human and rodent muscle fibers. Across human, mouse, and rat muscles, these antibodies sensitively detected stimulus-induced GLUT4 translocation, and labeling was abolished in muscle-specific GLUT4-knockout muscle, confirming specificity. Importantly, this study includes the first unambiguous visualization of endogenous GLUT4 translocation in intact human skeletal muscle fibers after insulin stimulation and exercise. In TBC1D4-knockout rats, insulin-stimulated GLUT4 translocation was absent despite wild-type-level GLUT4 expression, confirming an essential role for TBC1D4 in this process. Thus, exofacial GLUT4 antibodies provide a straightforward, sensitive, and specific approach to quantify endogenous GLUT4 translocation in fixed adult skeletal muscle.

Enteroviruses (EVs) have long been implicated in the development of islet autoimmunity (IA) and type 1 diabetes. However, given the ubiquity of EV infections in children, disease susceptibility is likely driven by host-specific immune responses rather than viral exposure alone. To investigate the host antibody response to EVs, we used virome-wide serological profiling (VirScan) to compare the EV antigen landscapes in IA-positive case children versus IA-negative control children across two independent pediatric cohorts separated by 12 years, using samples collected at the time point of seroconversion. We identified a reproducible and distinct EV-specific antibody signature in IA-positive case samples, with an enriched immunogenic hotspot localized within a highly conserved region in the 3D RNA-dependent RNA polymerase. Additionally, IA-positive male children exhibited significantly heightened antibody responses against a motif in the VP1 capsid protein compared with IA-negative male children (risk ratio 1.24; 95% CI 1.02, 1.52; P = 0.03). Our findings provide paradigm-shifting evidence that differential antiviral humoral responses, rather than the specific types of EV infection, play a central role in IA development, highlighting the need for an updated framework to study host-virus interactions in autoimmune pathogenesis.

Glucagon-like peptide 1 (GLP-1) receptor agonists improve dyslipidemia and reduce cardiovascular risk in type 2 diabetes (T2D), but the role of endogenous GLP-1 in lipid metabolism remains unclear. We evaluated the effect of dipeptidyl peptidase 4 (DPP-4) inhibition on the response of plasma triglycerides (TGs) to intraduodenal lipid and a mixed meal, and the impact of GLP-1 receptor blockade with exendin(9-39) in T2D. Fifteen participants with T2D, managed by diet and/or metformin, were studied on three occasions in a double-blind, randomized, crossover design. Vildagliptin (50 mg) or placebo was administered orally (t = -60 min), followed by intravenous exendin(9-39) from t = -60 to 150 min on one of the two vildagliptin days or 0.9% saline on two other days. A lipid emulsion was infused intraduodenally (2 kcal/min, t = 0-120 min), followed by a mixed meal (t = 120-150 min). Plasma TG levels, quantified by liquid chromatography-tandem mass spectrometry, increased after lipid and meal, with most individual TGs corresponding to those in the lipid emulsion. Vildagliptin reduced TG(54:4) and TG(54:5) concentrations (each P < 0.01), without affecting total TGs. Blocking endogenous GLP-1 during vildagliptin treatment increased plasma total TGs (P < 0.001), associated with elevations of 10 individual TG species (P < 0.05 each). These outcomes suggest that endogenous GLP-1 contributes to the physiological modulation of postprandial TG appearance in T2D.

There is significant interest in antigen-specific approaches to delaying type 1 diabetes in preclinical stages and supporting tolerance after diagnosis. We conducted a phase I trial of a nonintegrating DNA plasmid constructed to secrete the type 1 diabetes antigen preproinsulin (PPI) and the immune modulatory cytokines transforming growth factor-β1 (TGF-β1), interleukin-10 (IL-10), and IL-2. In this placebo-controlled, double-masked study of 47 adults with stage 3 type 1 diabetes, we showed that the drug is safe and well tolerated, with most reported adverse events (AEs) categorized as grade 1 and with no clinically significant difference in AEs among treatment groups. There were no untoward metabolic or immune effects. We found pharmacodynamic evidence of treatment, as demonstrated by a dose-dependent type 1 interferon (IFN) signature. Plasmid DNA, representing a pharmocokinetic measure, was detected in the two highest dosing groups. We did not find global or antigen-specific immune cell changes following treatment with a DNA plasmid expressing PPI, IL-2, IL-10, and TGF-β1, and we did not detect immune changes driven by IL-2, IL-10, or TGF-β1. Our results support further trials of this novel tolerizing antigen construct.