Embedded in the developmental origins of health and disease (DOHaD) hypothesis, maternal hyperglycemia in utero, from preexisting diabetes or gestational diabetes mellitus, predisposes the offspring to excess adiposity and heightened risk of prediabetes and type 2 diabetes development. This transmission creates a vicious cycle increasing the presence of diabetes from one generation to another, leading to the question: How can we interrupt this vicious cycle? In this article, we present the current state of knowledge on the intergenerational transmission of diabetes from epidemiological life course studies. Then, we discuss the potential mechanisms implicated in the intergenerational transmission of diabetes with a focus on epigenetics. We present novel findings stemming from epigenome-wide association studies of offspring DNA methylation in blood and placental tissues, which shed light on potential molecular mechanisms implicated in the mother-offspring transmission of diabetes. Lastly, with a perspective on how to break the cycle, we consider interventions to prevent offspring obesity and diabetes development before puberty, as a critical period of the intergenerational cycle. This article is part of a series of perspectives that report on research funded by the American Diabetes Association Pathway to Stop Diabetes program.

Identifying patterns of metabolic heterogeneity in type 2 diabetes (T2D) can help in the development of optimal treatment strategies. We aimed to identify metabolic patterns in patients with T2D in the Republic of Korea and analyze the risk of developing diabetes-related complications according to patterns. We identified three distinct metabolic patterns and observed that each pattern was associated with a heightened risk of developing various cardiovascular diseases. These findings highlight the necessity of devising treatment strategies based on these patterns to prevent diabetes-related complications.

Cytochrome c oxidase subunit 6A2 (COX6A2) expression is increased in diabetic islets. Increased COX6A2 promotes β-cell apoptosis via modulation of cyclophilin D-mediated cytochrome c release from mitochondria to the cytoplasm. Carbohydrate-responsive element-binding protein epigenetically regulates COX6A2 expression in β-cells. Roux-en-Y gastric bypass reduces COX6A2 expression by regulating the glucagon-like peptide 1/cAMP-dependent protein kinase/carbohydrate-responsive element-binding protein signaling pathway.

MG53 is predominantly expressed in striated muscles. The role of MG53 in diabetes has gradually been elucidated but is still full of controversy. Some reports have indicated that MG53 is upregulated in animal models with metabolic disorders and that muscle-specific MG53 upregulation is sufficient to induce whole-body insulin resistance and metabolic syndrome through targeting both the insulin receptor (IR) and insulin receptor substrate 1 (IRS-1) for ubiquitin-dependent degradation. Additionally, MG53 has been identified as a myokine/cardiokine that is secreted from striated muscles into the bloodstream, and circulating MG53 has further been shown to trigger insulin resistance by binding to the extracellular domain of the IR, thereby allosterically inhibiting insulin signaling. Conversely, findings have been reported from other studies that contradict these results. Specifically, no significant change in MG53 expression in striated muscles or serum has been observed in diabetic models, and the MG53-mediated degradation of IRS-1 may be insufficient to induce insulin resistance due to the compensatory roles of other IRS subtypes. Furthermore, sustained elevation of MG53 levels in serum or systemic administration of recombinant human MG53 (rhMG53) has shown no impact on metabolic function. In this article, we will fully characterize these two disparate views, strive to provide critical insights into their contrasts, and propose several specific experimental approaches that may yield additional evidence. Our goal is to encourage the scientific community to elucidate the effects of MG53 on metabolic diseases and the molecular mechanisms involved, thereby providing the theoretical basis for the treatment of metabolic diseases and the applications of rhMG53.

There is variability in early-onset autoimmune diabetes presentation in individuals with monogenic autoimmunity; the mechanism(s) underlying this is unclear. We examined whether type 1 diabetes (T1D) polygenic risk contributes to clinical phenotype in monogenic autoimmune diabetes. Individuals with monogenic autoimmune diabetes had higher T1D genetic risk scores compared with control cohorts, driven largely by increased presence of T1D-risk DR3-DQ2 haplotype. Established T1D polygenic risk alleles, particularly class II HLA genes, contribute to clinical presentation in monogenic autoimmunity.

Shared medical appointments (SMAs) for diabetes and group prenatal care (GPC) for pregnant patients have emerged as innovative care delivery models. They have the potential to transform diabetes care by overcoming many of the time limitations of traditional one-on-one clinical visits. There is compelling evidence that SMAs improve glycemic control for nonpregnant patients with diabetes, GPC reduces Black and White health disparities in preterm birth, and diabetes GPC increases postpartum glucose tolerance test uptake among patients with gestational diabetes mellitus. GPC models stand out as one of few interventions that reduce racial health disparities, which we hypothesize occurs because their effect is inadvertently exerted on both the patient and clinician through an over 20-h meaningful shared experience. In this article I explore the evidence for SMAs and GPC in diabetes and pregnancy, theoretical underpinnings of the models, their potential to promote more equitable care, and future directions from my perspective as a physician in high-risk obstetrics and 2019 American Diabetes Association Pathway Accelerator Award recipient. This article is part of a series of perspectives that report on research funded by the American Diabetes Association Pathway to Stop Diabetes program.

Small glycemic increments (≤0.5 mmol/L) can exert suppressive actions on endogenous glucose production (EGP); however, it is unclear if this is an insulin-dependent or -independent process. Here, we performed a low-rate glucose infusion in control participants without diabetes and in people with type 1 diabetes (T1D) to better understand this phenomenon. Glucose kinetics, hormones, and metabolites were measured during a 1 mg/kg/min glucose infusion (90 min), which rapidly increased glucose by ∼0.3 mmol/L in control participants. Insulin concentrations and secretion quickly increased by ∼20%, resulting in a ∼40% suppression of EGP, while glucose disposal remained unchanged. Free fatty acids (FFAs) and glucagon were gradually suppressed to ∼30% below baseline at 60 min. When repeated under constant basal insulin concentrations in participants with T1D, glucose infusion caused only partial and transient EGP suppression; hence, glucose increased in a near-linear manner, reaching levels ∼2 mmol/L above baseline at 90 min. FFAs and glucagon remained unchanged, while glucose disposal modestly increased. This demonstrates that small glycemic increments exert subtle stimulatory effects on insulin secretion that have potent metabolic actions on the liver and adipose tissue. It is conceivable that subtle increases in glucose could potentially serve as a signal for β-cell adaptation.

Smoking is widely regarded as a risk factor for type 2 diabetes because nicotine contributes to insulin resistance by desensitizing the insulin receptors in muscle, liver, or fat. Little is known, however, about the immediate regulation of islet hormonal output by nicotine, an agonist of ionotropic cholinergic receptors. We investigated this by imaging cytosolic Ca2+ dynamics in mouse and human islets using confocal microscopy and measuring glucagon secretion in response to the alkaloid from isolated mouse islets. Nicotine acutely stimulated cytosolic Ca2+ in glucagon-secreting α-cells but not in insulin-secreting β-cells. The 2.8- ± 0.5-fold (P < 0.05) increase in Ca2+, observed in >70% of α-cells, correlated well with a 2.5- ± 0.3-fold stimulation of glucagon secretion. Nicotine-induced elevation of cytosolic Ca2+ relied on influx from the extracellular compartment rather than release of the cation from intracellular depots. Metabotropic cholinergic signaling, monitored at the level of intracellular diacylglycerol, was limited to 69% of α-cells versus 94% of β-cells. We conclude that parasympathetic regulation of pancreatic islet hormone release uses different signaling pathways in β-cells (metabotropic) and α-cells (metabotropic and ionotropic), resulting in the fine-tuning of acetylcholine-induced glucagon exocytosis. Sustained nicotinic stimulation is, therefore, likely to attenuate insulin sensitivity by increasing glucagon release.

Diabetic keratopathy (DK) is a common chronic metabolic disorder that causes ocular surface complications. Among various therapeutic approaches, local delivery of nerve growth factor (NGF) remains the most effective treatment of DK. However, achieving a sustained therapeutic effect with NGF and the frequent drug delivery burden remain challenging during clinical practice. Here, we developed a novel adeno-associated virus (AAV)-based NGF delivery system that achieved 1-year-long-lasting effects by a single injection. We refined the corneal stromal injection technique, resulting in reduced corneal edema and improved AAV distribution homogeneity. AAV serotype AAV.rh10 exhibited high tropism and specificity to corneal nerves. A dose of 2 × 109 vector genomes was determined to achieve efficient Ngf gene expression without inducing corneal immune responses. Moreover, NGF protein was highly expressed in trigeminal ganglion through a retrograde transport mechanism, indicating the capacity for repairing corneal nerve damage at both the root and corneal nerve endings. In a mouse DK model, a single injection of AAV-Ngf into the corneal stroma led to marked corneal nerve regeneration for over 5 months. Together, we provide a novel therapeutic paradigm for long-term effective treatment of DK, and this therapeutic approach is superior to current DK therapies.

Type 1 diabetes treatment stands at a crucial and exciting crossroad since the 2022 U.S. Food and Drug Administration approval of teplizumab to delay disease development. In this article, we discuss four major conceptual and practical issues that emerged as key to further advancement in type 1 diabetes research and therapies. First, collaborative networks leveraging the synergy between the type 1 diabetes research and care community members are key to fostering innovation, know-how, and translation into the clinical arena worldwide. Second, recent clinical trials in presymptomatic stage 2 and recent-onset stage 3 disease have shown the promise, and potential pitfalls, of using immunomodulatory and/or β-cell protective agents to achieve sustained remission or prevention. Third, the increasingly appreciated heterogeneity of clinical, immunological, and metabolic phenotypes and disease trajectories is of critical importance to advance the decision-making process for tailored type 1 diabetes care and therapy. Fourth, the clinical benefits of early diagnosis of β-cell autoimmunity warrant consideration of general population screening for islet autoantibodies, which requires further efforts to address the technical, organizational, and ethical challenges inherent to a sustainable program. Efforts are underway to integrate these four concepts into the future directions of type 1 diabetes research and therapy.

Diabetes can lead to cell type-specific responses in the retina, including vascular lesions, glial dysfunction, and neurodegeneration, all of which contribute to retinopathy. However, the molecular mechanisms underlying these cell type-specific responses, and the cell types that are sensitive to diabetes have not been fully elucidated. Using single-cell transcriptomics, we profiled the transcriptional changes induced by diabetes in different retinal cell types in rat models as the disease progressed. Rod photoreceptors, a subtype of amacrine interneurons, and Müller glial cells (MGs) exhibited rapid responses to diabetes at the transcript levels. Genes associated with ion regulation were upregulated in all three cell types, suggesting a common response to diabetes. Furthermore, focused studies revealed that although MG initially increased the expression of genes playing protective roles, they cannot sustain this beneficial effect. We explored one of the candidate protective genes, Zinc finger protein 36 homolog (Zfp36), and observed that depleting Zfp36 in rat MGs in vivo using adeno-associated virus-based tools exacerbated diabetes-induced phenotypes, including glial reactivation, neurodegeneration, and vascular defects. Overexpression of Zfp36 slowed the development of these phenotypes. This work unveiled retinal cell types that are sensitive to diabetes and demonstrated that MGs can mount protective responses through Zfp36.

Diabetic vasculopathy, encompassing complications such as diabetic retinopathy, represents a significant source of morbidity, with inflammation playing a pivotal role in the progression of these complications. This study investigates the influence of N6-methyladenosine demethylase (m6A) modification and the m6A demethylase fat mass and obesity-associated (FTO) protein on macrophage polarization and its subsequent effects on diabetic microvasculopathy. We found that diabetes induces a shift in macrophage polarization toward a proinflammatory M1 phenotype, which is associated with a reduction in m6A modification levels. Notably, FTO emerges as a critical regulator of m6A under diabetic conditions. In vitro experiments reveal that FTO not only modulates macrophage polarization but also mediates their interactions with vascular endothelial cells. In vivo experiments demonstrate that FTO deficiency exacerbates retinal inflammation and microvascular dysfunction in diabetic retinas. Mechanistically, FTO stabilizes mRNA through an m6A-YTHDF2-dependent pathway, thereby activating the PI3K/AKT signaling cascade. Collectively, these findings position FTO as a promising therapeutic target for the management of diabetic vascular complications.

We examined the effect of increased levels of plasma ketones on left ventricular (LV) function, myocardial glucose uptake (MGU), and myocardial blood flow (MBF) in patients with type 2 diabetes (T2DM) with heart failure. Three groups of patients with T2DM (n = 12 per group) with an LV ejection fraction (EF) ≤50% received incremental infusions of β-hydroxybutyrate (β-OH-B) for 3-6 h to increase the plasma β-OH-B concentration throughout the physiologic (groups I and II) and pharmacologic (group III) range. Cardiac MRI was performed at baseline and after each β-OH-B infusion to provide measures of cardiac function. On a separate day, group II also received a sodium bicarbonate (NaHCO3) infusion, thus serving as their own control for time, volume, and pH. Additionally, group II underwent positron emission tomography study with 18F-fluoro-2-deoxyglucose to examine effect of hyperketonemia on MGU. Groups I, II, and III achieved plasma β-OH-B levels (mean ± SEM) of 0.7 ± 0.3, 1.6 ± 0.2, 3.2 ± 0.2 mmol/L, respectively. Cardiac output (CO), LVEF, and stroke volume (SV) increased significantly during β-OH-B infusion in groups II (CO, from 4.54 to 5.30; EF, 39.9 to 43.8; SV, 70.3 to 80.0) and III (CO, from 5.93 to 7.16; EF, 41.1 to 47.5; SV, 89.0 to 108.4), and did not change with NaHCO3 infusion in group II. The increase in LVEF was greatest in group III (P < 0.001 vs. group II). MGU and MBF were not altered by β-OH-B. In patients with T2DM and LVEF ≤50%, increased plasma β-OH-B level significantly increased LV function dose dependently. Because MGU did not change, the myocardial benefit of β-OH-B resulted from providing an additional fuel for the heart without inhibiting MGU.

IER3IP1 mutations are linked to the development of microcephaly, epilepsy, and early-onset diabetes syndrome 1. However, the underlying molecular mechanisms of cell dysfunction are unknown. Using targeted genome editing, we generated specific IER3IP1 mutations in human embryonic stem cell lines that were differentiated into pancreatic islet lineages. Loss of IER3IP1 resulted in a threefold reduction in endoplasmic reticulum-to-Golgi trafficking of proinsulin in stem cell-derived β-cells, leading to β-cell dysfunction both in vitro and in vivo. Loss of IER3IP1 also triggered increased markers of endoplasmic reticulum stress, indicating the pivotal role of the endoplasmic reticulum-to-Golgi trafficking pathway for β-cell homeostasis and function.

Incidences of childhood obesity and type 2 diabetes (T2D) are climbing at alarming rates. Evidence points to prenatal exposures to maternal obesity and gestational diabetes mellitus (GDM) as key contributors to these upward trends. Children born to mothers with these conditions face higher risks of obesity and T2D, beyond genetic or shared environmental factors. The underpinnings of this maternal-fetal programming are complex. However, animal studies have shown that such prenatal exposures can lead to changes in brain pathways, particularly in the hypothalamus, leading to obesity and T2D later in life. This article highlights significant findings stemming from research funded by my American Diabetes Association Pathway Accelerator Award and is part of a series of Perspectives that report on research funded by the American Diabetes Association Pathway to Stop Diabetes program. This critical support, received more than a decade ago, paved the way for groundbreaking discoveries, translating the neural programming findings from animal models into human studies and exploring new avenues in maternal-fetal programming. Our BrainChild cohort includes >225 children, one-half of whom were exposed in utero to maternal GDM and one-half born to mothers without GDM. Detailed studies in this cohort, including neuroimaging and metabolic profiling, reveal that early fetal exposure to maternal GDM is linked to alterations in brain regions, including the hypothalamus. These neural changes correlate with increased energy intake and predict greater increases in BMI, indicating that early neural changes may underlie and predict later obesity and T2D, as observed in animal models. Ongoing longitudinal studies in this cohort will provide critical insights toward breaking the vicious cycle of maternal-child obesity and T2D.

The prevalence of type 2 diabetes (T2D) varies among populations of different races/ethnicities. The influence of genetically proxied LDL cholesterol lowering through proprotein convertase subtilisin/kexin 9 (PCSK9) and HMG-CoA reductase (HMGCR) on T2D in non-European populations is not well established. A drug target Mendelian randomization approach was used to assess the effects of PCSK9 and HMGCR inhibition on T2D risk and glycemic traits in five populations: East Asian (EAS), South Asian (SAS), Hispanic (HISP), African (AFR), and Europe (EUR). Our study did not find relationships between genetically proxied PCSK9 inhibition and T2D risk in the EAS (odds ratio [OR] 1.02; 95% CI 0.95-1.10), SAS (1.05; 0.97-1.14), HISP (1.03; 0.94-1.12), or EUR population (1.04; 0.98-1.11). However, in the AFR population, primary analyses suggested an increased risk of T2D resulting from PCSK9 inhibition (OR 1.53; 95% CI 1.058-2.22; P = 0.024), although this was not supported in sensitivity analyses. Genetically proxied HMGCR inhibition was associated with an increased risk of T2D in SAS (OR 1.44; 95% CI 1.30-1.61; P = 9.8 × 10-12), EAS (1.36; 1.22-1.51; P = 4.2 × 10-10), and EUR populations (1.52; 1.21-1.90; P = 3.3 × 10-4). These results were consistent across various sensitivity analyses, including colocalization, indicating a robust finding. The findings indicate a neutral impact of long-term PCSK9 inhibition on T2D and glycemic markers in most non-EUR populations, with a potential increased risk in AFR cohorts. By contrast, HMGCR inhibition increased the risk of T2D in SAS, EAS, and EUR cohorts, underscoring the need to consider diversity in genetic research on metabolic diseases.