Gerald I Shulman’s research while affiliated with Howard Hughes Medical Institute and other places

What is this page?


This page lists works of an author who doesn't have a ResearchGate profile or hasn't added the works to their profile yet. It is automatically generated from public (personal) data to further our legitimate goal of comprehensive and accurate scientific recordkeeping. If you are this author and want this page removed, please let us know.

Publications (818)


Renal Angptl4 is a key fibrogenic molecule in progressive diabetic kidney disease
  • Article
  • Full-text available

December 2024

·

5 Reads

Science Advances

·

Han Zhou

·

Rachel Shenoi

·

[...]

·

Angiopoietin-like 4 (ANGPTL4), a key protein involved in lipoprotein metabolism, has diverse effects. There is an association between Angptl4 and diabetic kidney disease; however, this association has not been well investigated. We show that both podocyte-and tubule-specific ANGPTL4 are crucial fibrogenic molecules in diabetes. Diabetes accelerates the fibrogenic phenotype in control mice but not in ANGPTL4 mutant mice. The protective effect observed in ANGPTL4 mutant mice is correlated with a reduction in stimulator of interferon genes pathway activation, expression of pro-inflammatory cytokines, reduced epithelial-to-mesenchymal transition and endothelial-to-mesenchymal transition, lessened mitochondrial damage, and increased fatty acid oxidation. Mechanistically, we demonstrate that podocyte-or tubule-secreted Angptl4 interacts with Integrin β1 and influences the association between dipeptidyl-4 with Integrin β1. We demonstrate the utility of a targeted pharmacologic therapy that specifically inhibits Angptl4 gene expression in the kidneys and protects diabetic kidneys from proteinuria and fibrosis. Together, these data demonstrate that podocyte-and tubule-derived Angptl4 is fibrogenic in diabetic kidneys.

Download

Figure 2. Hepatic insulin resistance per se suppresses DNL (A) % DNL in the livers of wild-type (WT, left) or Insr T1150A mice (right) fed a high-fat diet (HFD) for 2 days (2d), 9 days (9d), or 4 weeks (4w). DNL was assessed by the deuterated water method. n = 7-13 mice per treatment group. (B and C) Hepatic glycogen content (B) and hepatic glucose 6-phosphate concentration (C) in the livers of fasted-refed WT (left) or Insr T1150A mice (right) treated as in (A). n = 5-7 mice per treatment group. Data are represented as mean G SEM. Statistical comparisons by one-way ANOVA with Tukey correction for multiple comparisons. Each dot represents a biological replicate. See also Table S1.
Figure 3. Substrate drives DNL irrespective of insulin resistance (A-B) Plasma glucose (A) and insulin (B) achieved during a hyperinsulinemic-hyperglycemic clamp in 2-day (d) high-fat diet (HFD)-fed wild-type mice, 4-week (w) HFD-fed wild-type mice, and 4w HFD-fed Insr T1150A mice. n = 15-21 mice per group. (C) Lipogenic hepatic triglyceride content produced versus average glucose achieved during a hyperinsulinemic-euglycemic clamp. Data analyzed by linear curve fit (least squares fit). n = 11-13 mice per group. (D) Lipogenic hepatic triglyceride synthesized in mice achieving an average glucose of $150-200 mg/dL; see box outlined in (C). n = 11-13 mice per group. (E and F) Hepatic acetyl-CoA content (E) and malonyl-CoA content (F) in mice treated as in (A and B). n = 6-13 mice per group. (G and H) Hepatic ChREBP (G) and SREBP1 (mature and precursor) (H) protein expression in mice treated as in (A and B). Quantification is shown to the right of the blot. Actin was used as a loading control. n = 8 mice per group. (I) Hepatic triglyceride content in mice treated as in (A and B). n = 16-21 mice per group. Data are represented as mean G SEM. n = 8-20 mice per group. Statistical comparisons by one-way ANOVA with Tukey correction for multiple comparisons. All western blots are representative of samples from the same experiment processed in parallel. Each dot represents a biological replicate. See also Figure S2.
Figure 4. Molecular regulation of lipogenesis is attenuated by insulin resistance (A) Western blot analysis of ChREBP, SREBP1 (precursor and mature), and FASN in the livers of 2-day high-fat diet (HFD)-fed (2d), 9-day HFD-fed (9d), and 4-week HFD-fed (4w) WT mice fasted overnight (À) or subjected to a modified ITT (+). Actin was used as a loading control. Quantification of blots shown in (B-F). n = 6 mice per group. Data are represented as mean G SEM. Statistical comparisons by two-way ANOVA with Tukey correction for multiple comparisons. All western blots are representative of samples from the same experiment processed in parallel; internal controls were used for normalization of data when combining quantification from different blots. Each dot represents a biological replicate. See also Table S1 and Figures S3 and S4.
High fat diet induced hepatic insulin resistance per se attenuates murine de novo lipogenesis

October 2024

·

12 Reads

iScience

Hepatic insulin resistance (IR) is often said to be “pathway-selective” with preserved insulin stimulation of de novo lipogenesis (DNL) despite attenuated insulin signaling toward glucose metabolism. However, DNL has not been assessed in models of liver-specific IR. We studied mice with differential tissue-specific lipid-induced IR achieved by different durations of high-fat diet (HFD) feeding. Mice with isolated hepatic IR demonstrated markedly reduced DNL, with a rebound seen in mice with whole-body IR. InsrT1150A mice (protected against diacylglycerol-PKCε-induced hepatic IR) maintained normal DNL with HFD feeding. During hyperinsulinemic clamps, hepatic IR reduced DNL, but hyperglycemia augmented DNL in both resistant and sensitive animals. Regulation through SREBP1c did not consistently correlate with changes in DNL. These results demonstrate that hepatic IR is not pathway-selective, highlighting the primacy of lipogenic substrate in stimulation of DNL. Future therapeutics to reduce lipogenesis should target substrate drivers of DNL rather than targeting plasma insulin levels.



Effect of Weight Loss on Skeletal Muscle Bioactive Lipids in People With Obesity and Type 2 Diabetes

September 2024

·

17 Reads

Diabetes

Muscle sn-1,2-diacylglycerol (DAG) and C18:0 ceramide accumulation in sarcolemmal and mitochondrial compartments have been proposed to regulate muscle insulin sensitivity. Here, we evaluated whether weight loss-induced improvements in insulin sensitivity were associated with changes in muscle sn-1,2-DAG and ceramide content in people with obesity and type 2 diabetes. We measured skeletal muscle insulin sensitivity, assessed by using the hyperinsulinemic-euglycemic clamp procedure in conjunction with stable isotopically labeled glucose tracer infusion, and skeletal muscle sn-1,2-DAG and ceramide contents by using liquid chromatography–tandem mass spectrometry after subcellular fractionation and DAG isomer separation in 14 adults with obesity and type 2 diabetes before and after marked (18.6 ± 2.1%) weight loss. Whole-body insulin sensitivity doubled after weight loss. Sarcolemmal sn-1,2-DAG and C18:0 ceramide contents after weight loss were not different from values before weight loss. In contrast, mitochondrial-endoplasmic reticulum (ER) C18:0 ceramide content decreased by ∼20% after weight loss (from 2.16 ± 0.08 to 1.71 ± 0.13 nmol/g, P < 0.005). These results suggest a decrease in muscle mitochondrial-ER C18:0 ceramide content could contribute to the beneficial effect of weight loss on skeletal muscle insulin sensitivity. Article Highlights



Role of AMPK in Atrial Metabolic Homeostasis and Substrate Preference

August 2024

·

50 Reads

Atrial fibrillation is the most common clinical arrhythmia and may be due in part to metabolic stress. Atrial specific deletion of the master metabolic sensor, AMP-activated protein kinase (AMPK), induces atrial remodeling culminating in atrial fibrillation in mice, implicating AMPK signaling in the maintenance of atrial electrical and structural homeostasis. However, atrial substrate preference for mitochondrial oxidation and the role of AMPK in regulating atrial metabolism are unknown. Here, using LC-MS/MS methodology combined with infusions of [ ¹³ C 6 ]glucose and [ ¹³ C 4 ]Ω-hydroxybutyrate in conscious mice, we demonstrate that conditional deletion of atrial AMPK catalytic subunits shifts mitochondrial atrial metabolism away from fatty acid oxidation and towards pyruvate oxidation. LC-MS/MS-based quantification of acyl-CoAs demonstrated decreased atrial tissue content of long-chain fatty acyl-CoAs. Proteomic analysis revealed a broad downregulation of proteins responsible for fatty acid uptake (LPL, CD36, FABP3), acylation and oxidation. Atrial AMPK deletion reduced expression of atrial PGC1-α and downstream PGC1-α/PPARα/RXR regulated gene transcripts. In contrast, atrial [ ¹⁴ C]2-deoxyglucose uptake and GLUT1 expression increased with fasting in mice with AMPK deletion, while the expression of glycolytic enzymes exhibited heterogenous changes. Thus, these results highlight the crucial homeostatic role of AMPK in the atrium, with loss of atrial AMPK leading to downregulation of the PGC1-α/PPARα pathway and broad metabolic reprogramming with a loss of fatty acid oxidation, which may contribute to atrial remodeling and arrhythmia.


Schematic representation of the variety of tests and procedures available at MMPCLive Centers to study the heterogeneity of diabetes and obesity in mice
The mouse metabolic phenotyping center (MMPC) live consortium: an NIH resource for in vivo characterization of mouse models of diabetes and obesity

Mammalian Genome

The Mouse Metabolic Phenotyping Center (MMPC)Live Program was established in 2023 by the National Institute for Diabetes, Digestive and Kidney Diseases (NIDDK) at the National Institutes of Health (NIH) to advance biomedical research by providing the scientific community with standardized, high quality phenotyping services for mouse models of diabetes and obesity. Emerging as the next iteration of the MMPC Program which served the biomedical research community for 20 years (2001–2021), MMPCLive is designed as an outwardly-facing consortium of service cores that collaborate to provide reduced-cost consultation and metabolic, physiologic, and behavioral phenotyping tests on live mice for U.S. biomedical researchers. Four MMPCLive Centers located at universities around the country perform complex and often unique procedures in vivo on a fee for service basis, typically on mice shipped from the client or directly from a repository or vendor. Current areas of expertise include energy balance and body composition, insulin action and secretion, whole body carbohydrate and lipid metabolism, cardiovascular and renal function, food intake and behavior, microbiome and xenometabolism, and metabolic pathway kinetics. Additionally, an opportunity arose to reduce barriers to access and expand the diversity of the biomedical research workforce by establishing the VIBRANT Program. Directed at researchers historically underrepresented in the biomedical sciences, VIBRANT-eligible investigators have access to testing services, travel and career development awards, expert advice and experimental design consultation, and short internships to learn test technologies. Data derived from experiments run by the Centers belongs to the researchers submitting mice for testing which can be made publicly available and accessible from the MMPCLive database following publication. In addition to services, MMPCLive staff provide expertise and advice to researchers, develop and refine test protocols, engage in outreach activities, publish scientific and technical papers, and conduct educational workshops and training sessions to aid researchers in unraveling the heterogeneity of diabetes and obesity.


Small molecule inhibition of glycogen synthase I reduces muscle glycogen content and improves biomarkers in a mouse model of Pompe disease

August 2024

·

14 Reads

·

1 Citation

AJP Endocrinology and Metabolism

Pompe disease is a rare genetic disorder caused by a deficiency of the enzyme acid alpha-glucosidase (GAA). This enzyme is responsible for breaking down glycogen, leading to the abnormal accumulation of glycogen, which results in progressive muscle weakness and metabolic dysregulation. In this study, we investigated the hypothesis that the small molecule inhibition of glycogen synthase I (GYS1) may reduce muscle glycogen content and improve metabolic dysregulation in a mouse model of Pompe disease. To address this hypothesis, we studied four groups of male mice: a control group of wild-type B6129SF1/J mice fed either regular chow (WT) or a GYS1 inhibitor (MZ-101) diet (WT-GYS1), and Pompe model mice B6;129-Gaatm1Rabn/J fed either regular chow (GAA-KO) or MZ-101 diet (GAA-GYS1) for 7 days. Our findings revealed that GAA-KO mice exhibited abnormal glycogen accumulation in the gastrocnemius, heart, and diaphragm. In contrast, inhibiting GYS1 reduced glycogen levels in all tissues compared to GAA-KO mice. Furthermore, GAA-KO mice displayed reduced spontaneous activity during the dark cycle compared to WT mice, while GYS1 inhibition counteracted this effect. Compared to GAA-KO mice, GAA-GYS1 mice exhibited improved glucose tolerance and whole-body insulin sensitivity. These improvements in insulin sensitivity could be attributed to increased AMPK phosphorylation in the gastrocnemius of WT-GYS1 and GAA-GYS1 mice. Additionally, the GYS1 inhibitor led to a reduction in the phosphorylation of GS S641 and the LC3 autophagy marker. Together, our results suggest that targeting GYS1 could serve as a potential strategy for treating glycogen storage disorders and metabolic dysregulation.




Citations (54)


... Emerging data indicate that glucagon is moreover involved in lipid metabolism since glucagon receptor antagonists were found to increase liver fat accumulation and LDL levels in early-phase clinical trials [12,13]. Glucagon was shown to increment hepatic lipolysis and hepatic ß-oxidation in mice, rats and humans via stimulation of the inositol trisphosphate receptor (INSP3R), thereby reversing hepatic steatosis in rodent models [14,15]. The question of whether and how lipids conversely regulate the secretion of glucagon is still debated. ...

Reference:

Alterations in Glucagon Levels and the Glucagon-to-Insulin Ratio in Response to High Dietary Fat or Protein Intake in Healthy Lean Adult Twins: A Post Hoc Analysis
Glucagon promotes increased hepatic mitochondrial oxidation and pyruvate carboxylase flux in humans with fatty liver disease
  • Citing Article
  • August 2024

Cell Metabolism

... A recent investigation by Hu et al. [46] showed that MCU-mediated uptake of ferrous iron (Fe 2+ ) into mitochondria during acetaminopheninduced hepatotoxicity triggered mitochondrial depolarization and cell death. Notably, a more recent study by LaMoia et al. [47] revealed that liver-specific deletion of MCU increased mitochondrial oxidation and reduced hepatic lipid accumulation. Surprisingly, in contrast to the findings by Tomar et al. [48] deletion of MCU gene in mouse liver inhibited MCU-mediated Ca 2+ uptake but aggravated hepatic lipid deposition. ...

Cytosolic calcium regulates hepatic mitochondrial oxidation, intrahepatic lipolysis, and gluconeogenesis via CAMKII activation
  • Citing Article
  • August 2024

Cell Metabolism

... Although the underlying biological mechanism remains unclear, insulin resistance, oxidation, and inflammation pathways could potentially explain the observed associations [42][43][44][45]. For example, both obesity and metabolic abnormality can increase the expression of proinflammatory cytokines [43,44], which contribute to neurodegeneration and neurotoxicity, leading to the onset of dementia [46][47][48]. ...

Cardiometabolic characteristics of people with metabolically healthy and unhealthy obesity

Cell Metabolism

... Due to its broad biologic involvement and distinct roles of the N-and C-terminal fragments (at least in humans), the function of Angptl4 in different disease contexts is ambiguous. Pro-fibrotic effects of Angptl4 have been reported in lung [82] and kidney fibrosis [91], while in liver fibrosis Angptl4 acted in a protective manner [96,109]. In atherosclerosis, loss of function mutation of ANGPTL4 in humans was associated with an increased risk [24]. ...

Renal Angptl4 is a key fibrogenic molecule in progressive diabetic kidney disease

... Genetic variants, particularly single nucleotide polymorphisms (SNP), influence various processes related to NAFLD development and progression, such as FFAs flow into the liver, oxidative stress, response to endotoxins, and cytokine production [34]. The SNP of the patatin-like phospholipase domaincontaining protein 3 (PNPLA3) gene's I148M variant is implicated in NAFLD [35], showing associations with reduced de novo lipogenesis, increased expression of SREBP-1c, and higher risks of steatosis and liver fibrosis [36]. Another variant, rs58542926, in the transmembrane 6 superfamily member 2 (TM6SF2) gene, is linked to lower plasma VLDL levels, hepatic steatosis, and higher ALT levels [35,37]. ...

The PNPLA3 I148M variant increases ketogenesis and decreases hepatic de novo lipogenesis and mitochondrial function in humans
  • Citing Article
  • October 2023

Cell Metabolism

... 18 Another study reported that loss of Cyr61 alleviates MASH in mice induced by low-dose carbon tetrachloride injections along with a western diet. 19 However, the effects of Cyr61 expression on hepatic insulin resistance and lipid metabolism in MASLD remain unknown. ...

Hepatocyte CYR61 polarizes profibrotic macrophages to orchestrate NASH fibrosis
  • Citing Article
  • September 2023

Science Translational Medicine

... In the IR interactome analysis, we identified the Rab11FIP1 protein, which is implicated in intracellular vesicle trafficking and RTK recycling 17,33 making it interesting for further validation. It is also reasonable to speculate that the observed increased basal ERK signaling may link to elevated IR endocytosis, reducing surface IR expression and facilitating the development of insulin resistance [46][47][48][49] . Compared to previous interactome studies primarily using IR overexpression cell models, we identified 45 dynamic IR interactors, which is deemed a modest number of IR interactors, however likely a natural consequence of studying an endogenous expression system 18,[20][21][22] . ...

MAD2-Dependent Insulin Receptor Endocytosis Regulates Metabolic Homeostasis
  • Citing Article
  • September 2023

Diabetes

... Besides, there are various reports on the effect of O-GlcNAcylation on body weight. For instance, the enhancement of O-GlcNAcylation in adipose tissue promotes diet-induced obesity [17], in contrast, the high-fat diet fed adipose tissue-specific Ogt knockout mice suppressed body weight gain due to inhibition of the healthy expansion of adipose tissue [18]. Neuronal O-GlcNAc transferase activation was shown to regulate appetite [19]. ...

O-GlcNAc modification is essential for physiological adipose expansion induced by high-fat feeding
  • Citing Article
  • May 2023

AJP Endocrinology and Metabolism

... To better understand the direct role of HSD17β13 in liver disease and fibrosis, several groups have generated HSD17β13 knockout (KO) or knockdown models to mimic the consequence of human loss of function mutations. However, these studies have produced widely conflicting results including 1) HSD17β13 KO has no impact on liver injury, fibrosis, or HCC development in western or high-fat diets (14), 2) a 60% knockdown of hepatic HSD17β13 protein results in lower liver fibrosis, but not steatosis, after 14 weeks of a choline-deficient high-fat diet (15), 3) Hsd17b13 deletion leads to increases liver steatosis and inflammation but exhibits no differences in fibrosis on a chow diet (16), or 4) ASO knockdown of Hsd17b13 reduces liver steatosis, but not fibrosis, on a 60% CDAHFD diet (17). In light of these inconsistent findings, and in the pursuit of preclinical models to test potential HSD17B13 therapeutics, we developed a new strain of Hsd17b13-null mice to investigate responses to several different dietary models of NASH. ...

Inhibition of HSD17B13 protects against liver fibrosis by inhibition of pyrimidine catabolism in nonalcoholic steatohepatitis

Proceedings of the National Academy of Sciences

... To evaluate the relative enzyme activity in the TCA cycle at different timepoints during perfusion, we conducted Q-Flux analysis ( 13 C 5 -glutamine-based method) using equations from a recent publication that validated this approach 34 . Previously we demonstrated that after 2 h of ex vivo incubation with 13 C 5 -glutamine a pseudo-steady state is reached, allowing Q-flux analysis 24 . ...

Q-Flux: A method to assess hepatic mitochondrial succinate dehydrogenase, methylmalonyl-CoA mutase, and glutaminase fluxes in vivo
  • Citing Article
  • December 2022

Cell Metabolism