PRMT4 Facilitates White Adipose Tissue Browning and Thermogenesis by Methylating PPARγ

Rethinking fat Browning: Uncovering new molecular insights into the synergistic roles of fasting, exercise, and cold exposure

The global obesity epidemic highlights the need to understand the molecular mechanisms that regulate energy metabolism. Among emerging research areas, fat browning-the transformation of white adipose tissue into beige fat-has gained significant attention. This review explores the molecular pathways involved in fat browning triggered by fasting, physical exercise, and cold exposure, emphasizing both shared and distinct regulatory mechanisms. These stimuli consistently induce physiological responses such as lipolysis, mitochondrial biogenesis, and improved insulin sensitivity. Notably, PGC-1α and SIRT3 are upregulated across all three conditions, underscoring their central roles in mitochondrial function and energy metabolism and identifying them as promising therapeutic targets. In contrast, UCP1 and PRDM16 exhibit condition-specific regulation, suggesting they may not be universally essential for fat browning. In addition, the review discusses species-specific differences in brown adipose tissue (BAT) activation, particularly between rodents and humans, highlighting the challenges of translating animal model findings to human therapies. Future research should aim to develop selective pharmacological activators of PGC-1α and SIRT3 to enhance therapeutic outcomes while minimizing adverse effects. This review also proposes that integrating fasting, exercise, and cold exposure could provide innovative strategies to promote metabolic health.

Photosensitive Biomimetic Nanomedicine-Mediated Recombination of Adipose Microenvironments for Antiobesity Therapy

Obesity-induced insulin resistance is a hallmark of metabolic syndrome, and chronic low-grade inflammation links obesity to insulin resistance through the activation of tissue-infiltrating immune cells. Current treatments are lacking in efficacy and immunosuppression. Therefore, novel therapies are needed to prevent chronic inflammation and alleviate obesity-related insulin resistance. In this work, novel red light-responsive biomimetic nanoparticles (RSCP NPs) are reported to perform targeted delivery of multiple drugs and effectively reduce nonspecific enrichment. These results showed that the dual-targeting and multiple-signaling response (red light signaling and different pH microenvironments) of the RSCP NPs enabled the precise delivery of astaxanthin (Asta) and rosiglitazone (Rosi) to M1-like macrophages and white adipocytes, respectively, to alleviate the low-grade inflammation of white adipose tissue (WAT) and promote white adipocyte browning. Moreover, RSCP NPs-mediated Asta and Rosi treatment robustly alleviated insulin resistance and other metabolic disorders in the obese animal models (high-fat diet (HFD)-induced or genetically obese mice). Overall, this study provides a theoretical and practical basis for the development and application of novel drug delivery systems for metabolic diseases by elucidating the synergistic long-term targeting mechanism and target molecule stability of red light-sensitive bionic nanodrug delivery systems.

TRIM56 Promotes White Adipose Tissue Browning to Attenuate Obesity by Degrading TLE3

In mammals, the activation of thermogenic adipocytes, such as beige and brown adipocytes, can significantly increase overall energy expenditure, offering a promising strategy to combat metabolic diseases. Despite its considerable potential, the regulatory mechanisms governing this activation remain largely elusive. This study bridges this gap by elucidating that tripartite motif 56 (TRIM56), an E3 ubiquitin ligase, is upregulated in response to cold stimuli, thereby promoting the recruitment of beige adipocytes. Notably, the overexpression of TRIM56 in adipocytes is shown to help mice maintain a core temperature under cold conditions, as well as confer protection against diet-induced obesity. Mechanistically, TRIM56 facilitates the degradation of the transducin-like enhancer protein 3 (TLE3) protein by promoting its K48-linked ubiquitination, which subsequently triggers the activation of thermogenic genes in subcutaneousl white adipose tissue and improved the metabolic profiles. These findings unveil a novel function for TRIM56 in adipocyte browning, suggesting its potential as a therapeutic target for the treatment of metabolic disorders.

Metformin inhibits the histone methyltransferase CARM1 and attenuates H3 histone methylation during gluconeogenesis

Hyperglycemia is a hallmark of metabolic disorders, yet the precise mechanisms linking epigenetic regulation to glucose metabolism remain underexplored. Coactivator-associated arginine methyltransferase 1 (CARM1), a type I histone methyltransferase, promotes transcriptional activation through the methylation of histone H3 at arginine residues H3R17 and H3R26. Here, we identify a novel mechanism by which metformin, a widely prescribed antidiabetic drug, inhibits CARM1 activity. Using biochemical and biophysical assays, we show that metformin binds to the substrate-binding site of CARM1, reducing histone H3 methylation levels in CARM1-overexpressing hepatic cells and liver tissues from metformin-fed mice. This epigenetic modulation suppresses the expression of gluconeogenic enzymes (G6Pase, FBPase, and PCK1), thereby reversing CARM1-induced glycolytic suppression and regulating gluconeogenesis. Importantly, metformin does not alter CARM1 protein levels and its recruitment to gluconeogenic gene promoters but diminishes H3R17me2a marks at these loci. Our findings reveal a previously unrecognized epigenetic mechanism of metformin action, offering new therapeutic insights for hyperglycemia management.

PRMT3 and CARM1: Emerging Epigenetic Targets in Cancer

The family of protein arginine methyltransferases (PRMTs) occupies an important position in biology, especially during the initiation and development of cancer. PRMT3 and CARM1(also known as PRMT4), being type I protein arginine methyltransferases, are key in controlling tumour progression by catalysing the mono-methylation and asymmetric di-methylation of both histone and non-histone substrates. This paper reviews the functions and potential therapeutic target value of PRMT3 and CARM1 in a variety of cancers. Studies have identified abnormal expressions of PRMT3 and CARM1 in several malignancies, closely linked to cancer progression, advancement, and resistance to treatment. Such as hepatocellular carcinoma, colorectal cancer, ovarian cancer, and endometrial cancer. These findings offer new strategies and directions for cancer treatment, especially in enhancing the effectiveness of conventional treatment methods.

Identification of Novel Organo-Se BTSA-Based Derivatives as Potent, Reversible, and Selective PPARγ Covalent Modulators for Antidiabetic Drug Discovery

Recent studies have identified selective peroxisome proliferator-activated receptor γ (PPARγ) modulators, which synergistically engage in the inhibition mechanism of PPARγ-Ser273 phosphorylation, as a promising approach for developing safer and more effective antidiabetic drugs. Herein, we present the design, synthesis, and evaluation of a new class of organo-Se compounds, namely, benzothiaselenazole-1-oxides (BTSAs), acting as potent, reversible, and selective PPARγ covalent modulators. Notably, 2n, especially (R)-2n, displayed a high binding affinity and superior antidiabetic effects with diminished side effects. This is mainly because it can reversibly form a unique covalent bond with the Cys285 residue in PPARγ-LBD. Further mechanistic investigations revealed that it manifested such desired pharmacological profiles primarily by effectively suppressing PPARγ-Ser273 phosphorylation, enhancing glucose metabolism, and selectively upregulating the expression of insulin-sensitive genes. Collectively, our results suggest that (R)-2n holds promise as a lead compound for treating T2DM and also provides an innovative reversible covalent warhead reference for future covalent drug design.

Unravelling the function of prdm16 in human tumours: A comparative analysis of haematologic and solid tumours

Extensive research has shown that PR domain 16 (PRDM16) plays a critical role in adipose tissue metabolism, including processes such as browning and thermogenesis of adipocytes, beigeing of adipocytes, and adipogenic differentiation of myoblasts. These functions have been associated with diseases such as obesity and diabetes. Additionally, PRDM16 has been correlated with various other conditions, including migraines, heterochromatin abnormalities, metabolic syndrome, cardiomyopathy, sarcopenia, nonsyndromic cleft lip, and essential hypertension, among others. However, there is currently no systematic or comprehensive conclusion regarding the mechanism of PRDM16 in human tumours, including haematologic and solid tumours. The aim of this review is to provide an overview of the research progress on PRDM16 in haematologic and solid tumours by incorporating recent literature findings. Furthermore, we explore the prospects of PRDM16 in the precise diagnosis and treatment of human haematologic and solid tumours.

Protein Arginine Methyltransferases: Emerging Targets in Cardiovascular and Metabolic Disease

Cardiovascular diseases (CVDs) and metabolic disorders stand as formidable challenges that significantly impact the clinical outcomes and living quality for afflicted individuals. An intricate comprehension of the underlying mechanisms is paramount for the development of efficacious therapeutic strategies. Protein arginine methyltransferases (PRMTs), a class of enzymes responsible for the precise regulation of protein methylation, have ascended to pivotal roles and emerged as crucial regulators within the intrinsic pathophysiology of these diseases. Herein, we review recent advancements in research elucidating on the multifaceted involvements of PRMTs in cardiovascular system and metabolic diseases, contributing significantly to deepen our understanding of the pathogenesis and progression of these maladies. In addition, this review provides a comprehensive analysis to unveil the distinctive roles of PRMTs across diverse cell types implicated in cardiovascular and metabolic disorders, which holds great potential to reveal novel therapeutic interventions targeting PRMTs, thus presenting promising perspectives to effectively address the substantial global burden imposed by CVDs and metabolic disorders.

Prmt6 represses the pro-adipogenic Ppar-gamma-C/ebp-alpha transcription factor loop

The feed-forward loop between the transcription factors Ppar-gamma and C/ebp-alpha is critical for lineage commitment during adipocytic differentiation. Ppar-gamma interacts with epigenetic cofactors to activate C/ebp-alpha and the downstream adipocytic gene expression program. Therefore, knowledge of the epigenetic cofactors associated with Ppar-gamma, is central to understanding adipocyte differentiation in normal differentiation and disease. We found that Prmt6 is present with Ppar-gamma on the Ppar-gamma and C/ebp-alpha promoter. It contributes to the repression of C/ebp-alpha expression, in part through its ability to induce H3R2me2a. During adipocyte differentiation, Prmt6 expression is reduced and the methyltransferase leaves the promoters. As a result, the expression of Ppar-gamma and C/ebp-alpha is upregulated and the adipocytic gene expression program is established. Inhibition of Prmt6 by a small molecule enhances adipogenesis, opening up the possibility of epigenetic manipulation of differentiation. Our data provide detailed information on the molecular mechanism controlling the Ppar-gamma-C/ebp-alpha feed-forward loop. Thus, they advance our understanding of adipogenesis in normal and aberrant adipogenesis.