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White adipose tissue

White adipose tissue (WAT), the predominant form of in mammals, is a specialized composed primarily of adipocytes that store energy as triglycerides in a single large , enabling efficient long-term energy reserves during periods of caloric surplus. These unilocular adipocytes, typically spherical and capable of expanding to nearly 100 µm in diameter, are embedded in a stromal vascular fraction that includes endothelial cells, immune cells such as macrophages, and preadipocytes, supported by an of and other proteins. In humans and other mammals, WAT comprises the largest volume of adipose tissue and is essential for maintaining by releasing free fatty acids and through during or increased metabolic demand. Beyond its role in , functions as a dynamic , secreting a variety of adipokines and cytokines that regulate systemic , , insulin sensitivity, and . Key hormones include leptin, which signals satiety to the and modulates energy expenditure, and adiponectin, which enhances insulin sensitivity and exerts anti-inflammatory effects. Other bioactive molecules, such as tumor necrosis factor-alpha (TNF-α) and interleukin-6 (IL-6), contribute to inflammatory responses, particularly in , while (PAI-1) influences and cardiovascular risk. This endocrine capacity positions as a central player in metabolic regulation, with its secretory profile varying by physiological state and depot location. WAT is distributed heterogeneously throughout the body in distinct depots, including subcutaneous sites (such as abdominal, gluteal, and femoral regions) that provide insulation, mechanical cushioning, and a metabolic , and visceral depots (like omental, mesenteric, and epicardial) that surround internal organs and drain directly into the . Subcutaneous WAT generally confers lower cardiometabolic risk and exhibits greater expandability through or , whereas visceral WAT expansion is strongly associated with , , and due to its proximity to the liver and pro-inflammatory profile. Depot-specific differences in , , and immune cell infiltration underscore WAT's heterogeneity, influencing overall metabolic health. In physiological contexts, WAT expands adaptively in response to chronic energy excess to prevent lipotoxicity from ectopic fat deposition in non-adipose tissues like muscle and liver, but impaired expandability can lead to metabolic dysfunction. It remains insulin-sensitive under normal conditions, facilitating triglyceride uptake via lipoprotein lipase, yet obesity often triggers chronic low-grade inflammation and fibrosis within WAT, exacerbating systemic diseases. These attributes highlight WAT's dual role in health and pathology, making it a key target for obesity and metabolic disorder research.

Overview

Definition and Characteristics

White adipose tissue (WAT) is a specialized form of primarily dedicated to the storage of energy in the form of triglycerides, serving as the main reservoir for excess caloric intake in mammals. It consists predominantly of adipocytes, which are large s characterized by a single, unilocular that occupies approximately 90% of the volume, displacing the and to the periphery and imparting a pale, "white" appearance due to the scarcity of mitochondria and absence of pigments associated with . This histological structure distinguishes WAT from other connective tissues and enables efficient accumulation without significant energy dissipation. Key biochemical features of WAT include its high triglyceride content, which can constitute over 90% of volume, facilitating long-term energy buffering during periods of scarcity. Mature adipocytes in WAT express specific markers such as perilipin (PLIN1), a protein that coats droplets to regulate and prevent untimely release, and fatty acid-binding protein 4 (FABP4), which aids in intracellular transport and is indicative of differentiated adipose cells. These markers underscore the tissue's role in maintaining homeostasis, with adipocytes typically spherical and ranging from 25 to 200 µm in diameter depending on nutritional status. In contrast to brown adipose tissue, which features multilocular adipocytes with numerous, large mitochondria expressing uncoupling protein 1 (UCP1) for heat production, WAT adipocytes possess few and small mitochondria, lacking UCP1 expression and thus exhibiting no significant thermogenic capacity. This structural divergence highlights WAT's specialization for energy conservation rather than expenditure. Evolutionarily, WAT emerged as an adaptive mechanism in mammals to buffer energy fluctuations, enabling survival through intermittent food availability by storing triglycerides as a readily mobilizable fuel source during famine or increased metabolic demands.

Distribution in the Body

White adipose tissue (WAT) is distributed throughout the body in distinct depots, primarily categorized as subcutaneous and visceral, each with specific anatomical locations and proportional contributions to total body fat. Subcutaneous adipose tissue (SAT) is located beneath the skin and constitutes the largest depot, accounting for approximately 80-90% of total body fat in lean adults; its main sites include the abdominal wall, gluteal region, femoral areas, and subscapular area. Visceral adipose tissue (VAT), comprising about 10-20% of total body fat, surrounds internal organs and is found in regions such as the omentum (greater omentum draping the intestines), mesentery (supporting the intestines), and perirenal area (encasing the kidneys). These depots vary in volume and function based on individual factors, influencing overall metabolic health. Sex differences in WAT distribution are pronounced, reflecting evolutionary adaptations for and . In females, there is a greater accumulation of SAT in the gluteofemoral region (thighs and ), which serves as a reserve for reproductive demands during and , while males tend to store more fat in visceral depots around the . These patterns persist across the lifespan but can shift with hormonal changes; for instance, postmenopausal women often exhibit increased deposition due to declining levels, resembling male patterns more closely. Age-related alterations further modify distribution, with advancing age associated with a redistribution toward higher accumulation, even as total body fat may stabilize or decline in some individuals. The anatomical positioning of these depots imparts distinct functional implications. SAT acts primarily as a protective cushion against mechanical stress and a long-term energy reservoir, exhibiting lower metabolic activity and reduced inflammatory potential compared to . In contrast, 's proximity to the liver and facilitates direct release of free fatty acids into systemic circulation, heightening risks of and metabolic dysregulation, particularly when expands excessively. Such site-specific properties underscore the importance of depot-specific assessments in evaluating outcomes.

Cellular and Structural Features

Adipocyte Morphology

Mature white , the primary cells in white adipose , exhibit a characteristic spherical when isolated from the . The majority of the cell volume is occupied by a single, large unilocular that stores triglycerides, compressing the into a thin peripheral rim and displacing the to the periphery. This structure optimizes storage capacity while minimizing cytoplasmic volume dedicated to other functions. Within adipose tissue, adipocytes primarily consist of white subtypes that are unilocular, but a distinct subtype known as adipocytes also exists, exhibiting intermediate features such as partial multilocularity and inducible thermogenic potential in response to stimuli like cold exposure or β-adrenergic signaling.00595-8) adipocytes arise from precursors in white fat depots and can revert to a white-like state under non-stimulatory conditions, highlighting their . Unlike white adipocytes, cells express thermogenic genes such as upon activation, though their baseline morphology remains predominantly unilocular. At the ultrastructural level, the central in white adipocytes is coated by perilipin proteins, particularly , which regulate lipid access and protect against . The plays a key role in by facilitating the and of triglycerides into the droplet, while mitochondria are sparse and small, lacking the abundance and cristae seen in adipocytes. This minimal mitochondrial content underscores the primary energy-storing rather than -dissipating function of white adipocytes. White adipocytes display significant size variability, typically ranging from 50 to 200 μm in diameter, influenced by nutritional status and depot location. In obesity, adipocytes undergo , expanding beyond normal limits, which induces cellular stress through mechanisms like endoplasmic reticulum overload and , contributing to metabolic dysfunction.

Stromal and Vascular Components

The stromal vascular fraction (SVF) of white adipose tissue () comprises a heterogeneous population of non- cells that provide , facilitate vascularization, and modulate immune responses within the tissue microenvironment. Isolated by enzymatic and , the SVF includes preadipocytes, fibroblasts, endothelial cells, , and macrophages, which collectively maintain tissue integrity and enable adaptive remodeling during physiological changes. These components interact dynamically to support function without directly participating in storage. Preadipocytes, a subset of adipose-derived stem cells marked by CD45⁻ CD146⁻ ⁺ expression, serve as progenitors that differentiate into mature adipocytes, contributing to expansion and regeneration. Fibroblasts form the foundational stromal network, secreting () components to provide mechanical stability and facilitate . Endothelial cells, constituting approximately 33% of fresh SVF, line the vascular structures and promote the formation of branched, networks essential for perfusion. Pericytes, identified as CD45⁻ CD146⁺ ⁻ cells, encase endothelial tubes to stabilize vessels and regulate during growth. Macrophages, often expressing CD11b⁺ and F4/80⁺, orchestrate vascular organization and immune surveillance within the depot. The vascular network in WAT features a dense capillary bed that envelops individual adipocytes, ensuring efficient delivery of oxygen, nutrients, and hormones while facilitating the secretion of adipokines into the circulation. This highly organized system supports metabolic demands by maintaining close proximity between capillaries and adipocytes, with each adipocyte typically surrounded by multiple vessels. Regulation occurs primarily through (VEGF) secreted by adipocytes, which binds VEGFR2 on endothelial cells to stimulate , , and tube formation, thereby enhancing vascular and oxygenation. Hypoxia-inducible factors further amplify VEGF expression in response to expanding adipocyte size, preventing metabolic stress. Among immune cells in the SVF, resident predominate and exhibit states that influence . In lean , these cells primarily adopt , induced by interleukin-4 (IL-4) and IL-13 via PPARγ and STAT6 signaling, producing cytokines like IL-10 and TGF-β to promote resolution of and support remodeling. This M2 state constitutes 5-10% of SVF cells and aids in maintaining insulin sensitivity and . In , however, shift toward pro-inflammatory , driven by free fatty acids, (LPS), and interferon-γ (IFN-γ) through TLR4, JNK, and pathways, leading to elevated TNF-α and IL-6 production that exacerbates local . This increases numbers to up to 50% in obese , contributing to immune modulation and pathological remodeling. The extracellular matrix (ECM) in WAT, composed mainly of fibrillar collagens and basal lamina proteins, acts as a dynamic scaffold that accommodates adipocyte hypertrophy and hyperplasia. Collagen types I and III, encoded by COL1A1, COL1A2, and COL3A1 genes, form interconnected networks that provide tensile strength and prevent mechanical rupture during tissue expansion. Laminin, particularly isoforms with α4, β1, and γ1 chains, integrates into the basement membrane surrounding adipocytes, promoting cell adhesion and signaling for growth. During adipogenesis, ECM remodeling involves initial degradation by matrix metalloproteinases (MMPs) followed by redeposition, with collagen I/III levels fluctuating and laminin peaking early to support structural adaptation. This scaffold is energy-dependent and insulin-regulated, ensuring stability against hypoxia and stress in expanding depots.

Development and Growth

Embryonic and Fetal Origins

White adipose tissue () arises from al progenitors during early embryonic development, with white adipocyte precursor cells (APCs) deriving from heterogeneous lineages, including Pax3- and Myf5-expressing progenitors primarily from paraxial mesoderm for trunk dorsal depots, while contributes substantially to ventral and visceral depots. Myf5-positive progenitors contribute to both (particularly anterior subcutaneous depots) and (BAT) formation, with greater predominance in BAT. These mesodermal origins ensure that WAT precursors are committed to unilocular storage functions early in embryogenesis, setting the stage for depot-specific adipose . The of white adipocyte precursors into mature is orchestrated by a core network of transcription factors, with (PPARγ) serving as the master regulator of . PPARγ coordinates the expression of genes essential for and insulin sensitivity, driving the commitment of multipotent progenitors toward the white adipocyte fate. Complementing PPARγ, the CCAAT/enhancer-binding protein (C/EBP) family—particularly C/EBPβ and C/EBPδ in early stages, followed by C/EBPα for terminal —activates downstream targets that finalize the adipogenic program, including morphological changes to unilocular cells capable of accumulation. This regulatory cascade is initiated in embryonic precursors, ensuring robust WAT formation independent of postnatal environmental cues. In human fetuses, adipose depots begin forming around gestational week 14, marking the onset of visible fat lobules in the second trimester. Subcutaneous depots, such as those in the cheeks and periorbital regions, emerge first, providing initial and mechanical cushioning, while visceral depots develop later, typically between weeks 20 and 24, as the grows. This sequential patterning reflects the progressive colonization of mesenchymal tissues by adipogenic progenitors, with depot maturation continuing until birth. Across mammalian species, WAT development shares conserved mesodermal origins and transcriptional mechanisms, but humans display distinct depot-specific gene expression profiles as early as the fetal stage. For instance, subcutaneous and visceral precursors in humans exhibit intrinsic differences in adipokine and metabolic gene regulation from mid-gestation, influencing lifelong depot functionality and susceptibility to metabolic disorders—patterns less pronounced in . These early variations underscore the evolutionary adaptations in human adipose biology.

Postnatal Expansion and Remodeling

White adipose tissue () expands postnatally primarily through two mechanisms: adipocyte , which involves an increase in existing size via accumulation, and adipocyte , which entails the and of new from cells. In adults, predominates as the main driver of mass expansion, particularly in response to chronic positive energy balance, while is more prominent during childhood or in cases of extreme where tissue demand exceeds the capacity for size increase alone. This shift reflects a decline in hyperplastic potential with age, as subcutaneous shows limited new cell formation in adults (approximately 1-2% labeled ), whereas visceral depots retain some capacity under prolonged . Hormonal signals tightly regulate these expansion processes, with insulin and glucocorticoids playing key roles in promoting WAT growth. Insulin stimulates adipocyte differentiation and lipogenesis by activating sterol regulatory element-binding protein 1 (SREBP1), a transcription factor that upregulates genes for fatty acid synthesis and triglyceride storage, thereby facilitating both hypertrophy and hyperplasia. Glucocorticoids, acting through their receptor, enhance adipocyte hypertrophy and differentiation, particularly in visceral depots, by inducing expression of pro-adipogenic factors like C/EBPβ and PPARγ, though excessive levels can impair healthy expansion. These hormones respond to nutritional cues, such as high-calorie intake, to coordinate tissue adaptation. Remodeling accompanies WAT expansion to maintain structural integrity and function, involving dynamic changes in vascularization and the (). Angiogenesis, driven by adipocyte-secreted factors like (), is essential during and to supply oxygen and nutrients, preventing in growing tissue. reorganization occurs via matrix metalloproteinases (MMPs) that degrade and remodel and other components, allowing tissue flexibility; however, in chronic overgrowth, this leads to excessive deposition and , characterized by elevated VI and stiffness that restricts further healthy expansion and promotes . Depot-specific patterns of expansion evolve across the lifespan, influenced by sex and developmental stage. During , males experience preferential visceral WAT expansion through androgen-mediated , establishing a central fat distribution pattern that contrasts with the subcutaneous bias in females. This depot dimorphism persists into adulthood, with visceral fat showing greater hypertrophic responsiveness to in males, while subcutaneous depots in both sexes rely more on during early life for accommodating growth.

Physiological Functions

Energy Homeostasis

White adipose tissue (WAT) serves as the primary long-term energy reservoir in the , storing excess caloric intake in the form of triglycerides within specialized adipocytes. This storage function is essential for maintaining , as it sequesters lipids that would otherwise accumulate ectopically in non-adipose tissues such as the liver and , thereby preventing and associated cellular dysfunction. By buffering fluctuations in nutrient availability, WAT ensures that energy surplus from feeding is safely partitioned away from vital organs, supporting overall metabolic stability during periods of caloric excess. The regulation of WAT's energy storage and mobilization is tightly controlled by hormonal signals that integrate peripheral nutrient sensing with control. , a secreted by adipocytes in proportion to fat mass, provides negative feedback to the , suppressing and increasing expenditure to prevent overaccumulation of body fat. In parallel, insulin signaling promotes postprandial lipid storage by enhancing and synthesis in adipocytes, thereby facilitating the deposition of dietary calories during fed states. These mechanisms collectively fine-tune WAT's role as a dynamic buffer, adapting to daily demands while signaling the to modulate intake and activity. In the context of whole-body , plays a pivotal role in buffering circulating glucose and free fatty acids, mitigating risks such as after meals. During abundance, rapidly sequesters these substrates, reducing their concentrations and preserving insulin sensitivity in other tissues. This integrative function positions as a central hub for systemic , where impaired storage capacity—such as in —can disrupt metabolic harmony by overwhelming this buffering system. Quantitatively, in an average adult can store approximately 100,000–200,000 kcal, equivalent to 15–20 kg of mass at typical compositions of 20–25% ; in , this capacity expands dramatically, with mass comprising up to 50% of weight and holding substantially more reserves.

Endocrine and Paracrine Signaling

White adipose tissue () functions as an active endocrine organ, secreting a variety of adipokines that exert systemic effects on , , and . These signaling molecules, primarily produced by adipocytes, communicate with distant organs such as the , liver, and to regulate , insulin sensitivity, and immune responses. In addition to endocrine actions, WAT engages in within the tissue microenvironment, where adipokines and cytokines influence local cellular interactions among adipocytes, immune cells, and stromal components. This dual signaling capability underscores WAT's role beyond mere , positioning it as a central regulator of physiological processes. Among the key adipokines, leptin stands out as a satiety signal predominantly secreted by WAT adipocytes in proportion to fat mass, acting on hypothalamic receptors to suppress food intake and promote energy expenditure. is primarily produced by white adipocytes, serving as a to maintain body weight by inhibiting hunger and stimulating . , another major , is predominantly expressed in adipocytes and circulates at high levels to enhance insulin sensitivity in peripheral tissues while exerting effects by suppressing pro-inflammatory production in macrophages and endothelial cells. In contrast, promotes inflammation and , with expression primarily in immune cells (particularly macrophages) and low levels in adipocytes in humans, contributing to metabolic dysregulation through activation of inflammatory pathways like . Paracrine signaling in WAT involves local interactions that modulate tissue function, such as tumor necrosis factor-α (TNF-α) secreted by infiltrating macrophages, which stimulates in adjacent adipocytes by activating and impairing insulin signaling. Similarly, interleukin-6 (IL-6) produced by adipocytes and macrophages within WAT can modulate insulin sensitivity locally, with elevated levels promoting a pro-inflammatory state that hinders in nearby cells. These paracrine effects help maintain tissue but can exacerbate dysfunction during excess fat accumulation. Depot-specific differences further shape signaling profiles: subcutaneous WAT secretes higher levels of , supporting beneficial metabolic effects, whereas visceral WAT produces more inflammatory cytokines like TNF-α and IL-6, linking it to greater cardiometabolic risk. Beyond and , WAT-derived adipokines influence , , and cardiovascular function. from WAT establishes a critical —approximately 3 ng/mL in circulation—required for the onset of by signaling adequate energy stores to the , thereby triggering gonadotropin-releasing hormone release. and also regulate , with adiponectin promoting differentiation and inhibiting activity to support formation, while leptin's effects vary by dose and context. In the cardiovascular , adipokines like protect against by reducing endothelial and improving vascular function, whereas elevated and TNF-α from WAT contribute to plaque formation and through pro-inflammatory and vasoconstrictive actions.

Metabolic Processes

Lipid Synthesis and Storage

White adipose tissue (WAT) primarily stores energy in the form of triglycerides through two main pathways: de novo lipogenesis from non-lipid precursors and uptake of circulating fatty acids followed by esterification. De novo (DNL) in adipocytes converts excess carbohydrates, mainly glucose, into fatty acids for triglyceride synthesis. This process begins with the uptake of glucose, which is metabolized to in the via citrate lyase after mitochondrial export as citrate. is then carboxylated by (ACC) to form , the rate-limiting step, followed by fatty acid chain elongation and desaturation by (FAS), producing palmitate as the primary product. DNL is transcriptionally regulated by sterol regulatory element-binding protein-1c (SREBP-1c), which is activated by insulin signaling and promotes the expression of ACC and FAS genes, ensuring efficient lipid accumulation during nutrient surplus. Circulating fatty acids, derived from dietary lipids or other tissues, are taken up by adipocytes via specialized transporters to support triglyceride formation. Fatty acid translocase (CD36) facilitates the translocation of long-chain fatty acids across the plasma membrane, while fatty acid-binding proteins (FABPs), particularly adipocyte FABP (A-FABP or FABP4), bind and shuttle these fatty acids intracellularly to prevent toxicity and direct them toward esterification. Once inside, fatty acids are activated to fatty acyl-CoA and esterified to glycerol-3-phosphate (derived from glucose or glyceroneogenesis) through sequential acylation steps, culminating in diacylglycerol acyltransferase (DGAT) enzymes—primarily DGAT1 and DGAT2—that catalyze the final acylation to form triglycerides. DGAT1 is localized to the endoplasmic reticulum and plays a key role in re-esterifying fatty acids during storage, while DGAT2 contributes to lipid droplet expansion. Triglycerides are stored in unilocular lipid droplets (LDs) within adipocytes, where biogenesis involves the neutral lipid core surrounded by a monolayer and associated proteins. LD formation starts at the , where triglycerides accumulate between membrane leaflets before budding off as nascent droplets that coalesce into larger structures. (PLIN1), the predominant LD coat protein in adipocytes, stabilizes these droplets in its basal, unphosphorylated state by restricting access of lipases like hormone-sensitive lipase (HSL), thereby preventing premature fatty acid release and promoting safe storage. This protective coating is essential for maintaining lipid during fed states. The energetic basis of storage reflects triglyceride's high density: one molecule forms from -3-phosphate esterified with three fatty acids, yielding approximately 9 kcal per gram of stored , far exceeding carbohydrates' 4 kcal/g and enabling efficient reserve in WAT.

Lipid Mobilization and Breakdown

Lipid mobilization and breakdown in white adipose tissue (WAT) primarily occur through the process of , a catabolic pathway that hydrolyzes stored triglycerides (TGs) into free fatty acids (FFAs) and to meet demands during or exercise. This process is tightly regulated to ensure the controlled release of substrates into the bloodstream. The cascade is a sequential enzymatic breakdown initiated by adipose triglyceride lipase (ATGL), the rate-limiting enzyme that hydrolyzes TGs within s to produce diacylglycerols (DGs) and one FFA. ATGL's activity facilitates net fatty acid efflux by driving the initial step, thereby limiting re-esterification of intermediates back into TGs. Hormone-sensitive (HSL) then acts on the DGs to yield monoacylglycerols (MGs) and a second FFA, while (MGL) completes the cascade by converting MGs into and the final FFA. This stepwise degradation—TG → DG → MG → + FFAs—occurs at the surface, facilitated by accessory proteins like (PLIN1) and comparative gene identification-58 (CGI-58), which are modulated during activation. Hormonal signals orchestrate the cascade through β-adrenergic signaling, where norepinephrine released from sympathetic nerves binds β-adrenergic receptors on adipocytes, activating to elevate levels. Elevated stimulates , which phosphorylates HSL to enhance its activity and translocation to lipid droplets, while also phosphorylating PLIN1 to release CGI-58, thereby activating ATGL. Catecholamines, such as norepinephrine, promote via this cAMP-PKA pathway, particularly during states. In contrast, insulin inhibits by activating , which degrades and reduces activity, thereby suppressing HSL and ATGL function. Upon release, FFAs enter the circulation bound to albumin and are primarily transported to tissues such as skeletal muscle and the liver for β-oxidation to generate ATP or, in the liver, for ketogenesis to fuel other organs. Glycerol, unable to be metabolized by adipocytes due to the absence of glycerol kinase, is released into the bloodstream and taken up by the liver for gluconeogenesis, contributing to glucose production during energy deficit. This coordinated efflux supports systemic energy homeostasis by providing substrates for oxidation without disrupting local storage structures in WAT.

Clinical Relevance

Association with Metabolic Diseases

White adipose tissue (WAT) dysfunction plays a central role in pathophysiology, particularly through the expansion of visceral WAT depots, which leads to tissue due to inadequate vascularization and increased size. This triggers the recruitment and infiltration of macrophages into the , fostering a low-grade inflammatory state. The infiltrating macrophages, along with dysfunctional , release pro-inflammatory cytokines such as tumor necrosis factor-alpha (TNF-α), which impairs insulin signaling pathways in and peripheral tissues, thereby promoting systemic . In the context of , obesity-associated dysfunction is characterized by reduced secretion of the anti-inflammatory and insulin-sensitizing adipokine . Lower levels from obese diminish in and by interfering with substrate-1 and activation, exacerbating and further . This deficiency correlates strongly with the progression from to overt , independent of total fat mass. Beyond obesity and diabetes, excess free fatty acids (FFAs) released from dysfunctional WAT contribute to non-alcoholic (NAFLD) by overwhelming hepatic handling capacity, leading to and inflammation. Dysregulated adipokines from WAT, including elevated and reduced , also promote and plaque formation in by enhancing vascular inflammation and . WAT dysfunction is a core feature of , a of conditions including central , , , and , with global prevalence estimated at approximately 25% among adults by 2025 projections. This underscores the pivotal role of maladaptation in driving the interconnected cardiometabolic risks observed worldwide.

Therapeutic and Research Implications

GLP-1 receptor agonists, such as , have demonstrated efficacy in reducing visceral white adipose tissue mass by promoting fat redistribution and mitigating in subcutaneous depots. These agents enhance insulin sensitivity and stimulate browning of white adipocytes, leading to increased energy expenditure and decreased ectopic fat accumulation. Thiazolidinediones, by activating peroxisome proliferator-activated receptor γ (PPARγ) in adipocytes, improve lipid partitioning toward subcutaneous white adipose tissue storage, thereby reducing in metabolically active organs. This PPARγ-mediated mechanism enhances uptake and storage capacity in white adipose tissue, contributing to better glycemic control. Surgical interventions targeting white adipose tissue include , which selectively removes subcutaneous fat to improve body contouring, though it may induce compensatory visceral fat accumulation if not combined with lifestyle modifications. Bariatric procedures, such as gastric bypass, induce substantial remodeling of white adipose tissue by reducing overall mass and alleviating , with long-term improvements in function and metabolic health. These surgeries promote , decreasing and enhancing insulin responsiveness through molecular changes in . Emerging research focuses on inducing beige fat within white adipose tissue to boost and energy expenditure, with β3-adrenergic receptor agonists like effectively activating this process in humans, similar to cold exposure. Cold-induced beiging increases uncoupled respiration in white adipocytes, offering a non-pharmacological strategy to combat by elevating whole-body energy use. Gene therapies targeting expression, such as adeno-associated virus-mediated delivery of (FGF21) to visceral white adipose tissue, have shown promise in restoring metabolic and reducing in preclinical models. These approaches aim to modulate secretion directly within adipose depots to improve systemic insulin . As of 2025, clinical trials are exploring anti-fibrotic agents to counteract white adipose tissue and , with agents like showing reductions in fibrotic markers alongside improvements in adipose . Ongoing investigations into modulation, including fecal microbiota transplantation, demonstrate potential to alleviate obesity-driven white adipose tissue by altering gut-derived metabolites that influence function. These trials highlight the gut 's role in regulating visceral adipose infiltration and pro-inflammatory signaling.