Fetuin-A is one of the important proteins in insulin-dependent metabolism, which is associated with impaired insulin sensitivity, ultimately leading to IR and its complications (1). Inhibit the insulin receptor tyrosine kinase, which leads to IR (31) (2). Participate IR indirectly by inducing lipid deposition in the adipose and liver, which causes inflammation (32) (3). Act as a marker for TLR-4 endogenous ligand. Free fatty acids stimulate adipose tissue inflammation and induce IR through the TLR-4 pathway, which is further enhanced by TLR-4 activation of the transcription factors NF-κB and activator protein-1 or Fos/Jun-induced production of inflammatory cytokines. Thus they enhance adipose tissue inflammation and IR (33) (4). Inhibit adiponectin and enhance adipose tissue IR by Wnt3a/PPARγ pathway (34) (5). Promote macrophage migration and conversion to M1 type in pancreatic β-cells, which triggers β-cell inflammation, impairs their functions, and aggravates IR (35). In addition, Fetuin-A impairs insulin sensitization and raises blood glucose levels leading to IR (36). Furthermore, Fetuin-A functions as an adipokine, with its expression directly related to the fat content in adipocytes, can subsequently enhance the absorption and storage of free fatty acids in these cells.

(1) Reduce adiponectin and impairs mitochondrial energy metabolism by inhibiting PPARγ phosphorylation (2). Enhance SREBP-1c by inducing mTOR phosphorylation, inducing adipogenesis and accumulation (34, 37), which collectively lead to hepatic steatosis (38).

Fetuin-A has shown pro-inflammatory effects in patients with IR, diabetes, obesity, atherosclerosis, MetS, NAFLD (38), and anti-inflammatory properties in systemic inflammation (39). In addition to this, Fetuin-A is an important inhibitor of vascular calcification and plays an important role in atherosclerosis and cardiovascular disease(CVD) (40). NAFLD is strongly linked to disruptions in glucose and lipid metabolism. Therefore, a substantial rise in Fetuin-A is closely related to ectopic fat in the liver (41). Elevated androgen levels enhance Fetuin-A expression via androgen receptors in hepatocytes (42), therefore, serum Fetuin-A levels are elevated in patients with PCOS (43).

(1) FGF21 increases glucose uptake by adipocytes and improves glucose metabolism and IR. FGF21 activates PPARγ in adipocytes and up-regulates the expression of adiponectin, which increases glucose uptake by adipocytes and reduces blood glucose levels. It also reduces blood glucose in an insulin-independent signaling pathway by up-regulating glucose transporter protein 1 in adipocytes (111) (2), FGF21 prevents cytokine-induced apoptosis in pancreatic islet β-cells (112) (3), It stimulates the downstream Ras-Raf-melanocyte-activated protein kinase signaling pathway, which induces peroxisome proliferator-activated receptor γ co activator-1a gene expression. This further activates the transcriptional activity of PPARγ, thereby regulating gluconeogenesis (113) (4), It promotes uptake of skeletal muscle glucose (114) (5), FGF21 also acts on the nervous system, such as①reducing glucose uptake by inhibiting the paraventricular nucleus of the hypothalamus (114), ② increasing glutamatergic neurons in the ventral medial hypothalamus to inhibit glucose uptake (115), ③ stimulating the hypothalamus by stimulation of adrenocorticotropic hormone-releasing hormone via ERK1/2-CREB signaling cascade, which in turn triggering the release of corticosterone to induce gluconeogenesis (116).

(1) It inhibits hepatic fat synthesis from scratch and suppresses the expression of the adipose transcription factor sterol regulatory element-binding protein 1c (117) (2), promotes hepatic fatty acid oxidation by (118) ① up-regulating the expression of long-chain lipoyl-coenzyme A synthetase and fatty acid transport proteins to activate fatty acids to acyl-CoAs, ② increasing the expression of PGC-1α and PPARα to promote fatty acid mitochondria expression, thereby promoting fatty acid mitochondrial oxidation (3), inhibiting hepatic very low-density lipoprotein receptors, thereby reducing hepatic TG accumulation (119) (4), promoting lipophagy in hepatic adipocytes to reduce fat deposition (120) (5), up-regulating the expression of heat-producing genes, such as uncoupling protein 1, in brown fat to promote the browning of white fat, which will regulate the whole-body lipid metabolism to improve NAFLD (121), or acts directly on brown adipose tissue and subcutaneous adipose tissue to enhance glucose uptake (122). Ameliorates NAFLD and NASH by ameliorating inflammation and stress injury (1): In terms of ameliorating inflammation: ① exerting anti-inflammatory effects by enhancing macrophage nuclear factor E2-related factor 2 and inhibiting the nuclear factor κB signaling pathway (123), ② inhibiting the recruitment of adiponectin-mediated helper T cell 17 and interleukin 17 secretion in a mouse model of NASH, thereby inhibiting the recruitment and activation of immune cells (124) (2). In terms of reducing oxidative stress injury: ① FGF21 can activate the phosphatidylinositol-3-kinase/protein kinase B signaling pathway, enhancing Nrf2-mediated antioxidant capacity and apoptosis (125). It can also activate the adenylate-activated protein kinase -silent information regulator 2-related enzyme 1 signaling pathway, which thereby enhancing mitochondrial activity and its oxidative capacity (126), ② FGF21 inhibits the eukaryotic initiation factor 2α-activating transcription factor 4 signaling pathway, thereby attenuating lipotoxicity and TG accumulation due to endoplasmic reticulum stress (127) (3). In terms of ameliorating fibrosis, FGF21 inhibits hepatic stellate cell (HSC) activation by down-regulating the expression of TGF-β, the phosphorylation of Smad2/3, the activation of NF-κB and the expression level of NF-κB inhibitory protein (IκBα), which in turn inhibit HSC activation, and these also increase the expression of cysteine protease 3 and decreases the expression of the B-lymphoblastoma 2 gene (Bcl-2)/Bcl-2-associated X protein ratio. All of these lead to apoptosis of activated HSC, thus inhibiting fibrosis (128). Moreover, FGF21 significantly down-regulated leptin signaling pathway-related proteins, at the same time, it was able to up-regulate upstream Nrf2 and cytokine signaling, negatively regulate the expression of factor 3 and ultimately blocked the platelet-derived growth factor-BBPDGF-BB-leptin axis to inhibit the activation of HSC (129).

FGF21 is an important regulator of lipids and glucose, which can reduce androgen levels and restore ovulation in PCOS patients by improving insulin sensitivity, promoting lipid metabolism and reducing body weight. The potential mechanisms by which FGF21 inhibits fertility, such as (1) regulation of the HPA or HPG axis by acting on downstream targets in the hypothalamus in the suprachiasmatic nucleus of the hypothalamus and hypothalamus Kisspeptin, as well as the pituitary gland. Higher level of FGF21 interferes with the liver-neuroendocrine axis by decreasing the expression of Apv and Kiss1 genes in the anterior ventral periventricular nucleus nucleus, leading to a decrease in Kisspeptin. These lead to a surge in LH and abnormalities in ovulation (130), resulting in infertility in female mice (131) (2). FGF21 directly affects gonadotropin-releasing hormone (GnRH) neurons through the ERK1/2 pathway to regulate GnRH secretion, thereby inhibiting the pituitary gonadal axis and affecting FSH and LH secretion, leading to reproductive dysfunction (132). FGF21 was expressed in serum of PCOS patients and in ovarian tissues of polycystic ovary (PCO) rat model. PCOS-induced obesity and IR resulted in elevated serum FGF21 in PCOS patients. In the ovarian tissues of PCO rats, the expression of FGF21 was significantly higher than that of healthy rats, which was most pronounced in granulosa cells, probably through the up-regulation of FGF21 by PPARγ. Studies have demonstrated that FGF21 levels are increased in PCOS and are associated with HOMA-IR, BMI, body fat percentage, and WHR, regardless of Estradiol levels and FAI. This suggests that elevated FGF21 is linked to metabolic disturbances in PCOS, but not to hormonal imbalances (133).

1. Gene polymorphisms:SHBG inherited single nucleotide polymorphisms in the human SHBG gene have been associated with the development of T2DM. The carriers of the SHBG rs6257 allele (CC or CT) have a higher risk of developing T2DM, whereas carriers of the rs6259 allele (AA or AG) have a lower risk of T2DM (140). And the SNPs rs1799941 in SHBG have also been associated (141).

2. Impact on glycated hemoglobin and glucose regulation: Changes in SHBG levels occur before clinical glucose abnormalities appear. SHBG levels are inversely associated with glycated hemoglobin levels, suggesting that SHBG could play a role in the early detection of individuals at risk for T2DM (142).

3. Regulation of hepatic gluconeogenesis: SHBG influences fasting blood glucose levels in humans by directly affecting hepatic gluconeogenesis (143).

Insulin plays a key role in regulating SHBG metabolism, and SHBG is a strong indicator of insulin sensitivity. Therefore, a decrease in SHBG levels is a predictor of the development of IR (144). Hepatocyte nuclear factor 4 alpha(HNF-4α), a key transcription factor of SHBG, also activates the promoters of several genes related to lipid metabolism in the liver (145). HNF-4α is reduced in the livers of obese/IR mice (146), and the HNF-4α single nucleotide polymorphisms and haplotypes correlate with IR and T2DM risk (147). So HNF-4α may serve as a bridge to link the SHBG-IR correlation. Low SHBG levels mediate IR in several ways, such as (1) Intrahepatic fat inhibits SHBG expression and reduces hepatic insulin sensitivity by decreasing HNF-4α (148) (2), It may also mediate IR independently of intrahepatic fat (149) (3), It indirectly mediates insulin sensitivity by regulating serum sex hormone levels and inhibiting adiponectin (150) (4), It may downregulate the involvement of the PI3K/AKT pathway thereby playing a role in local and systemic IR (148).

SHBG levels are low in obese PCOS patients (137), and positively correlated with HDL-C levels and negatively correlated with the occurrence of MetS (151). SHBG is not only a biomarker of intrahepatic fat accumulation, but also involved in intrahepatic lipid metabolism. Low levels of SHBG exacerbate PCOS dyslipidemia (152), specifically (1) Obesity and MetS are associated with adipose tissue IR. It increases lipolysis, which in turn promotes hepatic gluconeogenesis and adipogenesis. These subsequently inhibit HNF-4α and reduces SHBG production (153) (2), Adipokines and inflammatory factors may regulate SHBG expression: leading to localized inflammation and worsening of IR (152), ①TNF-α released from hepatic adiposity impairs hepatic insulin signaling and promotes the accumulation of intrahepatic TGs, leading to the downregulation of HNF-4α mRNA (154, 155), ②The adipose inflammatory cytokine IL-1β can inhibit the expression of HNF-4α through activation of the MEK1/2 and JNK/MAPK pathways (156). Thus, adipose tissue IR down-regulates hepatic SHBG. Correspondingly, SHBG also inhibits inflammation and lipid accumulation in macrophages and adipocytes, which may be a potential protective mechanism for MetS (150). SHBG overexpression significantly reduces hepatic fat accumulation through activation of the MEK1/2 pathway. Therefore, SHBG may be a therapeutic target for NAFLD overexpression of SHBG significantly decreases hepatic fat accumulation by activating the MEK1/2 pathway. SHBG could serve as a potential therapeutic target for NAFLD (157, 158).

1. IR can lead to higher levels of free or bioactive testosterone by acting on follicular membrane cells and reducing SHBG production in the liver. Low SHBG levels lead to HA, impair insulin sensitivity and exacerbate visceral obesity (12). In conclusion, SHBG, HA, and IR create a vicious cycle where IR, NAFLD, and PCOS interact with one another. Furthermore, low levels of SHBG stimulate the production of various active adipokines and inflammatory factors, such as C-reactive protein (CRP), which lead to localized inflammation and worsen IR (137). Low circulating levels of SHBG can be regarded as a biomarker for the diagnosis of IR inflammation (136). Reduced hepatic SHBG production is associated with HA in PCOS and is considered a biomarker of NAFLD in PCOS (137). The link between lower SHBG levels and a higher risk of NAFLD in adolescents with PCOS appears to support this conclusion (159).

2. HA exacerbates PCOS and HA reduces circulating adiponectin levels, a key factor in the development of IR in PCOS (160). The mechanisms involved, such as the excess of androgens, lead to adipocyte hypertrophy (161, 162), which induces IR and HI (163), or IR by reducing insulin clearance (164). HA further interferes with the negative feedback regulation of the hypothalamic-pituitary-ovarian axis, reduces the hypothalamus’ sensitivity to LH pulses, increases LH release, and raises the LH/FSH ratio (137), which further stimulates the ovaries to increase androgen secretion. They altogether form a vicious cycle.

3. Gene polymorphisms: SHBG polymorphisms with eight or more (TAAAA) n pentanucleotide repeat sequences (rs35785886) are associated with PCOS risk and low serum SHBG concentrations in PCOS (165). Another study evaluated polymorphisms in genes affecting androgen synthesis and SHBG and found that the CYP17A1 rs743572 gene polymorphism was negatively associated with susceptibility to PCOS (166).

4. Distant complications: lower SHBG levels were significantly associated with an increased risk of PCOS. PCOS with lower SHBG levels were more likely to have disease,such as HA, T2DM, IR, glucose intolerance, obesity, infertility, and cardiovascular disease (167).

1. Inhibition of GLUT4: Elevated CRP inhibits the translocation of GLUT4 to the cell membrane and mediating a decrease in glucose uptake in muscle and fat, which induce disturbances in glucose metabolism (181).

2. Regulation of leptin signaling and pro-inflammatory responses: CRP acts as a leptin-binding protein, blocking leptin signaling and generating leptin resistance, which induce glucose metabolism disorders and IR (182).

3. Inhibition of insulin signaling pathway: CRP inhibits hepatic and muscle insulin signaling through insulin receptor phosphorylation and activation of PI3K and Akt (183). As well as it activates the signaling pathway through Syk tyrosine kinase and RhoA, inducing phosphorylation of JNK and IRS-1, which inhibit endothelial cell insulin signaling (184).

4. Involvement in macrophage proliferation: CRP increases monocyte MCP-1 expression and promotes macrophage proliferation, which promote adipose tissue IR formation (183).

5. Regulation of adiponectin expression: CRP stimulates the production of TNF-α, which inhibits lipocalin (185), decreases insulin sensitivity, and reduces hepatic gluconeogenesis, thereby improving glucose homeostasis (186).

Under normal conditions, insulin inhibits hepatic synthesis of CRP. In IR, CRP is elevated. Chronic inflammation may also be a key initiator of IR (187). Both dysglycemic and dyslipidemic states can induce cellular inflammation. When inflammation occurs, adipocytes release cytokines such as IL-6 and TNF-α, leading to compensatory HI and IR. At the same time, IL-6 and TNF-α up-regulate hepatic CRP, and elevated CRP can further stimulate the release of inflammatory mediators, such as IL-6 and TNF-α, to exert an inflammatory effect. Thus, CRP, together with IL-6 and TNF-α, exert inflammatory effects and interact with IR.

1. Mediating foam cell formation: CRP facilitates foam cell formation by enhancing LDL uptake in macrophages and influencing the production of reactive oxygen species. Additionally, CRP promotes the transformation of macrophages into foam cells and regulates lipid metabolism, contributing to the development of atherosclerotic plaques (188).

2. Regulation of hepatic lipid metabolism: CRP influences hepatic lipid metabolism by promoting IR and enhancing the breakdown of adipose tissue, which releases free fatty acids into the liver. Furthermore, during IR, peripheral tissues experience reduced insulin sensitivity, while hepatic very low-density lipoprotein(VLDL) levels rise, contributing to disruptions in hepatic lipid metabolism (189).

3. Regulation of adiponectin expression: CRP stimulates TNF-a production and inhibits lipocalin, thereby affecting hepatic lipogenesis (190, 191).

4. Regulation of leptin signaling: Leptin specifically decreases the expression of enzymes involved in hepatic lipid synthesis, while also regulating hepatic cholesterol metabolism and lowering TG and VLDL-c levels in the liver (190). CRP functions as a leptin-binding protein and induces leptin resistance, which impacts hepatic lipid metabolism (182).

CRP levels in obese patients were significantly higher compared to non-obese patients. CRP showed a positive correlation with BMI, WHR, and waist circumference, indicating a strong association with total body fat, particularly visceral fat. However, most obese patients had CRP levels below 10 mg/L, suggesting that obesity is a state of low-grade chronic inflammation (192). Obesity is a predominantly pro-inflammatory process, and the main mechanism is that in obesity, classically activated macrophages (M1) have higher concentrations than alternatively activated macrophages (M2), expressing pro-inflammatory cytokines, and activating pro-inflammatory pathways, such as the JNK and TNF-kB signaling pathways, which lead to low-grade chronic inflammation throughout the body (190).

MetS is also a chronic systemic low-grade inflammatory state. Inflammation may play an important role in MetS, and CRP can be used as a predictor of MetS (193). CRP levels were positively correlated with BMI, TG, blood pressure and FPG, but negatively correlated with HDL-C (194).

CRP may be a potential biomarker of NAFLD and involved in NAFLD through the following pathways (195) (1). CRP is involved in NAFLD by inhibiting the insulin signaling pathway through activation of Smad3/mTOR signaling by TGF-β and ERK/mitogen-activated protein kinase (MAPK) (195) (2). CRP affects the regulation of lipid metabolism by leptin, which restricts storage of TG to prevent lipotoxicity, exerts an inhibitory effect on adipogenesis, and increase insulin sensitivity by inhibiting hepatic glucose and fat (196). Leptin shows a dual role in the development of NAFLD, preventing early hepatic steatosis and also acting negatively as an inflammatory and fibrotic factor (197) (3). By inducing ROS production and leading to impaired mitochondrial function.CRP upregulates ROS in target cells via Fcγ receptors (198), leading to further mitochondrial dysfunction and chronic inflammation (199, 200). ROS overproduction inhibits antioxidant production, leading to further oxidative damage in NAFLD (201).

PCOS is a disease of severe reproductive endocrine disorders.And HA, IR, obesity and inflammation interact with each other to influence the course of PCOS. CRP is the most reliable circulating marker in chronic low-grade inflammation in PCOS (202). Systemic and localized inflammation in the ovary may be the initial pathophysiological alteration in PCOS, and these inflammatory factors work together to influence the onset and progression of PCOS (203). Inflammatory factors are significantly increased in both serum and follicular fluid in PCOS, and the possible pathways such as (1): Infiltration from the circulation through the serum-granulocyte barrier (2), Up-regulation of inflammatory mediators in the ovarian granulocytes, which leads to an increase in local infiltration of circulating increased inflammatory cells into the ovarian tissues,and within the follicles (203). The elevated levels of inflammatory factors in PCOS are not related to obesity, but obesity exacerbates inflammatory state (204, 205). Elevated CRP in PCOS may be a predictive risk factor for the development of T2DM, and obesity and IR may be an important mechanism leading to its chronic inflammation, with all three contributing to each other in a vicious circle (206).

PCOS-related hyperandrogenism (HA) could potentially contribute to inflammation in adipose tissue. The possible mechanisms include: (i) androgen-induced hypertrophy of adipocytes, resulting in tissue hypoxia or the death of enlarged adipocytes, thereby triggering an inflammatory cascade and increasing CRP level (207). (ii) HA can activate mononuclear cells (MNCs) in a fasting state, and circulating MNCs as well as MNC-derived macrophages in tissues stimulate the production of adipocytokines in a paracrine manner. These adipocytokines, in turn, trigger the release of pro-inflammatory factors like TNF-α and IL-6, resulting in an increase in CRP levels (208). In a similar manner, the local increase in TNF-α encourages the hyperplasia of ovarian granulosa cells, resulting in the production of more androgens, creating a vicious cycle that continuously stimulates subacute inflammatory responses. IR also plays a pivotal role in chronic low-grade inflammation in PCOS. IR in adipose tissue increases lipolysis, along with hypertrophy of adipocytes caused by HA. These factors lead to adipose tissue dysfunction, activation of sympathetic nerves, and the further promotion of systemic inflammatory responses through the activation of the renin-angiotensin system, which in turn leads to an elevated serum CRP as systemic inflammation (209).

Accordingly, chronic inflammatory state in women with PCOS can directly trigger HA, specifically (1) CRP induces the inflammatory response with upregulation of the ovarian steroidogenic enzyme CYP17 in response to pro-inflammatory stimulition. CYP17 is the major rate-limiting enzyme in ovarian androgen synthesis, and its upregulation promotes hyperandrogenic state (210) (2), TNF-α, a pro-inflammatory cytokine, inhibits LH-dependent androgen production (211).