The following questions guided this scoping review of understanding the role of PNX in metabolism: What are the specific mechanisms underlying the involvement of PNX in energy homeostasis and metabolic regulation? What are the downstream signaling pathways activated by PNX that modulate metabolism regulation? How does PNX affect mitochondrial respiration rates and adenosine triphosphate (ATP) production in various metabolic contexts? What is the impact of PNX on glucose metabolism, insulin sensitivity, and pancreatic beta-cell function in health and metabolic disorders? How is PNX dysregulation implicated in the pathogenesis of metabolic disorders such as obesity, insulin resistance, dyslipidemia, and metabolic syndrome?

A systematic and comprehensive search strategy was employed to identify relevant studies. Four electronic databases (PubMed, Scopus, Google Scholar and Web of Science) were used to search for the articles published between 2013 and 2024. The data search was conducted on 30^th May 2024 using relevant keywords identified from Medical Subject Headings (MeSH). Keywords used for the data collection were PNX, metabolism, mitochondria, glycolysis and mitochondria respiration.

Two independent authors screened citation titles and abstracts and then reviewed potentially relevant articles in full, with a third author responsible for resolving any arising conflicts. The screening process was carried out using Covidence. The systematic scoping review employed a stringent selection process to ensure the reliability and comprehensiveness of the included studies. Initially, articles were screened against predefined inclusion criteria, tailored to the review’s objectives. Duplicate articles were rigorously identified and removed to eliminate redundancy and maintain data accuracy. Subsequently, non-English language articles were excluded to ensure consistency and facilitate understanding. Furthermore, abstracts from conferences and symposiums were omitted to prioritize full-text articles, enhancing the depth of the review. Theses and dissertations were also excluded to focus exclusively on peer-reviewed research, emphasizing the inclusion of high-quality, published studies. Review articles and book chapters were similarly excluded to prioritize original research findings, thereby enabling a comprehensive analysis of the current knowledge landscape. By adhering to these strict exclusion criteria, the review aimed to provide a systematic and rigorous synthesis of relevant research findings, minimizing potential bias and ensuring the reliability of the conclusions drawn.

Following the application of rigorous inclusion and exclusion criteria, the selected articles underwent meticulous data extraction. A structured form was employed to gather essential details from each study, encompassing the types of experiments conducted, the specific areas of investigation, and the key findings pertaining to PNX biological function. A qualitative synthesis of the extracted data was then conducted to analyze PNX’s role in metabolism. This synthesis involved systematically evaluating and comparing the findings from the included studies, thereby offering a comprehensive assessment of the available evidence regarding PNX’s impact on metabolic processes.

The results based on PNX’s effects on mitochondrial function, glycolytic metabolism, and mitochondrial respiration were organized under the following categories: types of PNX, action of PNX, findings, and outcomes. We reported the review following the Preferred Reporting Items for Systematic Review and Meta‐Analysis (PRISMA) guidelines –an extension for a scoping review.

These 23 articles were categorized based on their experimental designs into three groups: in vivo, in vitro, and studies combining both in vivo and in vitro approaches. Of these studies, 19 were conducted using in vivo models, nine were conducted in vitro, and six were designed to investigate both in vivo and in vitro. Additionally, the review included 12 studies focusing on PNX-14, nine studies examining PNX-20, one study focusing on both PN-14 and PNX-20 and two studies that did not specify any isoform of PNX.

The full-text articles identified were categorized according to the sex of the organisms or the cell sources, including humans, rats, mice, zebrafish and pufferfish. This classification is illustrated in Figure 3 and elicited in Table 1 . Among the 23 studies, 15 investigated male subjects, while 14 focused on female subjects. Additionally, seven studies included both sexes to examine the role of PNX. This distribution indicates a generally balanced interest in exploring the role of PNX across sexes, with a slight preference for male subjects. However, six studies utilized in vivo or in vitro models without specifying the sex.

This review identified PNX-14 as playing a significant role in various metabolic processes. PNX-14 has been reported to influence both glucose and lipid metabolism, highlighting its importance in energy regulation. Additionally, since metabolic processes are closely linked with food intake, PNX-14 has been found to regulate feeding behavior, further emphasizing its involvement in maintaining metabolic balance.

Similarly, PNX-20 is implicated in the regulation of glucose and lipid metabolism, as well as food intake. However, this review reveals that PNX-20 has additional roles beyond those shared with PNX-14. Specifically, PNX-20 has been reported to influence electrolyte metabolism and mitochondrial dynamics—functions not attributed to PNX-14. This suggests that while both PNXs share some common metabolic roles, PNX-20 may have broader effects on metabolic processes.

Three studies did not specify whether PNX-14 or PNX-20 was being measured. In these articles, the authors generally refer to the compound as PNX. Nevertheless, these studies highlighted the findings on the impact of PNX on glucose and lipid metabolism and food intake.

It is well documented that PNX-20 is mainly expressed in the central nervous system (CNS), particularly in the hypothalamus, and PNX-14 is expressed in the peripheral system. In the hypothalamus, PNX is highly expressed in key regions such as the paraventricular nucleus (PVN), supraoptic nucleus (SON), arcuate nucleus (ARC), and anteroventral periventricular nucleus (AVPV) ( Figure 4 ) (10). Out of these regions, ARC and PVN are primarily responsible for the regulation of metabolism (54, 55). Within the ARC, PNX has been observed to co-express with various neuropeptides such as NES-1 (51), neuropeptide Y (NPY) (56), and agouti-related peptide (AgRP) (57). These peptides collectively play essential roles in the complex signals network regulating hunger, energy expenditure, and overall metabolic processes. In the PVN, several key hormones and neuropeptides that are responsible for metabolism are expressed in these nuclei, including corticotropin-releasing hormone (CRH), thyrotropin-releasing hormone (TRH) and oxytocin (OT) (58). The expression of PNX in both nuclei indicates the presence of interaction with each other to regulate metabolic processes through both synergistic and antagonistic effects. This phenomenon has been observed with the reproductive neuropeptide kisspeptin, which seems to directly interact with both NPY/AgRP and POMC/CART neurons in a bidirectional manner (59).

Beyond the CNS, PNX is expressed in various peripheral organs involved in metabolic regulation, including the heart, pancreas, and adipose tissue. The expression of PNX in the heart is implicated in cardiovascular regulation by modulating heart contractility and relaxation in normal and obese rats (60). Proper cardiac function is essential for maintaining optimal blood flow and nutrient delivery to tissues, influencing overall metabolic efficiency (61). In the pancreas, the expression of PNX influences insulin secretion (33). Furthermore, PNX has been found to alleviate pancreatic injury induced by streptozotocin (STZ) and nicotinamide (NAD) in diabetic rats (40). Lastly, the presence of PNX in adipose tissue promotes the differentiation of preadipocytes into mature adipocytes through pathways such as cAMP/Epac and Epac-ERK, enhancing adipogenesis and playing a critical role in lipid storage and utilization (25). The dual expression of PNX in both the hypothalamus and peripheral organs highlights its integrative role in coordinating metabolic functions.

Apart from the expression of PNX, the reviewed studies demonstrate a significant interest in the sex-specific effects of PNX on metabolic regulation. Among the 23 studies examined, the distribution suggests a relatively balanced interest in understanding the role of PNX across sexes, though there is a slight emphasis on male subjects. Both phoenixin and nesfatin-1 significantly increased the secretion of follicle-stimulating hormone (FSH), LH, and testosterone in rat plasma without inducing any changes in plasma GnRH, thus indicating that both these neuropeptides play a synergistic role in regulating male sex hormones (52). Furthermore, a previous study has shown that PNX modulates the expression of estrogen and progesterone in obesity-induced female rats (53). These findings emphasized the integration between reproduction and metabolism regulation modulation through PNX in both sexes.

Interestingly, one study has indicated that PNX treatment exerts different mechanisms of action in different sexes (34). This study demonstrates that PNX treatment upregulates the expression of ghrelin O-acyl-transferase (GOAT), peptide YY (PYY) and cholecystokinin (CCK), which only can be observed in female fish (34). All these proteins play a significant role in regulating appetite, digestion, and overall metabolic processes (32, 62, 63). For instance, a previous study demonstrated that estrogen increases CCK mRNA levels (64). Additionally, PNX has been shown to elevate estrogen levels (53) and this suggests its mechanism of action may depend on the sex of the organism. Therefore, future studies must specify the sex of the organism model being used to elucidate the differential effects of PNX based on sex, which has often been neglected.

Most of the studies reviewed here that highlight PNX expression have been conducted predominantly in animal models. There is a notable paucity of research investigating PNX expression in human subjects or human-derived samples. This gap underscores the need for further exploration into the mechanisms underlying the actions of PNX to fully comprehend its physiological roles and potential therapeutic benefits. To translate findings from animal models into clinical practice, additional research is crucial to elucidate how PNX operates at the molecular level and how its modulation could impact human metabolic disorders. Such investigations are essential for identifying the therapeutic potential of PNX and developing targeted treatments for conditions where metabolic dysregulation plays a key role.

The involvement of PNX-14 in regulating insulin expression and secretion from pancreatic β cells suggests a critical regulatory function in managing glucose homeostasis and treating conditions like type 2 diabetes (33). The expression of PNX in pancreatic cells is induced by elevated glucose levels. A recent review has identified that the Pnx or SMIM20 gene contains several transcription factor binding sites. Notable putative sites within the promoter of this gene include those for activating transcription factor (ATF) from the CREB family, peroxisome proliferator-activated receptor (PPAR) and retinoid X receptor (RXR) heterodimer, glucocorticoid receptor (GR), nuclear factor kappa B (NF-κB), estrogen receptor (ER), CCAAT/enhancer-binding protein (C/EBP), and octamer-binding transcription factor 1 (OCT1) (10). It is postulated that these transcription factors are influenced by high glucose levels, which enhance or suppress their activity, leading to the regulation of genes involved in metabolism, energy balance, stress response, and inflammation, as well as the expression of the Pnx or SMIM20 gene. This complex regulatory network ensures proper cellular adaptation to elevated glucose levels, maintaining metabolic homeostasis.

The presence of PNX receptors and regulatory elements in the liver affects the expression of genes involved in glucose transport and metabolism, insulin-like growth factor expression, and ATP production (34). This influence alters glucose processing, ATP production, and gene expression related to glucose transport, potentially affecting liver function and glucose metabolism. These findings are supported by previous research showing that the activation of the cAMP/PKA pathway leads to the phosphorylation of CREB, which subsequently increases the expression of GLUT responsible for glucose uptake (65). Therefore, it is postulated that PNX may improve insulin resistance in diabetic patients by modulating gene expression in the pancreas and enhancing glucose uptake in the liver. Further studies in mammalian settings would strengthen this postulation as the current findings are demonstrated in a non-mammalian model.

Specifically, PNX-14’s regulation of insulin expression and secretion from pancreatic beta cells suggests a role in managing glucose homeostasis and treating conditions like type 2 diabetes (33). Its ability to alleviate NAFLD and exhibit cardioprotective effects during ischemia/reperfusion injury highlights its therapeutic potential in addressing liver and cardiac disorders associated with metabolic dysfunction (31, 60). Additionally, PNX-14’s promise in improving obesity-induced infertility by modulating mitochondrial dynamics underscores its potential role in reproductive health issues linked to metabolic disorders (53).

Lipid metabolism involves the synthesis and degradation of lipids in cells, including the breakdown or storage of fats for energy and the synthesis of structural and functional lipids. It consists of a balance between the catabolism and anabolism of lipids. Dysregulation of lipid metabolism can lead to metabolic disorders such as obesity, diabetes, and cardiovascular diseases (66). The recent findings have indicated the emerging role of PNX in modulating lipid metabolism.

As mentioned before, the promoter of Pnx or SMIM20 gene consists of putative binding sites for several transcription factors known to regulate lipid metabolism (10). Transcription factors such as NF-κB, PPAR-RXR and C/EBP have been identified as key regulators of lipid metabolic pathways (67–70). Therefore, it is suggested that the expression of PNX is directly influenced by these transcription factors, thereby linking the regulatory role of PNX to lipid metabolism. Recent findings have supported this hypothesis, showing that fatty acids such as palmitic acid, docosahexaenoic acid and oleatecan modulate the expression of PNX (43).

Previous study has demonstrated that PNX promotes the differentiation of preadipocytes into mature adipocytes through the cAMP/Epac-dependent pathway (25). The activation of Epac influences various downstream signaling molecules and pathways, leading to adipogenesis (71, 72). By enhancing the differentiation of adipocytes, PNX helps increase the number of fat cells capable of storing lipids, thereby playing a role in lipid homeostasis. This function is particularly relevant in the context of obesity, where proper adipocyte differentiation and function can mitigate the adverse effects of excess lipid accumulation (73). Additionally, PNX has been shown to have protective effects against high-fat diet-induced NAFLD in mice (31). NAFLD is characterized by excessive fat accumulation in the liver, often due to dysregulated lipid metabolism, inflammation, and oxidative stress. (74). Previous studies demonstrated that PNX ameliorate the inflammation and oxidative stress (75, 76). Thus, it is suggested that PNX has protective effects prevent the pathological fat accumulation and could lead to novel therapeutic approaches for treating lipid metabolism disorders.

In non-mammalian vertebrates, PNX facilitates adipocyte differentiation via the Epac-ERK signaling pathway (44). The ERK pathway is well-known for its role in cell growth and differentiation as well as lipid metabolism (77). Furthermore, previous study has shown that the ERK is found to modulate the adipogenesis process (78). Further study is required to elucidate mechanism on how PNX regulates ERK pathways in details. The conservation of this mechanism across species highlights the evolutionary importance of PNX in lipid metabolism and suggests its potential as a therapeutic target not only in humans but also in other animals. Furthermore, PNX has the ability to mitigate endothelial cell dysfunction and regulate hyperphagia. The ability of PNX to regulate lipid metabolism through these conserved pathways underscores its versatility and significance as potential therapeutic applications in maintaining metabolic health conditions such as obesity.

Electrolytes are essential for maintaining cellular function, fluid balance, and overall homeostasis, and any imbalance can lead to significant health issues (79, 80). Notably, PNX is expressed in the hypothalamic region such as PVN and SON that secretes vasopressin and oxytocin (9, 81).Furthermore, previous finding of PNX has shown to stimulates vasopressin secretion (46). Therefore, PNX is suggested to have potential therapeutic applications in managing conditions related to fluid and electrolyte imbalance, such as dehydration and hyponatremia. (46, 47).

Beyond its central actions, PNX is also expressed in peripheral tissues such as the kidneys, which are vital for electrolyte regulation (12). Interestingly, the GPR173 also has found expressed in the kidney tissue (82). The kidneys organ is responsible to filter blood, reabsorb essential electrolytes, and excrete waste products, thus maintaining electrolyte balance (83). The presence of PNX and its receptor may influence renal function by modulating the activity of various ion channels and transporters involved in electrolyte reabsorption and excretion. This regulation is crucial for maintaining the balance of sodium, potassium, calcium, and other vital electrolytes. Conditions such as obesity, hypertension, and type 2 diabetes mellitus (T2DM) are often associated with disruptions in electrolyte metabolism (84–86). Understanding the mechanisms by which PNX regulates electrolyte balance is particularly relevant for therapeutic studies in the context of metabolic disorders.

Food intake is essential for metabolism as it provides the calories and nutrients needed for energy production, growth, and maintenance of bodily functions (87). Carbohydrates, proteins, and fats from food are metabolized to produce energy, regulate blood glucose levels, and synthesize important biomolecules. Imbalances in food intake can disrupt these metabolic processes, leading to disorders such as obesity and diabetes (88–90).

PNX plays a multifaceted role in the regulation of food intake, primarily through its actions within the hypothalamus (91). Previous study has demonstrated that PNX increases food intake during the day while suppressing it at night (92). This finding suggests that PNX plays a role in regulating diurnal patterns of appetite, potentially influencing eating behavior based on the time of day. Recent reviews suggest that personalizing mealtimes may reduce circadian misalignment, enhance overall health, and help prevent metabolic disorder (93). By promoting daytime food intake and curbing nocturnal consumption, PNX may help align eating patterns with the natural circadian rhythms of the body, which could be beneficial for maintaining energy balance and metabolic health. Furthermore, the regulation of food intake by PNX is mediated through interactions with NPY1/NPY5 and CRF1/CRF2 receptors (6). Interestingly, CRF1 and CRF2 receptors are associated with the stress response and energy balance (94, 95). This dual mechanism suggests that PNX influences food intake by engaging both orexigenic neuropeptide pathways and stress-related signaling systems.

In infertile women with PCOS undergoing ovarian stimulation, higher baseline levels of nesfatin-1 (NES-1) and oxytocin (OT) were associated with pregnancy, while post-stimulation elevated phoenixin (PNX-14) levels predicted pregnancy. Pregnant women also showed increased post-stimulation levels of PNX-14, NES-1, and dopamine (DA) but decreased OT levels compared to non-pregnant counterparts. Additionally, a negative association between NES-1 and PNX was observed in pregnant participants, indicating potential roles for these neuroendocrine factors in reproductive success and their connection to metabolism warrants further investigation (50). Similarly, another study highlights their potential importance in regulating autonomic functions critical for maintaining metabolic homeostasis. With both NES-1 and PNX showing similar brain distributions, their co-expression in key hypothalamic nuclei suggests a potential role in metabolic regulation. Given the hypothalamus’s central role in integrating metabolic signals and regulating the hypothalamic-pituitary-gonadal axis, the wide distribution of PNX in conjunction with NES-1 suggests a possible involvement in metabolic pathways influencing reproductive health. Understanding the interplay between these neuropeptides and metabolic processes could provide insights into their roles in both metabolic regulation and reproductive function, warranting further investigation in contemporary neuroscience (49).

Mitochondrial dynamics is comprising processes such as mitochondrial biogenesis, fission, fusion, and mitophagy (96). These processes are essential for maintaining cellular health and function. PNX has been shown to influence mitochondrial biogenesis through its interaction with key signaling pathways, including the cAMP/PKA and Epac-ERK pathways (107). By modulating these pathways, PNX can enhance the production of mitochondria, which is particularly important in tissues with high energy demands, such as muscle and brown adipose tissue (97). Furthermore, the promotion of neuronal mitochondrial biogenesis by PNX indicates potential neuroprotective effects and utility in managing neurodegenerative diseases associated with mitochondrial dysfunction (107).

Another study has explored the impact of phoenixin on obesity-induced infertility in female rats (53). The study revealed that PNX treatment significantly ameliorated several markers of metabolic and reproductive dysfunction. Specifically, PNX increased the expression of mitofusin 2 (Mfn2), electron transport chain (ETC) complex-I and mitochondrial transmembrane potential. These changes were accompanied by improvements in ovarian histopathology, decreased serum levels of insulin and testosterone, as well as ovarian levels of dynamin-related protein 1 (Drp1), reactive oxygen species (ROS), TNF-α, MDA, and caspase-3. Therefore, it is suggested that PNX can counteract the adverse effects of obesity on fertility by modulating mitochondrial dynamics and reducing oxidative stress. Collectively, these insights pave the way for further exploration of phoenixin as a therapeutic agent in metabolic, fertility, and neurodegenerative disorders.

Metabolism and reproduction are integrated through a complex, multifaceted process (98). This integration ensures that reproductive success is closely aligned with the metabolic state of an organism. PNX has emerged as a significant mediator in this interplay, influencing both metabolic and reproductive functions (9). Metabolic hormones like insulin and leptin are known to influence reproductive hormone levels (99, 100). PNX modulates the activity of these metabolic hormones, thereby indirectly affecting reproductive hormones such as GnRH and LH (12). This hormonal interplay ensures that reproductive activities are aligned with the metabolic state of the organism (101).

Reproductive processes are energy-intensive and demand a well-regulated energy balance (102). PNX contributes to this balance by interacting with hormones that regulate appetite and energy expenditure, ensuring adequate energy availability for reproductive activities (33, 38, 45). Furthermore, PNX plays a significant role in mitochondrial dynamics, encompassing biogenesis, fission, fusion, and mitophagy (53, 107). These processes are vital for maintaining mitochondrial health and energy production, which are crucial for both metabolic and reproductive health (103, 104). Efficient mitochondrial function supports the energy needs of cellular processes and the synthesis of hormones and signaling molecules essential for reproduction.

Understanding the integrative role of PNX in metabolism and reproduction opens new avenues for therapeutic interventions. One pertinent example is PCOS, a disorder characterized by metabolic and reproductive dysfunctions, including insulin resistance, obesity, and irregular menstrual cycles (105). Studies have shown that PNX influences insulin sensitivity and glucose uptake, which are crucial factors in managing insulin resistance in PCOS (33). By modulating these metabolic pathways, PNX has the potential to alleviate some of the metabolic burdens associated with PCOS. Additionally, the role of PNX in lipid metabolism, including the regulation of lipogenesis and lipolysis (25, 31), could help manage obesity and its related complications in PCOS patients. Given the intriguing potential role of PNX in regulating reproduction and metabolism, a recent study demonstrated that knocking out the PNX gene did not affect fertility (45). This observation may be attributed to compensatory mechanisms that ensure the survival and continuity of the organism (106). Thus, warrant further study to elucidate the role of PNX in fertility.

Given the dual role of PNX in regulating both metabolic and reproductive functions, it presents a unique therapeutic target for managing PCOS. Further research is essential to fully elucidate the mechanisms through which PNX exerts its effects on metabolic and reproductive pathways in PCOS. Clinical studies exploring PNX levels in PCOS patients and the impact of PNX-based therapies on metabolic and reproductive outcomes are particularly warranted.