The process of sperm-egg fertilization is associated with the elimination of specific reproductive organelles. In many species, selective autophagy mediates the degradation of paternal mitochondria following fertilization while preserving maternal mitochondria. In C. elegans, the elimination of paternal mitochondria is mediated through ubiquitination and the mitophagy pathway, with the mitophagy process being directly regulated by FUNDC1 (56, 57). The phenomenon of paternal mitochondrial elimination has also been observed in mice. Upon the sperm reaches the oviduct, most of its mitochondria have already undergone phagocytosis and degradation (58). The strict maternal inheritance of mitochondria in mice is dependent on the interplay between mitochondrial E3 ubiquitin protein ligase 1 and the Parkin-mediated mitophagy pathway (59). In early embryos, the autophagy mechanism mediates the degradation of oocyte proteins, thereby facilitating embryonic implantation (60). At the blastocyst stage, trophoblast cells are regulated by autophagy, which promotes normal placental development (61). Autophagy collaborates with C-X-C chemokine ligand 12 and its receptors to participate in placental angiogenesis and vascularization, maintaining placental homeostasis (62). The key autophagy factors ATG5 and BECN1 play essential roles in embryonic organogenesis and development (63, 64). Collectively, autophagy is involved in a series of developmental processes, including pre-implantation, implantation, and post-implantation stages of embryogenesis. However, whether mitophagy directly modulates fertilization and implantation during female reproductive processes remains to be elucidated. According to current studies (65, 66), mitophagy may sustain cellular energy metabolism and oxidative stress balance, thereby providing adequate energy support for blastocyst cell migration, embryo adhesion, and embryogenesis. The precise mechanisms underlying this biological process warrant further investigation.

As previously discussed, follicular atresia is regulated by both apoptosis and mitophagy, with FSH serving as a key regulatory factor linking these two mechanisms. FSH modulates granulosa cell activity by either activating or suppressing excessive mitophagy under varying redox conditions. Furthermore, high-dose FSH has been shown to induce autophagy in bovine granulosa cells via the AKT-MTOR signaling pathway, thereby enhancing estradiol (E₂) production (67). In a study involving porcine oocytes, E₂ was found to alleviate oxidative stress, inhibit apoptosis, and promote in vitro maturation and developmental competence through autophagy-related mechanisms (68). These findings collectively indicate that FSH plays a pivotal role in mitophagy in the context of improving female reproductive function. During follicular development, AMH, secreted by granulosa cells of preantral and small antral follicles in the ovary, has been shown to inhibit forkhead box O3a (FOXO3a), an upstream effector of the PINK1-Parkin-mediated mitophagy pathway. This suggests that mitophagy may be involved in follicular activation; however, direct experimental evidence is required to confirm this hypothesis. Mitochondrial uncoupling protein 2 (UCP2), a mitochondrial membrane protein, contributes to mitochondrial homeostasis by reducing ROS, regulating apoptosis, and maintaining calcium homeostasis. In human cumulus cells, UCP2 has been implicated in the regulation of ROS production, apoptosis, and progesterone synthesis via autophagy, thereby participating in follicular development and early embryo implantation (69). Given the close interplay between mitophagy, oxidative stress, and apoptosis, it is of scientific interest to investigate whether UCP2 interacts with mitophagy and whether such interaction contributes to reproductive function. This warrants further experimental exploration.

Endometriosis is a chronic, hormone-dependent inflammatory disorder characterized by the ectopic implantation of endometrial glands and stroma outside the uterine cavity. It has been established as one of the leading causes of pelvic pain, dysmenorrhea, and infertility, affecting approximately 5% to 10% of women of reproductive age (86, 87). Accumulating evidence indicates that the interplay among apoptosis, angiogenesis, autophagy, and mitophagy plays a complex role in the pathogenesis of endometriosis in rodent models (88). PINK1 serves as a key initiator of mitophagy. In rat models of endometriosis (70), the PINK1-Parkin-mediated mitophagy pathway suppresses cell proliferation, migration, and invasion through upregulation of prohibitin 2. Furthermore, the PINK1-Parkin mitophagy pathway represents a critical mechanism by which macrophage stimulator 1 (Mst1), a negative regulator of endometriosis, modulates apoptosis and migration in human endometrial stromal cells (ESCs) (89). Mst1 inhibits Parkin transcription and expression, thereby suppressing mitophagy and promoting ESC apoptosis while restricting cell migration. Specifically, Mst1 overexpression leads to reduced Parkin expression, mitochondrial fragmentation, impaired lysosomal co-localization, cytoplasmic calcium overload, and decreased F-actin expression. Besides, the coordinated regulation of mitophagy and apoptosis via the PINK1-Parkin pathway has been associated with the mTOR signaling cascade (90, 91). Both autophagy and PINK1-Parkin-mediated mitophagy activate the mTOR pathway, which in turn stimulates pro-apoptotic Bcl-2 family proteins on the mitochondrial membrane, ultimately inducing apoptosis through calcium channel blockers. Endometrial cell apoptosis can counteract angiogenesis to some extent, thereby reducing the volume, area, and diameter of endometriotic lesions and impeding disease progression.

The mitochondrial quality control system in endometriosis has been closely linked to REV-ERB. Brain and muscle aryl hydrocarbon receptor nuclear translocator-like 1 (BMAL1) and Circadian Locomotor Output Cycles Kaput (CLOCK) are core components of the circadian clock machinery. REV-ERB forms a feedback regulatory loop with downstream target genes, directly influencing mitochondrial quality control and sleep-wake patterns (71). The chronic estrogen dependence of endometriosis may further contribute to sleep disturbances. Modulating circadian rhythms and restoring mitochondrial function may offer therapeutic potential for endometriosis. Although direct evidence linking mitophagy to circadian regulation remains limited, mitochondrial fission and fusion, processes closely associated with mitophagy, exhibit circadian oscillations synchronized with the light/dark cycle through the phosphorylation-dependent activation and inactivation of DRP1 (92). These findings suggest that mitophagy may play a role in the regulation of circadian rhythms and the progression of endometriosis.

PCOS is the most prevalent endocrine disorder in women of reproductive age, with major characteristics encompassing ovulation dysfunction, hyperandrogenism and polycystic ovarian morphology. One in six women of reproductive age is afflicted by PCOS, which constitutes the primary cause of subfertility (93, 94). The pathogenesis of PCOS is closely linked to mitochondrial energy metabolism (95). Studies have shown that in human ovarian granulosa cells (KNG) treated with dihydrotestosterone, the MMP and mtDNA content were reduced, whereas the abundance of autophagosomes and the levels of key mitophagy proteins PINK1 and Parkin were elevated. This suggests that excessive activation of mitophagy contributes to GC damage. Comparable alterations were detected in the GCs of individuals diagnosed with PCOS. In addition, the study by Zhao et al. revealed that in the GCs of patients with PCOS, in addition to the previously mentioned alterations, the mitophagy receptors Nix and RHEB were also highly expressed. This finding provides further evidence of the involvement of mitophagy in granulosa cell dysfunction in PCOS. Dysfunctional GCs can induce oxidative stress and chronic inflammation, consistent with the pathophysiological mechanisms underlying PCOS (96, 97). Future studies should aim to directly validate this targeted relationship, thereby facilitating potential clinical translation.

REV-ERB serves as a central regulator of the circadian clock and is intricately linked to mitochondrial biosynthetic functions (98). REV-ERB inhibits the translocation of Park2, a key factor in mitophagy, to mitochondria or modulates the activity of the mitophagy activator ULK1, thereby maintaining mitochondrial structure and function (72). In PCOS patients, REV-ERB expression is significantly reduced in GCs (73). A study by Amador et al. found that treating PCOS mice with SR9009, a REV-ERB agonist, suppressed over-activated mitophagy. This upregulated the expression of peroxisome proliferator-activated receptor γ coactivator 1α, nuclear respiratory factor 1, and mitochondrial transcription factor A, genes associated with mitochondrial biogenesis. The enhanced expression of these genes promoted mitochondrial biogenesis, corrected quality defects in GCs caused by PCOS, and facilitated follicular development and maturation, thereby regulating female reproductive capacity.

Iron-mediated mitophagy plays a critical role in the pathogenesis of PCOS. Ammonium ferric citrate activates transferrin receptor 1 (TFRC), thereby increasing intracellular iron levels, which leads to the accumulation and release of ROS, overactivation of the PINK1-dependent mitophagy pathway, induction of ferroptosis, and inhibition of follicular development via the TFRC/NOX1/PINK1/ACSL4 signaling axis. Therefore, reducing iron uptake may facilitate normal follicular development in PCOS. Zhang et al. (74) consistently reported that activation of ACSL4 in KNG cells suppressed normal follicular development, with abnormal follicle formation being closely associated with the initiation and progression of PCOS (99). The regulatory mechanism of mitophagy is influenced by the cellular redox status. CDGSH iron-sulfur domain 2 (CISD2), a protein found on the outer mitochondrial membrane, endoplasmic reticulum, and mitochondria-associated membranes, functions as a [2Fe-2S] cluster-containing protein with oxygen-reducing activity, and participates in the regulation of cellular iron metabolism, ROS homeostasis, and mitophagy (100–103). The involvement of CISD2 in electron and iron-sulfur cluster transfer defines its functional relationship with mitophagy. Under reducing conditions, CISD2 is unable to transfer [2Fe-2S] clusters; however, under oxidative stress, CISD2 facilitates iron transport into the mitochondrial matrix and transfers electrons to oxygen through oxidized NAD+ (an electron donor), thereby promoting oxidative stress and generating superoxide radicals (O₂⁻) (104–106). Wu et al. (75) established a PCOS model in KNG cells using testosterone and observed elevated CISD2 expression under oxidative conditions. Silencing CISD2 expression via shRNA significantly enhanced PINK1-Parkin-mediated mitophagy and upregulated SOD2 expression, thereby attenuating oxidative stress and stabilizing the follicular microenvironment.

Besides, studies have explored PCOS-related clinical features such as insulin resistance and obesity. In obese humans and rats, the expression levels of mitophagy-related molecules, including Parkin, FUNDC1, and BNIP3, are markedly decreased. These mitophagy defects impair the metabolic differentiation of adipose tissue, contributing to insulin resistance (76–78). Therefore, mitophagy may alleviate PCOS symptoms by modulating metabolic pathways, offering valuable insights for developing clinical strategies.

POI, characterized by the premature depletion of ovarian follicles before the age of 40, is a major contributor to female infertility (107). Mitophagy plays a critical role in maintaining ovarian function by mitigating excessive ROS accumulation and preventing mtDNA damage. However, excessive activation of mitophagy may contribute to the development of POI. Miao et al. demonstrated that in POI mice, the expression levels of PINK1 and Parkin were elevated in the ovaries, accompanied by an increased number of autophagosomes and autolysosomes in GCs, suggesting that excessive mitophagy is involved in the pathogenesis of POI (108). A cohort study involving 375 patients identified mitophagy as a potential therapeutic target for POI (109). Sequencing analysis revealed a homozygous single-nucleotide insertion in exon 1 of the SPATA33 gene (NM_153025.2: c.34dup; p.Cys12LeufsTer2). SPATA33, a protein exclusively expressed in mitochondrial germ cells, has been recognized as a novel mediator of mitophagy (110), providing genetic evidence linking POI with mitophagy. There are varying perspectives on the precise relationship between mitophagy and the pathogenesis of POI. Some studies have indicated that the pathological process of POI is closely associated with the suppression of the PINK1-Parkin pathway (111, 112). Yao et al. overexpressed neurotrophin-induced gene B (Nur77) in the ovaries of POI mice. Nur77, a member of the nuclear hormone receptor NR4A family, regulates pathological processes such as metabolic abnormalities, hypoxia stress, and inflammation. Activation of Nur77 can induce PINK1-Parkin pathway-mediated mitophagy, thereby improving follicular development and sex hormone levels in POI mice and enhancing ovarian function. However, this study lacked a control group with inhibited mitophagy and did not include recovery experiments following Nur77 overexpression (79). Compared to other reproductive disorders, research on POI is extensive and diverse, offering multiple perspectives for future investigations and aiding in the elucidation of the precise mechanisms of mitophagy’s involvement.

OA is defined as the progressive decline and ultimate exhaustion of ovarian function, marked by a reduction in follicle abundance and deterioration in oocyte quality (13). Furthermore, compromised oocyte quality is strongly associated with adverse reproductive outcomes, such as fertilization failure, impaired embryo development, and miscarriage. Wang et al. demonstrated that excessive activation of mitophagy mediated by the PINK1-Parkin pathway plays a critical role in the physiological mechanisms underlying OA, particularly in germinal vesicle-stage oocytes (113). Pan et al. proposed that both mitophagy and mitochondrial trafficking contribute to OA. Specifically, Parkin, lysosome-associated membrane protein 2, and mitochondrial dynamics-related protein 1 worked synergistically with mitochondrial Rho-GTPase, an OMM protein, to regulate mitochondrial transport and mitophagy during oocyte meiosis, thereby alleviating maturation defects in OA oocytes (114). Jin et al. further revealed that mitophagy exerts regulatory effects during this process. Notably, RAB7, a key regulator of the late endosome/lysosome network, remains active during meiosis to suppress excessive PINK1-Parkin-mediated mitophagy, thus enhancing oocyte quality in the context of OA (80). Besides, endogenous C-type natriuretic peptide (CNP), secreted by GCs in the follicular wall, mitigates DNA damage and apoptosis in OA oocytes, ensuring adequate time for cytoplasmic maturation (81, 82). This effect is primarily achieved through CNP destabilizing PINK1 and inhibiting Parkin recruitment, thereby restoring mitochondrial oxidative phosphorylation. The therapeutic potential of compounds like spermidine and traditional Chinese medicine for OA will be discussed in more detail later.

Melatonin (N-acetyl-5-methoxytryptamine) is a compound secreted in the ovary, composed of indoleamine and acetyl groups. Its receptors, MT1 and MT2, are highly expressed in GCs, thereby enhancing cellular communication between GCs and melatonin. This not only supports the physiological functions of GCs but also amplifies melatonin’s regulatory effects on GCs (115–117) Several studies (118, 119) have confirmed that during female reproduction, melatonin mitigates oxidative damage in GCs, reduces cell apoptosis, and promotes oocyte maturation. Xu et al. (120) proposed that melatonin regulates GCs via mitophagy. Specifically, melatonin upregulates the expression of PINK1, Parkin, BECLIN1, and LC3II/LC3I in bovine GCs, activating PINK1-Parkin-mediated mitophagy and enhancing reproductive capacity. The activation of mitophagy by melatonin relies on the SIRT1-FoxO1 signaling pathway. More precisely, melatonin interacts with NAD+-dependent histone deacetylase SIRT1, which deacetylates FoxO1 and inhibits its activity (121, 122), thereby reducing the transcriptional activity of pro-apoptotic factors mediated by FoxO1, decreasing GC apoptosis, and improving follicular development (123). In the context of PCOS, mitophagy exhibits protective effects on GCs through diverse regulatory mechanisms (124). In KNG cells, mice, and PCOS patients, melatonin significantly increases SIRT1 expression, suppresses excessive activation of the PINK1-Parkin pathway, restores mitochondrial function, and alleviates GC damage caused by PCOS, thereby improving both in vivo and in vitro phenotypes of PCOS. Therefore, further investigation into the mechanism of melatonin’s effects on GCs through mitophagy in various cellular environments is warranted.

Research (125, 126) on porcine oocytes has demonstrated that excessive activation of PINK1-Parkin-mediated mitophagy can lead to zinc deficiency. Zinc is an essential trace element that plays a critical role in numerous cellular physiological processes, including transcription, protein synthesis, enzyme activity, cell division, growth, and transport. In the female reproductive system, zinc deficiency inhibits the synthesis and activity of copper-zinc SOD2, increases the acetylation level of SOD2, and enhances cellular sensitivity to ROS, thereby triggering oxidative stress and early apoptosis in oocytes. These cellular events impair meiotic progression, disrupt cytoskeletal integrity, and cause mitochondrial dysfunction, ultimately reducing oocyte quality. Therefore, zinc supplementation may serve to inhibit hyperactivated mitophagy, alleviate oxidative stress, restore mitochondrial function in oocytes, and thereby maintain intracellular homeostasis within oocytes. Selenium is an essential trace element for female reproductive health. It is predominantly localized in the granulosa cell layer and highly expressed in large, healthy follicles, where it may serve as an antioxidant during the later stages of follicular development (127). Given the bidirectional regulatory relationship between mitophagy and oxidative stress, it is essential to investigate the involvement of mitophagy in selenium-mediated regulation of the female reproductive system. Furthermore, Zhang et al. (83) confirmed through non-targeted metabolomics technology that spermidine, a polyamine metabolite, is a key metabolite in the ovary. Increasing the level of spermidine in the ovaries of aged mice promoted follicular development, oocyte maturation, and early embryo development. Microtranscriptomic studies further revealed that this improvement in oocyte quality was achieved through activation of mitophagy and mitochondrial function mediation, and this mechanism remains active under oxidative stress conditions in porcine oocytes. In summary, regulating the mitophagy pathway effectively enhances oocyte quality.

Luteolysis is a pivotal regulatory mechanism in the female reproductive cycle. Bennegard et al. (128) suggested that elucidating the cellular events occurring during early luteolysis could be an important strategy for improving female fertility. Auletta et al. demonstrated that increasing PGF2α levels in the rhesus monkey luteum could induce luteolysis (129). Similarly, Plewes et al. observed this phenomenon in bovine luteum (130). During the early stages of luteolysis, PGF2α activates PINK1 and stimulates Parkin phosphorylation. This finding suggests that mitophagy and mitochondrial fission are involved in the early cellular activities of luteolysis. Although the PGF2α analogues used in these studies do not fully replicate the PGF2α secreted by the uterus, and physiological luteolysis involves more complex mechanisms than PGF2α signaling alone, this research highlights the potential of mitophagy as a therapeutic target for luteal insufficiency. The aforementioned therapeutic approaches targeting mitophagy have shown promising effects on granulosa cell damage, oocyte quality defects, and luteal insufficiency. Thus, mitophagy holds significant potential as a therapeutic target for enhancing female reproductive capacity.

Ginseng, a perennial herb belonging to the genus Panax in the family Araliaceae, contains ginsenoside Rg1 as its primary bioactive constituent. Ginsenoside Rg1 is a tetracyclic triterpene saponin that has demonstrated protective effects against oxidative stress-induced damage in various pathological conditions, including diabetes, ischemic stroke, and depression (131–133). In diabetic rat models, ginsenoside Rg1 significantly elevated superoxide dismutase (SOD) levels. In both in vivo and in vitro models of ischemic stroke, ginsenoside Rg1 activated the Nrf2/ARE signaling pathway, thereby enhancing the cellular antioxidant defense system. Furthermore, ginsenoside Rg1 was shown to downregulate the expression of NADPH oxidase isoforms NOX1 and NOX4 in the hippocampus of depression-induced rats, thereby alleviating oxidative stress. As previously discussed, a bidirectional regulatory relationship exists between oxidative stress and mitophagy. Ginsenoside Rg1 has also been reported to improve fertility in ovarian aging mouse models by increasing antioxidant enzyme levels, suggesting its potential regulatory role in the female reproductive system via mitophagy modulation (134). A study by Yang et al. (84) established an oxidative stress-induced OA model in Drosophila using tert-butyl hydroperoxide and demonstrated that ginsenoside Rg1 treatment induced PINK1-mediated mitophagy, thereby reducing oxidative damage and improving reproductive capacity. Molecular docking analysis further revealed that Rg1 exhibited strong binding affinity with the active domain of PINK1 and formed hydrogen bonds. These findings suggest that ginsenoside Rg1 may exert its therapeutic effects in OA by activating the PINK1-mediated mitophagy pathway in ovarian cells, promoting mitochondrial degradation, reducing excessive ROS accumulation, and alleviating redox imbalance caused by decreased SOD2 and catalase activity, ultimately reversing oxidative stress-induced reproductive damage.

Recent studies have indicated that salidroside (2-(4-hydroxyphenyl)ethyl-β-D-glucopyranoside), the primary bioactive compound extracted from the roots and rhizomes of Rhodiola rosea, exhibits therapeutic potential in the treatment of premature ovarian aging. In an experimental study on porcine oocytes (135), salidroside significantly reduced ROS levels, enhanced MMP and ATP production, increased mitochondrial DNA copy number, and promoted both cytoplasmic and nuclear maturation of oocytes. In subsequent embryo development, salidroside-treated embryos exhibited increased blastomere counts, improved blastocyst proliferation, and upregulated expression of pluripotency genes. Moreover, mitochondrial-targeted molecules have been shown to ameliorate spindle and chromosome abnormalities in aged mouse and human oocytes, suggesting that mitochondrial dysfunction plays a central role in the pathogenesis of ovarian aging (136). Therefore, the therapeutic effects of salidroside on OA are closely associated with mitophagy regulation. A recent study (85) confirmed through transcriptomic and microproteomic analyses that salidroside could maintain normal spindle and chromosome alignment and preserve mitochondrial membrane potential via mitophagy activation, thereby enhancing oocyte maturation, fertilization capacity, and embryonic developmental potential in OA mouse models.

Both ginsenoside Rg1 and salidroside are bioactive constituents of TCM, which are characterized by their multi-target and multi-pathway regulatory properties. Salidroside, for instance, interacts with key molecular targets such as Tumor Necrosis Factor-alpha, Interleukin-2, Bcl-2, Cyclooxygenase-2, Vascular Endothelial Growth Factor, cysteine-aspartic acid protease 3, and Hypoxia-Inducible Factor-1alpha, and modulates multiple signaling pathways including PI3K/Akt/mTOR, Mitogen-Activated Protein Kinases, Extracellular Signal-Regulated Kinase 1 and 2, Glycogen Synthase Kinase-3 Beta, and Nuclear Factor Erythroid 2-Related Factor 2. These molecular targets and pathways are closely associated with the pathophysiological mechanisms of female reproductive disorders, underscoring the therapeutic potential of salidroside in reproductive medicine. Despite its promising effects, there remains a lack of comprehensive long-term toxicological data to support its clinical application. However, existing toxicity studies have not identified significant adverse effects. Besides, the bioavailability of salidroside is closely related to its synthetic methodology. Therefore, optimizing the synthesis and derivatization of salidroside represents a promising avenue for advancing its clinical application in TCM (137).