Quercetin attenuates nicotine-induced ovarian and uterine dysfunction in rats

Quercetin, nicotine, and female reproduction

Article information

Korean J Fertil Steril. 2026;.cerm.2025.08298

Publication date (electronic) : 2026 January 2

doi : https://doi.org/10.5653/cerm.2025.08298

Elmira Sayad ¹

, Masoumeh Faghani ¹

, Parvaneh Keshavarz ²

, Ali Rafiei ³

, Fahimeh Mohammadghasemi^,²

¹Department of Anatomical Sciences, School of Medicine, Guilan University of Medical Sciences, Rasht, Iran

²Cellular and Molecular Research Center, School of Medicine, Guilan University of Medical Sciences, Rasht, Iran

³Department of Immunology, School of Medicine, Guilan University of Medical Sciences, Rasht, Iran

Corresponding author: Fahimeh Mohammadghasemi Cellular and Molecular Research Center, School of Medicine, Guilan University of Medical Sciences, Rasht, Iran Tel: +98-13-3369-0068 Fax: +98-13-3369-0036 E-mail: parsahistolab@gmail.com

*This work was supported by the grant number 140111240 in Guilan University of Medical Sciences Research Affair.

Received 2025 June 29; Revised 2025 August 3; Accepted 2025 August 7.

Abstract

Objective

Nicotine, a principal constituent of tobacco smoke, disrupts female reproductive physiology. Quercetin, a flavonoid with both phytoestrogenic and antioxidant properties, may counteract this toxicity. This study aimed to evaluate the histological, biochemical, and molecular effects of quercetin co-administration with nicotine on ovarian and uterine tissues in rats.

Methods

Thirty-two female Wistar rats were assigned to four groups: control, nicotine-treated (1 mg/kg), quercetin-treated (15 mg/kg), and a combined nicotine (1 mg/kg)–quercetin (15 mg/kg) group. Histopathological assessments were performed alongside biochemical analyses of oxidative stress markers—malondialdehyde (MDA), superoxide dismutase (SOD), and total antioxidant capacity (TAC)—and enzyme-linked immunosorbent assay (ELISA)-based hormonal profiling. Immunohistochemistry was employed to quantify estrogen receptor-alpha (ERα) and Ki-67 expression.

Results

Co-administration of nicotine and quercetin increased uterine wall thickness and was associated with elevated estradiol levels, reduced MDA activity, and increased SOD and TAC in both uterine and ovarian tissues compared with the nicotine group. The nicotine–quercetin group also showed a lower Ki-67 index in ovarian follicles and stroma, along with a marked reduction in atretic follicles. Conversely, there were significant increases in antral follicles, corpus luteum formation, and ERα expression in the uterine endometrium and epithelium, as well as in the ovarian stroma and corpus luteum, versus the nicotine-only group.

Conclusion

Quercetin (15 mg/kg) appears to protect against nicotine-induced reproductive impairments (1 mg/kg), likely through its antioxidant properties, its capacity to stabilize hormone levels, and its modulation of ERα and Ki-67 expression. These findings support quercetin’s therapeutic potential for preventing or alleviating smoking-related reproductive damage.

Keywords: Cell proliferation; Estrogen receptor alpha; Nicotine; Ovary; Quercetin; Uterus

Introduction

Nicotine, the predominant alkaloid in tobacco smoke, has been extensively documented for its deleterious effects on fertility in both sexes [1,2]. In females, the endometrium serves as a critical interface for embryo implantation and fetal development, with optimal endometrial function being a key determinant of successful reproduction [3,4]. Nicotine exposure has been shown to impair reproductive function by causing chronic anovulation, irregular menstrual cycles, abnormal uterine bleeding, and alterations in oogenesis and oocyte morphology [5]. These adverse outcomes are partly mediated by nicotine’s interference with the hypothalamic–pituitary–gonadal (HPG) axis, particularly through the disruption of luteinizing hormone-releasing hormone secretion [6-8]. Nicotine also suppresses androgen synthesis in theca cells and disturbs ovarian steroidogenesis [9]. A substantial body of clinical and experimental research supports nicotine’s harmful impact on essential reproductive processes, including folliculogenesis, granulosa cell proliferation, and estrogen receptor-alpha (ERα) expression [10-12]. Estrogen, acting through its receptors, is indispensable for female reproductive development, driving granulosa cell differentiation, follicular maturation, and ovulation [2,13]. Cigarette smoke has been shown to decrease ERα expression in both uterine and oviductal tissues [2,14], offering a plausible mechanistic explanation for smoking-related infertility and elevated risks of endometrial disorders [15,16]. Nicotine also exerts anti-proliferative effects on endometrial, granulosa, and theca cells in both humans and animal models [7,17]. Interestingly, certain reports suggest paradoxical protective associations between smoking and a reduced incidence of fibroids or endometriosis in postmenopausal women [18], although there is no consensus in this regard, and these observations may reflect complex hormonal interactions. Phytoestrogens, a class of plant-derived compounds structurally analogous to estradiol, can interact with estrogen receptors and exert either estrogenic or anti-estrogenic effects depending on dosage and tissue specificity [19,20]. Quercetin, a well-characterized flavonoid phytoestrogen, is widely recognized for its biological activities, including antioxidant, anti-inflammatory, and cardioprotective effects [21,22]. In reproductive health research, quercetin has demonstrated potential benefits, including enhancement of ovarian antioxidant defenses and modulation of steroidogenic pathways [20,23].

In vivo studies have shown that quercetin supplementation at 30 mg/kg improves oocyte quality and follicular development in rabbits [24]. At lower doses (12.5 mg/kg), quercetin appears to delay ovarian aging by regulating oxidative stress-related gene expression [23]. Additional evidence indicates that quercetin at 20 mg/kg can counteract nicotine-induced reproductive toxicity in female rats, primarily through antioxidative mechanisms [25]. Notably, the biological effects of quercetin are dose-dependent: at lower concentrations (e.g., 10 mg/kg) it tends to exhibit anti-estrogenic properties, whereas at higher doses (e.g., 100 mg/kg) it may exert estrogenic effects, as indicated by altered proliferating cell nuclear antigen expression in uterine tissue [26]. Quercetin also demonstrates selective cytostatic activity, suppressing cancer cell proliferation at low doses with minimal cytotoxicity [27].

Despite growing evidence of nicotine’s harmful effects on female reproductive health, therapeutic strategies remain limited. Given its antioxidative and phytoestrogenic properties, quercetin is a promising candidate but remains underexplored in this context. To address this gap, the present study investigates the protective effects of quercetin against nicotine-induced ovarian and uterine dysfunction in female rats, focusing on histological alterations, oxidative stress biomarkers, hormonal profiles, and the expression of key molecular markers, including ERα and Ki-67.

Methods

1. Ethical statements

All experimental procedures were reviewed and approved by the Institutional Animal Care and Use Committee of Guilan University of Medical Sciences (Approval Code: IR.GUMS.AEC.1401.015), in accordance with the guidelines of the National Institutes of Health for the ethical care and use of laboratory animals.

2. Animals and experimental groups

A total of 32 healthy female Wistar rats, aged 2 months and weighing 250 to 300 g, were obtained from the animal facility of the Faculty of Pharmacy, Guilan University of Medical Sciences. Animals were housed under standard laboratory conditions, including a controlled temperature (22±2 °C), a 12-hour light/dark cycle, and free access to standard rodent chow and water.

The rats were randomly divided into four experimental groups (n=8 per group) as follows:

(1) Control group: Received 0.3% ethanol in normal saline intraperitoneally.

(2) Nicotine group: Administered nicotine at a dose of 1 mg/kg intraperitoneally [28].

(3) Quercetin group: Received quercetin at 15 mg/kg orally via drinking water [29,30].

(4)Nicotine+quercetin group: Co-administered 1 mg/kg nicotine intraperitoneally and 15 mg/kg quercetin orally.

The dose of quercetin in this study was based on previous studies conducted on the ovaries [29,30], as well as our preliminary studies in the laboratory. All treatments were administered once daily for 28 consecutive days. Nicotine and quercetin were both purchased from Sigma-Aldrich (USA).

3. Estrous cycle determination by vaginal smearing

Estrous cycle staging was performed through vaginal cytology before the first treatment and 24 hours after the final dose. Vaginal smears were collected using sterile cotton swabs, stained with Papanicolaou stain, and examined under a light microscope. Only animals in the diestrus stage—identified by a predominance of leukocytes over cornified epithelial cells and the presence of a corpus luteum—were included in subsequent analyses [31,32].

4. Animal surgery

At the end of the treatment period, animals were anesthetized with an intraperitoneal injection of ketamine (80 mg/kg) and xylazine (10 mg/kg). Blood samples were collected from the inferior vena cava for hormonal analysis. Uterine horns and ovaries were excised bilaterally. The left uterine horn and ovary were fixed in 10% neutral buffered formalin for histological examination, while the right-sided tissues were preserved for biochemical and immunohistochemical analyses, including measurements of malondialdehyde (MDA), superoxide dismutase (SOD), and total antioxidant capacity (TAC) levels.

5. Hormone detection by enzyme-linked immunosorbent assay

Serum samples were obtained by centrifugation at 4,000 rpm for 10 minutes, aliquoted, and stored at −80 °C until analysis. Detection limits for the assays were as follows: estradiol, 8.2 pg/mL; progesterone, 0.105 ng/mL; and testosterone, 0.057 ng/mL (Monobind).

6. Measurement of antioxidant indices

Ovarian and uterine tissues were homogenized in cold phosphate-buffered saline, then centrifuged at 14,000 rpm at 4 °C. The supernatants were collected and stored at −80 °C until further analysis. MDA levels were assessed using a colorimetric assay kit (Teb Pazhohan Razi; 545 nm). SOD activity was measured colorimetrically at 450 nm using TPR’s commercial kit. TAC was quantified using the Kuzansist Azma kit (412 nm, Iran). Protein concentrations were determined via the Bradford assay (TPR).

7. Histology methods

Formalin-fixed uterine and ovarian tissues were dehydrated through a graded ethanol series, embedded in paraffin, and sectioned at a thickness of 5 μm using a rotary microtome (Leitz). Hematoxylin and eosin staining was performed on each section. For morphometric evaluation, three non-consecutive sections per tissue—spaced 50 μm apart—were selected. From each section, five randomly chosen microscopic fields were analyzed using Digimizer software ver. 5.7.0 (Digimizer Image Analysis Software). Histological parameters assessed included epithelial, stromal, and myometrial thickness; number of endometrial glands; and morphology and developmental stages of ovarian follicles (primary, preantral, antral, and atretic), based on established histological criteria.

8. Immunohistochemistry for ERα and Ki-67

Immunohistochemical staining was conducted to evaluate ERα and Ki-67 expression in uterine and ovarian tissues. Paraffin-embedded sections were deparaffinized, rehydrated, and subjected to antigen retrieval according to the protocol of Faghani et al. [7]. Slides were incubated with a rabbit monoclonal anti-mouse Ki-67 antibody (Zytomed) or a rabbit anti-human ER antibody (Vitro Master Diagnostica). Following primary antibody incubation, sections were counterstained with Mayer’s hematoxylin. Positive staining was visualized under a light microscope, and quantitative analysis was performed using Digimizer software. Results were expressed as the percentage of positively stained cells relative to the total number of cells in the analyzed fields.

9. Statistical analyses

Data were expressed as mean±standard error of the mean. The normality of distributions was assessed using the Kolmogorov–Smirnov test. Group comparisons were performed using one-way analysis of variance, followed by Tukey’s post hoc test for multiple comparisons. All statistical analyses were conducted using SPSS software ver. 22.0 (IBM Corp.), with a p<0.05 considered statistically significant.

Results

1. Sex hormones

Nicotine administration significantly decreased serum estradiol (E2) levels compared with the control group (47.97±4.41 pg/mL vs. 28.85±2.47 pg/mL, p<0.05). Treatment with quercetin alone did not significantly alter estradiol levels. However, co-administration of nicotine and quercetin markedly increased serum estradiol compared with the nicotine-only group (28.85±2.47 pg/mL vs. 46.87±4.96 pg/mL, p<0.05). No significant differences in serum progesterone or testosterone levels were observed among the four experimental groups (Figure 1).

Figure 1.

Serum concentrations of (A) estradiol, (B) progesterone, and (C) testosterone in the control, nicotine, quercetin, and nicotine+quercetin groups. Nicotine significantly lowered estradiol, whereas co-administration with quercetin partially restored its level compared with nicotine alone. Data are presented as mean±standard error of the mean (p<0.05; total n=32, n=8/group). ^a)p<0.05.

2. Antioxidant indices

Nicotine exposure significantly elevated MDA concentrations in both uterine (6.41±0.62 µM vs. 12.52±1.59 µM, p<0.05) (Figure 2A) and ovarian tissues (5.61±0.24 µM vs. 11.27±0.93 µM, p=0.001) (Figure 2D) compared with control animals. Co-treatment with quercetin significantly reduced nicotine-induced MDA elevation in both the uterus (12.52±1.59 µM vs. 3.87±0.40 µM, p=0.001) and ovary (11.27±0.93 µM vs. 7.67±0.44 µM, p=0.001). In the uterus, nicotine caused a significant decline in SOD activity (274.50±25.64 U/mg protein vs. 141.31±12.50 U/mg protein, p=0.001) (Figure 2B), which was reversed by co-treatment (141.31±12.50 U/mg protein vs. 300.51±11.53 U/mg protein, p=0.001). A similar pattern was observed in the ovary (Figure 2E), where nicotine-induced reduction in SOD activity was not statistically significant, but co-treatment significantly enhanced activity (188.55±8.95 U/mg protein vs. 265.97±12.23 U/mg protein, p<0.05). TAC also declined in the uterus (337.13±9.21 µM vs. 263.66±9.06 µM, p<0.05) and ovary (327.29±8.15 µM vs. 278.66±0.88 µM, p<0.05) in the nicotine group (Figure 2C, 2F). Co-treatment with quercetin significantly restored TAC levels in both uterine (263.66±9.06 µM vs. 326.97±14.35 µM, p<0.05) and ovarian tissues (278.66±0.88 µM vs. 363.99±14.02 µM, p<0.05).

Figure 2.

(A–F) Oxidative stress markers in uterine and ovarian tissue homogenates. Nicotine increased malondialdehyde (MDA) levels while reducing superoxide dismutase (SOD) activity and total antioxidant capacity (TAC). Co-treatment with quercetin significantly reversed these effects, enhancing antioxidant defenses in both tissues. Data are shown as mean±standard error of the mean (p<0.05, p=0.001; total n=32 animals, n=8/group). ^a)p<0.05; ^b)p=0.001.

3. Histological findings

Histological examination revealed preserved uterine architecture in both the control and quercetin-only groups. Nicotine exposure caused marked thinning of the luminal epithelium, endometrium, and myometrium, as well as a significant reduction in the number of endometrial glands (p<0.05). Co-treatment with quercetin significantly ameliorated these alterations (p=0.001), notably increasing myometrial thickness (102.78±4.3 µm vs. 76.48±5.65 µm, p=0.001) and epithelial thickness (11.37±0.66 µm vs. 8.04±0.62 µm, p=0.001) compared with the nicotine group (Table 1, Figure 3). Ovarian follicle analysis showed that nicotine significantly reduced the number of primary (6.12±0.89 number/microscopic field [n/f] vs. 14.33±2.38 n/f), preantral (8.5±1.26 n/f vs. 15.50±2.12 n/f), and antral follicles (0.87±0.29 n/f vs. 2.50±0.22 n/f) compared with controls (p<0.05). Quercetin alone increased the number of corpus luteum structures and follicles at various developmental stages (p<0.05) and reduced atretic follicles compared with nicotine treatment (11.00±1.11 n/f vs. 17.50±1.22 n/f). Co-treatment partially restored folliculogenesis, reduced follicular atresia (11.00±1.61 n/f vs. 17.50±1.22 n/f), and significantly increased the number of corpus luteum structures (28.14±3.67 n/f vs. 17.87±0.78 n/f, p=0.001), suggesting enhanced ovulatory potential (Table 2, Figure 4).

Table 1.

Uterus histomorphometry in experimental groups (total n=32 animals, n=8 each group)

Figure 3.

(A, B) Uterine histomorphometric parameters showing measurements of epithelial, endometrial, and myometrial thickness, as well as gland density, across experimental groups. Nicotine significantly thinned all layers and reduced gland number. Co-treatment markedly increased epithelial and myometrial thickness, with a non-significant trend toward increased endometrial thickness and gland count. Hematoxylin and eosin staining; magnifications: ×100, ×400 (total n=32, n=8/group). M.L, myometrium; E.L, endometrium; EG, glands; S, stroma; EP, epithelium.

Table 2.

Folliculogenesis in control, nicotine, quercetin and co-treatment of nicotine and quercetin groups (total n=32 animals, n=8 each group)

Figure 4.

Ovarian folliculogenesis across groups: (A) control, (B) nicotine, (C) quercetin, (D) nicotine+quercetin. Nicotine significantly reduced the number of primary, preantral, and antral follicles. Co-treatment decreased follicular atresia and increased antral follicles and corpora lutea compared with nicotine alone. Hematoxylin and eosin staining; magnifications: ×40, ×200, ×400 (total n=32, n=8/group). Asterisks are primordial follicles. CL, corpus luteum; GF, Graafian follicle; A, atretic follicle; PA, preantral follicle; O, Oocyte; PF, primary follicle.

4. ERα index

ERα expression was detected in all uterine compartments, including the luminal epithelium, glands, and stroma, as well as in ovarian stroma and corpus luteum (Figures 5 and 6). Control animals exhibited the highest ERα-positive cell counts and staining intensity. Nicotine markedly reduced ERα expression in the luminal epithelium (79.37%±7.57% vs. 13.74%±6.20%, p=0.001), with co-treatment partially restoring expression (13.74%±6.20% vs. 42.12%±6.68%, p<0.05). Stromal ERα expression also decreased with nicotine (60.49%±4.01% vs. 24.01%±3.50%, p=0.001) but improved with co-treatment (24.01%±3.50% vs. 62.79%±5.40%, p=0.001). In the endometrial glands, nicotine reduced ERα expression to the lowest level among all uterine compartments (78.68%±9.58% vs. 11.82%±4.18%, p=0.001), and this reduction was not significantly reversed by co-treatment.

Figure 5.

Uterine estrogen receptor-alpha (ERα) expression visualized via immunohistochemistry in the epithelium, stroma, and glands. (A) Control, (B) nicotine, (C) quercetin; (D) nicotine+quercetin. Brown staining indicates ERα-positive cells. Nicotine markedly reduced ERα expression across all compartments, while co-treatment significantly restored levels in the epithelium and stroma. Arrows indicate positively stained cells. (E–G) These show quantitative analysis of ERα expression in epithelium, stroma, and endometrial glands. Data are presented as mean±standard error of the mean (p<0.05, p=0.001; total n=32 animals, n=8/group). Sc, stromal cell; G, gland; EP, epithelium. ^a)p<0.05; ^b)p=0.001.

Figure 6.

Ovarian estrogen receptor-alpha (ERα) immunoreactivity in stroma and corpus luteum. (A) Control, (B) nicotine, (C) quercetin, (D) nicotine+quercetin. (A–D) These present representative images; brown staining denotes ERα-positive cells. Nicotine reduced the ERα index in both regions, whereas co-treatment significantly increased expression. (E–F) These provide quantitative analysis. Data are shown as mean±standard error of the mean (p<0.05, p=0.001; total n=32, n=8/group). ^a)p<0.05; ^b)p=0.001.

In the ovary, nicotine decreased ERα in the stroma (47.30%±2.12% vs. 23.77%±6.23%, p<0.05) and corpus luteum (56.96%±4.42% vs. 38.13%±6.22%, p<0.05). Co-treatment significantly restored ERα levels in both the stroma (23.77%±6.23% vs. 59.72%±3.17%, p=0.01) and corpus luteum (38.13%±6.22% vs. 62.80%±2.34%, p<0.05) (Figure 6).

5. Proliferative index (Ki-67)

Ki-67 immunohistochemistry revealed nuclear localization of the marker in all examined tissues (Figures 7 and 8). The control group displayed the highest Ki-67 proliferative index in both uterine and ovarian compartments. Nicotine significantly reduced the Ki-67 index in the uterine luminal epithelium (49.63%±10.37% vs. 7.41%±3.61%, p<0.05), stroma (61.18%±4.51% vs. 38.87%±4.38%, p<0.05), and glands (32.53%±1.96% vs. 13.22%±0.87%, p<0.05). Co-treatment slightly improved these indices relative to the nicotine group.

Figure 7.

Immunohistochemical detection of Ki-67 as a proliferation marker in the uterus. (A) Control, (B) nicotine, (C) quercetin, (D) nicotine+quercetin. Brown-stained nuclei indicate Ki-67-positive cells in epithelium, stroma, and glands. Nicotine reduced Ki-67 expression across all regions; no significant recovery was seen with co-treatment. Arrows indicate positive cells. (E–G) These provide quantitative data. Data expressed as mean±standard error of the mean (p<0.05, p=0.001; total n=32, n=8/group). Sc, stromal cell; EP, epithelium; G, gland. ^a)p<0.05; ^b)p=0.001.

Figure 8.

Ovarian Ki-67 expression assessed via immunohistochemistry. (A) Control, (B) nicotine, (C) quercetin, (D) nicotine+quercetin. Brown staining denotes Ki-67-positive cells in follicles, stroma, and corpus luteum. Nicotine significantly decreased Ki-67 levels in stroma and corpus luteum; co-treatment further reduced expression in follicles and stroma. (E–G) There present quantitative data. Data shown as mean±standard error of the mean (p<0.05, p=0.001; magnification: ×260; total n=32, n=8/group). O, oocyte; GL, granulosa layer; PA, preantral follicle; SC, stromal cell; BV, blood vessel; CL, corpus luteum; P, primary follicle; AF, atretic follicle; SF, secondary/antral follicle. ^a)p<0.05; ^b)p=0.001.

In ovarian tissue, nicotine reduced Ki-67 expression in stromal cells (25.86%±1.25% vs. 20.43%±0.60%, p<0.05) and corpus luteum (30.96%±1.22% vs. 17.08%±2.38%, p=0.001). Co-treatment further decreased Ki-67-positive cells in follicles (24.72%±1.55% vs. 12.82%±0.34%, p=0.001) and stroma (20.43%±0.60% vs. 7.61%±0.63%, p=0.001) compared with nicotine alone (Figure 8).

Discussion

This study demonstrated the protective role of quercetin against nicotine-induced alterations in the rat uterine endometrium and ovary, primarily through modulation of serum estradiol levels, ERα expression, oxidative stress markers, and cell proliferation indices—all of which are critical to reproductive function. These findings reinforce the concept that quercetin can mitigate the reproductive toxicity associated with nicotine exposure.

The endometrium, a hormonally responsive tissue, undergoes cyclic regeneration under the influence of estrogen, which is essential for implantation and successful pregnancy outcomes [33]. Similarly, the ovary plays a central role in steroidogenesis and gametogenesis, making it particularly susceptible to oxidative and cytotoxic insults [34].

Nicotine is known to disrupt steroidogenesis, primarily by inhibiting aromatase enzyme activity in various tissues, including the ovary and adipose tissue [35]. This enzymatic blockade likely accounts for the significant reduction in serum estradiol observed in our nicotine-treated group, a finding consistent with earlier studies [36]. The normalization of estradiol levels following co-treatment with quercetin aligns with previous reports showing that quercetin can counteract estrogen depletion induced by nicotine or heavy metals such as cadmium [25,37].

Nicotine exposure has also been linked to enhanced ovarian cell apoptosis, contributing to hormonal dysregulation [38]. In contrast, quercetin appears to exert anti-apoptotic effects, particularly by protecting granulosa cells and enhancing their responsiveness to gonadotropins [37]. These protective effects may be mediated through quercetin’s ability to modulate genes involved in apoptotic pathways, including downregulation of pro-apoptotic markers such as BCL2 associated X, apoptosis regulator (BAX) and caspase-3, and upregulation of anti-apoptotic proteins such as BCL2 [39].

Oxidative stress is a major mechanism through which nicotine exerts reproductive toxicity. In the present study, nicotine significantly elevated MDA levels—a marker of lipid peroxidation—while reducing the activity of endogenous antioxidants such as SOD and TAC. These findings are consistent with prior evidence showing that nicotine increases reactive oxygen species production while impairing antioxidant defense systems [40,41]. An oxidative microenvironment not only compromises ovarian function but can also impair endometrial receptivity and embryonic development.

Quercetin effectively restored antioxidant balance by increasing SOD activity and TAC while reducing MDA accumulation. This effect is likely attributable to quercetin’s well-known free radical-scavenging, metal-chelating, and membrane-stabilizing properties [42]. Such antioxidant actions are essential for maintaining redox homeostasis in reproductive tissues.

Nicotine-induced thinning of the luminal epithelium, endometrium, and myometrium, along with a decrease in the number of endometrial glands, is consistent with previous studies [43,44]. These alterations may result from estrogen deficiency as well as direct cytotoxic effects of nicotine metabolites [45]. The restoration of uterine histoarchitecture in the quercetin-treated group supports its estrogen-like protective effects, which have also been reported in chemotherapy-induced uterine injury models [46,47]. An increase in corpus luteum formation—an indicator of ovulation—was observed with quercetin treatment, either alone or in combination with nicotine. This suggests effective restoration of folliculogenesis in the co-treated group. Similarly, ginseng, another phytoestrogen, enhances follicular development and ovulation by modulating the HPG axis, stimulating proliferation of ovarian somatic cells, decreasing lipid peroxidation, and downregulating apoptotic pathways in the ovaries of nicotine-exposed mice [7]. In a rat model of polycystic ovary syndrome, quercetin has been shown to improve ovulatory dysfunction by lowering testosterone, estradiol, and luteinizing hormone levels, and by suppressing ovarian androgen receptor expression through downregulation of pro-inflammatory and apoptotic markers such as Bax, interleukin (IL)-1β, IL-6, and tumor necrosis factor-alpha [48]. In the present study, combined nicotine–quercetin treatment reduced the number of atretic follicles. This effect parallels findings with genistein, a phytoestrogen known for its strong affinity for ERs, which protects ovarian follicles from radiotherapy-induced damage, promotes the development of primordial, preantral, and antral follicles, and decreases atretic follicle numbers by inhibiting apoptosis and enhancing ER expression [49].

ERα is essential for uterine development and function [50], and its downregulation by nicotine disrupts estrogen signaling [2,14]. Nicotine and its metabolites, such as cotinine, competitively bind to ERs, interfering with hormone–receptor interactions and transcription [51]. The ability of quercetin to restore ERα expression likely derives from its phytoestrogenic properties. Phytoestrogens can act as either agonists or antagonists depending on tissue type, local estrogen concentration, and receptor distribution [52,53]. ERα and ERβ are differentially distributed across reproductive tissues, which may explain the variable responses to quercetin. Additionally, quercetin can influence multiple signaling pathways—including mitogen-activated protein kinase (MAPK), phosphoinositide 3-kinase (PI3K)/protein kinase B (AKT), and Janus kinase (JAK)/signal transducer and activator of transcription (STAT)—that regulate proliferation, differentiation, and apoptosis [21].

Nicotine’s suppression of Ki-67 expression suggests impaired cell proliferation, possibly mediated by nitric oxide pathways [17]. In our findings, quercetin further reduced Ki-67 indices in some compartments, especially at the low dose administered. This aligns with previous studies reporting that quercetin exhibits anti-proliferative or anti-estrogenic effects at lower concentrations [26,54]. Mechanistically, quercetin’s anti-proliferative activity may involve induction of cell cycle arrest at the S or G2/M phases, inhibition of cyclin-dependent kinases via MAPK or STAT signaling, and selective modulation of estrogen-responsive genes through structural interactions with nuclear receptors [55-57]. Importantly, quercetin demonstrates biphasic, dose-dependent effects: at higher doses, it may act as an estrogen agonist, whereas at lower doses, anti-estrogenic actions predominate [26,58]. This dual nature may explain its paradoxical influence on proliferation and receptor activity.

In conclusion, the present findings suggest that quercetin can attenuate the adverse reproductive effects of nicotine through modulation of oxidative stress, estradiol levels, and the expression of ERα and Ki-67 in uterine and ovarian tissues. However, while these results are promising, further studies—particularly clinical trials—are needed to confirm the therapeutic potential and safety of quercetin in mitigating nicotine-induced reproductive dysfunction.

While these findings are promising, several limitations should be noted. Rodent models, though informative, do not fully replicate human reproductive physiology, particularly in terms of estrogen receptor dynamics and hormonal regulation. Furthermore, the experimental exposure duration and dosing may not fully represent the complex patterns of long-term nicotine use or environmental exposure in humans.

Notes

Conflict of interest

No potential conflict of interest relevant to this article was reported.

Acknowledgments

We gratefully acknowledge all the research participants and Guilan University of Medical Sciences Research Affair for their support.

Author contributions

Conceptualization: FM. Methodology: ES, PK, AR. Formal analysis: ES. Data curation: ES, FM. Funding acquisition: FM. Project administration: FM. Visualization: ES, FM. Software: ES, FM. Validation: ES, FM. Investigation: ES, FM. Supervision: FM. Writing-original draft: ES, MF, PK, AR, FM. Writing-review & editing: ES, MF, PK, AR, FM. Approval of final manuscript: ES, MF, PK, AR, FM.

References

1. Harlev A, Agarwal A, Gunes SO, Shetty A, du Plessis SS. Smoking and male infertility: an evidence-based review. World J Mens Health 2015;33:143–60. 10.5534/wjmh.2015.33.3.143. 26770934.

2. Saadat SN, Mohammadghasemi F, Jahromi SK, Homafar MA, Haghiri M. Melatonin protects uterus and oviduct exposed to nicotine in mice. Interdiscip Toxicol 2014;7:41–6. 10.2478/intox-2014-0007. 26038675.

3. Peng-Fei H, A-Ru Na, Hui C, Hong-Yu W, Jin-Shan C. Activation of alpha7 nicotinic acetylcholine receptor protects bovine endometrial tissue against LPS-induced inflammatory injury via JAK2/STAT3 pathway and COX-2 derived prostaglandin E2. Eur J Pharmacol 2021;900:174067. 10.1016/j.ejphar.2021.174067. 33811838.

4. Taylor E, Gomel V. The uterus and fertility. Fertil Steril 2008;89:1–16. 10.1016/j.fertnstert.2007.09.069. 18155200.

5. Laldinsangi C. Toxic effects of smokeless tobacco on female reproductive health: a review. Curr Res Toxicol 2022;3:100066. 10.1016/j.crtox.2022.100066. 35310558.

6. Mohammadghasemi F, Jahromi SK. Melatonin ameliorates testicular damages induced by nicotine in mice. Iran J Basic Med Sci 2018;21:639–44. 29942456.

7. Faghani M, Saedi S, Khanaki K, Mohammadghasemi F. Ginseng alleviates folliculogenesis disorders via induction of cell proliferation and downregulation of apoptotic markers in nicotine-treated mice. J Ovarian Res 2022;15:14. 10.1186/s13048-022-00945-x. 35067219.

8. Mohammadghasemi F, Khanaki K, Moravati H, Faghani M. The amelioration of nicotine-induced reproductive impairment in male mouse by Sambucus ebulus L. fruit extract. Anat Cell Biol 2021;54:232–40. 10.5115/acb.20.161. 33597315.

9. Sanders SR, Cuneo SP, Turzillo AM. Effects of nicotine and cotinine on bovine theca interna and granulosa cells. Reprod Toxicol 2002;16:795–800. 10.1016/s0890-6238(02)00049-7. 12401508.

10. Sobinoff AP, Beckett EL, Jarnicki AG, Sutherland JM, McCluskey A, Hansbro PM, et al. Scrambled and fried: cigarette smoke exposure causes antral follicle destruction and oocyte dysfunction through oxidative stress. Toxicol Appl Pharmacol 2013;271:156–67. 10.1016/j.taap.2013.05.009. 23693141.

11. Van Voorhis BJ, Syrop CH, Hammitt DG, Dunn MS, Snyder GD. Effects of smoking on ovulation induction for assisted reproductive techniques. Fertil Steril 1992;58:981–5. 10.1016/s0015-0282(16)55446-6. 1426386.

12. Martin MB, Reiter R, Johnson M, Shah MS, Iann MC, Singh B, et al. Effects of tobacco smoke condensate on estrogen receptor-alpha gene expression and activity. Endocrinology 2007;148:4676–86. 17640996.

13. Corbo RM, Ulizzi L, Piombo L, Martinez-Labarga C, De Stefano GF, Scacchi R. Estrogen receptor alpha polymorphisms and fertility in populations with different reproductive patterns. Mol Hum Reprod 2007;13:537–40. 10.1093/molehr/gam041. 17556378.

14. Totonchi H, Miladpour B, Mostafavi-Pour Z, Khademi F, Kasraeian M, Zal F. Quantitative analysis of expression level of estrogen and progesterone receptors and VEGF genes in human endometrial stromal cells after treatment with nicotine. Toxicol Mech Methods 2016;26:595–600. 10.1080/15376516.2016.1218578. 27552315.

15. Laurent SL, Thompson SJ, Addy C, Garrison CZ, Moore EE. An epidemiologic study of smoking and primary infertility in women. Fertil Steril 1992;57:565–72. 10.1016/s0015-0282(16)54901-2. 1740199.

16. Al-Zoughool M, Dossus L, Kaaks R, Clavel-Chapelon F, Tjonneland A, Olsen A, et al. Risk of endometrial cancer in relationship to cigarette smoking: results from the EPIC study. Int J Cancer 2007;121:2741–7. 10.1002/ijc.22990. 17657712.

17. Khorram O, Han G, Magee T. Cigarette smoke inhibits endometrial epithelial cell proliferation through a nitric oxide-mediated pathway. Fertil Steril 2010;93:257–63. 10.1016/j.fertnstert.2008.09.074. 19022425.

18. Baron JA. Beneficial effects of nicotine and cigarette smoking: the real, the possible and the spurious. Br Med Bull 1996;52:58–73. 10.1093/oxfordjournals.bmb.a011533. 8746297.

19. Miksicek RJ. Commonly occurring plant flavonoids have estrogenic activity. Mol Pharmacol 1993;44:37–43. 10.1016/s0026-895x(25)13162-3. 8341277.

20. Jahan S, Abid A, Khalid S, Afsar T, Qurat-Ul Ain, Shaheen G, et al. Therapeutic potentials of Quercetin in management of polycystic ovarian syndrome using Letrozole induced rat model: a histological and a biochemical study. J Ovarian Res 2018;11:26. 10.1186/s13048-018-0400-5. 29615083.

21. Jian X, Shi C, Luo W, Zhou L, Jiang L, Liu K. Therapeutic effects and molecular mechanisms of quercetin in gynecological disorders. Biomed Pharmacother 2024;173:116418. 10.1016/j.biopha.2024.116418. 38461683.

22. Mihanfar A, Nouri M, Roshangar L, Khadem-Ansari MH. Therapeutic potential of quercetin in an animal model of PCOS: possible involvement of AMPK/SIRT-1 axis. Eur J Pharmacol 2021;900:174062. 10.1016/j.ejphar.2021.174062. 33798596.

23. Wang J, Qian X, Gao Q, Lv C, Xu J, Jin H, et al. Quercetin increases the antioxidant capacity of the ovary in menopausal rats and in ovarian granulosa cell culture in vitro. J Ovarian Res 2018;11:51. 10.1186/s13048-018-0421-0. 29929541.

24. Naseer Z, Ahmad E, Epikmen ET, Ucan U, Boyacioglu M, Ipek E, et al. Quercetin supplemented diet improves follicular development, oocyte quality, and reduces ovarian apoptosis in rabbits during summer heat stress. Theriogenology 2017;96:136–41. 10.1016/j.theriogenology.2017.03.029. 28532829.

25. Ola D, Adeyemi DH, Obembe OO, Ogooluwa AA, Ladele MO, Owonikoko ST, et al. Nicotine exacerbates reproductive biomarkers via generation of free radicals in female Wistar rats: Protective role of Quercetin. Res J Health Sci 2021;9:378–88. 10.4314/rejhs.v9i4.6.

26. Shahzad H, Giribabu N, Sekaran M, Salleh N. Quercetin induces dose-dependent differential morphological and proliferative changes in rat uteri in the presence and in the absence of estrogen. J Med Food 2015;18:1307–16. 10.1089/jmf.2014.3293. 26135605.

27. Jeong JH, An JY, Kwon YT, Rhee JG, Lee YJ. Effects of low dose quercetin: cancer cell-specific inhibition of cell cycle progression. J Cell Biochem 2009;106:73–82. 10.1002/jcb.21977. 19009557.

28. Bordel R, Laschke MW, Menger MD, Vollmar B. Nicotine does not affect vascularization but inhibits growth of freely transplanted ovarian follicles by inducing granulosa cell apoptosis. Hum Reprod 2006;21:610–7. 10.1093/humrep/dei393. 16311296.

29. Slighoua M, Amrati FE, Chebaibi M, Mahdi I, Al Kamaly O, El Ouahdani K, et al. Quercetin and ferulic acid elicit estrogenic activities in vivo and in silico. Molecules 2023;28:5112. 10.3390/molecules28135112. 37446770.

30. Algandaby MM. Quercetin attenuates cisplatin-induced ovarian toxicity in rats: Emphasis on anti-oxidant, anti-inflammatory and anti-apoptotic activities. Arab J Chem 2021;14:103191. 10.1016/j.arabjc.2021.103191.

31. Ajayi AF, Akhigbe RE. Staging of the estrous cycle and induction of estrus in experimental rodents: an update. Fertil Res Pract 2020;6:5. 10.1186/s40738-020-00074-3. 32190339.

32. Marcondes FK, Bianchi FJ, Tanno AP. Determination of the estrous cycle phases of rats: some helpful considerations. Braz J Biol 2002;62:609–14. 10.1590/s1519-69842002000400008. 12659010.

33. Vallve-Juanico J, Giudice LC. Immune phenotypes and mediators affecting endometrial function in women with endometriosis. In : Kaga K, ed. Immunology of endometriosis Elsevier; 2022. p. 169–91.

34. Rashidi Z, Khosravizadeh Z, Talebi A, Khodamoradi K, Ebrahimi R, Amidi F. Overview of biological effects of Quercetin on ovary. Phytother Res 2021;35:33–49. 10.1002/ptr.6750. 32557927.

35. Barbieri RL, McShane PM, Ryan KJ. Constituents of cigarette smoke inhibit human granulosa cell aromatase. Fertil Steril 1986;46:232–6. 10.1016/s0015-0282(16)49517-8. 3732529.

36. Mohammadghasemi F, Jahromi SK, Hajizadeh H, Homafar MA, Saadat N. The protective effects of exogenous melatonin on nicotine-induced changes in mouse ovarian follicles. J Reprod Infertil 2012;13:143–50. 23926539.

37. Nna VU, Usman UZ, Ofutet EO, Owu DU. Quercetin exerts preventive, ameliorative and prophylactic effects on cadmium chloride: induced oxidative stress in the uterus and ovaries of female Wistar rats. Food Chem Toxicol 2017;102:143–55. 10.1016/j.fct.2017.02.010. 28229914.

38. Valavanidis A, Vlachogianni T, Fiotakis K. Tobacco smoke: involvement of reactive oxygen species and stable free radicals in mechanisms of oxidative damage, carcinogenesis and synergistic effects with other respirable particles. Int J Environ Res Public Health 2009;6:445–62. 10.3390/ijerph6020445. 19440393.

39. Jia Y, Lin J, Mi Y, Zhang C. Quercetin attenuates cadmium-induced oxidative damage and apoptosis in granulosa cells from chicken ovarian follicles. Reprod Toxicol 2011;31:477–85. 10.1016/j.reprotox.2010.12.057. 21262342.

40. Khademi F, Totonchi H, Mohammadi N, Zare R, Zal F. Nicotine-induced oxidative stress in human primary endometrial cells. Int J Toxicol 2019;38:202–8. 10.1177/1091581819848081. 31113282.

41. Al-Gubory KH, Fowler PA, Garrel C. The roles of cellular reactive oxygen species, oxidative stress and antioxidants in pregnancy outcomes. Int J Biochem Cell Biol 2010;42:1634–50. 10.1016/j.biocel.2010.06.001. 20601089.

42. Moridani MY, Pourahmad J, Bui H, Siraki A, O'Brien PJ. Dietary flavonoid iron complexes as cytoprotective superoxide radical scavengers. Free Radic Biol Med 2003;34:243–53. 10.1016/s0891-5849(02)01241-8. 12521606.

43. El-Meligy M, Abdel Samaei A, Abdel Hady R, Saad Eldien H. Effect of nicotine injection and its stoppage on reproduction in female rats. Egypt J Anat 2010;33:1–23. 10.21608/ejana.2010.3638.

44. Patil S, Patil S, Bhaktaraj B, Patil SB. Effect of graded doses of nicotine on ovarian and uterine activities in albino rats. Indian J Exp Biol 1999;37:184–6. 10641142.

45. Bao H, Vepakomma M, Sarkar MA. Benzo(a)pyrene exposure induces CYP1A1 activity and expression in human endometrial cells. J Steroid Biochem Mol Biol 2002;81:37–45. 10.1016/s0960-0760(02)00045-6. 12127040.

46. Samare-Najaf M, Zal F, Safari S, Koohpeyma F, Jamali N. Stereological and histopathological evaluation of doxorubicin-induced toxicity in female rats' ovary and uterus and palliative effects of quercetin and vitamin E. Hum Exp Toxicol 2020;39:1710–24. 10.1177/0960327120937329. 32666839.

47. Vaskova J, Klepcova Z, Spakova I, Urdzik P, Stofilova J, Bertkova I, et al. The importance of natural antioxidants in female reproduction. Antioxidants (Basel) 2023;12:907. 10.3390/antiox12040907. 37107282.

48. Zheng S, Chen Y, Ma M, Li M. Mechanism of quercetin on the improvement of ovulation disorder and regulation of ovarian CNP/NPR2 in PCOS model rats. J Formos Med Assoc 2022;121:1081–92. 10.1016/j.jfma.2021.08.015. 34538551.

49. Haddad YH, Said RS, Kamel R, Morsy EM, El-Demerdash E. Phytoestrogen genistein hinders ovarian oxidative damage and apoptotic cell death-induced by ionizing radiation: co-operative role of ER-β, TGF-β, and FOXL-2. Sci Rep 2020;10:13551. 10.1038/s41598-020-70309-2. 32782329.

50. Pelletier G, El-Alfy M. Immunocytochemical localization of estrogen receptors alpha and beta in the human reproductive organs. J Clin Endocrinol Metab 2000;85:4835–40. 11134151.

51. Rehan M, Ahmad E, Beg MA. Structural binding perspectives of a major tobacco alkaloid, nicotine, and its metabolite cotinine with sex-steroid nuclear receptors. J Appl Toxicol 2020;40:1410–20. 10.1002/jat.3993. 32346888.

52. Cao Y, Zhuang MF, Yang Y, Xie SW, Cui JG, Cao L, et al. Preliminary study of quercetin affecting the hypothalamic-pituitary-gonadal axis on rat endometriosis model. Evid Based Complement Alternat Med 2014;2014:781684. 10.1155/2014/781684. 25530789.

53. Chakravarthi VP, Ratri A, Masumi S, Borosha S, Ghosh S, Christenson LK, et al. Granulosa cell genes that regulate ovarian follicle development beyond the antral stage: the role of estrogen receptor β. Mol Cell Endocrinol 2021;528:111212. 10.1016/j.mce.2021.111212. 33676987.

54. Sirotkin AV, Stochmalova A, Alexa R, Kadasi A, Bauer M, Grossmann R, et al. Quercetin directly inhibits basal ovarian cell functions and their response to the stimulatory action of FSH. Eur J Pharmacol 2019;860:172560. 10.1016/j.ejphar.2019.172560. 31344364.

55. Kedhari Sundaram M, Raina R, Afroze N, Bajbouj K, Hamad M, Haque S, et al. Quercetin modulates signaling pathways and induces apoptosis in cervical cancer cells. Biosci Rep 2019;39:BSR20190720. 31366565.

56. Luo CL, Liu YQ, Wang P, Song CH, Wang KJ, Dai LP, et al. The effect of quercetin nanoparticle on cervical cancer progression by inducing apoptosis, autophagy and anti-proliferation via JAK2 suppression. Biomed Pharmacother 2016;82:595–605. 10.1016/j.biopha.2016.05.029. 27470402.

57. Michala AS, Pritsa A. Quercetin: a molecule of great biochemical and clinical value and its beneficial effect on diabetes and cancer. Diseases 2022;10:37. 10.3390/diseases10030037. 35892731.

58. Maggiolini M, Bonofiglio D, Marsico S, Panno ML, Cenni B, Picard D, et al. Estrogen receptor alpha mediates the proliferative but not the cytotoxic dose-dependent effects of two major phytoestrogens on human breast cancer cells. Mol Pharmacol 2001;60:595–602. 11502892.

Article information Continued

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (https://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Parameter	Control	Nicotine	Quercetin	Nicotine+Quercetin
Endometrium thickness (µm)	130.21±15.50^b),c)	80.81±6.33^a),c)	121.26±8.38^b),c)	112.09±3.61
Myometrium thickness (µm)	104.84±11.92^b),c)	76.48±5.65^a),c)	102.83±4.99^b),c)	102.78±4.31^b),c)
Epithelium thickness (µm)	12.24±1.02^b),c)	8.04±0.62^a),c)	10.93±0.63^b),c)	11.37±0.66 b^b),c)
Endometrial glands (n)	95.16±14.96^b),c)	39.37±5.79^a),c)	91.00±19.66	77.42±14.21

Parameter	Control	Nicotine	Quercetin	Nicotine+Quercetin
Primordial follicles (n/f)	13/50±2/84	5/87±1/82	19/14±3/06^b),c)	11/00±3/13
Primary follicles (n/f)	14/33±2/38^b),c)	6/12±0/89^a,c)	17/28±2/85^b),c)	7/85±1/50
Preantral follicles (n/f)	15/50±2/12^b),c)	8/50±1/26^a,c)	15/14±1/73^b),c)	10/14±1/10
Antral follicles (n/f)	2/50±0/22^b),c)	0/87±0/29^a,c)	2/57±0/57^b),c)	2/42±0/20^b),c)
Atretic follicles (n/f)	13/33±2/44	17/50±1/22	11/00±1/11^b),c)	11/00±1/61^b),c)
Corpus luteum (n/f)	19/16±2/46	17/87±0/78	31/42±3/25^a),b),c)	28/14±3/67^b),c)