Search Results (2,108)

The biodiversity of marine and coastal ecosystems is constantly threatened by pollutants from a diversity of human activities. The polycyclic aromatic hydrocarbons (PAHs) are a class of pollutants widely released and deposited in these environments, leading to several impacts on the community of organisms that integrate these ecosystems. As lipophilic compounds, PAHs become bioavailable to organisms and can enter the trophic chain, leading to physiological changes and affecting different levels of biological organization. Several studies demonstrate that PAHs act as endocrine disruptors in marine fish, interfering with endocrine signaling through hormonal disturbances and, consequently, causing inhibition or overexpression of genes, enzymes, and proteins that are essential for reproduction success. These changes, in turn, can lead to population decline and cause immeasurable ecosystem damage. This review synthesizes studies published mainly between 2015 and 2025, aiming to critically present research that identifies different endocrine-reproductive changes in marine fish species exposed to PAHs in contaminated sites, highlighting the involved cellular mechanisms. Finally, we provide a survey of patents developed to identify PAHs in aquatic environments and how these techniques can be used in marine biomonitoring to evaluate water quality and the risk of exposure to biota and human populations. Full article

Lead (Pb) is a naturally occurring metal that is environmentally ubiquitous due to industrial activities, such as mining, smelting, and fossil fuel combustion. Exposure to Pb adversely affects the central nervous system, gastrointestinal tract, lungs, liver, bones, and cardiovascular system, leading to a multitude of negative health impacts, such as anemia and neurological disorders. While significant research has focused on the effects of Pb on the nervous and immune systems, Pb’s impact as a reproductive endocrine disruptor remains largely understudied. The first objective of this review was to collate the current literature regarding the effects of Pb on the reproductive system of aquatic species (primarily fish) and agricultural livestock to highlight the ecological significance and impacts on animal health. Literature supports the hypothesis that exposure to Pb can impede reproductive processes by affecting hormone levels, reproductive organ development, and fertility. A second objective of this review was to elucidate putative mechanisms underlying Pb as a reproductive endocrine disruptor using molecular data and computational approaches. Based on transcriptomics data, Pb is hypothesized to perturb key pathways important for hypothalamic–pituitary–gonadal axis functions, such as circadian regulation and estrogen receptor signaling. Given the widespread environmental presence of Pb, understanding these mechanisms is essential for improving risk assessments and protecting animal reproductive health. Full article

Porcine Teschovirus (PTV) is a highly prevalent pathogen within swine populations, primarily associated with encephalitis, diarrhea, pneumonia, and reproductive disorders in pigs, thereby posing a significant threat to the sustainable development of the pig farming industry. In this study, a novel strain of PTV was isolated from the feces of a pig exhibiting symptoms of diarrhea, utilizing PK-15 cell lines. The structural integrity of the viral particles was confirmed via transmission electron microscopy, and the viral growth kinetics and characteristics were evaluated in PK-15 cells. High-throughput sequencing facilitated the acquisition of the complete viral genome, and subsequent phylogenetic analysis and full-genome alignment identified the strain as belonging to the PTV 2 genotype. Further investigation revealed that infection with the PTV-GXLZ2024 strain induces phosphorylation of the eukaryotic translation initiation factor 2α (eIF2α) in PK-15 cells, indicating activation of the unfolded protein response (UPR) through the PERK pathway, with minimal involvement of the IRE1 or ATF6 pathways. Notably, ATF4 protein expression was progressively downregulated throughout the infection, while downstream CHOP protein levels remained unchanged, indicating an incomplete UPR induced by PTV-GXLZ2024. Furthermore, PERK knockdown was found to enhance the replication of PTV-GXLZ2024. This study provides critical insights into the molecular mechanisms underlying PTV pathogenesis and establishes a foundation for future research into its evolutionary dynamics and interactions with host organisms. Full article

Under refined management, high-yield cotton fields are approaching their maximum output. However, how to break this yield upper limit, specifically the source–sink relationship is still inadequately researched. This experiment was conducted to explore the interaction mechanism between yield formation and source–sink parameters (photosynthesis, nitrogen content, canopy structure and dry matter accumulation and distribution). The treatments consisted of a no cutting source and sink treatment (CK), cutting 1/2 leaves per plant (1/2L) and cutting 1/2 bolls per plant (1/2B) at the initial flowering stage (IFS), the flower and boll stage (FABS), and the full boll stage (FBS). The results showed that 1/2L treatment minimized yield losses to 2.3–5.9% by enhancing photosynthetic compensation, with FBS-1/2L showing the smallest reduction (2.3–2.9%) due to higher leaf N content and SPAD values, whereas, the 1/2B treatments resulted in significant yield losses attributable to fewer bolls, especially the FBS-1/2B treatments, which reduced yields by 35.7–41.9%, with a compensatory rate of only 8.1–14.3%. It is noteworthy that the compensation rates of IFS-1/2B and FABS-1/2B could reach 26.7–32.3% and 18.7–23.8% of their yields due to the higher leaf N content. In a word, the source damage can be buffered by physiological compensation, while the sink loss leads to yield collapse due to the irreversibility of reproductive development. Thus, the core regulator of high-yield cotton fields was sink strength. Accordingly, optimizing the sink quality was performed through moderate boll thinning at the IFS, enhancing water and fertilizer supply at the FABS and strengthening sink organ protection at the FBS in order to realize a breakthrough in yield limit. Full article

In this study, oyster fermentation broth (OFB) was prepared by fermenting oysters with yeast, and its effects on oxidative stress and reproductive damage induced by tripterygium glycosides (TG) in male rats were investigated. Component analysis revealed that OFB contained bioactive substances including proteins (1.19 g/L), taurine (0.76 g/L), organic acids (2.30 mg/mL), polyphenols (123.00 mg GAE/L), flavonoids (1.97 mg RE/L), and zinc (1.10 mg/L). In vitro study revealed that OFB exhibited notable antioxidant activity, with a total antioxidant capacity of 1.28 U/mL, and DPPH, ABTS, and hydroxyl radical scavenging rates of 55.80%, 69.54%, and 48.36%, respectively. Animal experiments showed that, compared with the TG-induced model group, rats administered both low-dose (5 mL/kg) and high-dose (10 mL/kg) OFB showed significantly increased testis and seminal vesicle + prostate indices, sperm count, and serum testosterone (T) levels and decreased sperm malformation rate (p < 0.01 for all). Histological analysis of the testis revealed an increased number of spermatogenic cells and sperm within the seminiferous tubules, along with ameliorated pathological conditions compared to the model group. Potential mechanisms might be related to OFB increasing the activities of catalase (CAT), superoxide dismutase (SOD), and glutathione peroxidase (GSH-PX) enzymes and reducing levels of malondialdehyde (MDA) in testis (p < 0.01). The findings demonstrated that OFB successfully alleviated TG-induced reproductive damage in male rats, which might be attributed to its excellent antioxidant effect. The study offers valuable insights for producing functional foods from oysters and further validates OFB’s efficacy in promoting reproductive function. Full article

A novel skin test for an in vivo assessment of SARS-CoV-2-specific T-cell immunity was developed using CoronaDermPS, a multiepitope recombinant polypeptide encompassing MHC II–binding CD4+ T-cell epitopes of the SARS-CoV-2 structural proteins (S, E, M) and full length nucleocapsid (N). In silico epitope prediction and modeling guided antigen design, which was expressed in Escherichia coli, was purified (>95% purity) and formulated for intradermal administration. Preclinical evaluation in guinea pigs, mice, and rhesus macaques demonstrated a robust delayed type hypersensitivity (DTH) response at optimal doses (10–75 µg), with no acute or chronic toxicity, mutagenicity, or adverse effects on reproductive organs. An integrated clinical analysis included 374 volunteers stratified by vaccination status (EpiVacCorona, Gam-COVID-Vac, CoviVac) prior to COVID-19 infection (Wuhan/Alpha, Delta, Omicron variants), and SARS-CoV-2–naïve controls. Safety assessments across phase I–II trials recorded 477 adverse events, of which >88% were mild and self-limiting; no severe or anaphylactic reactions occurred. DTH responses were measured at 24 h, 72 h, and 144 h post-injection by papule and hyperemia measurements. Overall, 282/374 participants (75.4%) exhibited a positive skin test. Receiver operating characteristic analysis yielded an overall AUC of 0.825 (95% CI: 0.726–0.924), sensitivity 79.5% (95% CI: 75.1–83.3%), and specificity 85.5% (95% CI: 81.8–88.7%), with comparable diagnostic accuracy across vaccine, and variant subgroups (AUC range 0.782–0.870). CoronaDerm-PS–based skin testing offers a simple, reproducible, and low-cost method for qualitative evaluation of T-cell–mediated immunity to SARS-CoV-2, independent of specialized laboratory equipment (Eurasian Patent No. 047119). Its high safety profile and consistent performance across diverse cohorts support its utility for mass screening and monitoring of cellular immune protection following infection or vaccination. Full article

Dromedary camels raised under semi-extensive management can act as One Health sentinels for environmental exposures and food chain surveillance, yet serum reference information remains scarce. Our objective was to provide the most comprehensive assessment to date of physiological and toxicological serum profiles in dromedary camels (Camelus dromedarius) from the Canary Islands. We included 114 clinically healthy animals of different sex, age, and reproductive status. Serum samples were analyzed for essential, toxic, and potentially toxic elements using inductively coupled plasma mass spectrometry (ICP-MS). In addition, a high-throughput multi-residue method based on QuEChERS extraction followed by UHPLC-MS/MS and GC-MS/MS was used to screen for 360 organic compounds, including pesticides, veterinary drugs, human pharmaceuticals, and persistent organic pollutants. Essential elements showed biologically consistent variations according to sex, age group, and pregnancy status. Males had higher levels of selenium and copper, while calves showed elevated concentrations of manganese and zinc. Pregnant females exhibited lower iron, zinc, and selenium levels, consistent with increased fetal demand. These results provide preliminary reference values for healthy camels, stratified by physiological status. In contrast, classical toxic elements such as arsenic, mercury, lead, and cadmium were found at very low or undetectable concentrations. Several potentially toxic elements, including barium, strontium, and rare earth elements, were detected sporadically but without toxicological concern. Only 13 organic compounds (3.6%) were detected in any sample, and concentrations were consistently low. The most prevalent was the PAH acenaphthene (55.3%), followed by the fungicide procymidone and the PAH fluorene. Notably, no residues of the usually detected 4,4′-DDE or PCB congeners were found in any sample. These findings confirm the low environmental and dietary exposure of camels under low-intensity farming systems and highlight their value as sentinel species for food safety and environmental monitoring. Full article

Sexual behavior is a complex process in which the brain plays an active role. In the male rat, stimuli from the female are perceived through sensory receptors related to olfaction, hearing, vision, and the perigenital area, priming the individual for a sexual response. This process culminates with ejaculation and the deposition of semen into the uterine tract with the aim of achieving fertilization. The brain plays a fundamental role in both generating motivation and executing male sexual behavior. Meanwhile, the spinal cord, through the autonomic nervous system and the pelvic ganglion, transmits information to the reproductive organs, including the testes. Currently, there is extensive evidence demonstrating the involvement of various brain structures in the regulation of sexual behavior, as well as specific regions of the spinal cord involved in the control of ejaculation. For instance, the medial preoptic area (MPOA) has been shown to regulate the secretion of pituitary hormones, which in turn modulate the function of reproductive organs. Among these, testosterone production is particularly notable, as this hormone not only directly affects reproductive organs but also exerts a modulatory role on brain nuclei responsible for sexual behavior. Although there is a reciprocal regulation between the nervous and endocrine systems, it is important to note that the execution of sexual behavior also impacts peripheral structures, such as the major pelvic ganglion (MPG) and the testis, preparing the organism for reproduction. The purpose of this mini-review is to provide an overview of the main brain nuclei involved in the regulation of sexual behavior, as well as the spinal cord regions implicated in reproduction. Finally, we discuss how these structures may alter their function in the context of neurodegenerative diseases, aiming to introduce readers to this field of study. Full article

Phytophagous beetles, particularly those within the superfamilies Chrysomeloidea and Curculionoidea, constitute one of the most diverse and ecologically significant groups of insect herbivores. Within this group, the subfamily Bruchinae is especially notable for its close association with leguminous plant seeds. As most Bruchinae species do not feed during the adult stage, the timing and regulation of vitellogenesis remain unclear. Previous studies suggest that vitellogenesis may be triggered by volatile organic compounds emitted by host seeds, which promote juvenile hormone (JH) synthesis. This increase in JH is hypothesized to stimulate vitellogenesis, enhance female attractiveness, and ultimately facilitate fertilization and oviposition. To explore this hypothesis, we investigated the external cues regulating reproductive physiology in the capital breeder Zabrotes subfasciatus. Specifically, we examined the effects of host seeds and male presence on oviposition dynamics, fecundity, ovary activation, and the expression of vitellogenic genes (vg and vgR) throughout adult life. Our results show that females initiate vitellogenesis during the final phases of adult development, enabling oviposition to begin as early as the first day after emergence. Oviposition remains at basal levels throughout adult life unless both host seeds and males are present (p < 0.0001). This oviposition pattern is consistent with ovary activation dynamics, which reveal that vitellogenesis peaks early in the oviposition period and is prolonged by the presence of seeds and males (p < 0.05). Notably, vg and vgR gene expression respond differentially to these cues (p < 0.05). We integrate our findings with previous literature to propose a working model for the regulation of oviposition in the Bruchinae beetle Z. subfasciatus. Full article

The neuropeptide oxytocin (OXT) is involved in social bonding, reproduction, and childbirth. Its activity is mediated by the oxytocin receptor (OXTR), also expressed in the skin. OXT alleviates dermal fibroblast senescence, and OXT levels correlate with visible skin aging. OXT inhibits nociceptive signaling and promotes neuronal plasticity. Here, we demonstrate OXT-like benefits of OXTR activation for skin touch sensoriality and nociception, as well as visible skin health and beauty indicators, using an aqueous extract of Hyacinthus orientalis bulbs. OXTR activation was evaluated in a Chinese hamster ovary (CHO) cell model. Nociception and innervation benefits were investigated in keratinocyte/sensory neuron coculture models. A placebo-controlled clinical study evaluated gentle touch receptivity, nociception, skin tone, elasticity, and wrinkling. The extract activated OXTR and enhanced dermal fibroblast proliferation in vitro. In the keratinocyte-neuron coculture, the HO extract lowered nociceptive CGRP release below that of the unstimulated and OXT controls and promoted neuronal survival and dendricity. An organ-on-a-chip coculture showed decreased electrical activity and increased neuronal peripherin. Clinically, we observed selective left-side frontal alpha-wave activation, indicating pleasant sensation, reduced nociception, enhanced skin glow, improved elasticity, and reduced wrinkling. This extract thus shows high value for holistic wellbeing solutions, enhancing the skin’s receptivity to pleasant sensations and promoting well-aging. Full article

Background: The genus Ephedra (Ephedraceae) is a dioecious gymnosperm, where female individuals produce the pharmacologically active ephedrine alkaloids. Identifying the sex of specimens without reproductive cones is challenging due to their xeromorphic and morphological similarity. The challenges in sex identification complicate conservation and propagation efforts. Methods: Sequence-Related Amplified Polymorphism (SRAP) markers were applied to distinguish genders in five Ephedra species, particularly the vegetative branches, as well as powdered and fragmented specimens. The fresh material for the five studied Ephedra species and two sexes per species (totaling 10 samples; 5 females & 5 males) was collected from Sinai, Egypt. Results: The SRAP marker results revealed an exclusively male-specific band, and this is not applicable in females in the studied species. The applied SRAP markers grouped males and females in different UPGMA clusters and proved their efficiency in distinguishing between males and females in the five studied species. The Polymorphic Information Content (PIC) values are low (0.16–0.38); this suggests moderate genetic diversity between the females of the studied species, reflecting slow evolutionary rates. Conclusions: The SRAP markers are efficient for identifying Ephedra species at the species and gender levels, even in the absence of sex organs and molecular sequences. Recommendation: This study recommends the use of SRAP markers for conserving and propagating female plants for ephedrine production and suggests sequencing a 95 bp male-specific band to determine if it corresponds to a known sex-linked gene. Full article

Background: Uterine leiomyomas are the most common pelvic tumors in women of reproductive age. There is no clear conclusion in the literature regarding the pathophysiology of these conditions. STAT proteins stimulate the transcription of target genes. STAT-3 leads to an increase in VEGF levels and plays a role in tumorigenesis. IL-26 and other cytokines are vital immune response mediators. Cytokine dysregulation affects the immune response of various organs and tissues, making them prone to various diseases, such as inflammation, infection, and tumors. Methods: In the present study, we aimed to determine whether STAT-3 and IL-26 play a role in the development of uterine leiomyoma. This case–control study included 38 patients who underwent hysterectomy due to uterine leiomyoma and 30 patients who underwent hysterectomy due to non-organic benign gynecological causes other than myoma. Sections from the myometrium of the control group and the leiomyoma tissue of the case group were subjected to immunohistochemical staining for STAT-3 and IL-26. Results: When the uterine tissue sections of the control group incubated with STAT-3 were examined under a light microscope, the smooth muscle and fibroblast cells in the myometrium were STAT-3-negative, while the number of smooth muscle and fibroblast cells showing strong STAT-3-staining in the leiomyoma sections was high. When the uterine tissue sections incubated with IL-26 were examined under a light microscope, the normal smooth muscle and fibroblast cells in the control group were IL-26-negative, while there was an increase in the number of cells showing strong IL-26-staining in the leiomyoma smooth muscle and fibroblast cells. Conclusions: Our findings show that STAT-3 and IL-26 levels are significantly increased in uterine leiomyomas, and this increase may play a role in the growth and progression of uterine fibroids. The current results may enable the development of innovative treatment options, as they demonstrate the role of novel pathways in the formation of uterine fibroids. Full article

The genera: Lerniana Delicado et Hauffe, 2022, Trichonia Schütt, 1980, and two clades (“Radomaniola” elongata Radoman, 1973, and an unnamed clade referred to as “Radomaniola” sp. 1, sp. 2) whose assignment to any genus remains unknown, form sister group with the genus Radomaniola Szarowska, 2007 (Hydrobiidae W. Stimpson, 1865, subfamily Horatiinae D. W. Taylor, 1966). The paper deals with all these clades sister to Radomaniola. Cytochrome c oxidase subunit I (COI) sequences have been used to infer phylogenetic relationships between the snails collected at 15 localities in southern Greece and one in Montenegro. Thirty-two haplotypes represent eight Molecular Taxonomical Units (mOTUs) of the species level, four of them within the genus Lerniana: L. seminula (Frauenfeld, 1863), L. tritonum (Bourguignat, 1852), and two other of these four species are both described as new. First of them has been found at seven localities in Peloponnese, Attica and southern Thessaly, the second only at one locality, sympatrically with the former species. “Radomaniola” elongata does not belong to Radomaniola, and its relationships remain unknown, similarly as in other unnamed clade, whose genus-level assignment cannot currently be resolved. The shells, protoconchs, radulae, female reproductive organs and penes are presented, also for Trichonia trichonica Radoman, 1973, for which the genus assignment remains undecided based on our molecular results. The study clearly illustrates how fragmentary is our knowledge is on the real biodiversity of the minute truncatelloid gastropods, whose morphology—simple and variable—makes species distinction hardly possible. Informed decisions on species and habitat protection should consider the above. Full article

The prepubertal period represents a critical stage of development, where the reproductive system is susceptible to toxicants such as cadmium (Cd). Cd induces oxidative stress, causes alterations in the antioxidant enzymes and testosterone concentration, and affects reproductive organs. (–)-Epigallocatechin-3-gallate (EGCG), a polyphenol with antioxidant properties, has been studied for its protective effects. We evaluated the effects of EGCG on antioxidant activity and improvement of testicular and epididymal histology in Cd-exposed prepubertal rats. Twenty-eight male Wistar rats, on postnatal day (PND) 21, were distributed into four groups: Ctrl (saline), Cd (1 mg/kg CdCl₂), EGCG (10 mg/kg), and Cd+EGCG (1 mg/kg CdCl₂ + 10 mg/kg EGCG). Treatments were administered intraperitoneally from PND 21 to 49. After euthanasia, blood, testes, and epididymides were collected for Cd content, testosterone concentration, antioxidant activity, and histological evaluation. Cd exposure increased blood Cd, reduced testosterone, impaired antioxidant activity, and caused epithelial disorganization in both organs. In contrast, co-administration of EGCG significantly lowered Cd accumulation, restored testosterone concentration and antioxidant enzymes, and preserved histological integrity of testes and epididymides. These findings demonstrate that EGCG exerts protective effects against Cd-induced reproductive damage during the prepubertal period, suggesting its potential therapeutic use to counteract Cd toxicity in reproductive development. Full article

Iron represents an essential element required for normal physiologic processes throughout organ systems. A vast network of transporters is involved not only in uptake of this element but in processing, oxidation, and recycling to maintain it in a tight balance to avoid excess storage. This complex network of transporters, including heme and ferroportin, among many others, are responsible for facilitating inter-organ tissue iron exchange and availability, contributing to overall heme homeostasis. However, exposure to high levels of iron can overwhelm compensatory mechanisms that result in its accumulation and toxicity. This is the case of patients with genetic diseases such as hemoglobinopathies who suffer from chronic anemia and require, in most instances, a lifetime of red blood cell transfusions to overcome disease crises. Thus, in light of the extensive role of iron in the body, the aim of this review is to present important metabolic pathways involved in iron homeostasis across the cardiovascular, reproductive, hematopoietic, urinary, respiratory, endocrine, and central nervous systems while contrasting these against negative effects caused by iron excess. Full article