Search Results (824)

Aquaporins (AQPs) are transmembrane channel proteins that transport water and small solutes. Their dysregulation in cancer reveals functions beyond maintaining osmotic balance. This review summarizes that AQPs drive tumor progression through three core mechanisms: metabolic reprogramming, enhanced motility, and remodeling of the immune microenvironment. Specifically, AQP3, AQP7, and AQP9 serve as metabolic hubs for glycerol, while AQP3 and AQP8 help maintain redox homeostasis. AQP1 and AQP4 facilitate cell migration via hydrodynamic mechanisms, and AQP5 promotes invasion through signaling pathways such as Ras/NF-κB. In immune regulation, AQP9 and AQP3 modulate immune cell function by transporting metabolites, and AQP1 influences angiogenesis. Other isoforms, including AQP0, AQP2, AQP6, AQP10, and AQP11, also play roles in malignancy. Collectively, AQPs form a multifunctional network linking tumor metabolism, physical properties, and immunity, offering insights for novel diagnostic and therapeutic strategies. However, tissue-specific functions, complex regulatory mechanisms, and challenges in developing targeted therapies remain significant hurdles in translational medicine. Full article

Aquaporins (AQPs) are increasingly recognized as key regulators of tumor progression, influencing key hallmarks of cancer progression and cellular homeostasis. Their frequent overexpression in malignancies highlights their potential as therapeutic targets, yet the development of selective synthetic inhibitors remains challenging due to structural conservation and off-target toxicity. Natural compounds have recently emerged as promising modulators of AQP expression and function, offering greater molecular diversity and generally favorable safety profiles. This review synthesizes current evidence on phytochemicals, including bacopaside II, curcumin, resveratrol, quercetin, EGCG, all-trans retinoic acid, chrysin, and rottlerin, that interact with AQP isoforms relevant to cancer biology. These agents regulate AQPs through transcriptional control, redox modulation, signaling-pathway interference, or direct pore blockade, thereby attenuating oncogenic processes such as migration, angiogenesis, inflammation, and metabolic adaptation. Several compounds, notably bacopaside II and rottlerin, display isoform-selective inhibitory properties that directly impair AQP1- and AQP3-mediated permeability. Collectively, available evidence positions natural AQP modulators as promising lead compounds providing scaffolds for further drug development in oncology. Continued structural, mechanistic, and preclinical research is required to optimize isoform specificity and therapeutic efficacy, paving the way for their integration into future anticancer strategies. Full article

Background: Apocynum venetum L., a saline–alkali-tolerant plant, is a valuable resource for forage, textile, and medicinal purposes. This study aimed to identify the AQP gene family in A. venetum genome-wide and explore their potential functions under abiotic stress. Methods: Gene identification, phylogenetic relationships, structural features, and evolutionary patterns were analyzed, along with gene expression patterns and correlations with physiological traits. Results: Phylogenetic analysis classified the 25 candidate AvAQP genes into five distinct subgroups, with members exhibiting conserved gene structures, motifs, and phosphorylation patterns. Subcellular localization predictions indicate targeting primarily to the plasma membrane or the vacuole, with one isoform (AvTIP5;1) predicted to localize to both. Synteny analysis revealed three intraspecific and multiple interspecific gene pairs (26 with Arabidopsis thaliana and 34 with Medicago truncatula). In silico promoter analysis identified 49 cis-regulatory elements associated with phytohormone response, stress signaling, and development, providing preliminary clues for their possible involvement in diverse biological processes. qPCR profiling under abiotic stress demonstrated tissue-specific expression patterns among AvAQP members under different stress conditions. Correlation analyses between gene expression and physiological indicators (growth- and water-related traits) were predominantly positive, with only a few negative correlations under stress conditions, suggesting that AvAQP expression may be associated with plant physiological status. Conclusions: This study presents a comprehensive analysis of the AQP family in A. venetum providing a foundation for further functional characterization of these genes in response to abiotic stress. Full article

Respiratory syncytial virus (RSV), a member of the genus Orthopneumovirus, is an etiological agent in infant lower respiratory tract infections (LRTIs) producing substantial global morbidity. Here, secretoglobin (Scgb1a1)-derived progenitors play a primary role in triggering innate, inflammatory, and cell state transitions in response to RSV LRTIs. Whether RSV activation of innate signaling in this epithelial sentinel population leads to chronic airway disease is unknown. To understand the role of innate signaling in Scgb1a1-derived progenitors, a model of RSV post-viral disease (PVLD) was developed and studied in the presence or absence of RelA conditional knockout (CKO). Single-cell RNA sequencing (scRNA-seq) studies showed that RSV-PVLD induced a transition of atypical, differentiation-intermediate, alveolar type 2 (aAT2) cells characterized by tumor protein 63 (TRP63), aquaporin 3 (AQP3), and Itgβ4 expression, as well as changes in PDGFRβ mesenchyme. A single-cell trajectory analysis and lineage-tracing experiments using Scgb1a1 CreER^TM X mTmG mice demonstrated that the Scgb1a1+ populations were precursors to the aAT2 population. Mechanistically, we found that the formation of the aAT2 population was prevented by RelA CKO. A differential gene expression analysis revealed that RSV-PVLD coordinately upregulates nuclear receptor subfamily 1 group D (Nr1d1/2), clock and basic helix-loop-helix ARNT-like 1 (Bmal) genes both in the aAT2 cell and in its Pdgfrα+ mesenchymal niche in a RelA-dependent manner. A systematic analysis of intercellular epithelial–mesenchymal communication in the scRNA-seq data showed that the clock-dysregulated epithelial–mesenchymal niche produces aberrant ANGPTL4 expression. ANGPTL4 upregulation was confirmed by the measurement of both its mRNA and protein. Moreover, ANGPTL4 is biologically active in the BALF of RSV-PVLD mice, inhibiting lipoprotein lipase activity. We conclude that RSV-PVLD is mediated, at least in part, by RelA signaling in Scgb1a1-derived epithelial progenitors, dysregulating ANGPTL4 signaling in an epithelial–mesenchymal niche, resulting in persistence of atypical alveolar epithelial cells with dysregulated of clock gene expression. Full article

Background: The skin microbiome plays a crucial role in maintaining barrier function and preventing inflammaging. Heat-treated probiotics offer stability advantages for topical formulations while potentially maintaining bioactive properties. Objective: To evaluate the safety, molecular mechanisms, and clinical efficacy of heat-treated Lactiplantibacillus plantarum Skinbac™ SB01 and Bifidobacterium animalis spp. lactis Skinbac™ SB05 in reducing visible signs of skin aging. Methods: In vitro studies assessed cytotoxicity (MTT/LDH assays), Aquaporin-3 (AQP3) expression, and reactive oxygen species (ROS) production in Normal Human Epidermal Keratinocytes (NHEK). A 30-day open-label clinical study (n = 20 females, 18–70 years) evaluated three formulations (face cream, serum, and eye contour) using instrumental measurements of hydration, elasticity, density, and roughness parameters. Results: In vitro testing showed a significant increase in AQP3 expression (+22% ± 3%, p = 0.03) and a non-significant reduction in ROS levels (−33% ± 9%, p = 0.06) at 10⁷ TFU/well, with no cytotoxicity observed. Clinical evaluation demonstrated statistically significant improvements: eye contour formulation achieved +10.5% deep skin hydration (p < 0.0001) and −11% average roughness (p < 0.0001); serum showed +28.7% immediate hydration (p < 0.0001); and face cream improved gross skin elasticity by +6.3% (p < 0.01). No adverse events were reported. An independent and methodologically distinct placebo-controlled study was included for contextual support and was not directly compared with the present trial; this study evaluated a related 1% postbiotic formulation and reported statistically significant improvements over placebo in roughness, wrinkle depth, hydration, and biomechanical parameters. Conclusions: This pilot study provides preliminary evidence that heat-treated L. plantarum SB01 and B. animalis spp. lactis SB05 formulations could safely improve skin hydration and reduce roughness parameters. While in vitro results show a significant increase in AQP3 expression and an exploratory (non-significant) reduction in ROS levels, larger controlled trials are warranted to confirm clinical efficacy. Full article

To characterize the transcriptional and physiological alterations induced by manganese stress in Coilia nasus, juveniles (mean weight 5.0 ± 0.2 g) were subjected to either manganese exposure (5.50 ± 0.03 mg/L) or control (0 mg/L) for a 12 h period. Subsequently, gill tissues were excised for evaluation of antioxidant parameters and RNA-Seq analysis. A total of 753 DEGs were identified in the manganese exposure group compared to controls, comprising 287 up-regulated and 466 down-regulated genes. GO and KEGG enrichment analysis of DEGs showed that most of the DEGs were involved in immune and metabolic pathways, which disturbed the biological processes related to immunity and metabolism at the molecular level. The acute manganese stress initiated a multi-level antioxidant response to cope with oxidative stress in Coilia nasus. This finding was further supported by the significant increase in MDA content and significant decrease in GSH content and GSH-Px activity under manganese exposure, while SOD and CAT activities were significantly increased. Simultaneously, the acute manganese stress triggered profound metabolic reprogramming to cope with energy pressure in Coilia nasus, which showed that manganese exposure significantly down-regulated energy metabolism-related genes (pfkm, pgam2, eno3, pkm, aqp9, apoa1, tkt, sds); furthermore, the overall energy metabolism network was widely inhibited, while lipid metabolism-related genes (fabp3, cpt1a) were significantly up-regulated to compensatorily activate fatty acid transport and β-oxidation pathways. In addition, the acute manganese stress initiated a complex immune response pattern to cope with cell damage in Coilia nasus, which showed that manganese exposure significantly enhanced the expression of inflammatory signaling genes (mapk1, stat1, tgfb3); furthermore, certain inflammatory pathways were activated, while the expressions of immune regulatory genes (traf6, il-10) were significantly decreased. In summary, these results indicated that manganese exposure could impair immune function, disrupt metabolism, and induce oxidative stress in Coilia nasus. Full article

Background: Bronchopulmonary dysplasia (BPD) is a common lung disease in premature infants. Hyperoxia-induced oxidative stress and ferroptosis are key pathological mechanisms leading to alveolar epithelial (AT) cell injury and impaired alveolar development. M2 macrophage-derived exosomes (M2-Exo), as intercellular communication carriers, have potential protective effects in regulating oxidative stress-related diseases, but the molecular mechanism by which they exert effects by regulating ferroptosis in BPD remains unclear. Objective: To explore the protective effect of M2-Exo on hyperoxia or inflammation-induced BPD models and clarify its antioxidant mechanism. Method: In vitro AT cell injury models and in vivo BPD models were constructed by hyperoxia or LPS induction. M2-Exo were isolated, identified, and used to intervene in models. Oxidative stress and ferroptosis-related indicators (ROS, MDA, iron accumulation, GPX4), AT cell functional markers (AQP5, SPC), and ZAKα-p38 pathway activation contents were detected. ZAKα overexpression was used to verify pathway dependence. Results: M2-Exo intervention significantly enhanced AT cell viability, upregulated the expression of AQP5 and SPC, and reversed alveolar simplification. Concurrently, it effectively suppressed hyperoxia or LPS-induced oxidative stress and ferroptosis, as evidenced by reduced contents of ROS and MDA, diminished iron accumulation, and GPX4 expression. Mechanistically, M2-Exo significantly inhibited the activation of the ZAKα-p38 pathway, and ZAKα overexpression could antagonize the antioxidant, anti-ferroptotic, and AT cell protective effects of M2-Exo. Conclusions: M2-Exo alleviate AT cell oxidative stress and ferroptosis by inhibiting the ZAKα-p38 pathway, thereby improving hyperoxia or inflammation-induced BPD and providing a new strategy and molecular target for the antioxidant treatment of BPD. Full article

Aquaporins (AQPs) are a family of small integral membrane proteins that mediate the selective transport of water and, in some cases, small solutes such as glycerol and hydrogen peroxide. In the skin, distinct AQP isoforms are expressed throughout the epidermis, dermis, and hypodermis, where they play key roles in maintaining hydration, regulating keratinocyte and fibroblast proliferation, modulating inflammatory responses, and preserving overall tissue integrity. Increasing evidence indicates that aberrant AQP expression or function contributes to skin carcinogenesis, influencing tumor initiation, local invasion, metastasis, and responses to microenvironmental stress. Alterations in specific AQP isoforms have been associated with both major classes of cutaneous malignancies—non-melanoma skin cancers (NMSC), including basal cell carcinoma and squamous cell carcinoma, as well as malignant melanoma (MM)—yet their mechanistic contributions remain incompletely understood. This review synthesizes current knowledge on the involvement of each AQP isoform in skin cancer pathogenesis and progression, integrating findings from molecular, cellular, and in vivo studies. By clarifying the diverse roles of AQPs in cutaneous malignancies, this work aims to support the development of targeted interventions and guide future research in this rapidly evolving field. Full article

Oocyte vitrification imposes oxidative stress that compromises maturation competence. Aquaporin-7 (AQP7) has been implicated in cellular redox regulation, but its specific role in cryopreserved oocytes remains unclear. Here, germinal vesicle (GV) stage oocytes were vitrified and warmed with AQP7 inhibitor Z433927330 (0.5, 5, 50 μM). AQP7 inhibition disrupted redox balance, compromised mitochondrial function. Consequently, it severely compromised developmental competence, leading to significantly reduced cleavage (39.90% ± 6.17 vs. 52.93% ± 3.37) and blastocyst formation rates (1.67% ± 2.89 vs. 5.17% ± 2.49) in vitro. To confirm, we performed microinjection-mediated AQP7 knockdown and overexpression and assessed their effects on maturation. AQP7 knockdown further reduced the maturation rate of vitrified oocytes (20.22% ± 3.14 vs. 36.31% ± 2.10), whereas overexpression partially restored it (43.98% ± 4.71 vs. 33.74% ± 2.21). The mitochondrial-targeted antioxidant MitoQ partially rescued the maturation rate (53.13% ± 2.75 vs. 43.52% ± 2.71). Thus, AQP7 is essential for the maturation of vitrified sheep oocytes by safeguarding intracellular redox homeostasis, thereby preventing mitochondrial dysfunction and cytoskeletal damage, and loss of embryonic developmental potential. Full article

Background: Obesity is associated with hypothalamic dysfunction characterized by neuroinflammation and altered transcriptional programs. While resveratrol (RSV) has shown beneficial metabolic effects in peripheral tissues, its central effects on hypothalamic gene expression in obesity remain poorly understood. This study provides the first predictive transcriptomic analysis of the hypothalamic response to RSV in a mouse model of diet-induced obesity. C57BL/6 male mice were fed a high-fat diet (HFD) to induce obesity and then subsequently treated with RSV. Methods: Hypothalamic RNA was extracted and analyzed using RNA sequencing. Differentially expressed genes (DEGs) were identified and functionally analyzed through KEGG pathway analysis. Results: Although RSV did not significantly alter body weight, it reversed the expression of several HFD-induced DEGs. Key genes modulated by RSV included Aqp7, Ccl27a, Lta, Rilp, M6pr-ps, C1ra, Snail1, Gbgt1, and Ppargc1b, which are involved in inflammation, lipid metabolism, mitochondrial function, and immune signaling. Pathway enrichment analysis revealed significant modulation of TNF and NF-κB signaling, cytokine–cytokine receptor interactions, glycosphingolipid biosynthesis, and phagosome-related activity. Remarkably, 45% of RSV-responsive transcripts were non-coding RNAs, suggesting epigenetic regulation. Conclusions: RSV reprograms the hypothalamic transcriptome in obesity, targeting both coding and non-coding RNAs associated with inflammation and metabolic regulation, independently of weight loss. These findings identify RSV as a potential central modulator of metabolic dysfunction and highlight the hypothalamus as a promising therapeutic target in obesity-related disease. Full article

Background: Neuromyelitis optica spectrum disorder (NMOSD) is an autoimmune demyelinating disease with important disability accumulation. Early-onset NMOSD, defined as disease onset before age 50, exhibits distinct clinical characteristics compared to late-onset disease. We present a case series of patients with first symptom onset before age 30. Methods: A retrospective review of 10 patients diagnosed with NMOSD at our center in San Luis Potosí, Mexico, with disease onset before age 30. Clinical presentation, imaging findings, AQP4 antibody status, treatment response, and disability outcomes were analyzed. Results: The mean age at onset was 18.6 years (range 6–30). Area postrema syndrome was the most common presentation (40%), followed by acute myelitis and optic neuritis (30% each). All tested patients were AQP4-positive. The mean EDSS at follow-up was 6.6, indicating severe disability. Most patients received rituximab with variable response rates. Conclusions: Our cohort showed higher disability than reported in other early-onset series, emphasizing the need for prompt diagnosis and aggressive treatment in this population. Full article

This study investigated the role of trpc3 in osmoregulation under salt stress in grass carp (Ctenopharyngodon idella). Tissue expression analysis showed trpc3 was highest in the brain, followed by gills, skin, and muscle. In gills and kidney, its expression increased with salinity. RNA interference using synthesized trpc3-dsRNA (2 μg/g) significantly reduced its expression. Under early salt stress, serum osmolality, Na⁺, Ca²⁺, and renal NKA activity were comparable between the interference and non-interference groups. However, gill CaN, NKA, and Ca²⁺-ATPase, as well as renal CaN and Ca²⁺-ATPase activities were significantly lower in the interference group. During late salt stress, the interference group exhibited significantly higher serum osmolality, Na⁺ concentration, and renal NKA activity than the non-interference group. Serum Ca²⁺ concentration remained unchanged between groups. Conversely, gill CaN, NKA, and Ca²⁺-ATPase, as well as renal CaN and Ca²⁺-ATPase activities were significantly lower in the interference group. Gene expression analysis revealed that early plcxd1 was higher, while trpc3, calm1a, aqp3a, nka beta 1b subunit, IL-1β, hsp70, and gill nkcc1 variant X1 were lower in the interference group. Late-stage expression showed nka beta 1b subunit (gills/kidney) and renal trpc3, nkcc1 variant X1 were higher; gill trpc3, plcxd1, aqp3a, nkcc1 variant X1, IL-1β and renal plcxd1, aqp3a, nkcc1 variant X1, hsp70 were comparable; and gill calm1a, hsp70 and renal calm1a, IL-1β remained lower in the interference group. In summary, grass carp trpc3 may mediate Ca²⁺ influx to regulate ion transport in the gills and kidney, playing a key role in restoring osmotic homeostasis. Full article

The commercialization of proton-exchange-membrane fuel cells is constrained by the limitations of perfluorosulfonic acid membranes like Nafion, which suffer from high methanol crossover, humidity-dependent conductivity, high cost, and poor environmental sustainability. This review presents a comprehensive analysis of aquaporin-inspired chitosan/cellulose (AQP-CS) composite membranes as a transformative, bio-inspired alternative. The central design paradigm integrates a sustainable chitosan/cellulose matrix—which offers inherent mechanical stability, tunable proton conduction, and excellent fuel barrier properties—with biomimetic water channels engineered for selective hydration transport. This synergistic architecture aims to fundamentally decouple water management from proton conduction, directly addressing the core performance flaw of conventional membranes. The review is structured to explicitly trace the logical pathway from the foundational material properties of chitosan and cellulose to the functional requirements for integrating synthetic aquaporin-mimetic components. Experimental evidence from advanced chitosan composites, demonstrating proton conductivities up to 0.131 S cm⁻¹ alongside drastically reduced methanol permeability, validates the potential of this approach. Consequently, AQP-CS composites establish a novel framework for developing next-generation fuel cell membranes that combine high performance with ecological design. However, key challenges in the stable integration of biomimetic channels, long-term operational durability, and scalable manufacturing must be resolved to enable practical deployment and mark a significant leap toward sustainable energy conversion technologies. Full article

Background: Follicle-stimulating hormone (FSH)-based vaccines show the potential to disrupt spermatogenesis without disturbing sexual function and libido in males. Herein, we developed a novel FSH vaccine based on the tandem of a conserved 13-amino acid receptor-binding epitope of FSHβ (FSHβ13AA-T) and tested its effect on reproductive physiology and function using the male mouse as a model. Methods: Serum reproductive hormone levels, testicular histology, daily sperm production, sperm motility, libido and fertility of male mice following FSH vaccination were determined. Results: Compared to placebo-immunized controls, FSH vaccination triggered (p < 0.05) marked antibody generation, inhibited spermatogenesis and reduced sperm motility (p < 0.05), without adverse effects on serum LH and testosterone levels as well as the libido of male mice. Mechanistically, FSH vaccination suppressed (p < 0.05) testicular local estrogen production by downregulated aromatase encoding gene Cyp19a1 expression and also downregulated (p < 0.05) expression of key spermatogenic genes in testes, including Creb, INHα, Wnt2, Aqp8, Cmtm2a and Spata19, thus disrupting and impairing spermatogenesis and sperm motility. Conclusions: These results demonstrate that immunization of male mice against FSHβ13AA could substantially inhibit spermatogenesis and reduce sperm motility. Thus, FSHβ13AA-based vaccines hold potential for development as male contraceptives that do not compromise libido in species including men in which FSH is essential for spermatogenesis. Full article

Painful diabetic neuropathy (PDN) is a prevalent and debilitating complication of diabetes, characterized by persistent neuropathic pain that severely impairs quality of life. Current management strategies predominantly target peripheral nerve dysfunction and offer only symptomatic relief, with no disease-modifying therapies available. Emerging evidence now underscores the critical role of central nervous system (CNS) glial cells—microglia, astrocytes, and oligodendrocytes, collectively termed the “glial triad”—in driving PDN pathogenesis. This review synthesizes recent advances elucidating how these glial cells contribute to neuroinflammation, metabolic dysregulation, and central sensitization. We detail specific mechanisms including microglial NLR Family Pyrin Domain Containing 3 (NLRP3) inflammasome activation and metabolic reprogramming, astrocytic aquaporin-4 (AQP4) polarity disruption impairing glymphatic function, and oligodendrocyte myelination deficits via Mammalian Target of Rapamycin (mTOR) signaling. Furthermore, we discuss the translational potential of glia-derived biomarkers (e.g., Translocator Protein (TSPO), Glial Fibrillary Acidic Protein (GFAP), myelin basic protein (MBP)) for early diagnosis and patient stratification. Finally, we highlight promising therapeutic avenues that target glial pathways, such as interleukin-35 (IL-35), β-hydroxybutyrate, and metformin, which aim to shift the treatment paradigm from symptomatic control to disease modification. By integrating preclinical and clinical insights, this review proposes the glial triad as a central player in PDN and suggests that targeted glial interventions may represent a promising frontier for future disease-modifying strategies. Full article