Search Results (181)

Efficient propagation of Hydrangea arborescens is essential for the stable production of high-quality plantlets. However, propagation via stem cuttings is often limited by environmental conditions and inconsistent rooting. This study aimed to identify an effective in vitro culture medium by integrating quantitative growth traits with image-based quality analysis. Seven culture media (M1–M7), consisting of Murashige and Skoog (MS), McCown Woody Plant (McCown), and Gamborg B5 basal media supplemented with different plant growth regulator combinations, were evaluated based on shoot number, root number, plant height, and fresh weights, and plantlet quality was assessed using Green area, ExG (excess green index), and a composite z-score. Significant differences were observed among treatments. M5 and M7 produced the highest shoot numbers, and M7 showed the greatest fresh weight. Image-based analysis indicated that M2 and M7 exhibited the highest overall quality, whereas M3 showed the lowest performance. Basal media types did not significantly affect plantlet quality, whereas hormone treatments enhanced both shoot multiplication and callus formation. A positive association was observed between callus formation rate and shoot number (Spearman’s ρ = 0.74, p < 0.001). Overall, M7 (Gamborg B5 medium supplemented with 30 g∙L⁻¹ sucrose, 1.5 mg∙L⁻¹ BA, and 0.25 g∙L⁻¹ gelrite) provided a balanced combination of high propagation efficiency and plantlet quality, and these findings contribute to the efficient production of high-quality planting materials. Full article

Knot-free timber production in Cunninghamia lanceolata depends critically on internodal characteristics, yet the mechanisms governing internode elongation remain poorly understood, hindering breeding efforts for longer-internode varieties. In this study, we selected two clones with distinct internodal traits (the C1 clone exhibited a 25.03% longer internodal length than the C11 clone) as materials. Enzyme-linked immunosorbent assay (ELISA) and RNA sequencing were used to investigate dynamics in endogenous hormones and transcriptional regulation in internodal growth. Results showed that the difference in indole-3-acetic acid (IAA) rhythms in apical buds is a key factor of C1’s longer internodal growth; higher levels of IAA and cytokinins in the apical buds of C1 may support sustained internodal growth; upregulated IAA-related genes in upper phloem (PIN1 and SAURs), which are involved in polar transport and signal response, indicates a stronger capacity to establish apical dominance. Hormone transport may be regulated by very long-chain fatty acids (VLCFAs). Consistent with reduced brassinosteroid activity, genes involved in VLCFA biosynthesis and transport were generally lower in C1, implying excessive VLCFA accumulation in C11 may be negative to IAA transporting and internode growth. This study offers a preliminary insight into internodal growth mechanisms influenced by hormone biosynthesis and transport in C. lanceolata., providing a basis for genetic improvement, germplasm selection, and exogenous hormone applications in knot-free timber cultivation. Full article

Cardiac fibrosis is a central determinant of heart failure progression and arises from pathological remodeling characterized by fibroblast activation, myofibroblast differentiation, and excessive extracellular matrix deposition. In contrast, physiological remodeling permits adaptive cardiac growth without net fibrosis. Pregnancy represents an underexplored physiological model of reversible cardiac remodeling. In response to hemodynamic load, the maternal heart undergoes hypertrophic growth that resolves postpartum, constituting a natural paradigm of fibrosis-resistant cardiac adaptation. Pregnancy and lactation are accompanied by profound endocrine and immune reprogramming of maternal tissues. We propose that this hormonal milieu orchestrates coordinated crosstalk among endothelial cells, fibroblasts, and immune cell populations to suppress profibrotic pathways and preserve extracellular matrix homeostasis. Candidate regulators include estrogen, progesterone, prolactin family peptides, relaxin, oxytocin, and components of the renin–angiotensin–aldosterone system. During the postpartum and lactational period, prolactin and oxytocin may further promote reverse remodeling. These hormones likely act by modulating local cytokine and growth factor networks that otherwise drive fibroblast activation. By focusing on non-myocyte cardiac cells and extracellular matrix dynamics, this review positions pregnancy as a translational model to uncover endogenous anti-fibrotic mechanisms and identify novel therapeutic strategies for cardiac fibrosis. Full article

Modern genetic selection for high productivity has created a physiological conflict in ruminants, where the metabolic demands of lactation compete directly with the energy requirements of reproduction. This review provides a mechanistic synthesis of how key nutritional factors modulate the endocrine and cellular pathways governing reproductive success in cattle and sheep. Negative energy balance (NEB), characteristic of the early postpartum period, suppresses the hypothalamic–pituitary–gonadal (HPG) axis by impairing the pulsatile secretion of gonadotropin-releasing hormone (GnRH) and luteinizing hormone (LH), mediated through reduced kisspeptin signaling, growth hormone (GH) resistance, and decreased circulating insulin, insulin-like growth factor-1 (IGF-1), and leptin. At the macronutrient level, excess rumen-degradable protein elevates blood urea nitrogen and impairs the uterine environment, while omega-3 polyunsaturated fatty acids inhibit prostaglandin F2α synthesis to support corpus luteum maintenance. At the micronutrient level, selenium, copper, and zinc are essential antioxidant cofactors protecting gametes and embryos from oxidative stress, while vitamins A, D, and E regulate gene expression in reproductive tissues. Furthermore, maternal nutrition during critical gestational windows programs the reproductive capacity of offspring through epigenetic modifications, with profound implications for long-term herd fertility. Understanding these nutritional–reproductive interactions is crucial for developing precision feeding strategies that optimize herd fertility, improve animal welfare, and ensure the economic sustainability of livestock management. A thorough understanding of these nutritional–reproductive interactions is essential for developing precision feeding strategies that optimize fertility in high-producing ruminants. Full article

Endocrine disorders are increasingly recognized as major contributors to secondary cardiomyopathies, leading to profound alterations in cardiac structure and function. This comprehensive review synthesizes current evidence on the genetic basis of cardiomyopathies associated with endocrine conditions, including primary aldosteronism, Cushing’s syndrome, pheochromocytoma/paraganglioma, acromegaly, thyroid disorders, hyperparathyroidism, and diabetic cardiomyopathy. We examine the contribution of somatic and germline mutations, genetic polymorphisms, shared molecular pathways transforming growth factor-β (TGF-β)/SMAD (TGF-β/SMAD signaling, the renin–angiotensin–aldosterone system, oxidative stress, and calcium handling), sarcomeric gene modifiers, ion channel variants, and epigenetic mechanisms to disease pathogenesis. We propose a conceptual framework distinguishing three major categories of genetic involvement: (i) variants causing the primary endocrinopathy; (ii) genetic modifiers of myocardial susceptibility under conditions of hormonal excess; and (iii) direct pleiotropic effects, whereby single gene variants independently cause both endocrine and cardiac phenotypes. In addition, we discuss genotype–phenotype correlations, ethnic and population differences in genetic susceptibility, the emerging role of polygenic risk scores, and precision medicine approaches. Overall, this review provides an integrated perspective on the complex genetic architecture of endocrine-related cardiomyopathies and outlines practical considerations for genetic testing aimed at improving patient management and clinical outcomes. Full article

Oxidative stress contributes to reproductive disorders, immune dysfunction, and reduced productivity in livestock during periods of high metabolic demand and environmental challenge. Selenium supports antioxidant defense systems because it is incorporated as selenocysteine into selenoproteins, including glutathione peroxidases and thioredoxin reductases that detoxify peroxides and sustain redox balance. The review summarizes selenium occurrence and chemical forms in feeds, as well as its absorption, transportation, and storage. The review also outlines the major features of selenoprotein biosynthesis and its prioritized allocation, with an emphasis on cattle, pigs, sheep, and goats. Evidence from multiple sources indicates that selenium status and supplementation interacts with antioxidant capacity, immune competence, thyroid hormone metabolism, reproductive performance, and the transfer of selenium to milk and offspring. In ruminants, rumen microbial transformations can reduce the bioavailability of inorganic selenium salts, and organic sources, such as selenium-enriched yeast, hydroxy-selenomethionine, and selenitetriglycerides, often increase blood and milk selenium more effectively. In pigs, organic selenium is commonly associated with enhanced antioxidant and immune indices in sows and piglets during late gestation, lactation, and weaning, whereas effects on growth performance are inconsistent. The review emphasizes the narrow margin between adequacy and excess and outlines practical considerations for supplementation and monitoring, alongside research needs for emerging selenium forms and functional biomarkers. Full article

Background/Objectives: Acromegaly is a systemic connective tissue disease driven by chronic growth hormone (GH) and insulin-like growth factor-1 (IGF-1) excess; yet, the female reproductive tract—especially the extracellular matrix (ECM)-rich cervix—has been poorly studied. We aimed to compare uterine and cervical morphology in women with acromegaly versus healthy controls and a gynecologic disease comparator, testing the hypothesis of selective cervical hypertrophy. Methods: We performed a retrospective case–control study of reproductive-age women who underwent pelvic ultrasound: acromegaly (n = 33), healthy controls (n = 45), and adenomyosis without acromegaly (n = 44). Uterine body measurements were obtained by TAUS/TVUS; cervical biometry was performed transvaginally in all cases. Volumes were estimated using the ellipsoid formula, and a uterus-to-cervix (U:C) volume ratio was calculated. Group differences were analyzed with Mann–Whitney tests and Bonferroni correction. Results: A total of 122 women were included. Uterine body length, width, AP size, and volume did not differ between acromegaly and either comparison group (all p-values non-significant). In contrast, cervical length, width, AP thickness, and volume were significantly higher in acromegaly than in healthy controls, with a corresponding reduction in the U:C volume ratio, indicating disproportionate cervical enlargement. Compared with adenomyosis, women with acromegaly again showed larger cervical width, AP thickness, and volume, together with altered U:C indices, whereas cervical length did not differ, suggesting a pattern not explained by nonspecific pelvic pathology. Conclusions: Women with acromegaly demonstrate a distinct uterine phenotype characterized by selective cervical hypertrophy with preserved uterine corpus size—an ECM-centric “acromegalic uteropathy.” This noninvasive morphometric signature may have diagnostic and procedural relevance and warrants confirmation in prospective studies. Full article

Lipids are the major energy reservoir, but excessive fat accumulation drives immune cell trapping, chronic inflammation, autoimmunity, and cancer. Lipid synthesis, secretion, degradation, and the shuttling to cellular organelles and compartments are still poorly investigated in all cell types of the mammalian body. The major routes of FA uptake are dietary uptake, lipolysis, and de novo synthesis. We highlight disease associations zooming in on the Signal Transducer and Activator of Transcription 1/3/5 (STAT1/3/5) molecules in association with cytokine, growth factors, and hormone action, steering lipid metabolism. We compare STAT-lipid crosstalk from nuclear and mitochondrial perspectives, highlighting roles in immunity, metabolic diseases, and cancer, and providing insights into key regulatory mechanisms of lipid metabolism. A high degree of cellular flexibility in metabolic adaptation explains the need for fine-tuning, in which STAT molecules can function as rheostats to maintain energy equilibrium within cellular compartments. This concept bridges, e.g., high-energy flux or the Warburg effect, with the Hydride Transfer Complex upon low-energy provision. Another interesting STAT1/3/5 aspect is their Lipid droplet (LD) association and LD formation. LDs play key roles in disease initiation or progression, including autoimmunity or cancer, as well as chronic inflammatory diseases due to their role in (1) lipotoxicity, (2) cell death regulation, (3) immune system amelioration, and (4) energy provision. Finally, the therapeutic consequences of the angles are outlined, along with future research directions. Full article

Melatonin, a multifunctional hormone with antioxidant, anti-inflammatory, and chronobiotic effects, is essential for a healthy pregnancy and fetal development. In the context of the Developmental Origins of Health and Disease (DOHaD), excessive oxidative stress acts as a key driver of maladaptive fetal programming, increasing lifelong susceptibility to cardiovascular, kidney, and metabolic (CKM) disorders. Importantly, most evidence derives from rodent models, and the protective effects of maternal melatonin supplementation appear partial and model-dependent rather than universal. Experimental studies indicate that maternal melatonin supplementation can prevent programmed hypertension, renal dysfunction, and metabolic derangements by restoring redox homeostasis, influencing epigenetic and nutrient-sensing pathways, and modulating the gut microbiome. Early clinical investigations in pregnancies complicated by preeclampsia or intrauterine growth restriction suggest that melatonin is well tolerated, improves placental function, and benefits neonatal outcomes. However, optimal dosing and long-term safety for offspring remain to be established. This review synthesizes mechanistic and translational evidence, framing melatonin as an integrative biological mediator with potential to guide preventive strategies and mitigate the intergenerational risk of CKM syndrome. Full article

The blueberry variety ‘Liberty’ shows excessive vegetative growth and difficulty in flower bud differentiation under container cultivation. Paclobutrazol (PBZ), a widely used plant growth regulator, effectively modulates the balance between vegetative and reproductive growth in plants; however, its application in container-cultivated blueberries remains understudied. This study systematically investigated the effects of different PBZ concentrations (0–200 mg·L⁻¹) on the growth and development, physiological characteristics, and fruit quality of container-cultivated ‘Liberty’ blueberries and further clarified the optimal application time. Results showed that low-concentration treatments (≤75 mg·L⁻¹) significantly enhanced root development, increased new shoot diameter, and elevated the root-to-shoot ratio. Concurrently, it induced the coordinated thickening of palisade and spongy tissues in leaves and significantly increased the maximum photochemical efficiency (Fv/Fm) and chlorophyll content. The contents of endogenous hormones indole-3-acetic acid (IAA) and gibberellin (GA₃) in new shoots were significantly reduced, while the cytokinin-to-gibberellin ratio (CTK/GA₃) in flower buds was markedly elevated. These changes effectively promoted flower bud differentiation, increased bud number, and advanced the flowering time by approximately 2 days. Fruit quality was significantly improved. Under high concentration treatments, the content of malondialdehyde (MDA) continuously accumulated, and the activities of antioxidant enzymes (CAT, POD, SOD) significantly decreased. Furthermore, the efficacy of paclobutrazol weakened with the delay of application time. Comprehensive analysis indicated that the 50 mg·L⁻¹ concentration effectively suppressed excessive vegetative growth and maximally improved fruit quality, with its application at the mid-stage of secondary shoot growth exhibiting favorable coordination of plant growth and development. This provides a theoretical basis for the application of paclobutrazol in blueberry production. Full article

Phosphorus is an essential mineral involved in bone mineralization, energy metabolism, and cellular signaling, whose serum concentration is tightly regulated by an endocrine network including fibroblast growth factor 23 (FGF23), parathyroid hormone (PTH), vitamin D and Klotho. Disruption of this balance, particularly in chronic kidney disease (CKD), leads to hyperphosphatemia, which is strongly associated with bone fragility, vascular calcification, and increased mortality. In CKD, impaired phosphorus homeostasis triggers endocrine dysregulation characterized by elevated PTH and FGF23 levels, Klotho deficiency, and altered vitamin D metabolism, resulting in major skeletal and vascular consequences. Experimental and clinical evidence indicates that phosphorus overload contributes directly to skeletal deterioration and early vascular remodeling, even prior to clinically detectable renal impairment. Moreover, high dietary phosphorus intake under conditions of normal renal function reproduces several molecular and structural alterations typically observed in CKD, supporting a pathogenic role for chronic phosphorus excess. The dietary source of phosphorus has gained increasing relevance, as inorganic phosphate additives exhibit high intestinal bioavailability and impose a greater systemic phosphorus burden. Current management strategies rely on dietary restriction, phosphate binders, modulation of intestinal phosphorus transport and optimization of mineral-regulating hormones, although evidence for improved clinical outcomes remains limited. A deeper understanding of the molecular mechanisms linking phosphorus overload to bone and vascular pathology may facilitate the development of more effective preventive and therapeutic strategies. Full article

Background: Acromegaly is a rare, chronic, systemic, and progressive disease characterized by an excess secretion of growth hormone (GH) and increased circulating insulin-like growth factor 1 (IGF-1) concentrations, typically due to a macroadenoma in the pituitary gland. Both GH and IGF-1 are implicated in cancer promotion based on experimental and epidemiological data, but research findings remain conflicting and population-based data are scarce. Although there is a high mortality rate among acromegalic patients due to cardiovascular diseases, cancer is the third leading cause of death. Aim: The aim of the present study was to assess the risk of different types of cancer in acromegaly and the impact of changes in disease control and patient outcomes over time. Methods: Patients diagnosed with acromegaly at the Ankara University Ibn-i Sina Hospital Endocrinology and Metabolic Diseases Department between 2015 and 2019 were included in this study. Data including demographic data, history of cancer, size of adenoma (micro or macro), serum IGF-1 and GH levels at the time of diagnosis, serum prostate-specific antigen (PSA), thyroid ultrasonography, and, if needed, thyroid fine needle aspiration cytology (TFAC), colonoscopy, and mammography results were collected from patient records retrospectively. Results: We screened 83 patients, and 78 patients with the compensatory data (female/male: 39/39, 50%/50%) were included. The mean age of patients was 49.4 ± 11.9 years and 41.7 ± 12.1 years at the time of diagnosis. The median duration of follow-up was 72 (12–420) months. Periodic thyroid ultrasonography was performed in 65/78 (83.3%) of the patients, and a colonoscopy and mammography were also conducted in 27/78 (34.6%) and 32/39 (82%) of the patients at least once over the course of the disease, respectively. Cancer was detected in 17/78 (21.7%) of the patients; 11/78 (14.1%) of them had well-differentiated thyroid cancer and 2/39 (5.1%) had breast cancer. Prostate cancer, renal cell carcinoma, pancreatic cancer, malignant chordoma, schwannoma, and colon cancer were detected in one patient each. The increased cancer risk in acromegalic patients did not correlate with age, sex, age at diagnosis, time to diagnosing acromegaly, duration of acromegaly, GH and IGF-1 levels at diagnosis, pituitary adenoma size, or Ki-67 levels. Conclusions: Cancer was detected in 21.7% of the acromegaly patients, 14.1% of whom had well-differentiated thyroid cancer. In this study, we demonstrated that thyroid cancer is the most common malignancy in Turkish acromegalic patients, consistent with the results of previous studies. The increased cancer risk in acromegalic patients did not correlate with age, sex, age at diagnosis, time to diagnosing acromegaly, duration of acromegaly, or GH and IGF-1 levels at diagnosis. Full article

Potassium (K⁺) is essential for plant growth and development, influencing numerous physiological processes and stress responses. While the importance of K⁺ in overall plant performance is well-established, its specific effects on root system architecture and the underlying molecular mechanisms in woody perennials remain poorly understood. This knowledge gap is particularly significant for citrus rootstocks like trifoliate orange (Poncirus trifoliata L.), where root system optimization directly impacts drought resistance, nutrient acquisition, and overall orchard productivity. Here, we investigated how varying K⁺ concentrations (K₀, K₂, K₆, and K₁₂) affect trifoliate orange seedling development by comprehensively analyzing root architecture parameters, root hair morphology, endogenous hormone levels, and expression patterns of cell-wall-modifying and auxin-related genes. We found that moderate K⁺ levels (K₆) optimized root architectural development while both deficiency (K₀, K₂) and excess (K₁₂) inhibited overall growth and root architecture but enhanced root hair development. This morphological dichotomy corresponded to distinct hormonal profiles, showing reduced auxin (IAA), gibberellins (GAs), and zeatin riboside (ZR) levels under K⁺ stress conditions. Gene expression analysis revealed significant upregulation of expansins (PtEXPA4, PtEXPA5, PtEXPA7) and reconfiguration of auxin biosynthesis (TAA/TAR/YUC) and transport (AUX/LAX/ABCB/PIN) machinery under non-optimal K⁺ conditions. Our findings suggest that K⁺ availability modulates trifoliate orange root development through coordinated regulation of hormone homeostasis and gene expression, particularly within the auxin signaling network. These findings elucidate K⁺-responsive root developmental plasticity as a potential adaptive strategy, providing valuable insights for optimizing fertilization strategies in citrus cultivation and identifying potential molecular targets for enhancing potassium use efficiency in woody perennials. Full article

The maintenance of bone homeostasis requires the coordinated activity of specialized cells (osteoblasts, osteoclasts and osteocytes), soluble factors and hormones with regulatory functions. Disruption of this tightly controlled balance contributes to several skeletal pathological conditions, among which osteoporosis is one of the most prevalent. Iron, an essential element for the basic cellular functions of both osteoblasts and osteoclasts, plays a pivotal role in preserving bone homeostasis and skeletal integrity. Both iron deficiency and iron overload impair bone remodeling through distinct but converging mechanisms. Iron deficiency compromises collagen synthesis, alters hypoxia-dependent signaling, and may affect vitamin D metabolism, collectively predisposing the individual to reduced bone mineral density and increased fracture risk. Conversely, excess iron enhances oxidative stress, promotes osteoclastogenesis, and suppresses osteoblast differentiation and function, thereby favoring bone loss, particularly in the aging population and postmenopausal individuals. Hepcidin, the master regulator of systemic iron availability, has emerged as a key modulator of bone turnover, whereas the bone-derived hormone fibroblast growth factor 23 (FGF23) links iron imbalance to phosphate homeostasis, vitamin D metabolism, and inflammation. Beyond metabolic bone diseases, dysregulated iron handling is increasingly recognized as a hallmark of osteosarcoma biology, influencing tumor growth, metabolic reprogramming, and an individual’s susceptibility to ferroptosis. The emerging, albeit only preclinical, evidence of the roles of iron and ferroptosis in osteosarcoma is therefore also covered. This review summarizes the current understanding of the interactions between iron metabolism and bone biology and addresses how an imbalance in iron metabolism may lead to major skeletal disorders. Overall, iron homeostasis could represent a potential target for preventing and treating osteoporosis and for improving therapeutic strategies for osteosarcoma. Full article

Background: Seaweed consumption is a major source of dietary iodine in Korea, particularly among lactating women during the postpartum period. This practice raises concerns regarding short-term iodine excess and its potential effects on thyroid function. We examined the prevalence of thyroid disease and hormone abnormalities 1 year after childbirth among postpartum women with varying levels of seaweed-derived iodine intake. Methods: Between 17 July 2021 and 10 December 2021, 147 postpartum women were enrolled within two weeks after childbirth at postpartum care centers in Korea, which provide structured residential maternal and infant care, including standardized meals, during the early postpartum period. Participants provided informed consent and completed baseline questionnaires and dietary assessments. Iodine intake, including seaweed soup consumption during the 8-week postpartum period, and infant growth indicators were evaluated. A total of 81 participants completed the 1-year follow-up. At follow-up, dietary records, thyroid disease prevalence, hormone levels, urinary iodine concentration, and infant growth indicators were assessed. Results: At 1 year, none of the 81 participants had thyroid disease. The prevalence of abnormal triiodothyronine (T3), free thyroxine (FT4), and thyroid-stimulating hormone (TSH) was analyzed by iodine-intake quartiles, revealing no significant differences (T3: p = 0.4175; FT4: p = 0.1591; TSH: p = 0.9344). Conclusions: These findings suggest that the evidence regarding an association between short-term postpartum iodine intake and thyroid outcomes one year after childbirth remains inconclusive. Owing to the limited sample size, high attrition, and observational design, the study may have been underpowered to detect clinically meaningful differences, and potential effects cannot be excluded. Therefore, these results should be interpreted cautiously, and larger, well-designed longitudinal studies with repeated thyroid assessments are needed to better clarify the long-term implications of postpartum iodine exposure. Full article