Hormonal Pathways Research Articles

Lufenuron affects the fecundity of Panonychus citri by regulating the methyl farnesoate-ponasteroneA network.

In insects, the juvenile hormone (JH) and 20-hydroxyecdysone (20E) pathways jointly regulate fecundity, but only methyl farnesoate (MF) and ponasteroneA exist in mites. Comparative transcriptomic analysis in Panonychus citri showed that E75B was significantly downregulated when exposed to lufenuron. Knockdown of E75B significantly affects the expression of vitellogenin (Vg), Fushi tarazu factor1 (Ftz-f1) and juvenile hormone acid O-methyltransferase (JHAMT), reducing fecundity in mites. The knockdown of Ftz-f1 produced a more significant effect than the knockdown of E75B, indicating that the ponasteroneA pathway positively regulates fecundity in P.citri. After the knockdown of JHAMT, the expression levels of both Vg and Ftz-f1 and fecundity were significantly increased, along with the inhibition of Kr-h1, suggesting that JHAMT was negatively correlated with fecundity in the regulatory network. Knockdown of Kr-h1 inhibited the expression of Vg and Ftz-f1 and fecundity, and whether the drop in fecundity is caused by Kr-h1 or Ftz-f1 is unclear. Subsequent feeding with MF induced Kr-h1 and Vg expression, whereas no significant effects were observed for JHAMT and Ftz-f1. Therefore, the MF pathway stimulates fecundity independently. RNA interference (RNAi) showed that JHAMT and Ftz-f1 inhibited each other, resulting in opposite effects of MF and ponasteroneA pathways on steady-state fecundity when either factor changed. Meanwhile, JHAMT knockdown led to increased fecundity, indicating that the stimulating effect of the ponasteroneA pathway was greater than the inhibiting effect of the MF pathway, and demonstrating the dominant role of the ponasteroneA pathway. Therefore, the interaction between JHAMT and Ftz-f1 may be closely associated with the maintenance of MF-ponasteroneA regulatory network homeostasis and is involved in the reduction of fecundity in P.citri induced by exposure to lufenuron.

Do 5-Alpha Reductase Inhibitors Influence the Features of Suspicious Lesions on Magnetic Resonance Imaging and Targeted Biopsy Results for Prostate Cancer Diagnosis?

Introduction: 5-alpha reductase inhibitors (5-ARIs) change hormonal pathways and reduce prostate size. We evaluated the effects of 5-ARIs on prostatic multiparametric magnetic resonance imaging (mpMRI) suspicious findings and in the identification of prostate cancer using targeted biopsies. Methods: We conducted a retrospective study including 600 consecutive patients who, between 2017 and 2021, underwent combined transperineal fusion biopsies. Primary outcomes were Prostate Imaging Reporting and Data System version 2 (PIRADS v2) scores and the identification of clinically significant prostate cancer from suspicious lesions (targeted CSPC). Outcomes were compared between patients treated with 5-ARIs for a minimum of 6 months and the other patients. Results: Patients treated with 5-ARIs were older (p < 0.001) with higher rates of previous prostate biopsies (p = 0.004). PIRADS scores were 3, 4, and 5 in 15 (29%), 28 (54%), and 9 (17%) patients among the 5-ARI group and 130 (24%), 308 (56%), and 110 (20%) patients among the others, and the scores were not different between the groups (p = 0.69). The targeted CSPC identification rate among 5-ARI patients was 31%, not different compared to the non-5-ARI group (p = 1). Rates of targeted CSPC for each PIRADS score were not affected by 5-ARI treatment. The 5-ARI was not associated with neither PIRADS ≥ 4 score nor targeted CSPC on logistic regression analyses (OR = 0.76, 95% CI 0.4–1.4 and OR = 1.02, 95% CI 0.5–1.9, respectively). Conclusions: 5-ARI treatment is not associated with PIRADS score alterations or targeted biopsy results. Patients treated by 5-ARIs with suspicious lesions should not be addressed differently during the mpMRI-related diagnostic process.

Abstract PR012: A novel plasma-based epigenomic assay for comprehensive profiling of cancerous and inflammatory disease states

Abstract Background: We developed a method for comprehensive epigenomic profiling from 1 ml of patient (pt) plasma, targeting histone modifications and DNA methylation. This approach can be applied to plasma from pts with cancer and inflammatory conditions, allowing us to infer expression levels of diagnostic markers and drug targets, measure activity of therapeutically targetable transcription factors, and detect non-genomic mechanisms of resistance. By examining the transcriptional status of therapeutic gene targets and pathways, our method addresses the need for new approaches in liquid biopsy (LBx) assays, providing clinically actionable information that enhances the understanding of cancer and inflammatory biology and therapeutic response. Methods: We developed an innovative multimodal assay capable of revealing genome-wide transcriptional activity of promoters and enhancers from chromatin, as well as surveying the DNA methylome. Utilizing this assay on plasma samples from pts with 5 non- cancer conditions and 15 different tumor types, we generated comprehensive genome-wide transcriptional profiles across 21 conditions. Results: We identified transcriptional activation in cancer pt plasma of cancer-associated biomarkers (e.g., HER2, DLL3) in a tumor-specific manner and in autoimmune disorders such as rheumatoid arthritis and systemic lupus erythematosus/lupus nephritis. Epigenomic profiling simultaneously inferred the expression of multiple pertinent ADC and radio-immune targets (e.g., MET, HER2, HER3, TROP2, B7H4 in breast cancer and PSMA in prostate cancer), and SLFN11, a biomarker for sensitivity to these agents. The multimodal platform assesses transcriptional regulation genome-wide, enabling analysis of select genes as well as related pathways. For example, a multimodal classifier robustly predicted HER2 status across multiple HER2-expressing tumors. HER2 classification of breast cancer pts by epigenomic LBx was concordant with standard tissue-based IHC for 64/72 (89%) breast cancer samples (AUC 0.9). Accurate classification was achieved for 11/14 (79%) gastroesophageal adenocarcinoma and 4/4 (100%) ovarian cancer pts. A multi-modal predictive model trained on FOLH1 plasma epigenomic regulatory signals demonstrated significant accuracy in predicting quantitative readouts from PSMA PET scans (total SUVmean) in metastatic castration resistance prostate cancer pts and was associated with response to pluvicto. Epigenomic signatures also delineated activation of the endocrine signaling pathway in breast cancer and multiple mechanisms of resistance to androgen receptor signaling inhibition in prostate cancer, including reactivation of the androgen receptor, glucocorticoid signaling bypass, and histological transformation to a neuroendocrine subtype. Conclusions: This comprehensive epigenomic LBx assay offers a platform for simultaneous genome-wide transcriptional assessment of disease and therapy-relevant genes and pathways, marking a paradigm shift in our ability to assess the underlying transcriptional states of cancer and inflammatory diseases. Citation Format: Travis Clark, Anthony D'Ippolito, Aparna Gorthi, Jonathon Beagan, Jamey Guess, Amy Donahue, Mandy Greene, Alyssa Lau, Fernando Ramirez, Kristian Cibulskis, Jenna Wurster, Michael Coyne, Mary McGillicuddy, Baovy Tran, Tyrone Tamakloe, Hathairat Sawaengsri, Corrie Painter, Juliann Chmielecki, Geoff Otto, Matthew Eaton, Carl Barrett. A novel plasma-based epigenomic assay for comprehensive profiling of cancerous and inflammatory disease states [abstract]. In: Proceedings of the AACR Special Conference: Liquid Biopsy: From Discovery to Clinical Implementation; 2024 Nov 13-16; San Diego, CA. Philadelphia (PA): AACR; Clin Cancer Res 2024;30(21_Suppl):Abstract nr PR012.

Nuclear receptor E75/NR1D2 promotes tumor malignant transformation by integrating Hippo and Notch pathways.

Hormone therapy resistance and the ensuing aggressive tumor progression present a significant clinical challenge. However, the mechanisms underlying the induction of tumor malignancy upon inhibition of steroid hormone signaling remain poorly understood. Here, we demonstrate that Drosophila malignant epithelial tumors show a similar reduction in ecdysone signaling, the main steroid hormone pathway. Our analysis of ecdysone-induced downstream targets reveals that overexpression of the nuclear receptor E75, particularly facilitates the malignant transformation of benign tumors. Genome-wide DNA binding profiles and biochemistry data reveal that E75 not only binds to the transcription factors of both Hippo and Notch pathways, but also exhibits widespread co-binding to their target genes, thus contributing to tumor malignancy. We further validated these findings by demonstrating that depletion of NR1D2, the mammalian homolog of E75, inhibits the activation of Hippo and Notch target genes, impeding glioblastoma progression. Together, our study unveils a novel mechanism by which hormone inhibition promotes tumor malignancy, and describes an evolutionarily conserved role of the oncogene E75/NR1D2 in integration of Hippo and Notch pathway activity during tumor progression.

Child health, nutrition and gut microbiota development during the first two years of life; study protocol of a prospective cohort study from the Khyber Pakhtunkhwa, Pakistan

Recent evidence suggests that the development of gut microbiota during infancy affects several metabolic, immune, and endocrine pathways in humans. An imbalance in gut microbiota diversity or function, also known as dysbiosis, not only affects early child growth and development, but is also linked with the development of chronic, non-communicable diseases in later life. The Child Health And Microbiome Development Study – Pakistan (CHAMP) study aimed to longitudinally assess gut microbiota development and associated factors (maternal, child, and demographic) during early childhood in populations residing in malnutrition-endemic communities in Pakistan. A prospective cohort of mother-infant pairs (n=70) will be recruited from District Swat, Pakistan, and followed for two years. Complete information about demographic characteristics, anti-natal and post-natal care, dietary intake, feeding practices, and child health will be collected at baseline and 3, 6, 12, 18, and 24 months. Anthropometric measurements (height, weight, mid-upper arm circumference, and head circumference), dry blood spots, and fecal samples were also collected. Ethical approval for the study was obtained from Khyber Medical University, Pakistan. The study is also registered on clincaltrial.gov (Ref no: NCT05793294). The study findings will help researchers understand gut microbiota development, associated factors, and their impact on longitudinal growth in infants during the first two years of life.

Ethylene and its crosstalk with hormonal pathways in fruit ripening: mechanisms, modulation, and commercial exploitation

Ethylene and its crosstalk with hormonal pathways in fruit ripening: mechanisms, modulation, and commercial exploitation

Transcriptional Profiling Analysis Providing Insights into the Harsh Environments Tolerance Mechanisms of Krascheninnikovia arborescens

Krascheninnikovia arborescens, an endemic shrub in China, thrives in desertification-prone environments due to its robust biomass, hairy leaves, and extensive root system. It is vital for ecological restoration and serves as a valuable forage plant. This study explored the molecular mechanisms underlying K. arborescens’ adaptation to desert conditions, focusing on its physiological, biochemical, and transcriptomic responses to drought, salt, and alkali stresses. The results revealed that the three stresses have significant impacts on the photosynthetic, antioxidant, and ion balance systems of the plants, with the alkali stress inducing the most pronounced changes and differential gene expression. The clustering and functional enrichment analyses of differentially expressed genes (DEGs) highlighted the enrichment of the induced genes in pathways related to plant hormone signaling, phenylpropanoid biosynthesis, and transcription factors following stress treatments. In these pathways, the synthesis and signal transduction of abscisic acid (ABA) and ethylene, as well as the flavonoid and lignin synthesis pathways, and transcription factors such as MYB, AP2/ERF, bHLH, NAC, and WRKY responded actively to the stress and played pivotal roles. Through the WGCNA analysis, 10 key modules were identified, with the yellow module demonstrating a high correlation with the ABA and anthocyanin contents, while the turquoise module was enriched in the majority of genes related to hormone and phenylpropanoid pathways. The analysis of hub genes in these modules highlighted the significant roles of the bHLH and MYB transcription factors. These findings could offer new insights into the molecular mechanisms that enable the adaptation of K. arborescens to desert environments, enhancing our understanding of how other desert plants adapt to harsh conditions. These insights are crucial for exploring and utilizing high-quality forage plant germplasm resources and ecological development, with the identified candidate genes serving as valuable targets for further research on stress-resistant genes.

Microbiota-Gut-Brain Axis in Age-Related Neurodegenerative Diseases.

Age-related neurodegenerative diseases (NDs) pose a formidable challenge to healthcare systems worldwide due to their complex pathogenesis, significant morbidity, and mortality. Scope and Approach: This comprehensive review aims to elucidate the central role of the microbiotagut- brain axis (MGBA) in ND pathogenesis. Specifically, it delves into the perturbations within the gut microbiota and its metabolomic landscape, as well as the structural and functional transformations of the gastrointestinal and blood-brain barrier interfaces in ND patients. Additionally, it provides a comprehensive overview of the recent advancements in medicinal and dietary interventions tailored to modulate the MGBA for ND therapy. Accumulating evidence underscores the pivotal role of the gut microbiota in ND pathogenesis through the MGBA. Dysbiosis of the gut microbiota and associated metabolites instigate structural modifications and augmented permeability of both the gastrointestinal barrier and the blood-brain barrier (BBB). These alterations facilitate the transit of microbial molecules from the gut to the brain via neural, endocrine, and immune pathways, potentially contributing to the etiology of NDs. Numerous investigational strategies, encompassing prebiotic and probiotic interventions, pharmaceutical trials, and dietary adaptations, are actively explored to harness the microbiota for ND treatment. This work endeavors to enhance our comprehension of the intricate mechanisms underpinning ND pathogenesis, offering valuable insights for the development of innovative therapeutic modalities targeting these debilitating disorders.

Peripubertal exposure to oxyfluorfen, a diphenyl herbicide, delays pubertal development in the male rat by antagonizing androgen receptor activity.

We recently identified the herbicide oxyfluorfen as an inhibitor of iodide uptake by the sodium iodide symporter (NIS), a key step in thyroid hormone synthesis, using in vitro assays. We also observed a suppression of serum T4 and T3 in juvenile rats exposed orally to oxyfluorfen for 4-8 days. The purpose of the present study was to further evaluate effects of an extended 31-day oral exposure using a male pubertal rat study (15 to 500 mg/kg). Oxyfluorfen delayed puberty at all doses (1.3 -3.5 days) suppressing ventral prostate at 62.5 mg/kg and above and seminal vesicle weights at 31.25 mg/kg and above with no effect on testosterone or luteinizing hormone. Serum T4 and T3 were suppressed by all doses up to 80%, with a linear increase in serum TSH. Based on delayed puberty without changes in testosterone, we hypothesized that oxyfluorfen interferes with androgen receptor (AR) function. Results from our Hershberger study, with oxyfluorfen (62.5 and 125 mg/kg) co-treated with testosterone proprionate (TP , 1 mg/kg) for 10 days showed 3 of 5 of the androgenic tissue weights were suppressed compared to TP alone indicating AR antagonism. We next confirmed this effect in an in vitro AR transcriptional activation reporter assay (0-20 μM) with 125 pM 5αDH-11-ketotestosterone and found concentration-dependent inhibition of AR luminescence activity (EC50 1.75 µM) without cytotoxicity. Here, we confirmed the endocrine disrupting effects of oxyfluorfen using both in vitro and in vivo evaluations of the thyroid hormone and AR pathways. This abstract doesn't necessarily reflect U.S. EPA policy.

Ex vivo and miniaturized in vitro models to study microbiota-gut-brain axis.

The microbiota-gut-brain axis involves complex bidirectional communication through neural, immune, and endocrine pathways. Microbial metabolites, such as short-chain fatty acids, influence gut motility and brain function by interacting with gut receptors and modulating hormone release. Additionally, microbial components such as lipopolysaccharides and cytokines can cross the gut epithelium and the blood-brain barrier, impacting immune responses and cognitive function. Ex vivo models, which preserve gut tissue and neural segments, offer insight into localized gut-brain communication by allowing for detailed study of nerve excitability in response to microbial signals, but they are limited in systemic complexity. Miniaturized in vitro models, including organ-on-chip platforms, enable precise control of the cellular environment and simulate complex microbiota-host interactions. These systems allow for the study of microbial metabolites, immune responses, and neuronal activity, providing valuable insights into gut-brain communication. Despite challenges such as replicating long-term biological processes and integrating immune and hormonal systems, advancements in bioengineered platforms are enhancing the physiological relevance of these models, offering new opportunities for understanding the mechanisms of the microbiota-gut-brain axis. This review aims to describe the ex vivo and miniaturized in vitro models which are used to mimic the in vivo conditions and facilitate more precise studies of gut brain communication.

The eyestalk photophore of Northern krill Meganyctiphanes norvegica (M. Sars) (Euphausiacea) re-investigated: Innervation by specialized ommatidia of the compound eye

Members of the Euphausiacea (“krill”) generate bioluminescence using light organs, the so-called photophores, including one pair associated with the eyestalks, two pairs on the thoracic segments, and four unpaired photophores on the pleon. The photophores generate light via a luciferin–luciferase type of biochemical reaction in light-emitting cells comprised in a photophore compartment called “lantern”. The behavioral significance of bioluminescence in krill is discussed controversially, and possible functions include a defensive function, camouflage by counter-shading, and intra-specific communication. Light production of all krill photophores is controlled by hormonal and neuronal pathways but our knowledge about the nature of these pathways is still rudimentary. Here, we provide a detailed description of the eyestalk photophore's histology in Northern krill Meganyctiphanes norvegica, and used immunohistochemistry combined with confocal laser-scan microscopy to explore this organ's serotonergic innervation. Furthermore, we provide evidence that the photophore is innervated by a distinct photophore nerve that originates from a specialized cluster of ca. 30 highly modified ommatidia at the dorsal rim of the compound eye that are optically isolated from the other ommatidia. Our findings suggest the compound eye – photophore link as a major anatomical axis to adjust the photophore activity.

Analysis of vitamin D metabolism, thyroid and autoimmune markers in the vitiligo pathways and their possible interaction with sleep.

Vitiligo is an autoimmune skin disease that can be influenced by stress, including that resulting from sleep deprivation and sleep disturbances. Sleep is essential in the regulation of several hormonal, metabolic and autoimmune pathways that may have important roles in vitiligo. This study aimed to investigate the potential interplay between hormonal, metabolic, and autoimmune markers in vitiligo patients, and the possible influence of sleep quality in these vitiligo pathways. A cohort of 30 vitiligo patients and 26 healthy controls were assessed for various laboratory markers, including thyroid-stimulating hormone (TSH), parathyroid hormone (PTH), serum calcium, 1.25(OH)2D, 25(OH)D, anti-thyroid peroxidase (anti-TPO), anti-thyroglobulin (anti-TG), and antinuclear antibodies (ANA). The study evaluated sleep quality using the Pittsburgh Sleep Quality Index (PSQI). Positive anti-TPO were found in the vitiligo group, but did not in the control group. Vitamin D 25(OH)D mean levels were clinically insufficient in both groups (< 30mg/dL). Reactive ANA was analyzed with 2 variables related to vitiligo: phototherapy and skin activity. No statistical correlation was found in the chi-square test on this relationship. Descriptive findings have shown that the positivity to anti-TPO and anti-TG, associated or not with reactive ANA, was higher in vitiligo group. Great part (85.7%) of vitiligo group were "poor sleepers" (PSQI > 5), which has increased (88.2%) when considering only individuals with signs of vitiligo activity. Autoimmune hypothyroidism and positive anti-TPO are expected in vitiligo, although this marker is not usually measured in the first laboratory screening to this disease. Adequate vitamin D levels may be a key adjuvant in skin pigmentation, and be related to sleep quality and immune regulation, as this vitamin can be related to better sleep and immunomodulation in autoimmune diseases. Evaluating ANA before phototherapy can be controversial, but it should be considered in cases with a poor response to this treatment, or when there is a higher risk of other autoimmune diseases. Poor sleep predominated in the vitiligo group, based on PSQI scores that reported worse subjective sleep in these patients. Worse sleep predominated in individuals with signs of skin activity and reactive autoimmune markers. Screening these components could be important in the management of vitiligo, as maintaining body homeostasis can help to improve the disease course. Sleep should be considered as a potential modulator of several multidirectional vitiligo pathways.

Targeting the hypothalamus for modeling age-related DNA methylation and developing OXT-GnRH combinational therapy against Alzheimer’s disease-like pathologies in male mouse model

The hypothalamus plays an important role in aging, but it remains unclear regarding the underlying epigenetics and whether this hypothalamic basis can help address aging-related diseases. Here, by comparing mouse hypothalamus with two other limbic system components, we show that the hypothalamus is characterized by distinctively high-level DNA methylation during young age and by the distinct dynamics of DNA methylation and demethylation when approaching middle age. On the other hand, age-related DNA methylation in these limbic system components commonly and sensitively applies to genes in hypothalamic regulatory pathways, notably oxytocin (OXT) and gonadotropin-releasing hormone (GnRH) pathways. Middle age is associated with transcriptional declines of genes which encode OXT, GnRH and signaling components, which similarly occur in an Alzheimer’s disease (AD)-like model. Therapeutically, OXT-GnRH combination is substantially more effective than individual peptides in treating AD-like disorders in male 5×FAD model. In conclusion, the hypothalamus is important for modeling age-related DNA methylation and developing hypothalamic strategies to combat AD.

Genetic Regulation of Fruit Shape in Horticultural Crops: A Review

The shape of fruits is a critical trait affecting the commercial value and consumer acceptance of horticultural crops. Genetic regulation of fruit shape involves complex interactions among multiple genes and environmental factors. This review summarizes recent advances in understanding the genetic mechanisms controlling fruit shape in several key horticultural crops, including tomato, pepper, cucumber, peach, and grape. We present the identification and characterization of genes and quantitative trait loci (QTLs) that influence fruit shape, focusing on the roles of genes such as OVATE, SUN, FAS, LC, ENO, GLOBE, CsSUN, CsFUL1, CsCRC, PpCAD1, PpOFP1, and VvSUN. This review highlights the importance of hormonal pathways, particularly those involving synthesis and concentration of cytokinins and brassinosteroids in shaping fruit morphology, and explores how these genes interact and form regulatory networks that collectively determine the final fruit shape. This knowledge provides a foundation for developing strategies to improve fruit quality and yield through genetic modification and breeding programs.

A Comprehensive Pan-Cancer Analysis of the Mitochondrial Uncoupling Protein UCP2, with a Focus on Sex and Gender-Related Aspects.

Mitochondrial uncoupling protein 2 (UCP2) plays a crucial role in regulating oxidative stress and cellular metabolism, positioning it as an important subject in oncological research. The involvement of UCP2 in cancer is complex and context-dependent, suggesting it as a potential therapeutic target. In this study, we aimed to perform a comprehensive pan-cancer analysis of UCP2, with a particular focus on gender-related malignancies such as breast (BRCA), prostate (PRAD), ovarian (OV), and testicular tumors (TGCT). We analyzed UCP2 expression in The Cancer Genome Atlas (TCGA), examining correlations with prognosis, tumor mutational burden (TMB), microsatellite instability (MSI), immune cell infiltration, immune checkpoint genes, genes involved in steroidogenesis, sex hormone receptor genes, and drug sensitivity. Significant variability in UCP2 expression was observed across cancer types. UCP2 levels were elevated in BRCA and OV but reduced in PRAD and TGCT. High UCP2 expression was associated with a better prognosis in OV and poorer overall survival in PRAD. Furthermore, UCP2 correlated with TMB and MSI in OV, TGCT, and BRCA. UCP2 expression was also linked to immune cell infiltration, immune checkpoint genes, steroidogenic genes, and sex hormone receptor genes, with variable effects depending on cancer type and gender. Additionally, UCP2 also demonstrated sensitivity to specific anticancer drugs. Our findings highlight the interplay between UCP2, immune and hormonal pathways, and drug responseand reveal potential opportunities for new therapeutic combinations, especially in gender-related cancers.

Environmental Pollutant Anthracene Induces ABA-Dependent Transgenerational Effects on Gemmae Dormancy in Marchantia polymorpha.

Anthracene, a polycyclic aromatic hydrocarbon (PAH) from fossil fuel combustion, poses significant environmental threats. This study investigates the role of abscisic acid (ABA) in the anthracene tolerance of the liverwort Marchantia polymorpha using mutants deficient in ABA perception (Mppyl1) or biosynthesis (Mpaba1). In this study, we monitored the role of ABA in the anthracene tolerance response by tracking two ABA-controlled traits: plant growth inhibition and gemmae dormancy. We found that the anthracene-induced inhibition of plant growth is dose-dependent, similar to the growth-inhibiting effect of ABA, but independent of ABA pathways. However, gemmae dormancy was differentially affected by anthracene in ABA-deficient mutants. We found that gemmae from anthracene-exposed WT plants exhibited reduced germination compared to those from mock-treated plants. This suggests that the anthracene exposure of mother plants induces a transgenerational effect, resulting in prolonged dormancy in their asexual propagules. While Mppyl1 gemmae retained a dormancy delay when derived from anthracene-exposed thalli, the ABA biosynthesis mutant Mpaba1 did not display any significant dormancy delay as a consequence of anthracene exposure. These results, together with the strong induction of ABA marker genes upon anthracene treatment, imply that anthracene-induced germination inhibition relies on ABA synthesis in the mother plant, highlighting the critical role of MpABA1 in the tolerance response. These findings reveal a complex interplay between anthracene stress and ABA signaling, where anthracene triggers ABA-mediated responses, influencing reproductive success and highlighting the potential for leveraging genetic and hormonal pathways to enhance plant resilience in contaminated habitats.

Differential modulation of hormonal pathways by strigolactone and karrikin signaling

Differential modulation of hormonal pathways by strigolactone and karrikin signaling

Insights into the Sex-Related Effects of Dietary Polyphenols and Metabolic Disruptors on Inflammatory and (Neuro) Endocrine Pathways in Obesity: The HEAL Project.

this study was performed under the umbrella of the Health Extended Alliance for Innovative Therapies, Advanced Lab Research, and Integrated Approaches of Precision Medicine (HEAL ITALIA) partnership and funded under the National Recovery and Resilience Plan, Mission 4 Component 2 Investment 1.3, and by the European Union. the overall objective of the HEAL project is to identify innovative and effective therapeutic approaches to reduce disease burden. The present research falls within Spoke 7: Prevention Strategies: Integrated and gender medicine approaches for prevention strategies based on environmental, lifestyle, and clinical biometric data. Obesity represents a primary risk factor worldwide for the onset of numerous life-threatening diseases, including metabolic, cardiovascular, and neurological diseases. Environmental and gender-related factors influence obesity development. However, the molecular mechanisms underlying the effects of those agents on different organs of the human body are not fully understood yet. here, we present a study protocol aimed at shedding light on (i) the complex interplays among adipose tissue, brain and gut in obesity, and (ii) the effects of specific dietary components and environmental metabolism-disrupting compounds on those interactions. To this purpose, we combined ex vivo, in vitro, and in vivo approaches to gain additional knowledge about the molecular mechanisms underlying connections between organs. the data provided by this study will contribute to defining new targets for therapeutic and/or preventive interventions, thereby allowing more personalized approaches to nutrition.

Golgiphagy: a novel selective autophagy to the fore.

The Golgi apparatus is the central hub of the cellular endocrine pathway and plays a crucial role in processing, transporting, and sorting proteins and lipids. Simultaneously, it is a highly dynamic organelle susceptible to degradation or fragmentation under various physiological or pathological conditions, potentially contributing to the development of numerous human diseases. Autophagy serves as a vital pathway for eukaryotes to manage intracellular and extracellular stress and maintain homeostasis by targeting damaged or redundant organelles for removal. Recent research has revealed that autophagy mechanisms can specifically degrade Golgi components, known as Golgiphagy. This review summarizes recent findings on Golgiphagy while also addressing unanswered questions regarding its mechanisms and regulation, aiming to advance our understanding of the role of Golgiphagy in human disease.

Combating wheat yellow mosaic virus through microbial interactions and hormone pathway modulations

BackgroundThe rhizosphere microbiome is critical for promoting plant growth and mitigating soil-borne pathogens. However, its role in fighting soil-borne virus-induced diseases, such as wheat yellow mosaic virus (WYMV) transmitted by Polymyxa graminis zoospores, remains largely underexplored. In this study, we hypothesized that during viral infections, plant microbiomes engage in critical interactions with plants, with key microbes playing vital roles in maintaining plant health. Our research aimed to identify microbial taxa that not only suppress the disease but also boost wheat yield by using a blend of techniques, including field surveys, yield assessments, high-throughput sequencing of plant and soil microbiomes, microbial isolation, hydroponic experiments, and transcriptome sequencing.ResultsWe found that, compared with roots and leaves, the rhizosphere microbiome showed a better performance in predicting wheat yield and the prevalence of P. graminis and WYMV across the three WYMV-impacted regions in China. Using machine learning, we found that healthy rhizospheres were marked with potentially beneficial microorganisms, such as Sphingomonas and Allorhizobium-Neorhizobium-Parararhizobium-Rhizobium, whereas diseased rhizospheres were associated with a higher prevalence of potential pathogens, such as Bipolaris and Fusicolla. Structural equation modeling showed that these biomarkers both directly and indirectly impacted wheat yield by modulating the rhizosphere microbiome and P. graminis abundance. Upon re-introduction of two key healthy rhizosphere biomarkers, Sphingomonas azotifigens and Rhizobium deserti, into the rhizosphere, wheat growth and health were enhanced. This was attributed to the up-regulation of auxin and cytokinin signaling pathways and the regulation of jasmonic acid and salicylic acid pathways during infections.ConclusionsOverall, our study revealed the critical role of the rhizosphere microbiome in combating soil-borne viral diseases, with specific rhizosphere microbes playing key roles in this process.9s7rr2_Gfui1KYKQgMf1m6Video