The current study focuses on the vascular cambium and the reiterative formation of phloem fiber bundles in cotton stems. The role of the TDIF-PXY-WOX pathway was examined in regulating cambial activity and the differentiation of phloem fibers. A study was conducted to identify and characterize the cotton WOX family genes, focusing on WOX4 and WOX14, aiming to identify and analyze their phylogenetic relationships, tissue-specific expression profiles, functional roles, and metabolic consequences. Through a sequence analysis of the Gossypium hirsutum genome, 42 cotton loci were identified as WOX family members. GhWOX4 exhibited a close homology to 7 loci, while GhWOX14 displayed homology with 8 loci. Tissue-specific expression analysis revealed prominent expression patterns of GhWOX4 and GhWOX14 in cotton internodes and roots, suggesting their involvement in vascular tissue development. Functional studies utilizing VIGS (virus-induced gene silencing) demonstrated that the knockdown of GhWOX4 and GhWOX14 resulted in a significant reduction in stem diameter and bast fiber production. This result suggests that secondary phloem fiber development is regulated by GhWOX4 and GhWOX14 genes in cotton. Additionally, the metabolic profiling of VIGS plants revealed significant alterations in amino acids, organic acids, and sugars, with implications for primary metabolic pathways. These findings suggest that GhWOX4 and …

In our studies, we used the environmentally important crustacean Hyalella azteca (H. azteca) as an invertebrate model and 17β-estradiol (E2) as a representative of environmental estrogenic endocrine disrupting compounds (EDCs) for proteomics-based investigations of endocrine disruptions in an aquatic ecosystem. Using liquid chromatography coupled with tandem mass spectrometry, our investigation focused for the first time on the recognition of biological and molecular events affected by E2 exposure with the long-term goal of identifying panels of potential biomarkers for environmental estrogenic endocrine disruption. We analyzed E2-induced changes in protein expressions in female and male H. azteca using label-free quantitative proteomics. With discovery-driven shotgun approach, we identified over 50 proteins that were affected by E2 in a sex-specific manner in our model organism. We selected four E2-regulated proteins (vitellogenin, cuticle protein CPR RR, titin and clumping factor A-like protein) for validation by parallel reaction monitoring-based targeted proteomics. Altogether, our proteomics studies have characterized for the first time E2-triggered endocrine disruption in H. azteca and recognized sex-specific changes in the male and female H. azteca's proteome after aquatic exposure to this estrogen. Through targeted proteomics, we were also able to quantitatively characterize a panel of selected proteins that showed distinctive sex-specific responses to …