Project description:Sperm contains essential proteins for interaction with eggs, however, there are only several sperm proteins reported with important role in fertilization, and gamete proteomics are limited in marine invertebrate species. We present here a sperm proteomic profile of marine mussel Mytilus galloprovincialis. There are 816 proteins were successfully identified by LC-MS/MS based on 1-DE SDS-PAGE. Many of the identifications are relevant to sperm cell physiology and mtDNA functioning. The results will contribute to better understand the proteins involved in fertilization in M. galloprovincialis, as well as the other marine invertebrate species.

Project description:Dutch Harbor Marine Invasive Species BioBlitz

Project description:Microscopic Marine Invertebrate Microbiomes

Project description:Using in vivo interaction proteomics, two HAKAI-interacting zinc finger proteins, HIZ1 and HIZ2, were discovered as novel components of the Arabidopsis m6A writer complex. HAKAI is required for the interaction between HIZ1 and MTA. Whilst HIZ1 knockout plants have normal levels of m6A, plants in which it is overexpressed show reduced methylation. In addition, HIZ1 was found to be involved in root hair development upon auxin transport inhibition in a HAKAI-dependent manner. Mutant plants lacking HIZ2 are viable but have an 85% reduction in m6A abundance and show severe developmental defects. Our findings suggest that HIZ1 appears to be a HAKAI-dependent negative regulator of m6A deposition and HIZ2 is a novel and essential member of the Arabidopsis m6A writer complex.

Project description:Using in vivo interaction proteomics, two HAKAI-interacting zinc finger proteins, HIZ1 and HIZ2, were discovered as novel components of the Arabidopsis m6A writer complex. HAKAI is required for the interaction between HIZ1 and MTA. Whilst HIZ1 knockout plants have normal levels of m6A, plants in which it is overexpressed show reduced methylation. In addition, HIZ1 was found to be involved in root hair development upon auxin transport inhibition in a HAKAI-dependent manner. Mutant plants lacking HIZ2 are viable but have an 85% reduction in m6A abundance and show severe developmental defects. Our findings suggest that HIZ1 appears to be a HAKAI-dependent negative regulator of m6A deposition and HIZ2 is a novel and essential member of the Arabidopsis m6A writer complex.

Project description:BOEM-IZ Marine Invertebrate BARCODE

Project description:E3 ubiquitin-ligases are important for the cellular protein homeostasis and their deregulation is implicated in cancer. The E3 ubiquitin-ligase Hakai is involved in tumour progression and metastasis, through the regulation of the tumour suppressor E-cadherin. Hakai is overexpressed in colon cancer, however, the implication in colitis-associated cancer is unknown. Here, we investigated the potential role of Hakai in intestinal inflammation and cancer bowel disease.Several mouse models of colitis and associated cancer were used including AOM-DSS, acute colitis, and genetically modified mice deficient for the IL-10 gene, to analyse Hakai expression by immunohistochemistry. Interactome analysis of Hakai was performed and effect on selected protein was determined by plasmid and siRNA transfection, western-blotting, immunoprecipitation, immunofluorescence and ubiquitination assays. Lipid accumulation was assayed by oil red staining. Immunohistochemistry was also performed in inflamed colon biopsies from ulcerative colitis, Crohn's disease and colorectal cancer patients. Our results show that Hakai was downregulated in inflammatory tissues in different mouse models. Fatty Acid Synthase (FASN) protein was identified as a novel Hakai-interacting protein. Hakai induces FASN ubiquitination and degradation via lysosome, thus regulating FASN-mediated lipid accumulation. An inverse expression of FASN with Hakai expression was detected in inflammatory AOM/DSS mouse model. In conclusion, Hakai regulates FASN ubiquitination and degradation, resulting in the regulation of FASN-mediated lipid accumulation, which is associated to the development of inflammatory bowel disease. The interaction between Hakai and FASN may be an important mechanism for the homeostasis of intestinal barrier function and in the pathogenesis of this disease.

Project description:N6-methyladenosine (m6A) is an abundant modification in eukaryotic mRNA, regulating mRNA dynamics by influencing mRNA stability, splicing, export and translation. Recent studies discovered m6A methyltransferases (?writer?), demethylases (?eraser?) and binding proteins (?reader?), which modulate m6A methylation. However, the precise m6A regulating machinery still remains incompletely understood. Here we demonstrate that ZC3H13, a zinc finger protein, plays an essential role in modulating m6A methylation on polyadenylated RNA in the nucleus. ZC3H13 exists in an evolutionary-conserved macromolecular complex containing WTAP, Virilizer and Hakai. We confirm the interaction among those proteins and demonstrate that knockdown of Zc3h13 in mouse embryonic stem cell (mESC) significantly decreases global m6A level on mRNA, mainly at 3? untranslated regions (3? UTR). Interestingly, fractionation assays show that upon Zc3h13 knockdown a great majority of WTAP, Virilizer and Hakai translocate to the cytoplasm and the nuclear presence of the methyltransferase Mettl3 and Mettl14 also decrease significantly. In contrast, knockdown of WTAP, Virilizer or Hakai does not change the nuclear localization of Zc3h13. This suggests that Zc3h13 is required for nuclear localization of the Zc3h13-WTAP-Virilizer-Hakai complex, which is important for RNA m6A methylation. Finally, Zc3h13 depletion, as does WTAP, Virilizer or Hakai, impairs self-renewal and triggers mESC differentiation. Taken together, our findings demonstrate that Zc3h13 plays an essential role in anchoring WTAP, Virilizer and Hakai in the nucleus to facilitate m6A methylation and to regulate mESC self-renewal.

Project description:Proteome analysis of the surface matrix of chitinous barrier membranes of the tunicate Ciona intestinalis Type A, a marine filter-feeding invertebrate chordate. This chitinous membrane separate food microbes from the gut epithelium, as a physical barrier. As controls, we used mucus cords from the esophagus.

Project description:Marine invertebrates of the 2017 MarineGEO Kaneohe Bay BioBlitz