Proteomic analysis of primitive gut from bovine embryo

The development of embryo biotechnology in farm animals is hampered by embryo losses in first trimester of gestation, period in which the primitive gut is being established. The study of proteins contained in the primitive gut at this early stage of pregnancy may increase the knowledge about the molecular pathways involved in normal embryonic development and loss of embryos, as well as their involvement in organogenesis and cell differentiation.primitive gut from bovine embryos on day 39 SD± 4 of development (ranging from 33 to 45 days) were collected at a local slaugtherhouse. The samples were processed and pooled for label-free shotgun proteomics analysis using MudPIT (Multidimensional Protein Identification Technology) tandem MSE acquisition. Functional and pathway analysis using FatiGo (www.babelomics.org); Pathway Express (http://vortex.cs.wayne.edu/ ontoexpress) and Ingenuity Pathway Analysis (www.ingenuity.com) were used to identify relevant ontologies and canonical or noncanonical pathways represented by the expressed proteins in the primitive gut. A total of 74 protein sequences were identified corresponding to 30 unique proteins expressed by the bovine primitive gut. out of 30 unique proteins, 21 proteins were used on the ontology and pathway analysis. The ontology analysis showed an enrichment of ontologies related to binding (N=5); catalytic activity (N=6); intracellular organelle (N=6). There was an enrichment of ontologies associated to cytoskeleton modifications; cell differentiation process (N=3); cellular migration (N=4) and cell metabolism (N=6). Furthermore, the pathway and the network analysis showed an enrichment of cell-to-cell communication pathways such as gap and tight junction, and focal adhesion pathways. In addition, pathways involved in cellular movement (regulation of actin cytoskeleton and leukocyte transendothelial migration) were extremely enrichment in the group of proteins expressed by the bovine primitive gut. Our results suggested that the cells from primitive gut have high migratory profile and are composed of not fully differentiated cells with high cellular metabolism. The proper migration and differentiation of these cells would dictate the fate of the developing embryo. Moreover, understanding the function and interaction of proteins expressed by normal embryo will give clues of the impact of the reproductive biotechnologies in embryo development during the window between implantation and placentation. (AU)