An overview of yeast cell wall proteins and their contribution in yeast display system

Yeast surface display has become an increasingly popular tool for protein engineering and library screening applications. Although, recent advances have greatly expanded the capability of yeast surface display, the protein display system is still far away from industrial application. One of the major components of a stable, efficient and successful yeast surface display system is cell wall anchor protein with which our desired foreign protein will be attached. We studied 80 different yeast cell wall anchored proteins originated mostly from Saccharomyces cerevisiae and Candida albicans. We studied in details all the cell wall proteins in order to find out suitable cell wall proteins to recommend for the researchers to use in the construction of yeast display system. We considered selective physical properties of different yeast cell wall proteins that are crucial for selecting best suited cell surface anchor proteins which are molecular weight, binding domain of anchor protein, length of amino acid and fusion site. Finally, our studies showed that Ccw11, Ccw12. Cwp1, Cwp2, Dan1, Gas1, Gas5, Exg1, Ycr89, Ecm33, Pga4, Sap9, Sap10, Pst1, Pir1, Pir2, Pir3, Pir4, Cis1, Scw4, Scw6, Bgl2, Uth1, Scw1 are the promising and suitable cell wall anchor proteins could be used in construction of yeast cell surface display system. Additionally, this review presents detailed information about all the cell wall proteins in a single work. The future researchers in this field will be able to construct more efficient yeast display system for recombinant protein production at industrial scale using the knowledge presented in this work. Asian J. Med. Biol. Res. June 2019, 5(4): 246-257

Expressing Xylanases in Escherichia Coli by Cell Surface Display

In this research, xylan was utilized by a recombinant whole cell biocatalyst, which was developed by expressing three xylanases — β-xylosidase, endoxylanase, and α-arabinofuranosidase — on the surface of the E. coli BL21 (DE3). The xylanases were displayed on the surface of the cells by fusing with anchor proteins, Blc. The assimilation of xylan by cell surface display was the first step in the consolidated bioprocessing (CBP). This result shows that the engineering strains could be endowed with the ability to assimilate xylan. The co-display engineering strains utilized xylan and expressed less metabolic burden than the engineering strains secreting extracellular xylanases.

Promotion and inhibition of cardiac hypertrophy by A-kinase anchor proteins

Originally identified as mediators of cyclic adenosine monophosphate (cAMP) and protein kinase A signaling, A-kinase anchor proteins (AKAPs) are now recognized as a diverse family of molecular scaffolds capable of interacting with many other proteins. Members of the AKAP family within the heart can take on either pro- or anti-hypertrophic roles by interacting with a myriad of protein kinases and phosphatases in the process. AKAPs often form the core of large signaling complexes (or signalosomes) that allow multiple pathways to converge and functionally intertwine. Approximately 30% of AKAPs discovered to date are expressed in the heart, but the functions of many of these remain to be discovered. This review focuses on AKAPs that have been demonstrated to play roles in mediating cardiac hypertrophy.