Investigation of genes and proteins involved in xylan biosynthesis

Sammanfattning: Wood formation or xylogenesis is a fundamental process for so diverse issues as industry, shelter and a sustainable environment. Wood is comprised of secondary xylem, rigid large cells with thick cell walls that are lignified. The basis for the sturdy cells is an advanced composite made up of cellulose fibers cross-linked by hemicelluloses and finally embedded in lignin. This fiber-composite is the secondary cell walls of woody plants. Cell division and differentiation is regulated by switching on and off genes. Proteins encoded by these genes execute the major functions in the cells. They steer the entire machinery operating the structure and function of the cells, maintaining growth and synthesising essential products such as the cell wall carbohydrates. Here we describe the investigation of genes and proteins involved in xylan formation as well as the development of a model system that will aid the functional analysis of wood formation. Xylan is the main hemicellulose or cross linking glycan in dicot wood and thereby one of the most abundant carbohydrates on earth. We demonstrate that hybrid aspen cell suspension cultures can be used as a model system for secondary cell wall formation. We have also examined glycosyltransferases from CAZy family 43 that play a part in secondary cell wall formation. We have focused on one of these, Pt×tGT43A, a likely ortholog of Arabidopsis IRX9, which plays a crucial role in xylan formation. The protein was transiently expressed in Nicotiana benthamiana and its function and localization is described. Also, we investigate a glycoside hydrolase, Pt×tXyn10A, involved in wood formation. Its role is not clear but it most likely modifies xylan as it gets incorporated into the secondary cell wall after secretion from the Golgi. This influences the interaction between cellulose, xylan and lignin in the finished wood cell. We have also cloned a transcription factor, Pt×tMYB021, a likely ortholog of Arabidopsis MYB46 and we show that it activates GT43A, GT43B and Xyn10A. By analysis of the promoter sequences we identify a CA-rich motif putatively important for xylem-specific genes. By mastering proteins involved in xylogenesis we will acquire the tools to improve and develop the wood product market. Xylan is an immense unexploited source of renewable carbohydrate. New products envisioned include e.g. faster growing trees, changed fiber characteristics, optimised utilization of wood carbohydrates for biofuels and biomaterials as well as invention of intelligent materials by biomimetic engineering.