IDENTIFICATION OF PUTATIVE-S-ADENOSYL-L-METHIONINE: PHOSPHOETHANOLAMINE-N-METHYLTRANSFERASE T-DNA MUTANTS IN ARABIDOPSIS

Gleason, Amber

07 1900

<p> Some plants such as spinach, sugar beet, and wheat accumulate the quaternary ammonium compound glycine betaine when exposed to stresses in their environment. Environmental stress can be in the form of an excess or deficiency of water, high salt content, and/or exposure to excessively low or high temperatures and many if not all of these stresses are associated with cell dehydration. </p> <p> Glycine betaine is an organic solute that is believed to help restore the osmotic potential of a cell undergoing dehydration by reducing water loss and preventing damage to the structure and function of macromolecules. However, many plants such as Arabidopsis, tobacco, and rice do not accumulate glycine betaine. Given the perceived benefits of glycine betaine production by plants under stress, studies have been carried out to identify factors regulating its production. </p> <p> Glycine betaine is synthesized by the two-step oxidation of choline. The capacity to synthesize phosphocholine for choline production has been found to limit the production of glycine betaine in non-accumulating plants such as tobacco. As such, genetic engineering has been used to enhance the production of choline to up-regulate the synthesis of glycine betaine. This strategy has required knowledge of the enzyme(s) catalyzing the three N-methylation steps of the phosphocholine biosynthetic pathway. </p> <p> This study focused on a gene product identified as putative-phosphoethanolamine N-methyltransferase (putative PEAMT) based upon its similarity to a spinach Nmethyltransferase known to convert phosphoethanolamine to phosphocholine. This gene is located at the locus Atlg73600 on chromosome I of Arabidopsis and its predicted amino acid sequence has high similarity to two other genes encoding N-methylating enzymes located at At3 g 18000 (a biochemically confirmed PEAMT) and At 1 g48600 (annotated as a putative PEAMT). </p> <p> In this study, publicly available microarray data was examined to identify an expression profile of transcripts associated with the Atlg73600 gene in organs and tissues of Arabidopsis at various developmental stages. A summary of the micro array data shows the highest abundance of transcripts for Atlg73600 to be in the rosette leaves of Arabidopsis at 18.0- 20.9 days of growth. </p> <p> Arabidopsis plants grown from seeds from four SALK lines reported to have a TDNA insert in the Atlg73600 gene were screened for the presence of a T-DNA tag using a three primer PCR design strategy. Individual plants from two of the lines were found to have a T-DNA insert present. RT-PCR was then used to analyze the expression of transcripts associated with the Atlg73600 gene in these mutant lines. Transcripts were not detected among the amplified products from eDNA produced from the SALK line designated 062703 but they were found at reduced levels in eDNA of SALK line 016929c. </p> <p> In future studies the two T -DNA mutant lines identified in this study can be used to assign a biological role for the product of the Atlg73600 gene by examining the phenotype of these mutant plants relative to that of wild-type plants under normal and/or stressed conditions. The line found with no expression associated with the Atlg73600 gene will be useful in crosses with T -DNA knock-out mutants of genes at loci At3g18000 and Atlg48600. Systematic knock-outs for each of the genes in isolation and in combination will help discern whether there is functional redundancy in their biological roles or if their individual expression contributes uniquely towards the development of a plant or its stress response. Given the associated role for PEAMT in phosphatidylcholine metabolism, lipidomics could be used to determine if the composition of the plant membranes is altered relative to wild-type when the Atlg73600 gene is knocked-out. </p> / Thesis / Master of Science (MSc)

PUTATIVE-S-ADENOSYL-L-METHIONINE

PHOSPHOETHANOLAMINE-N-METHYLTRANSFERASE

T-DNA

ARABIDOPSIS