Your search keyword '"Arioli, Tony"' showing total 2 results

1. A mutation in an Arabidopsis ribose 5-phosphate isomerase reduces cellulose synthesis and is rescued by exogenous uridine.

Author

Howles, Paul A., Birch, Rosemary J., Collings, David A., Gebbie, Leigh K., Hurley, Ursula A., Hocart, Charles H., Arioli, Tony, and Williamson, Richard E.

Subjects

ARABIDOPSIS, MONOSACCHARIDES, URIDINE, PHOSPHATES, ISOMERASES

Abstract

The Arabidopsis radial swelling mutant rsw10 showed ballooning of root trichoblasts, a lower than wild-type level of cellulose and altered levels of some monosaccharides in non-cellulosic polysaccharides. Map-based cloning showed that the mutated gene ( At1g71100) encodes a ribose 5-phosphate isomerase (RPI) and that the rsw10 mutation replaces a conserved glutamic acid residue with lysine. Although RPI is intimately involved with many biochemical pathways, media supplementation experiments suggest that the visible phenotype results from a defect in the production of pyrimidine-based sugar–nucleotide compounds, most likely uridine 5′-diphosphate–glucose, the presumed substrate of cellulose synthase. Two of three RPI sequences in the nuclear genome are cytoplasmic, while the third has a putative chloroplast transit sequence. The sequence encoding both cytoplasmic enzymes could complement the mutation when expressed behind the CaMV 35S promoter, while fusion of the RSW10 promoter region to the GUS reporter gene established that the gene is expressed in many aerial tissues as well as the roots. The prominence of the rsw10 phenotype in roots probably reflects RSW10 being the only cytosolic RPI in this tissue and the gene encoding the plastid RPI being relatively weakly expressed. We could not, however, detect a decrease in total RPI activity in root extracts. The rsw10 phenotype is prominent near the root tip where cells undergo division, endoreduplication and cell expansion and so are susceptible to a restriction in de novo pyrimidine production. The two cytosolic RPIs probably arose in an ancient duplication event, their present expression patterns representing subfunctionalization of the expression of the original ancestral gene. [ABSTRACT FROM AUTHOR]

Published

2006

2. The cellulose-deficient Arabidopsis mutantrsw3 is defective in a gene encoding a putative glucosidase II, an enzyme processing N-glycans during ER quality control.

Author

Burn, Joanne E., Hurley, Ursula A., Birch, Rosemary J., Arioli, Tony, Cork, Ann, and Williamson, Richard E.

Subjects

ARABIDOPSIS thaliana, GLUCOSIDASES

Abstract

Summary: rsw3 is a temperature-sensitive mutant of Arabidopsis thaliana showing radially swollen roots and a deficiency in cellulose. The rsw3 gene was identified by a map-based strategy, and shows high similarity to the catalytic α-subunits of glucosidase II from mouse, yeast and potato. These enzymes process N-linked glycans in the ER, so that they bind and then release chaperones as part of the quality control pathway, ensuring correct protein folding. Putative β-subunits for the glucosidase II holoenzyme identified in the Arabidopsis and rice genomes share characteristic motifs (including an HDEL ER-retention signal) with β-subunits in mammals and yeast. The genes encoding the putative α- and β-subunits are single copy and, like the rsw3 phenotype, widely expressed. rsw3 reduces cell number more strongly than cell size in stamen filaments and probably stems. Most features of the rsw3 phenotype are shared with other cellulose-deficient mutants, but some – notably, production of multiple rosettes and a lack of secreted seed mucilage – are not and may reflect glucosidase II affecting processes other than cellulose synthesis. The rsw3 root phenotype develops more slowly than the rsw1 and rsw2 phenotypes when seedlings are transferred to the restrictive temperature. This is consistent with rsw3 reducing glycoprotein delivery from the ER to the plasma membrane whereas rsw1 and rsw2 act more rapidly by affecting the properties of already delivered enzymes. [ABSTRACT FROM AUTHOR]

Published

2002