Peptide: N- glycanase is expressed in prestalk cells and plays a role in the differentiation of prespore cells during development of Dictyostelium discoideum.

Peptide: N- glycanase (PNGase) enzyme is found throughout eukaryotes and plays an important role in the misfolded glycoprotein degradation pathway. This communication reports the expression patterns of the pngase transcript (as studied by the analysis of β- galactosidase reporter driven by the putative pngase promoter) and protein (as studied by the analysis of β- galactosidase reporter expressed under the putative pngase promoter as a fusion with the pngase ORF) during development and further elucidated the developmental defects of the cells lacking PNGase (png-). The results show that the DdPNGase is an essential protein expressed throughout development and β- galactosidase activity was present in the anterior part of the slug. In structures derived from a null mutant for pngase, the prestalk A and AO patterning was expanded and covered a large section of the prespore region of the slugs. When developed as chimeras with wild type, the png- cells preferentially populate the prestalk/stalk region. When the mutants were mixed in higher ratios, they also tend to form the prespore/spore cells. The results emphasize that the DdPNGase has an essential role during development and the mutants have defects in a system that changes the physiological dynamics in the prespore cells. DdPNGase play a role in development both during aggregation and in the differentiation of prespore cells.

Optimization of b-galactosidase production using Kluyveromyces lactis NRRL Y-8279 by response surface methodology

This paper investigates the production and optimization of b-galactosidase enzyme using synthetic medium by Kluyveromyces lactis NRRL Y-8279 in shake flask cultures. Among the different cell disintegration methods used, the highest specific activity was obtained when the cells were permeabilized using isoamyl alcohol. Response surface methodology was used to investigate the effects of four fermentation parameters (agitation speed, pH, initial substrate concentration and incubation time) on b-galactosidase enzyme production. Results of the statistical analysis showed that the fit of the model was good in all cases. Maximum specific enzyme activity of 4218.4 U g-1 was obtained at the optimum levels of process variables (pH 7.35, agitation speed 179.2 rpm, initial sugar concentration 24.9 g l-1 and incubation time 50.9 hrs). The response surface methodology was found to be useful in optimizing and determining the interactions among process variables in b-galactosidase enzyme production.