Properties of a chimeric glucose dehydrogenase improved by site directed mutagenesis

Glucose dehydrogenase, a membrane bound enzyme oxidizing glucose to gluconic acid in the periplasmic space of Gram-negative bacteria plays a key role in mineral phosphate solubilization and is also an industrially important enzyme, being used as a glucose biosensor. A chimeric glucose dehydrogenase (ES chimera) encoding the N-terminal transmembrane domain from Escherichia coli and the C-terminal periplasmic domain from Serratia marcescens was constructed and the expression was studied on MacConkey glucose medium. The phosphate solubilizing ability of the chimeric GDH was also evaluated, substantiating the role of GDH in mineral phosphate solubilization (MPS). Four mutants of ES chimeric GDH were generated by site directed mutagenesis and the enzyme properties studied. Though the substrate affinity was unaltered for E742K and Y771M, the affinity of H775A and EYH/KMA to glucose and galactose decreased marginally and the affinity to maltose increased. Though Y771M showed a decreased GDH activity there was an increase in the heat tolerance. All the mutants showed an increase in the EDTA tolerance. The triple mutant EYH/KMA showed improved heat and EDTA tolerance and also an increase in affinity to maltose over the ES chimeric GDH

Ethyl methanesulfonate mutagenesis–eenhanced mineral phosphate solubilization by groundnut-associated Serratia marcescens GPS-5

Twenty-three bacterial isolates were screened for their mineral phosphate–solubilizing (MPS) ability on Pikovskaya and National Botanical Research Institute’s phosphate (NBRIP) agar. The majority of the isolates exhibited a strong ability to solubilize hydroxyapatite in both solid and liquid media. The solubilization in liquid medium corresponded with a decrease in the pH of the medium. Serratia marcescens GPS-5, known for its biocontrol of late leaf spot in groundnut, emerged as the best solubilizer. S. marcescens GPS-5 was subjected to ethyl methanesulfonate (EMS) mutagenesis, and a total of 1700 mutants, resulting after 45 minutes of exposure, were screened on buffered NBRIP medium for alterations in MPS ability compared with that of the wild type. Seven mutants with increased (increased-MPS mutants) and 6 mutants with decreased (decreased-MPS mutants) MPS ability were isolated. All seven increased-MPS mutants were efficient at solubilizing phosphate in both solid and liquid NBRIP medium. Among the increased-MPS mutants, EMS XVIII Sm-35 showed the maximum (40%) increase in the amount of phosphate released in liquid medium compared with wild-type S. marcescens GPS-5, therefore, it would be a useful microbial inoculant in groundnut cultivation. EMS III Sm W, a nonpigmented mutant, showed the lowest solubilization of phosphate among the 6 decreased-MPS mutants