Mass spectrometry reveals stable modules in holo and apo RNA polymerases I and III.

RNA polymerases are essential enzymes which transcribe DNA into RNA. Here, we obtain mass spectra of the cellular forms of apo and holo eukaryotic RNA polymerase I and III, defining their composition under different solution conditions. By recombinant expression of subunits within the initiation heterotrimer of Pol III, we derive an interaction network and couple this data with ion mobility data to define topological restraints. Our data agree with available structural information and homology modeling and are generally consistent with yeast two hybrid data. Unexpectedly, elongation complexes of both Pol I and III destabilize the assemblies compared with their apo counterparts. Increasing the pH and ionic strength of apo and holo forms of Pol I and Pol III leads to formation of at least ten stable subcomplexes for both enzymes. Uniquely for Pol III many subcomplexes contain only one of the two largest catalytic subunits. We speculate that these stable subcomplexes represent putative intermediates in assembly pathways.

High-level secretory expression of penicillin amidase from Providencia rettgeri in Saccharomyces cerevisiae: purification and characterization.

Heterologous production of the heterodimeric penicillin G amidase (PAC) from Providencia rettgeri was optimized in Saccharomyces cerevisiae. Several factors, including the effect of different growth and induction conditions, were identified to be critical for the enzyme overproduction and secretion. The PAC yield was significantly increased by more than 500-fold compared to that obtained in the native bacterium, and the recombinant enzyme was almost entirely secreted. Electrophoretic characterization of the secreted rPAC(Pr), which was purified over 20-fold by a combination of hydrophobic interaction and ion-exchange chromatography, demonstrated a microheterogeneity of the recombinant enzyme. The recombinant PAC(Pr) was further characterized in terms of specific activity, pH, and temperature profiles and kinetic parameters. The data presented here suggest that by overexpressing rPAC(Pr) in S.cerevisiae and purifying secreted enzyme from culture medium one can readily obtain a large amount of an alternative source of penicillin amidase with properties comparable to that of todays main industrial source of enzyme.