Enhanced alkaline catalase production by Serratia marcescens FZSF01: enzyme purification, characterization, and recombinant expression

Background: Catalase (CAT) is an important enzyme that degrades H2O2 into H2O and O2. To obtain an efficient catalase, in this study, a new strain of high catalase-producing Serratia marcescens, named FZSF01, was screened and its catalase was purified and characterized. Results: After optimization of fermentation conditions, the yield of catalase produced by this strain was as high as 51,468 U/ml. This catalase was further purified using two steps: DEAE-fast flow and Sephedex-G150. The purified catalase showed a specific activity of 197,575 U/mg with a molecular mass of 58 kDa. This catalase exhibited high activity at 20­70°C and pH 5.0­11.0. Km of the catalase was approximately 68 mM, and Vmax was 1886.8 mol/min mg. This catalase was further identified by LC­MS/MS, and the encoding gene was cloned and expressed in Escherichia coli BL21 (DE3) with a production of 17,267 ± 2037 U/ml. Conclusions: To our knowledge, these results represent one of the highest fermentation levels reported among current catalase-producing strains. This FZSF01 catalase may be suitable for several industrial applications that comprise exposure to alkaline conditions and under a wide range of temperatures.

Novel nonsense mutation in the katA gene of a catalase-negative Staphylococcus aureus strain

Abstract We report the first description of a rare catalase-negative strain of Staphylococcus aureus in Chile. This new variant was isolated from blood and synovial tissue samples of a pediatric patient. Sequencing analysis revealed that this catalase-negative strain is related to ST10 strain, which has earlier been described in relation to S. aureus carriers. Interestingly, sequence analysis of the catalase gene katA revealed presence of a novel nonsense mutation that causes premature translational truncation of the C-terminus of the enzyme leading to a loss of 222 amino acids. Our study suggests that loss of catalase activity in this rare catalase-negative Chilean strain is due to this novel nonsense mutation in the katA gene, which truncates the enzyme to just 283 amino acids.

Listeria seeligeri Gene Encoding Heme-containing Catalase Produces No Activity in Streptococcus pneumoniae

Streptococcus pneumoniae is a facultative anaerobe lacking catalase enzyme and requires exogenous catalase supplemented to culture media for aerobic growth. We introduced a catalase gene (kat) of Listeria seeligeri into S. pneumoniae and tried to see if this listerial kat gene was expressed within the pneumococcal host. To clone the listerial kat gene in the pneumococcal chromosome, a non-replicating plasmid pAHA-LSt3, along with its original promoter region was used for integration the chromosome via homologous recombination. One of three resulting transformants was confirmed to contain the kat gene and designated as EHS2. In addition, the kat gene was subcloned in Escherichia coli in frame to the lac promoter of a shuttle vector to generate pDL-Kat, which was subsequently used for pneumococcal transformation. Four identical recombinants were identified to contain the plasmid with the kat gene. By performing RT-PCR, it was observed that the listerial kat gene was indeed transcribed within pneumococcal recombinants from its original promoter in the chromosome of EHS2 and from the lac promoter in the plasmid pDL-Kat. In contrast to the E. coli kat+ recombinants, however, the pneumococcal kat+ recombinants failed to reveal any catalase activities detectable by ferricyanide staining on non-denaturing PAGE. When the pDL-Kat plasmid DNA purified from pneumococci was allowed to transform E. coli again, many kat+ recombinants were obtained, ruling out the possibility of the defective kat E. coli transformants gene within pneumococci. The observation that the listerial kat gene in pneumococci was unable to produce the functional catalase enzyme, which requires a heme group at its active site and a cofactor NADPH, suggests pneumococcal defect in heme production.