Insights into the role of the (alpha+beta) insertion in the TIM-barrel catalytic domain, regarding the stability and the enzymatic activity of chitinase A from Serratia marcescens.

Chitinase A (ChiA) from Serratia marcescens is a mesophilic enzyme with high catalytic activity and high stability. The crystal structure of ChiA has revealed a TIM-barrel fold of the catalytic domain, an (alpha+beta) insertion between the B7 beta-strand and A7 alpha-helix of the TIM-barrel, an FnIII domain at the N-terminus of the molecule and a hinge region that connects the latter to the catalytic domain. In this study, the role of the (alpha+beta) domain on the stability, catalytic activity and specificity of the enzyme was investigated by deleting this domain and studying the enzymatic and structural properties of the resulting truncated enzyme. The obtained data clearly show that by removing the (alpha+beta) domain, the thermal stability of the enzyme is substantially reduced, with an apparent T(m) of 42.0+/-1.0 degrees C, compared to the apparent T(m) of 58.1+/-1.0 degrees C of ChiA at pH 9.0. The specific activity of ChiADelta(alpha+beta) was substantially decreased, the pH optimum was shifted from 6.5 to 5.0 and the substrate and product specificities were altered.

The stability of the archaeal HU histone-like DNA-binding protein from Thermoplasma volcanium.

The complete genome analysis of the archaeon Thermoplasma volcanium has revealed a gene assigned to encode the histone-like DNA-binding protein HU. Thermoplasma volcanium is a moderate thermophile growing around 60 degrees C and it is adaptable to aerobic and anaerobic environment and therefore it is unique as a candidate for the origin of eukaryotic nuclei in the endosymbiosis hypothesis. The HU protein is the major component of the bacterial nuclei and therefore it is an important protein to be studied. The gene for HUTvo protein (huptvo) was cloned from the genomic DNA of T. volcanium and overexpressed in Escherichia coli. A fast and efficient purification scheme was established to produce an adequate amount of bioactive protein for biochemical and biophysical studies. Highly purified HUTvo was studied for its DNA-binding activity and thermostability. As studied by circular dichroism and high-precision differential scanning microcalorimetry, the thermal unfolding of HUTvo protein is reversible and can be well described by a two-state model with dissociation of the native dimeric state into denatured monomers. The G versus T profile for HUTvo compared to the hyperthermophilic marine eubacterial counterpart from Thermotoga maritima, HUTmar, clearly shows that the archaeal protein has adopted a less efficient molecular mechanism to cope with high temperature. The molecular basis of this phenomenon is discussed.