Biotechnology and Bioengineering, Vol.43, No.3, 225-231, 1994
Immobilization of a Proteinase from the Extremely Thermophilic Organism Thermus Rt41A
An extracellular proteinase from Thermus strain Rt41A was immobilized to controlled pore glass (CPG) beads. The properties of the free and CPG-immobilized enzymes were compared using both a large (azocasein) and a small (peptidase) substrate. The specific activity of the immobilized proteinase was 5284 azoU/mg with azocasein and 144 sucU/mg for SucAAPFpNA. The percentage recovery of enzyme activity was unaffected by pore size when it was immobilized at a fixed level of activity/g of beads, whereas it increased with increasing pore size when added at a fixed level/m2 of support. Saturation of the CPG beads was observed at 540 azoU/m2 of 105-nm beads. Lower levels (50 aZoU/M2 of 50-nm beads) were used in characterization experiments. The pH optimum of the immobilized Rt41A proteinase was 8.0 for azocasein and 9.5 for SucAAPFpNA, compared with the free proteinase which was 10.5 for both substrates. The immobilized enzyme retained 65% of its maximum activity against azocasein at pH 12, whereas the free proteinase retained less than 10% under the same conditions. Stability at 80-degrees-C increased on immobilization st all pH values between 5 and 11, the greatest increase in half-life being approximately 12-fold at pH 7.0. Temperature-activity profiles for both the free and immobilized enzymes were similar for both substrates. The stability of the immobilized proteinase, however, was higher than that of the free enzyme in the absence and presence of CaCl2. Overall, the results show that low levels of calcium (10 muM) protect against thermal denaturation, but that high calcium or immobilization are required to protect against autolysis.
Keywords:THERMOMONOSPORA-FUSCA YX;THERMOSTABLE PROTEINASE;SERINE PROTEASE;PURIFICATION;CALDOLYSIN;SUBSTRATE;STABILITY;ENZYMES;CALCIUM;IONS