Abstract
The mycelium of Mucor rouxii reached a 50% degree of lysis after 50 days incubation, and was then stable with the incubation time. The pH of the medium was 4.3 when autolysis began, rising to pH 7.6 after 6 days of autolysis and remaining there for the duration of the experiment. Maximum degradation of mycelium occurs during the first days of autolysis. Glucosamine is present in the culture liquid during all the autolytic process. Enzymes implicated in the degradation of chitosan and chitin were studied in the culture fluid during autolysis. An exochitosanase activity was detected after a day of autolysis, and its activity increased during 20 days of autolysis and afterwards remained constant until the end of the process. An endochitosanase activity was detected in the culture fluid from the beginning of the autolysis, having its maximum activity after 34 days of incubation. Both activities show an optimum pH of 5.5, but the pH range of activity for endochitosanase was broader than for exochitosanase. Both activities were not inhibited by 0.5 mM glucosamine. Activities of the enzymes B-N-acetylglucosaminidase and chitinase were not found. The chitosan content in the cell walls decreased with the incubation time. In these cell walls the chitin content experienced an increase at the beginning of the autolysis, decreasing afterwards. The enzymatic complex obtained from autolyzed cultures of M. rouxii hydrolyzed 2-day-old cell walls of this fungus. The hydrolysis was 21% after 24 h of incubation, liberating glucose and glucosamine. As a consequence protoplasts from M. rouxii germinated spores were obtained with its own lytic enzymes in adequate osmotic conditions. The involvement of chitosanases in the autolysis of this fungus have been studied.
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