Effect of ammonia on the synthesis and function of the N 2 -fixing enzyme system in Clostridium pasteurianum

Abstract

The N(2)-fixing system of Clostridium pasteurianum operates under regulatory controls; no activity is found in cultures growing on excess NH(3). The conditions which are necessary for the synthesis and function of this system were studied in whole cells by using acetylene reduction as a sensitive assay for the presence of the N(2)-fixing system. Nitrogenase of N(2)-fixing cultures normally can fix twice as much N(2) as is needed to maintain the growth rate. When cultures that have grown for four or more generations on NH(3) exhaust NH(3) from the medium, a diauxic lag of about 90 min ensues before growth is resumed on N(2). Neither N(2)-fixing nor acetylene reduction activity can be detected before growth is resumed on N(2). N(2) is not a necessary requirement for this synthesis since under argon that contains less than 10(-8)m N(2), the N(2)-fixing system is made. If NH(3) is added to N(2)-dependent cultures, synthesis of the enzyme system is abruptly stopped, but the enzyme already present remains stable and functional for at least 6 hr (over three generations). Cultures grown under argon in a chemostat controlled by limiting ammonia have derepressed nitrogenase synthesis. If the argon is removed and replaced by N(2), partial repression of nitrogenase occurs.