The metabolism of cyclohexanol by Nocardia globerula CL1

Abstract

1. Nocardia globerula CL1, isolated by enrichment on cyclohexanol and grown with it as carbon source, oxidized it with a Qo₂ of 39μl/h per mg dry wt. and the overall consumption of 2.2μmol of oxygen/mol of substrate. Cyclohexanone, 2-hydroxycyclohexan-1-one dimer and cyclohexane-1,2-dione were oxidized with Qo₂ values similar to that for cyclohexanol whereas ∈-caprolactone and 6-hydroxycaproate were oxidized very slowly and adipate not all. 2. Disrupted cell suspensions could not be shown to catalyse the conversion of cyclohexanol into cyclohexanone. 3. A cyclohexanol-induced cyclohexanone oxygenase (specific activity 0.55μmol of NADPH oxidized/min per mg of protein) catalysed the consumption of 1mol of NADPH and 1mol of O₂ in the presence of 1mol of cyclohexanone. NADPH oxidation did not occur under anaerobic conditions. The only detected reaction product with 25000g supernatant was 6-hydroxycaproate. 4. Extracts of cyclohexanol-grown cells contained a lactone hydrolase (specific activity 15.6μmol hydrolysed/min per mg of protein), which converted ∈-caprolactone into 6-hydroxycaproate. 5. Incubation of 6-hydroxycaproate with 25000g supernatant in the presence of NAD⁺ resulted in NAD⁺ reduction under anaerobic conditions, oxygen consumption under aerobic conditions and the conversion of 6-hydroxycaproate into adipate. 6. Cyclohexanone oxygenase fractions devoid of ∈-caprolactone hydrolase catalysed the stoicheiometric formation of ∈-caprolactone from cyclohexanone in the presence of excess of NADPH. 7. The reaction sequence for the oxidation of cyclohexanone by N. globerula CL1 is: cyclohexanol → cyclohexanone → ∈-caprolactone → 6-hydroxycaproate → adipate. 8. It is suggested that the adipate may be further dissimilated by β-oxidation.