Abstract
Cholesterol is one of the most ubiquitous compounds in nature. The 9,10-seco-pathway for the aerobic degradation of cholesterol was established thirty years ago. This pathway is characterized by the extensive use of oxygen and oxygenases for substrate activation and ring fission. The classical pathway was the only catabolic pathway adopted by all studies on cholesterol-degrading bacteria. Sterolibacterium denitrificans can degrade cholesterol regardless of the presence of oxygen. Here, we aerobically grew the model organism with 13C-labeled cholesterol, and substrate consumption and intermediate production were monitored over time. Based on the detected 13C-labeled intermediates, this study proposes an alternative cholesterol catabolic pathway. This alternative pathway differs from the classical 9,10-seco-pathway in numerous important aspects. First, substrate activation proceeds through anaerobic C-25 hydroxylation and subsequent isomerization to form 26-hydroxycholest-4-en-3-one. Second, after the side chain degradation, the resulting androgen intermediate is activated by adding water to the C-1/C-2 double bond. Third, the cleavage of the core ring structure starts at the A-ring via a hydrolytic mechanism. The 18O-incorporation experiments confirmed that water is the sole oxygen donor in this catabolic pathway.
Highlights
Steroids are ubiquitous and structurally diverse in nature
The addition of a,a9-D to the G. cholesterolivorans culture resulted in the accumulation of AD and ADD, indicating an interruption in the cholesterol catabolic pathway (Figure 2AII)
Steroid C26-hydroxylase activity was detected in aerobically cholesterol-grown G. cholesterolivorans cells, but not in S. denitrificans cells (Table S1). These results suggested that S. denitrificans may adopt an alternative pathway to degrade cholesterol
Summary
Steroids are ubiquitous and structurally diverse in nature. Cholesterol is an essential structural component of animal cell membranes where it acts as a regulator of membrane fluidity and permeability. Cholesterol serves as a crucial precursor for the biosynthesis of steroid hormones, bile acids, and vitamin D. Plants [1,2] and fungi [3,4] synthesize small quantities of cholesterol. Eukaryotes are the main producers of steroids, they lack degradation pathways for recycling the carbon content of these compounds. The degradation of steroids is dominated by bacteria [5]. Because steroids have limited functional groups, they are usually attacked by bacterial oxygenases using molecular oxygen as a co-substrate [6,7]
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