Bile acids microbial hydroxylation

Experimental procedures have been described in which the desired reactions have been carried out either by whole microbial cells or by enzymes (1—3). These involve carbohydrates (qv) (4,5) steroids (qv), sterols, and bile acids (6—11) nonsteroid cycHc compounds (12) ahcycHc and alkane hydroxylations (13—16) alkaloids (7,17,18) various pharmaceuticals (qv) (19—21), including antibiotics (19—24) and miscellaneous natural products (25—27). Reviews of the microbial oxidation of aUphatic and aromatic hydrocarbons (qv) (28), monoterpenes (29,30), pesticides (qv) (31,32), lignin (qv) (33,34), flavors and fragrances (35), and other organic molecules (8,12,36,37) have been pubflshed (see Enzyp applications, industrial Enzyt s in organic synthesis Elavors AND spices). 

Bile acids within the enterohepatic circulation that undergo absorption in the terminal ileum encounter a relatively low number of species and population of bacteria and return to the liver in portal blood relatively unchanged. However, the approximately 5% of the bile-acid pool that enters the colon provides substrate for the extensive microbial population that deconjugate and oxidise hydroxyl groups leading to formation of the secondary bile acids deoxycholic and lithocholic acids that are the major bile acids in faeces. 

The intestinal microflora of man and animals can biotransform bile acids into a number of different metabolites. Normal human feces may contain more than 20 different bile acids which have been formed from the primary bile acids, cholic acid and chenodeoxycholic acid [1-5], Known microbial biotransformations of these bile acids include the hydrolysis of bile acid conjugates yielding free bile acids, oxidation of hydroxyl groups at C-3, C-6, C-7 and C-12 and reduction of oxo groups to give epimeric hydroxy bile acids. In addition, certain members of the intestinal microflora la- and 7j8-dehydroxylate primary bile acids yielding deoxycholic acid and lithocholic acid (Fig. 1). Moreover, 3-sulfated bile acids are converted into a variety of different metabolites by the intestinal microflora [6,7]. 

Besides the functionalization of alkanes and cycloalkanes, from an early stage on enzymatic steroid hydroxylation with wild-t) e whole cells was a broadly studied research field, leading to a range of industrial processes [131]. An early example is the production of hydrocortisone by microbial lla-hydroxylation starting from bile acid. Further examples are microbial hydroxylations running at a scale of up to 200m at the company Schering AG. 

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