Another compound with M+H=371, identified only in the AF13ΔnorA extract, eluted at 15.6 min. Taken together, the observed alteration in the metabolic flux between
the control and knockout transformants suggests the presence of other minor natural products and intermediates in the biosynthetic pathway to AFB1. An ion with the expected mass, elution time, and chromophore for AFOH (314 Da, 10.3 min) was detected in extracts of a 2-day A. flavus norA knockout culture, but not in the control culture extract. AFOH, after feeding to a strain of A. parasiticus with defective ordA, but intact norA, was readily oxidized to AFB1 (Fig. 4, lane 3); deoxyAFB1 was not detected. Similarly, AFOH was oxidized to AFB1 by yeast click here cells whether or not they expressed norA or ordA (Fig. 4, lanes 7–9). Orthologs of the aryl alcohol dehydrogenase-encoding gene norA are found in the gene clusters of all aflatoxin-
and sterigmatocystin-producing Aspergillus species (Ehrlich et al., 2005). The role of NorA in aflatoxin biosynthesis has not yet been defined. In previous studies, mutants of norA in A. parasiticus failed to show a detectable phenotype (J.W. Cary and K.C. Ehrlich; P.-K. Chang and K.C. Ehrlich, unpublished data). Our results show that A. flavus lacking norA accumulate deoxyAFB1. This is the first time that deoxyAFB1 has been shown to be a natural metabolite of aflatoxin-producing Aspergillus cultures. DeoxyAFB1 most likely results from dehydration of aflatoxicol (AFOH) as had been demonstrated previously in synthetic Ku-0059436 ic50 studies and confirmed here (Lau & Chu, 1983). AFOH is a natural enzymatic
reduction product of AFB1. Therefore, we suggest that A. flavus norA mutants lacking the aryl alcohol dehydrogenase accumulate an increased amount of the presumed NorA substrate AFOH, compared with cultures with intact norA, and that AFOH undergoes acid-catalyzed dehydration in the acidic growth medium to yield deoxyAFB1 (Fig. 5). The presence of AFB1 in AF13ΔnorA mutant extracts indicates that only a portion of AFB1 is reduced to AFOH in the absence of NorA, suggesting an oxidative role for Dipeptidyl peptidase NorA that minimizes accumulation of AFOH. This provides an insight into the previously reported phenomenon that aflatoxin producers and nonproducers are capable of interconverting AFB1 and AFOH (Nakazato et al., 1990). The counterpart reductive enzymes involved in this oxidation-state balance as well as the underlying ecological rationale for the activity remain undefined. A blastp search of the translated A. flavus genomic DNA database with the A. flavus NorA sequence revealed the presence of six genes predicted to encode proteins (AFLA_134080, E=0; AFLA_077060, E=0; AFLA_124600, E=−175; AFLA_096620, E=−107; AFLA_027250, E=−42; AFLA_093600, NorB, E=−44) with a high degree of homology (E value<−40). It is possible that these homologs could complement the function of NorA to some extent, even in the absence of NorB.