Software al2co is

used in this analysis. The conservation calculation method is Sum-of-pairs measure and gap fraction to suppress calculation is 0.50. A. The frequency obtained in the comparison of all the tested strains. B. The frequency of the non-pigment producing strains. C. Histogram of the mutant ratios of the nucleotides and amino acid residues of the four genes. Among the pigment-producing strains, sequences of the four genes in the O1 strain 3182 were the same as those in N16961; the exception being VC1345, in which a 10-bp sequence was missing between nucleotides 258 and 267. This caused a frameshift mutation and complete change in check details its protein sequence (Figure 1). Among the six O139 pigment-producing strains, the sequences of the four genes were almost identical, with the exception of four nucleotide differences: in the VC1346 gene, C591 in JX2006135, and A863 in JX2006135 and 95-4; and in the VC1347 gene, A1 in 98-200. Because of the high similarity identified

in the cluster analysis of these four genes, all of the six pigment-producing PI3K Inhibitor Library strains could be grouped into one cluster, and, with the exception of the VC1344 gene, none of the non-pigment-producing strains was included in the clusters of the pigment-producing strains (Figure 4). In VC1345, a 15-bp fragment deletion, from nucleotide 539 to 554, was found in all six of the O139 pigment-producing strains, suggesting that this deletion mutation may be correlated with their pigment phenotype. In the borders of the deletion region, a short direct repeat (GCGGTGTT) was found (Figure

1). Figure 4 The cluster analysis of Mocetinostat solubility dmso the protein sequences of the four tyrosine catabolic genes, VC1344 (A), VC1345 (B), VC1346 (C) and VC1347 (D). Strains marked with black square are pigment producing strains. 3.2 Functional complementation of the VC1345 gene of strain 95-4 Using overlap PCR (Figure 1), we obtained the fragment Adenosine which contain the complementary 15 nt which is absent in the wild pigment production strain 95-4, corresponding to the filling in the 15-bp gap in the VC1345 and retained the remainder of the gene sequence as in the pigment production wild-type. We then cloned this fragment containing backbone of the wild-type VC1345 gene of strain 95-4 and the 15 nt filling, into the expression vector pET15b and this recombinant plasmid was transformed into the wild-type 95-4 strain. This gene was expressed with induction of IPTG. After trans-complementation, strain 95-4 with the plasmid carrying the 15 nt filling of VC1345 gene no longer produced pigment, whereas the control strain 95-4 containing its own VC1345 gene cloned in pET15b showed no change in its pigment producing ability. This therefore showed that providing HGO enzyme is sufficient to avoid the pigment production and filling in of the 15-bp gap is sufficient to recover VC1345 gene function. 3.