Journal of Bacteriology, December 2003, p . 6976-6980, Vol . 185, No . 23

Construction of mutant subunit genes. Mutations were introduced into the bphA1 gene of Burkholderia sp . strain LB400 (2, 10) as follows . With appropriate mutagenic primers, two overlapping DNA fragments which contained a given mutation were synthesized by PCR (22) . Subsequently, these two fragments were joined by overlap extension PCR (9) . By using established procedures (24), the resulting products were cleaved with restriction enzymes and ligated into identically cleaved and dephosphorylated pAIA100, a recombinant expression vector harboring the four genes of the BDO system, bphA1^mA2A3A4 (bphA1^m contains silent mutations that introduce additional restriction sites), downstream of a phage T7 late promoter (28) . After cloning, the integrity of all PCR-synthesized fragments was verified by DNA sequencing (11) . The names of the resulting plasmids and the respective AA exchanges are given in Table 1 .

 
Concentrations and activities of variants. Genes were expressed in Escherichia coli BL21(DE3)(pLysS) (26) . Subsequently, resting cells were prepared and disrupted with a French press as previously described (28) . The supernatants obtained by centrifugation at 15,000 x g for 45 min were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (10) . Despite exchanges of only single residues, some of the variants differed in mobilities (not shown) . No significant differences were observed in the concentrations of dissolved wild-type (WT) and variant subunits . BDO activities were assayed with resting cells (final optical density at 600 nm, 0.1) . They were mixed with resting cells harboring pDD372 (final optical density at 600 nm, 0.2), which contains bphBC (10) . The conversion of biphenyl into 2-hydroxy-6-oxo-6-phenylhexa-2,4-dienoate was monitored for 60 min as described previously (28) . Activities varied between approximately 1 and 130% of the WT value (Table 1) . Such differences are not unusual when enzymes are modified at or near the active site . The largest effects were observed with variants Ile326Ala, Phe378Ala, and Phe384Ala . An explanation for the effect of the Ile326Ala exchange is not apparent; however, a model of the BDO structure (see below) suggests that the replacements of the Phe residues decrease the activity by enlarging the substrate-binding pocket . Additionally, Phe378Ala may eliminate a stacking interaction with the biphenyl .

Effects of AA replacements on the structure of the active site. Two substituted biphenyls, 2,3'- and 3,4'-chlorobiphenyl (CB), are dioxygenated by the WT enzyme at a total of seven different sites (28) . Therefore, they were selected as sensitive probes to monitor the effects of individual AA replacements on the steric-electronic structure of the active site . As described previously (28), resting cells were incubated with the CBs, products were quantitated by high-pressure liquid chromatography-UV spectrometry, and their percentages were determined (Table 1) . If the percentages for the WT and the variant, after convergence by one standard deviation, still differed by a factor of 1.5, 2.5, or 4.0 for at least one of the metabolites, the effects were classified as moderate, strong, or very strong, respectively . Numerical values are given in Fig . 1 .

 
Significant effects of AA exchanges were observed in all three regions . For correlations with the spatial positions of the respective residues, a model of the BDO hydroxylase was derived from NDO crystal structures (5, 14) by using Modeller (23) . Restraint parameters were kept at the default values . The root mean square deviation of modeled C-alpha atoms to the template coordinates was 0.5 Å, and no short nonbonded contacts smaller than 2.5 Å occurred . In order to stay as close as possible to the template structure, no additional molecular dynamics calculations were attempted . The dioxygen was positioned side-on relative to the mononuclear iron (13) . A ligand molecule, derived by using Sybyl 6.8 (Tripos Inc., St . Louis, Mo.) from a template structure obtained from the Cambridge Crystallographic Data Centre (Cambridge, United Kingdom), was placed manually in the active site of the model at the approximate position of the ligand in the NDO structure (Fig . 2) . Below, the assignments of functions to specific residues are based on the BDO model .

 
Very strong effects (factors of >7) were observed for the exchanges of three residues (Met231, Phe378, and Phe384) that belong to the substrate-binding pocket (Fig . 2) . In contrast, the replacement of Ala234, another substrate-lining residue, resulted in only a 2.3-fold difference from the WT value . On the other hand, significant effects (factors of between 1.5 and 3.5) were also observed for replacements of AAs that do not directly interact with substrate molecules and may be regarded as second-shell residues, i.e., Ile243, Met324, Ile326, Phe 332, Pro334, Trp342, Asn377, Val383, Gly389, Trp392, and Val393 (Fig . 2) . In most, although not all, of these cases, the model suggests potential mechanisms . Five of the AAs (Met324, Phe 332, Pro334, Asn377, and Val383) are direct neighbors of substrate-lining residues (His323, Leu333, Phe378, and Phe384, respectively) (Fig . 2) . Their replacements most likely influence the spatial positions of the latter and thereby affect the preferred positions of the substrate . Similarly, Ile243Ala and Ile326Ala could transfer their influence through main chain shifts to residues His239 and His323, respectively, which directly interact with the mononuclear iron and the substrate, respectively (Fig . 2) . Bulky Trp residues often act as spacers between structural elements . The replacements of Trp342 and Trp392 by the much smaller Ala residues should cause an approach between the ß strand or helix, respectively, carrying these residues and the helix containing the substrate-binding Phe227 (Fig . 2) .

Altogether, eight subunit positions examined in the present work have previously been investigated in class II and class III ARHDOs . Agreements with the present results are found for five positions, disagreements are found in two cases, and a partial agreement is found in one instance (Fig . 1) . This suggests that in most cases the available data should correctly predict whether or not the replacement of a specific residue in another class II or class III ARHDO will influence substrate interaction .

As pointed out above, exchanges of residues that are not in the immediate vicinity of the bound substrate were found to significantly influence the structure of the active site . An importance of such residues has also been observed with other enzymes (25) . The medium- or long-range interactions that are responsible for such indirect effects of AA replacements are neither obvious nor currently predictable and are thus of particular interest . A determination of the structure of a respective variant-substrate complex is required for a definite elucidation of the underlying mechanisms . The present results identified a number of candidates for such studies . Moreover, the present study suggests several sensitive positions as key targets for AA replacements that aim at the generation of enzymes with optimized substrate or product specificities .

We gratefully acknowledge funding of this work through a grant from the Deutsche Forschungsgemeinschaft (Ho 1219/2-1) .

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