Site-directed mutagenesis was utilized to construct mutants, containing one or two tryptophan residues, of the bifunctional enzyme fructose 6-phosphate,2-kinase−fructose 2,6-bisphosphatase. Two of the single-tryptophan mutants (W15 and W64) had the tryptophan residue located in the kinase domain, which is in the N-terminal half, and two (W299 and W320) had the tryptophan residue located in the phosphatase domain, which is in the C-terminal half. The double-tryptophan mutants were W15/W64, W15/W299, W64/W299, and W299/W320. Dynamic polarization data indicated that these tryptophan residues had varying degrees of local mobility. Steady-state polarization data revealed energy transfer between the tryptophan residues in the double mutant W299/W320 but not in the W15/W64, W15/W299, or W64/W299 mutants, indicating the proximity of the W299 and W320 residues. The binding of fructose-6-phosphate resulted in a significant increase in the anisotropy of the W15 mutants, but did not affect the anisotropies of any of the other single-tryptophan mutants. Binding of fructose-2,6-bisphosphate also significantly increased the anisotropy of W15. In the case of fructose-6-phosphate binding, the increased anisotropy was shown to be due to a restriction of the tryptophan residue's local mobility in the presence of bound ligand, which suggests that the N-terminus is located near the kinase active site. These increases in anisotropies were used to estimate the dissociation constants of fructose-6-phosphate and fructose-2,6-bisphosphate, which were 29 ± 3 and 2.1 ± 0.3 μM, respectively. These observations are considered in light of the recently published crystal structure for this bifunctional enzyme.
The bifunctional enzyme 6-phosphofructo-2-kinase/fructose-2, 6-bisphosphatase plays an essential role in the regulation of glucose metabolism by both producing and degrading Fru-2,6-P(2) via its distinct catalytic activities. The 6-PF-2-K and Fru-2,6-P(2)ase active sites are located in separate domains of the enzyme. The kinase domain is structurally related to the superfamily of mononucleotide binding proteins that includes adenylate kinase and the G-proteins. We have determined three new structures of the enzymatic monomer, each with a different ligand in the ATP binding site of the 6-PF-2-K domain (AMP-PNP, PO(4), and water). A comparison of these three new structures with the ATPgammaS-bound 6-PF-2-K domain reveals a rearrangement of a helix that is dependent on the ligand bound in the ATP binding site of the enzyme. This helix motion dramatically alters the position of a catalytic residue (Lys172). This catalytic cation is analogous to the Arg residue donated by the rasGAP protein, and the Arg residue at the core of the GTP or GDP sensing switch motion seen in the heterotrimeric G-proteins. In addition, a succinate molecule is observed in the Fru-6-P binding site. Kinetic analysis of succinate inhibition of the 6-PF-2-K reaction is consistent with the structural findings, and suggests a mechanism for feedback inhibition of glycolysis by citric acid cycle intermediates. Alterations in the 6-PF-2-K kinetics of several proteins mutated near both the switch and the succinate binding site suggest a mode of communication between the ATP- and F6P binding sites. Together with these kinetic data, these new structures provide insights into the mechanism of the 6-PF-2-K activity of this important bifunctional enzyme.
IgH rearrangements (VH-D, D-JH) are central to the generation of antibody diversity. The majority of the diversity seen in the third hypervariable region is generated by the D segment and at the joints formed by both junctional and N segment variation during D-JH and VH-D rearrangements. The mechanisms that regulate rearrangement are thought to obey the 12/23 rule, wherein D-D or VH-JH rearrangements are precluded. Here, we present evidence that D-D fusions do in fact occur, either as direct or inverted rearrangements. The fused D segments so generated may be fully capable of proceeding in subsequent D-JH and VH-D rearrangements. The resultant VH-D-D-JH recombinations add another dimension to the potential repertoire of IgH V regions by increasing the level of combinatorial diversity and by providing additional sites for N region variation.
Sequencing techniques for single- and double-stranded DNA were used to determine the nucleotide sequence of the gene encoding P2, the major outer membrane (porin) protein of Haemophilus influenzae type b (Hib). The open reading frame encoding the P2 protein comprised 361 amino acid codons. Comparison of the inferred amino acid sequence with data obtained by amino acid sequencing of the N terminus of the mature or fully processed P2 protein revealed that this protein has a signal peptide composed of 20 amino acids. N-terminal amino acid sequencing of tryptic peptides derived from purified P2 allowed direct identification of 158 of the 341 amino acids in the fully processed P2 protein; there was 100% correlation between these amino acid sequences and that inferred from the nucleotide sequence. The amino acid sequence of Hib P2 protein had 23 to 25% homology with the sequence of the OmpF porin of Escherichia coli and with that of the Neisseria gonorrhoeae porin P.IA. Codon usage in the Hib P2 gene was significantly different from that observed for a gene encoding a porin of E. coli. DNA hybridization studies indicated that there is a single copy of the P2 gene in the Hib chromosome. The availability of the nucleotide and amino acid sequences for the Hib P2 protein will facilitate investigation of the antigenic characteristics and structure-function relationship of this porin.
A bifunctional enzyme, fructose-6-phosphate 2-kinase−fructose 2,6-bisphosphatase, catalyzes synthesis and degradation of fructose 2,6-bisphosphate. Mutants of basic residues, including Lys51, Arg78, Arg79, Arg136, Lys172, and Arg193, immediately around the active site of rat testis fructose 6-P,2-kinase were constructed, and their steady state kinetics, ATP binding, and the effect of pH on the kinetics were characterized. All mutants showed a several-fold increase in KMgATP, much larger increases in KFru 6-P, and decreased V compared to those of the wild type enzyme (WT). Replacement of Lys172 and Arg193 with Ala and Leu, respectively, also produced mutants with large KFru 6-P values. Substitution of Lys51, which is located in a Walker-A motif (GXXGXGKT, amino acids 45−52), with Ala or His resulted in enzymes with increased KMgATP values and unable to bind Fru 6-P. The dissociation constants for 2‘(3‘)-O-(N-methylanthraniloyl)-ATP (mantATP) and ATP of all these mutants except Lys51 were similar. Lys51 mutants were unable to bind mantATP. The pH dependence of V and the V/Ks for MgATP and Fru 6-P suggest a mechanism in which reactants and enzyme combine irrespective of the protonation state of groups required for binding and catalysis, but only the correctly protonated enzyme−substrate complex is catalytically active. A chemical mechanism is suggested in which a general base accepts a proton from the 2-hydroxyl of Fru 6-P concomitant with nucleophilic attack on the γ-phosphate of MgATP. Phosphoryl transfer is also facilitated by interaction of the γ-phosphate with a positively charged residue that neutralizes the remaining negative charge. The dianionic form of the 6-phosphate of fructose 6-P is required for binding, and it is likely anchored by a positively charged enzyme residue. A comparison of the pH dependence of kinetic parameters for Ala or His mutant proteins at Lys51, Lys172, and Arg79 suggests that Lys51 interacts with the γ-phosphate of MgATP and that several other arginines likely participate in transition state stabilization of the transferred phosphoryl. The active site general base has yet to be identified.
To assess the impact of various heavy and light chain mutations on p-azophenylarsonate binding, murine antibodies have been produced in insect cells (SF9) utilizing a baculovirus expression system. When expressed in this system, an antibody composed of a canonical CRIA+ heavy and light chain can bind antigen and express idiotype indistinguishably from analogous hybridoma-derived antibodies. Antibodies comprised of either light chains mutant at the V-J junction or heavy chains mutant at the V-D junction were found to be incapable of binding arsonate. In addition, substitutions in the first and second complementarity determining regions of the heavy chain were shown to play a role in arsonate binding, most likely related to affinity maturation targeted at the carrier protein. These results confirm the obligatory role that junctional diversity plays in the generation of arsonate-specific antibodies, as well as extend our understanding of the role of other variable region amino acids in arsonate binding.
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