The invariant tryptophan in an H chain V region is not essential to antibody binding

The first amino acid residue of the second framework region in all antibody H and L chain V regions sequenced to date is invariably tryptophan. To test whether this invariance is essential to proper domain folding and generation of a functional antibody, the tryptophan residue in the heavy chain V region of a mouse anti-p-azophenylarsonate antibody was converted to an alanine residue by oligonucleotide-directed mutagenesis of the H chain gene. The mutant gene was transfected into mouse hybridoma cells that produce the homologous L chain, and the resulting mutant antibody was purified from the cell supernatant. It was shown to have essentially the same reactivity as wild type toward a series of anti-idiotypic antibodies and to bind Ag with a Ka similar to that of wild type.     

Patterns of mutations and selection in antibodies to the phosphocholine-specific determinant in Proteus morganii

The contribution of somatic mutation to the generation of an antibody response was investigated by using the phosphocholine (PC) determinant in the bacterium Proteus morganii as the model Ag. The response to this determinant is restricted to a single VH/VL pair and apparently is derived from only one or two precursors per mouse. In this study we examined hybridoma antibodies from nine individual mice which produced representatives of 12 different clones. We found that all antibodies reactive with the PC Ag of P. morganii contained somatic mutations; the number ranged from 2 to 20. Two clusters of mutations were observed, one in complementarity-determining residue (CDR) 2 and the other in CDR 3 of VH. Examination of a three-dimensional model of M603, an antibody with the same V region composition as the anti-PC antibodies under study, showed that these clusters occupied an area of the binding site which presumably interacts with carrier elements of the PC epitope in P. morganii. A high incidence of recurring mutations were found in both clusters, and one of these was invariant, leading to an Asn for Asp substitution at 95. Ag binding studies with these antibodies and an additional one, which was unmutated except for the invariant substitution at 95, showed that: 1) antibodies having only the 95Asn mutation failed to bind the PC Ag of P. morganii, 2) addition of a second recurring mutation, at 52a (CDR 2), was sufficient to create strong binding to the P. morganii Ag, and 3) accumulation of mutations was directly correlated with increased binding activity for Ag. These results show that somatic mutations play a critical, if not essential, role in generating specificity for this PC Ag, and that Ag, and most likely a carrier element of the epitope, is a primary force in the continued selection and expansion of Ag-reactive B cells.     

The highly conserved aspartic acid residue between hypervariable regions 1 and 2 of human immunodeficiency virus type 1 gp120 is important for early stages of virus replication.

Between hypervariable regions V1 and V2 of human immunodeficiency virus type 1 (HIV-1) gp120 lies a cluster of relatively conserved residues. The contribution of nine charged residues in this region to virus infectivity was evaluated by single-amino-acid substitutions in an infectious provirus clone. Three of the HIV-1 mutants studied had slower growth kinetics than the wild-type virus. The delay was most pronounced in a mutant with an alanine substituted for an aspartic acid residue at position 180. This aspartic acid is conserved by all HIV-1 isolates with known nucleotide sequences. Substitutions with three other residues at this position, including a negatively charged glutamic acid, all affected virus infectivity. The defect identified in these mutants suggests that this aspartic acid residue is involved in the early stages of HIV-1 replication.     

The molecular and biochemical characterization of mutant monoclonal antibodies with increased antigen binding.

Mutant mAb with increased Ag binding were generated from a hybridoma cell line, 36-65, that secretes an IgG1,kappa anti-p-azophenylarsonate-(Ars) specific antibody. The mutant antibodies were identified using an Ars-specific ELISA and sib selection so that approximately 10(6) cells could be analyzed. The ELISA used as Ag a low ratio of Ars coupled to BSA and was set up so that only those antibodies that had higher binding than the parent would be detected. Seven mutant producing cell lines were isolated from five independent clones of 36-65. The mutant antibodies bind Ag 20 to more than 200-fold better than the parent and have wild type V region sequences. All have C region mutations that result in an increased avidity. At least five different genetic events are responsible for the C region mutations.     

Clonal characterization of the human IgG antibody repertoire to Haemophilus influenzae type b polysaccharide. III. A single VKII gene and one of several JK genes are joined by an invariant arginine to form the most common L chain V region

To characterize the L chain V region repertoire of IgG anti-Haemophilus influenzae type b capsular polysaccharide (Hib-PS) antibodies, clonal antibodies were purified from immune serum and internal amino acid sequences of VKII anti-Hib-PS L chains obtained. We examined VKII L chains because it is the most common VL family expressed in the anti-Hib-PS response. Comparison of VKII amino acid sequences, including the entire CDR2 and CDR3 regions, of five anti-Hib-PS clonal antibodies from four unrelated individuals revealed complete identity with the exception of a single CDR3 residue from one antibody. When the sequence of these antibodies was compared with known VKII genes and myeloma proteins, it was found to be identical to the human VKII gene, A2, whose genomic sequence is presented here. In addition, all five of the VKII anti-Hib-PS antibodies examined contain an arginine inserted at the V-J junction. Finally, in contrast to the extraordinary homology of the VKII-encoded residues, there is variability in the JK gene utilization by these antibodies. These results demonstrate that the most common L chain V region in IgG anti-Hib-PS antibodies is the product of a single germ-line gene. The invariant arginine insertion suggests that this residue has an important role in Ag binding.     

Adaptation of human immunodeficiency virus type 1 to cells expressing a binding-deficient CD4 mutant (lysine 46 to aspartic acid).

Human immunodeficiency virus (HIV-1) was adapted to replicate efficiently in cells expressing an altered form of the CD4 viral receptor. The mutant CD4 (46 K/D) contained a single amino acid change (lysine 46 to aspartic acid) in the CDR2 loop of domain 1, which results in a 15-fold reduction in affinity for the viral gp120 glycoprotein. The ability of the adapted virus to replicate in CD4 46 K/D-expressing cells was independently enhanced by single amino acid changes in the V2 variable loop, the V3 variable loop, and the fourth conserved (C4) region of the gp120 glycoprotein. Combinations of these amino acids in the same envelope glycoprotein resulted in additive enhancement of virus replication in cells expressing the CD4 46 K/D molecule. In cells expressing the wild-type CD4 glycoproteins, the same V2 and V3 residue changes also increased the efficiency of replication of a virus exhibiting decreased receptor-binding ability due to an amino acid change (aspartic acid 368 to glutamic acid) in the gp120 glycoprotein. In neither instance did the adaptive changes restore the binding ability of the monomeric gp120 glycoprotein or the oligomeric envelope glycoprotein complex for the mutant or wild-type CD4 glycoproteins, respectively. Thus, particular conformations of the gp120 V2 and V3 variable loops and of the C4 region allow postreceptor binding events in the membrane fusion process to occur in the context of less than optimal receptor binding. These results suggest that the fusion-related functions of the V2, V3, and C4 regions of gp120 are modulated by CD4 binding.     

Characterization of the BaeSR two-component system from Salmonella Typhimurium and its role in ciprofloxacin-induced mdtA expression

Two-component systems are one of the most prevalent mechanisms by which bacteria sense, respond and adapt to changes in their environment. The activation of a sensor histidine kinase leads to autophosphorylation of a conserved histidine residue followed by transfer of the phosphoryl group to a cognate response regulator in an aspartate residue. The search for antibiotics that inhibit molecular targets has led to study prokaryotic two-component systems. In this study, we characterized in vitro and in vivo the BaeSR two-component system from Salmonella Typhimurium and evaluated its role in mdtA regulation in response to ciprofloxacin treatment. We demonstrated in vitro that residue histidine 250 is essential for BaeS autophosphorylation and aspartic acid 61 for BaeR transphosphorylation. By real-time PCR, we showed that mdtA activation in the presence of ciprofloxacin depends on both members of this system and that histidine 250 of BaeS and aspartic acid 61 of BaeR are needed for this. Moreover, the mdtA expression is directly regulated by binding of BaeR at the promoter region, and this interaction is enhanced when the protein is phosphorylated. In agreement, a BaeR mutant unable to phosphorylate at aspartic acid 61 presents a lower affinity with the mdtA promoter.     

Effect of H chain V region on complement activation by immobilized immune complexes.

Activation of C by immune complexes (IC) in tissues and the inflammatory consequences are major determinants in the pathogenesis of many autoimmune disorders. To assess the factors involved in C activation by such IC, we examined the binding of C components by chimeric IgG1 antibodies bound to immobilized Ag. We previously reported that alterations in the H chain V regions can affect the binding of first component of C (C1q) and a major breakdown product of the third C component (C3b) when otherwise identical antibodies were bound to immobilized (Tyr, Glu)-Ala-Lys. To evaluate C activation of these antibodies in well defined IC, we utilized a 9-amino acid peptide conjugated to BSA as Ag. The peptide:BSA conjugate was bound similarly by the two IgG1 antibodies which differed mainly in the CDR3 regions, but also in 9 other amino acids in the H chain V region. When soluble IC were prepared with the two antibodies, they activated C similarly. However, C activation by solid phase Ag:antibody complexes differed; we found that antibody 10B bound more C1q and C3b than antibody B11 did, unless the Ag was present at high density on the plates. These data suggest that the variable region differences affect C activation by these antibody when they are bound to immobilized Ag. Furthermore, these results underscore the differences in C activation by the same antibody depending upon whether the IC are free in solution or immobilized.     

Critical aspartic acid residues in pseudouridine synthases.

The pseudouridine synthases catalyze the isomerization of uridine to pseudouridine at particular positions in certain RNA molecules. Genomic data base searches and sequence alignments using the first four identified pseudouridine synthases led Koonin (Koonin, E. V. (1996) Nucleic Acids Res. 24, 2411-2415) and, independently, Santi and co-workers (Gustafsson, C., Reid, R., Greene, P. J., and Santi, D. V. (1996) Nucleic Acids Res. 24, 3756-3762) to group this class of enzyme into four families, which display no statistically significant global sequence similarity to each other. Upon further scrutiny (Huang, H. L., Pookanjanatavip, M., Gu, X. G., and Santi, D. V. (1998) Biochemistry 37, 344-351), the Santi group discovered that a single aspartic acid residue is the only amino acid present in all of the aligned sequences; they then demonstrated that this aspartic acid residue is catalytically essential in one pseudouridine synthase. To test the functional significance of the sequence alignments in light of the global dissimilarity between the pseudouridine synthase families, we changed the aspartic acid residue in representatives of two additional families to both alanine and cysteine: the mutant enzymes are catalytically inactive but retain the ability to bind tRNA substrate. We have also verified that the mutant enzymes do not release uracil from the substrate at a rate significant relative to turnover by the wild-type pseudouridine synthases. Our results clearly show that the aligned aspartic acid residue is critical for the catalytic activity of pseudouridine synthases from two additional families of these enzymes, supporting the predictive power of the sequence alignments and suggesting that the sequence motif containing the aligned aspartic acid residue might be a prerequisite for pseudouridine synthase function.     

Alteration in H chain V region affects complement activation by chimeric antibodies

Chimeric antibodies to the synthetic polypeptide (Tyr, Glu)-Ala-Lys ((T,G)-A-L) were used to examine C activation by human IgG1. Two IgG1 antibodies, which contained mouse L chains and H chains with mouse V domains and human C domains, differed only in their VH domain. Ag binding and C activation by these antibodies were analyzed by ELISA. When limiting amounts of Ag were used in the assays, the antibodies required different quantities of Ag for optimal binding, suggesting that the antibodies bind to different epitopes on the (T,G)-A-L molecule. However, when competitive inhibition assays were performed with an optimal concentration of Ag, there were no differences in relative binding affinities for (T,G)-A-L or dissociation characteristics of the antibodies. C activation was examined at optimal Ag concentration to ensure equivalent binding of two IgG1 antibodies to Ag. After combination with immobilized Ag, these two antibodies bearing different V regions exhibited marked differences in the binding of C components C1q and C3d. When present in equal amounts in the assay, antibody 10B activated C and bound more C1q and C3d than antibody B11. These results indicate that V region differences can affect C activation by IgG.     

The aspartic acid in deltorphin I and dermenkephalin promotes targeting to delta-opioid receptor independently of receptor binding.

Recent studies on the highly potent and selective delta-opioid agonists demenkephalin (Tyr-D-Met-Phe-His-Leu-Met-Asp-NH2) and deltorphin I (Tyr-D-Ala-Phe-Asp-Val-Val-Gly-NH2) suggested that key structural features necessary for specific targetting to the delta-opioid receptor are located within the C-terminal halves of these naturally occurring heptapeptides. To investigate the contribution of aspartic acid 4 residue in deltorphin I and aspartic acid 7 residue in dermenkephalin to the delta-addressing ability of the C-terminal ends, fourteen analogs were synthesized and assessed for their ability to bind to mu and delta-opioid receptors in rat brain membrane homogenates. Results showed that i/ although the tetrapeptide C-terminus of dermenkephalin and deltorphin I differ in amino acid composition, they play a similar role in specifying correct addressing of these peptides to the delta-receptor, ii/ the negatively charged side chain of aspartic acid 4 residue in deltorphin I and aspartic acid 7 residue in dermenkephalin is not involved in binding contact at the delta-receptor site, nor in maintaining a delta-bioactive folding of the peptides, iii/ these side chains are, in contrast, functionally or structurally required to confer high delta-selectivity by preventing mu-site recognition and/or binding.     

Evidence for involvement of a hydrophobic patch in framework region 1 of human V4-34-encoded Igs in recognition of the red blood cell I antigen

The monoclonal IgM cold agglutinins that bind to the I/i carbohydrate Ags on the surface of RBCs all have Ig H chains encoded by the V4-34 gene segment. This mandatory use indicates that distinctive amino acid sequences may be involved in recognition. Critical amino acids exist in framework region 1 (FR1) of V4-34-encoded Ig, and these generate a specific Id determinant which apparently lies close to the I binding site. However, I binding by Id-expressing Ig can be modulated by sequences in complementarity-determining region (CDR)(H)3. Examination of the crystal structure of an anti-I cold agglutinin has revealed a hydrophobic patch in FR1 involving residue W7 on beta-strand A and the AVY motif (residues 23-25) on beta-strand B. In this study we used mutagenesis to show that each of the strand components of the hydrophobic patch is required for binding the I carbohydrate Ag. In addition, the crystal structure reveals that amino acids in the carboxyl-terminal region of CDR(H)3 form a surface region adjacent to the hydrophobic patch. We propose that the I carbohydrate Ag interacts simultaneously with the entire hydrophobic patch in FR1 and with the outside surface of CDR(H)3. This interaction could leave most of the conventional binding site available for binding other Ags.     

Site-directed mutagenesis of catalytic active-site residues of Taka-amylase A.

The cDNA encoding Taka-amylase A (EC.3.2.1.1, TAA) was isolated to identify functional amino acid residues of TAA by protein engineering. The putative catalytic active-site residues and the substrate binding residue of TAA were altered by site-directed mutagenesis: aspartic acid-206, glutamic acid-230, aspartic acid-297, and lysine-209 were replaced with asparagine or glutamic acid, glutamine or aspartic acid, asparagine or glutamic acid, and phenylalanine or arginine, respectively. Saccharomyces cerevisiae strain YPH 250 was transformed with the expression plasmids containing the altered cDNA of the TAA gene. All the transformants with an expression vector containing the altered cDNA produced mutant TAAs that cross-reacted with the TAA antibody. The mutant TAA with alteration of Asp206, Glu230, or Asp297 in the putative catalytic site had no alpha-amylase activity, while that with alteration of Lys209 in the putative binding site to Arg or Phe had reduced activity.     

Replacement of lysine-181 by aspartic acid in the third transmembrane region of endothelin type B receptor reduces its affinity to endothelin peptides and sarafotoxin 6c without affecting G protein coupling.

A conserved aspartic acid residue in the third transmembrane region of many of the G protein-coupled receptors has been shown to play a role in ligand binding. In the case of endothelin receptors, however, a lysine residue replaces this conserved aspartic acid residue. To access the importance of this residue in ligand binding, we have replaced it with an aspartic acid in the rat endothelin type B (ETb) receptor by PCR mediated mutagenesis. The binding characteristics and functional properties of both the wild type and mutant receptors were determined in COS-7 cells transiently expressing the cloned receptor cDNAs. Using 125I-ET-1 as the radioactive peptide ligand in displacement binding studies, the wild type receptor displayed a typical non-isopeptide-selective binding profile with similar IC50 values (0.2-0.6 nM) for all three endothelin peptides (ET-1, ET-2, and ET-3) and sarafotoxin 6c (SRTX 6c). Interestingly, the mutant receptor showed an increase in IC50 values for ET-1 (5 nM), ET-2 (27 nM), and ET-3 (127 nM) but displayed a much larger increase in IC50 value for SRTX 6c (> 10 uM). The lysine mutant receptor still elicited full inositol phosphate (IP) turnover responses in the presence of saturating concentrations of endothelins (10 nM of ET-1, 100 nM of ET-2, or 1 uM of ET-3), indicating that the mutation (K181D) did not affect the coupling of mutant receptor to the appropriate G protein. These results demonstrate that lysine-181 on the receptor is important for binding ET peptides; however, it is required for binding the ETb selective agonist-SRTX 6c.     

A region corresponding to second aspartate-rich motif in tryptophan isoprenylating enzyme,ComQ, serves as a substrate-binding site

Posttranslational isoprenylation of a tryptophan residue identified from Bacillus quorum sensing pheromone, ComX pheromone, is unique and essential for the bioactivity. A modifying enzyme, ComQ, forms ComX pheromone from the ComX precursor and isoprenyl pyrophosphate and exhibits moderate similarity to isoprenyl pyrophosphate synthases. We investigated non-conserved region in ComQ, corresponding to isopentenyl pyrophosphate binding region of the synthases, using in vitro cell-free isoprenylation. These results suggested that the only conserved aspartic acid residue in the region of ComQ is critical for enzyme activity and responsible for ComX binding. Our findings should contribute to basic understanding of the mechanism of tryptophan isoprenylation.     

Isothermal titration calorimetry reveals differential binding thermodynamics of variable region-identical antibodies differing in constant region for a univalent ligand

The classical view of immunoglobulin molecules posits two functional domains defined by the variable (V) and constant (C) regions, which are responsible for antigen binding and antibody effector functions, respectively. These two domains are thought to function independently. However, several lines of evidence strongly suggest that C region domains can affect the specificity and affinity of an antibody for its antigen (Ag), independent of avidity-type effects. In this study, we used isothermal titration calorimetry to investigate the thermodynamic properties of the interactions of four V region-identical monoclonal antibodies with a univalent peptide antigen. Comparison of the binding of IgG1, IgG2a, IgG2b, and IgG3 with a 12-mer peptide mimetic of Cryptococcus neoformans polysaccharide revealed a stoichiometry of 1.9-2.0 with significant differences in thermodynamic binding parameters. Binding of this peptide to the antibodies was dominated by favorable entropy. The interaction of these antibodies with biotinylated peptides manifested greater enthalpy than for native peptides indicating that biotin labeling affected the types of Ag-Ab complexes formed. Our results provide unambiguous thermodynamic evidence for the notion that the C region can affect the interaction of the V region with an Ag.     

Primary structure of sensory rhodopsin I, a prokaryotic photoreceptor.

The gene coding for sensory rhodopsin I (SR-I) has been identified in a restriction fragment of genomic DNA from the Halobacterium halobium strain L33. Of the 1014 nucleotides whose sequence was determined, 720 belong to the structural gene of SR-I. In the 5' non-coding region two putative promoter elements and a ribosomal binding site have been identified. The 3' flanking region bears a potential terminator structure. The SR-I protein moiety carries no signal peptide and is not processed at its N terminus. The C terminus, however, lacks the last aspartic acid residue encoded by the gene. Analysis of the primary structure of SR-I reveals no consistent homology with the eukaryotic photoreceptor rhodopsin, but 14% homology with the halobacterial ion pumps, bacteriorhodopsin (BR) and halorhodopsin (HR). Residues conserved in all three proteins are discussed with respect to their contribution to secondary structure, retinal binding and ion translocation. The aspartic acid residue which mediates in BR the reprotonation of the Schiff base (D96) is replaced in SR-I by a tyrosine (Y87). This amino acid replacement is proposed to be of crucial importance in the evolution of the slow-cycling photosensing pigment SR-I.     

Synthetic peptide substrates for mammalian pyruvate dehydrogenase kinase and pyruvate dehydrogenase phosphatase

The specificities of pyruvate dehydrogenase kinase and pyruvate dehydrogenase phosphatase were probed using synthetic peptides corresponding to the sequence around phosphorylation sites 1 and 2 on pyruvate dehydrogenase [Tyr-His-Gly-His-Ser(P1)-Met-Ser-Asp-Pro-Gly-Val-Ser(P2)-Tyr-Arg]. The dephosphotetradecapeptide containing aspartic acid at position 8 was a better substrate for the kinase than was the tetradecapeptide containing asparagine at position 8. The apparent Km and V values for the two peptides were 0.43 and 6.1 mM and 2.7 and 2.4 nmol of 32P incorporated/min/mg, respectively. Methylation of the aspartic acid residue also increased the apparent Km of the tetradecapeptide about 14-fold. These results indicate that an acidic residue on the carboxyl-terminal side of phosphorylation site 1 is an important specificity determinant for the kinase. Phosphate was incorporated only into site 1 of the synthetic peptide by the kinase. The phosphatase exhibited an apparent Km of 0.28 mM and a V of 2.3 mumol of 32P released/min/mg for the phosphorylated tetradecapeptide containing aspartic acid. Methylation of the aspartic acid residue had no significant effect on dephosphorylation. The octapeptide and phosphooctapeptide produced by cleavage of the aspartyl-prolyl bond by formic acid were poorer substrates for the kinase and phosphatase than were the tetradecapeptide and phosphotetradecapeptide, respectively. Modification of the amino terminal by acetylation or lysine addition had only a slight effect on the kinase and phosphatase activities.     

Kinetic and Spectroscopic Studies of Bicupin Oxalate Oxidase and Putative Active Site Mutants

Ceriporiopsis subvermispora oxalate oxidase (CsOxOx) is the first bicupin enzyme identified that catalyzes manganese-dependent oxidation of oxalate. In previous work, we have shown that the dominant contribution to catalysis comes from the monoprotonated form of oxalate binding to a form of the enzyme in which an active site carboxylic acid residue must be unprotonated. CsOxOx shares greatest sequence homology with bicupin microbial oxalate decarboxylases (OxDC) and the 241-244DASN region of the N-terminal Mn binding domain of CsOxOx is analogous to the lid region of OxDC that has been shown to determine reaction specificity. We have prepared a series of CsOxOx mutants to probe this region and to identify the carboxylate residue implicated in catalysis. The pH profile of the D241A CsOxOx mutant suggests that the protonation state of aspartic acid 241 is mechanistically significant and that catalysis takes place at the N-terminal Mn binding site. The observation that the D241S CsOxOx mutation eliminates Mn binding to both the N- and C- terminal Mn binding sites suggests that both sites must be intact for Mn incorporation into either site. The introduction of a proton donor into the N-terminal Mn binding site (CsOxOx A242E mutant) does not affect reaction specificity. Mutation of conserved arginine residues further support that catalysis takes place at the N-terminal Mn binding site and that both sites must be intact for Mn incorporation into either site.