Destabilizing loop swaps in the CDRs of an immunoglobulin V<sub>L</sub> domain

Helms, Larry R.; Wetzel, Ronald

doi:10.1002/pro.5560041012

Cited by 42 publications

(26 citation statements)

References 51 publications

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“…Most substitutions are not tolerated, suggesting that sequence information in this turn plays a significant role in dictating the overall structure of the 0-barrel. These results are consistent with recent work by Helms and Wetzel(1995), who reported that substitutions in the hypervariable loops of an immunoglobulin V, domain destabilize the structure of that P-barrel as well. Mutagenesis studies of a &turn in staphylococcal nuclease have led to similar conclusions (R.O.…”

Section: Ja Ybe and Mh Hechtsupporting

confidence: 93%

Sequence replacements in the central β‐turn of plastocyanin

Ybe

Hecht

1996

Protein Science

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The role of 0-turns in dictating the structure of a @-barrel protein is assessed by probing the tolerance of the central 0-turn of poplar plastocyanin to substitution by arbitrary sequences. Native plastocyanin binds copper and is colored bright blue. However, when the wild-type Pr~,,-Ser,,-Gly,,-Val~~ turn sequence is replaced by arbitrary tetrapeptides, the vast majority (92/98 = 94%) of mutant proteins cannot fold into the native blue structure. Characterization of the colorless mutant proteins demonstrates that the majority of substitutions in this type I1 0-turn disrupt the native structure severely. Gross structural changes are indicated by major differences in the CD spectra of the mutants relative to the wild-type protein, and by the much larger apparent size of mutant proteins in gel filtration experiments. These mutant proteins do not bind copper. Furthermore, Cys,, forms a disulfide bond readily in the colorless mutant proteins, indicating that it has moved away from the buried position it occupies in the native copper binding site and has become exposed. These results indicate that the central 0-turn in plastocyanin is not merely a default structure arising in response to the surrounding context; rather, sequence information in this turn plays an active role in dictating the location of a chain reversal in the &barrel structure. These findings are discussed in terms of their implications for the folding of natural proteins, as well as the design of de novo proteins.

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Section: Ja Ybe and Mh Hechtsupporting

confidence: 93%

Sequence replacements in the central β‐turn of plastocyanin

Ybe

Hecht

1996

Protein Science

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“…4). Destabilizing effects of loop grafting into an antibody framework have been reported previously (40), but in that particular case, the grafted sequences were totally unrelated to antibody hypervariable loops. The use of naturally occurring CDR sequences for grafting into immunoglobulin frameworks often ensures that the inserted loops are optimally functional as they have been proofread and selected for functionality during the formation of the B cell receptors.…”

Section: Discussionmentioning

confidence: 67%

Functional Consequences of Insertions and Deletions in the Complementarity-determining Regions of Human Antibodies

Lantto

Ohlin

2002

Journal of Biological Chemistry

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Insertions and deletions of nucleotides in the genes encoding the variable domains of antibodies are natural components of the hypermutation process, which may expand the available repertoire of hypervariable loop lengths and conformations. Although insertion of amino acids has also been utilized in antibody engineering, little is known about the functional consequences of such modifications. To investigate this further, we have introduced single-codon insertions and deletions as well as more complex modifications in the complementaritydetermining regions of human antibody fragments with different specificities. Our results demonstrate that single amino acid insertions and deletions are generally well tolerated and permit production of stably folded proteins, often with retained antigen recognition, despite the fact that the thus modified loops carry amino acids that are disallowed at key residue positions in canonical loops of the corresponding length or are of a length not associated with a known canonical structure. We have thus shown that single-codon insertions and deletions can efficiently be utilized to expand structure and sequence space of the antigen-binding site beyond what is encoded by the germline gene repertoire.Antibodies are highly specific receptors of the immune system that also have a great potential as reagents in biological chemistry and as therapeutic agents. The part of the antibody that makes contact with the antigen is comprised of two variable (V) 1 domains, the heavy (H) and the light (L), which both are made up of a two-␤-sheet framework. From this framework, six complementarity-determining region (CDR) loops, three from the light domain and three from the heavy domain, protrude and make up the antigen-binding site (1, 2). Five of these CDR loops generally adopt only a limited number of backbone conformations, so-called canonical structures (reviewed in Ref.3), which are determined by the lengths of the loops and by the presence of specific key residues. The antigen specificity of the binding site is mainly determined by the sequence and conformation of these CDR loops.Antibody diversity is generated by the imprecise recombination of two or three sets of germline gene segments and by the combination of different heavy and light domains (4). The diversity is further increased by the process of somatic hypermutation (5) and by receptor editing and revision (6). As the germline variable gene repertoire encodes a rather limited number of CDR loop lengths (IMGT, the international ImMunoGeneTics data base, Ref. 7), the number of observed canonical structures is similarly limited. However, it was recently discovered that B cells evolve the genes encoding immunoglobulin V domains not only by nucleotide substitution but also through an additional mechanism of insertion and deletion of nucleotides during the hypermutation process (8 -11). This mechanism has the potential to expand the available repertoire of loop lengths and conformations if the insertions and deletions involve entire codons a...

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“…Apparent differences may be due to the nature of CDR loops that are, by necessity, different in all V L domains. A systematic study of the contribution of different CDR loops has not been carried out; however, significant differences in the stability of isolated V L domains have been observed with different length loops, 76 and replacement of the loops in one V L domain has significantly increased stability. 77 Loop regions can be important in the initial stages of protein folding, bringing different regions of the protein into close proximity.…”

Section: Comparison To Other Ig-like Domainsmentioning

confidence: 96%