5 resultados para Cloning of cDNA encoding Large isoform of rubisco activase
em Aston University Research Archive
Resumo:
During the last decade the use of randomised gene libraries has had an enormous impact in the field of protein engineering. Such libraries comprise many variations of a single gene in which codon replacements are used to substitute key residues of the encoded protein. The expression of such libraries generates a library of randomised proteins which can subsequently be screened for desired or novel activities. Randomisation in this fashion has predominantly been achieved by the inclusion of the codons NNN or NNGCor T, in which N represents any of the four bases A,C,G, or T. The use of thesis codons however, necessities the cloning of redundant codons at each position of randomisation, in addition to those required to encode the twenty possible amino acid substitutions. As degenerate codons must be included at each position of randomisation, this results in a progressive loss of randomisation efficiency as the number of randomised positions is increased. The ratio of genes to proteins in these libraries rises exponentially with each position of randomisation, creating large gene libraries, which generate protein libraries of limited diversity upon expression. In addition to these problems of library size, the cloning of redundant codons also results in the generation of protein libraries in which substituted amino acids are unevenly represented. As several of the randomised codons may encode the same amino acid, for example serine which is encoded six time using the codon NNN, an inherent bias may be introduced into the resulting protein library during the randomisation procedure. The work outlined here describes the development of a novel randomisation technique aimed at a eliminating codon redundancy from randomised gene libraries, thus addressing the problems of library size and bias, associated with the cloning of redundant codons.
Resumo:
Historically, calcitonin gene-related peptide (CGRP) receptors have been divided into two classes, CGRP(1) and CGRP(2).After the cloning of calcitonin receptor-like receptor (CLR) and receptor activity-modifying proteins (RAMPs), it became clear that the CGRP(1) receptor was a complex between CLR and RAMP1. It is now apparent that the CGRP(2) receptor phenotype is the result of CGRP acting at receptors for amylin and adrenomedullin. Accordingly, the term "CGRP(2)" receptor should no longer be used, and the "CGRP(1)" receptor should be known as the "CGRP" receptor.
Resumo:
Although techniques such as biopanning rely heavily upon the screening of randomized gene libraries, there is surprisingly little information available on the construction of those libraries. In general, it is based on the cloning of 'randomized' synthetic oligonucleotides, in which given position(s) contain an equal mixture of all four bases. Yet, many supposedly 'randomized' libraries contain significant elements of bias and/or omission. Here, we report the development and validation of a new, PCR-based assay that enables rapid examination of library composition both prior to and after cloning. By using our assay to analyse model libraries, we demonstrate that the cloning of a given distribution of sequences does not necessarily result in a similarly composed library of clones. Thus, while bias in randomized synthetic oligonucleotide mixtures can be virtually eliminated by using unequal ratios of the four phosphoramidites, the use of such mixtures does not ensure retrieval of a truly randomized library. We propose that in the absence of a technique to control cloning frequencies, the ability to analyse the composition of libraries after cloning will enhance significantly the quality of information derived from those libraries. (C) 2000 Published by Elsevier Science B.V. All rights reserved.
Resumo:
Amino acid substitution plays a vital role in both the molecular engineering of proteins and analysis of structure-activity relationships. High-throughput substitution is achieved by codon randomisation, which generates a library of mutants (a randomised gene library) in a single experiment. For full randomisation, key codons are typically replaced with NNN (64 sequences) or NNG CorT (32 sequences). This obligates cloning of redundant codons alongside those required to encode the 20 amino acids. As the number of randomised codons increases, there is therefore a progressive loss of randomisation efficiency; the number of genes required per protein rises exponentially. The redundant codons cause amino acids to be represented unevenly; for example, methionine is encoded just once within NNN, whilst arginine is encoded six times. Finally, the organisation of the genetic code makes it impossible to encode functional subsets of amino acids (e.g. polar residues only) in a single experiment. Here, we present a novel solution to randomisation where genetic redundancy is eliminated; the number of different genes equals the number of encoded proteins, regardless of codon number. There is no inherent amino acid bias and any required subset of amino acids may be encoded in one experiment. This generic approach should be widely applicable in studies involving randomisation of proteins. © 2003 Elsevier Ltd. All rights reserved.
Resumo:
Three iromps (iron-regulated outer membrane proteins) of Aeromonas salmonicida were identified by the use of specific antibodies together with Southern hybridization analysis and limited nucleotide sequencing of their genes. The results of these experiments together with a search of the international database for homologous sequences led to their identification as follows: -86 kDa iromp (FstA) as a Vibrio anguillarum Fat A homologue -82 kDa iromp (FepA) as an Escherichia coli FepA homologue -74 kDa iromp (IrpA) as an Escherichia coli Cir homologue.
