Independent folding of individual components in hybrid proteins

Slilaty, Steve N.; Ouellet, Mario; Fung, Margaret; Shen, Shi-Hsiang

doi:10.1111/j.1432-1033.1990.tb19433.x

Cited by 7 publications

(3 citation statements)

References 41 publications

(19 reference statements)

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“…In addition, the SOS induction assays indicated that the putative LexA552 protein would not suffer autoproteolytic cleavage by RecA coprotease, even though it contains the amino acids apparently involved in this process (13,36). This agrees with the fact that only protein fusions containing the entire 135 carboxy-terminal residues of LexA of E. coli are self-cleavable (35).…”

Section: Discussionsupporting

confidence: 71%

“…On the basis of its sequence, this transcript should encode a fusion protein of about 29 kDa, containing the first 184 amino acids encoded by lexA and 82 amino acids encoded by the HindIII fragment of Tn5. Therefore, since this LexA552 protein would lack the last 18 amino acids of the C-terminal domain, its normal DNAbinding activity would be inhibited and it would be unable to cleave itself (32,35).…”

Section: Resultsmentioning

confidence: 99%

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Construction and characterization of two lexA mutants of Salmonella typhimurium with different UV sensitivities and UV mutabilities

et al. 1996

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Salmonella typhimurium has a SOS regulon which resembles that of Escherichia coli. recA mutants of S. typhimurium have already been isolated, but no mutations in lexA have been described yet. In this work, two different lexA mutants of S. typhimurium LT2 have been constructed on a sulA background to prevent cell death and further characterized. The lexA552 and lexA11 alleles contain an insertion of the kanamycin resistance fragment into the carboxy-and amino-terminal regions of the lexA gene, respectively. SOS induction assays indicated that both lexA mutants exhibited a LexA(Def) phenotype, although SOS genes were apparently more derepressed in the lexA11 mutant than in the lexA552 mutant. Like lexA(Def) of E. coli, both lexA mutations only moderately increased the UV survival of S. typhimurium, and the lexA552 strain was as mutable as the lexA ؉ strain by UV in the presence of plasmids encoding MucAB or E. coli UmuDC (UmuDC Ec ). In contrast, a lexA11 strain carrying any of these plasmids was nonmutable by UV. This unexpected behavior was abolished when the lexA11 mutation was complemented in trans by the lexA gene of S. typhimurium. The results of UV mutagenesis correlated well with those of survival to UV irradiation, indicating that MucAB and UmuDC Ec proteins participate in the error-prone repair of UV damage in lexA552 but not in lexA11. These intriguing differences between the mutagenic responses of lexA552 and lexA11 mutants to UV irradiation are discussed, taking into account the different degrees to which the SOS response is derepressed in these mutants.The SOS regulon, which plays an important role in bacterial responses to DNA damage, has been most extensively studied in Escherichia coli (41). This regulon is composed of more than 20 genes (see reference 12) and is involved in several physiological responses such as DNA repair and mutagenesis, whose expression is transcriptionally regulated by LexA and RecA proteins. LexA repressor binds to similar operators of most SOS genes, including recA and lexA. Treatments that cause DNA damage or stalled DNA replication lead to the activation of the RecA coprotease which facilitates the autocatalytic cleavage of LexA and the subsequent derepression of SOScontrolled genes (see reference 13). The umuDC operon, as well as the analogous mucAB operon, is induced as part of the SOS response, and its products are required for most UV and chemical mutagenesis in E. coli. The UmuD protein is processed to the mutagenically active form UmuDЈ by activated RecA through a mechanism similar to that of the cleavage of LexA (2, 22, 34). The mechanism of SOS mutagenesis is not yet clarified, but biochemical evidence suggests that the UmuCUmuDЈ complex and RecA help DNA polymerase III holoenzyme to facilitate error-prone translesion DNA synthesis (29).The closely related species Salmonella typhimurium has a SOS regulatory system which resembles that of E. coli (37). Several SOS loci such as recA (28), uvrB (31), uvrD (25), sulA (4), and several other din (damage-inducible) loci...

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Section: Discussionsupporting

confidence: 71%

Section: Resultsmentioning

confidence: 99%

Construction and characterization of two lexA mutants of Salmonella typhimurium with different UV sensitivities and UV mutabilities

et al. 1996

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“…Domains have been often observed to fold independently of the remainder of polypeptide. A few of many examples include lysozyme (Radford et al, 1992), thermolysin (Corbett & Roche, 1986), aspartate transcarbamylase (Maley & Davidson, 1988), lexA repressor (Slilaty et al, 1990), exotoxin (Brinkmann et al, 1992), and Tu elongation factor (Nock et al, 1995). Though it is not always clear that single domains (and domain-segments) fold independently, ends of such segments certainly delineate transition from one structural unit to another.…”

Section: Domain Foldingmentioning

confidence: 99%

Ribosome‐mediated translational pause and protein domain organization

1996

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Because regions on the messenger ribonucleic acid differ in the rate at which they are translated by the ribosome and because proteins can fold cotranslationally on the ribosome, a question arises as to whether the kinetics of translation influence the folding events in the growing nascent polypeptide chain. Translationally slow regions were identified on mRNAs for a set of 37 multidomain proteins from Escherichia coli with known three-dimensional structures. The frequencies of individual codons in mRNAs of highly expressed genes from E. coli were taken as a measure of codon translation speed. Analysis of codon usage in slow regions showed a consistency with the experimentally determined translation rates of codons; abundant codons that are translated with faster speeds compared with their synonymous codons were found to be avoided; rare codons that are translated at an unexpectedly higher rate were also found to be avoided in slow regions. The statistical significance of the occurrence of such slow regions on mRNA spans corresponding to the oligopeptide domain termini and linking regions on the encoded proteins was assessed. The amino acid type and the solvent accessibility of the residues coded by such slow regions were also examined. The results indicated that protein domain boundaries that mark higher-order structural organization are largely coded by translationally slow regions on the RNA and are composed of such amino acids that are stickier to the ribosome channel through which the synthesized polypeptide chain emerges into the cytoplasm. The translationally slow nucleotide regions on mRNA possess the potential to form hairpin secondary structures and such structures could further slow the movement of ribosome. The results point to an intriguing correlation between protein synthesis machinery and in vivo protein folding. Examination of available mutagenic data indicated that the effects of some of the reported mutations were consistent with our hypothesis.Keywords: codon usage; domain linkers; peptide channel; protein folding; ribosome; translation The rate of protein translation is nonuniform along the mRNA (Varenne et al., 1984). Ribosomes seem to pause as well as stack at specific regions on mRNA (Chaney & Morris, 1979;Wolin &Walter, 1988;Kim et al., 1991;Kim & Hollingsworth, 1992). Two of the mRNA features that slow the ribosome during translation are the presence of slow codons (Varenne et al., 1984;Bonekamp et al., 1985;Wolin & Walter, 1988) and the formation of higher order nucleotide structures (Chaney & Morris, 1979;Tu et al., 1992). The resultant translational pause may temporally separate the adjacent regions on the growing nascent polypeptide. Given that proteins can fold cotranslationally with the possible involvement of the ribosome (Phillips, 1966;Baldwin, 1975;Yonath, 1992;Kudlicki et al., 1994;Wiedmann et al., 1994;Brimacombe, 1995), the temporal separation might exert a phenotypic effect on the structural organization of the encoded protein. We show that as much as 70% of the do...

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