Maurice W. Southworth scite author profile

The Mycobacterium xenopi gyrase A mini-intein has been engineered to yield a controllable N-terminal or C-terminal, single-splice-junction autocleavage element. When combined with an affinity tag, these modified mini-inteins can be used to purify target proteins after a single combined chromatography/cleavage step. Cleavage at the intein N terminus was induced with thiol reagents, while cleavage at the intein C terminus was induced by a temperature shift to 16 degrees-25 degrees C. Different preferences for the residue immediately preceding the intein were observed during thiol-induced, N-terminal splice-junction cleavage of the M. xenopi gyrase A mini-intein vs. the Saccharomyces cerevisiae vacuolar ATPase, subunit A (VMA) intein present in the IMPACT purification system. Furthermore, the M. xenopi gyrase A mini-intein C-terminal autocleavage vector allows isolation of polypeptides with N-terminal cysteine residues that are active in the Intein Mediated Protein Ligation method of protein semisynthesis.

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An alternative protein splicing mechanism for inteins lacking an N-terminal nucleophile

Southworth

2000

164

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Variations in the intein-mediated protein splicing mechanism are becoming more apparent as polymorphisms in conserved catalytic residues are identi®ed. The conserved Ser or Cys at the intein N-terminus and the conserved intein penultimate His are absent in the KlbA family of inteins. These inteins were predicted to be inactive, since an N-terminal Ala cannot perform the initial reaction of the standard protein splicing pathway to yield the requisite N-terminal splice junction (thio)ester. Despite the presence of an N-terminal Ala and a penultimate Ser, the KlbA inteins splice ef®ciently using an alternative protein splicing mechanism. In this non-canonical pathway, the C-extein nucleophile attacks a peptide bond at the N-terminal splice junction rather than a (thio)ester bond, alleviating the need to form the initial (thio)ester at the N-terminal splice junction. The remainder of the two pathways is the same: branch resolution by Asn cyclization is followed by an acyl rearrangement to form a native peptide bond between the ligated exteins.

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Identification and purification of a bacterial ice-nucleation protein.

Wolber¹,

Deininger²,

Southworth³

et al. 1986

Proc. Natl. Acad. Sci. U.S.A.

167

126

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The protein product of a gene (inaZ) responsible for ice nucleation by Pseudomonas syringae S203 has been identified and purified after overexpression in Escherichia coli. The amino acid composition and the N-terminal sequence of the purified, denatured protein corresponded well with that predicted from the sequence of the inaZ gene. The product of inaZ was also found to be the major component in preparations of ice-nucleating, proteinaceous particles, obtained after extraction with and gel filtration in a mixture of urea and the nondenaturing detergent octyl 1-D-thioglucopyranoside. The activity of these preparations in the absence of added lipid implies that the protein participates directly in the nucleation process.Some bacteria of the genera Pseudomonas, Erwinia, and Xanthomonas can nucleate the crystallization of ice from supercooled water (1-3). Genes encoding the ice-nucleation active (Ina') phenotype have been cloned from Erwinia herbicola, Pseudomonas syringae, and Pseudomonas fluorescens (4-7). Theoretical considerations (8), as well as the actual sequence of the inaZ gene from P. syringae (6), suggest that the bacteria synthesize a template for ice-crystal formation, rather than an enzyme. The translation product predicted from the inaZ sequence is a protein with repetitive primary structure; its tertiary structure, which might also be repetitive, could provide considerable insight into the mechanism of ice nucleation. The ice nuclei of P. syringae are associated with its outer membrane (9) and are believed to contain both protein (9-11) and lipid (11) components. One report has suggested that the inaZ product is a phosphatidylinositol synthase, and that the lipid phosphatidylinositol is a key component of the water-binding template (12).Here, we argue that the active component of bacterial ice nuclei is a protein, the product of inaZ. We have reached this conclusion after purifying the InaZ protein. To Ice-Nucleation Spectra. Ice-nucleation frequencies were measured by a drop-freezing method with an instrument constructed as described by Vali (16). For analysis of column fractions, 20 drops of 10 ,u1 per dilution were examined at a dilution interval of 10-2; in all other cases, 40 drops of 10 p.1 per dilution were tested, with a dilution interval of 10-1. All spectra of subcellular fractions were normalized to the frequency per cell, by dividing the frequency per ml value for a given sample by the ratio (volume of sample)/(number of cells used to prepare sample).Construction of pMWS10. The region of DNA encoding the P. syringae S203 inaZ gene (6) was digested with restriction enzymes Aha III (cutting at nucleotide 775) and EcoRI (cutting at nucleotide 4453), resulting in a fragment beginning 23 base pairs 5' of the initiator codon. The EcoRI end was converted to a HindIII end by addition of a linker, and the fragment was inserted into pKK223.3 (17), so that inaZ was placed downstream of the tac promoter. The construct retained the original ribosome binding site of inaZ. The plasmid pMWS10 ...

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Control of protein splicing by intein fragment reassembly

Southworth

Adam

Panne³

et al. 1998

153

110

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Inteins are protein splicing elements that mediate their excision from precursor proteins and the joining of the flanking protein sequences (exteins). In this study, protein splicing was controlled by splitting precursor proteins within the Psp Pol-1 intein and expressing the resultant fragments in separate hosts. Reconstitution of an active intein was achieved by in vitro assembly of precursor fragments. Both splicing and intein endonuclease activity were restored. Complementary fragments from two of the three fragmentation positions tested were able to splice in vitro. Fragments resulting in redundant overlaps of intein sequences or containing affinity tags at the fragmentation sites were able to splice. Fragment pairs resulting in a gap in the intein sequence failed to splice or cleave. However, similar deletions in unfragmented precursors also failed to splice or cleave. Single splice junction cleavage was not observed with single fragments. In vitro splicing of intein fragments under native conditions was achieved using mini exteins. Trans-splicing allows differential modification of defined regions of a protein prior to extein ligation, generating partially labeled proteins for NMR analysis or enabling the study of the effects of any type of protein modification on a limited region of a protein.

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