Alpha-amylase starch binding domains: cooperative effects of binding to starch granules of multiple tandemly arranged domains.

The Lactobacillus amylovorus alpha-amylase starch binding domain (SBD) is a functional domain responsible for binding to insoluble starch. Structurally, this domain is dissimilar from other reported SBDs because it is composed of five identical tandem modules of 91 amino acids each. To understand adsorption phenomena specific to this SBD, the importance of their modular arrangement in relationship to binding ability was investigated. Peptides corresponding to one, two, three, four, or five modules were expressed as His-tagged proteins. Protein binding assays showed an increased capacity of adsorption as a function of the number of modules, suggesting that each unit of the SBD may act in an additive or synergic way to optimize binding to raw starch.

The membrane channel-forming colicin A: synthesis, secretion, structure, action and immunity.

The study of colicin release from producing cells has revealed a novel mechanism of secretion. Instead of a built-in 'tag', such as a signal peptide containing information for secretion, the mechanism employs coordinate expression of a small protein which causes an increase in the envelope permeability, resulting in the release of the colicin as well as other proteins. On the other hand, the mechanism of entry of colicins into sensitive cells involves the same three stages of protein translocation that have been demonstrated for various cellular organelles. They first interact with receptors located at the surface of the outer membrane and are then transferred across the cell envelope in a process that requires energy and depends upon accessory proteins (TolA, TolB, TolC, TolQ, TolR) which might play a role similar to that of the secretory apparatus of eukaryotic and prokaryotic cells. At this point, the type of colicin described in this review interacts specifically with the inner membrane to form an ion channel. The pore-forming colicins are isolated as soluble proteins and yet insert spontaneously into lipid bilayers. The three-dimensional structures of some of these colicins should soon become available and site-directed mutagenesis studies have now provided a large number of modified polypeptides. Their use in model systems, particularly those in which the role of transmembrane potential can be tested for polypeptide insertion and ionic channel gating, constitutes a powerful handle with which to improve our understanding of the dynamics of protein insertion into and across membranes and the molecular basis of membrane excitability. In addition, their immunity proteins, which exist only in one state (membrane-inserted) will also contribute to such an understanding.

Identification of functional regions of the colicinogenic plasmid ColA.

ColA is a colicinogenic plasmid of 6.72 kb. It is compatible with ColE1 but not with ColK. Transposon insertion mutagenesis as well as complementation studies have been carried out to investigate the location of the various functional regions of this plasmid. Four independent ColA::Tn1 and one ColA::Tn3 plasmids were isolated and the locations of insertions were determined. From these plasmids, six different deletion mutants were constructed. In addition, various restriction fragments of ColA have been cloned into pUC8 to carry out complementation studies. We have thus confirmed the location of the DNA regions involved in colicin production, colicin release and immunity function. The DNA region involved in conjugal mobility promoted by R64 drd11 has been identified and we have demonstrated that the ColE1 mobility proteins can act in trans on the bom (basis of mobility) site of ColA. The location of this site, as well as the region involved in stable maintenance of ColA, have also been determined. These results are discussed with regard to the homology in nucleotide sequence between ColA and ColE1.

The complete nucleotide sequence of the colicinogenic plasmid ColA. High extent of homology with ColE1.

The complete nucleotide sequence of the colicinogenic plasmid ColA has been determined. The plasmid DNA consists of 6720 bp (molecular weight 4.48 X 10(6]. Fifteen putative biological functions have been identified using the functional map previously determined. These include 11 genes and 3 DNA sites. Nine genes encode proteins of which 3 have been fully characterized. The replication region of ColA coding for RNAI and RNAII is highly homologous to that of ColE1 and Clo DF13. The same holds true for the site-specific recombination region containing palindromic symmetry and involved in stable maintenance of the plasmids. A high percentage of homology has been detected for putative mobility proteins encoded by ColA and ColE1. The exclusion proteins are also highly homologous.

A molecular genetic approach to the functioning of the immunity protein to colicin A.

A plasmid (pColAF1), derived from pColA, and lacking the region encoding Cai (colicin A immunity protein) and Cal (colicin A lysis protein) has been constructed. The strains carrying pColAF1 produce normal amounts of colicin A which remains in the cell cytoplasm and does not result in loss of viability. Similar results have also been obtained for transposon insertion mutants lacking Cai. Structure prediction analysis indicates that four peptide regions of Cai might span the cytoplasmic membrane. Since the NH2- and COOH-terminal regions are charged, this analysis suggests a topology of the 178 residues polypeptide chain in which regions 38 to 70 and 124 to 143 might be exposed at the outer side of the cytoplasmic membrane. With mutants constructed using recombinant DNA techniques, we could demonstrate that the removal of a 30 residue COOH-terminal region, and mutations altering the surface exposed loop comprised of aminoacid residues 124-143 abolish the protecting function of Cai.

Lysis protein encoded by plasmid ColA-CA31. Gene sequence and export.

A gene, cal, coding for a polypeptide needed for the release of colicin A from Escherichia coli cells has been identified by transposon insertion. The cal gene was located on the ColA plasmid map adjacent to cai, the gene coding for colicin A immunity protein, and therefore 592 bases downstream from caa, the structural gene for colicin A. Transcription of cal is in the same direction as caa, that is in the opposite direction to cai. Its sequence has been determined and the predicted amino acid composition features a basic N-terminal end followed by a serie of hydrophobic residues similar to the signal sequence in precursors of exported proteins. The C-terminal part also contains a core of hydrophobic residues. The overall amino acid sequence of the cal protein is homologous to that of lytic proteins encoded by the related plasmids pColE1, and pCloDF13. The cal protein has been identified on urea-SDS-polyacrylamide gels by selective labelling with various radioactive amino acids and its synthesis is co-induced with that of colicin A. The cal protein undergoes slow processing with loss of the N-terminal "signal" region and the mature form is released into the medium together with colicin A.

Complete nucleotide sequence of the structural gene for colicin A, a gene translated at non-uniform rate.

The complete nucleotide sequence of the structural gene for colicin A has been established. This sequence consists of 1776 base-pairs. According to the predicted amino acid sequence, the colicin A polypeptide chain comprises 592 amino acids and has a molecular weight of 62,989. The amino-terminal part is rich in proline and glycine and accordingly secondary structure prediction indicates that this region (1 to 185) is beta-structured. The rest of the molecule (residues 186 to 592) is very rich in alpha-helix. An uncharged amino acid sequence of 48 residues is located in the C-terminal part of the molecule, which is involved in the membrane depolarization caused by colicin A. A similar region has been found in colicin E1, which has the same mode of action as colicin A. Three peptides of these bacteriocins were found to be homologous, but a comparison of the bacteriocin genes did not reveal any significant homology out of the corresponding regions. The codon usage of both genes, however, exhibits some similarity and is quite different from that of genes coding for highly or weakly expressed proteins of Escherichia coli.

Nucleotide sequence of promoter, operator and amino-terminal region of caa, the structural gene of colicin A.

The nucleotide sequence of 378 bp covering the promoter-operator regions and the region coding for the N-terminal portion of the colicin A gene was determined. These assignments were made possible by the determination of the N-terminal 12 amino acids of the colicin A protein. DNA sequence homologies between operator regions of recA, lexA, uvrA, uvrB, cea and caa genes are discussed.

Physical map of pColA-CA31, an amplifiable plasmid, and location of colicin A structural gene.

Evidence showing that the plasmic ColA, derived from strain CA31[pColA] can be amplified in the presence of chloramphenicol is presented. This plasmid has been purified and its Mr-value has been found to be 4.6 X 10(6) or 7 kb. Twelve cleavage sites have been mapped in pColA by using single and double restriction endonuclease digestions. These sites were ordered in relation to the single HindIII site. The other restriction endonucleases used were, respectively, SmaI, AvaI, PstI and HincII. Establishment of the map was helped by hybridization of pColA endonuclease digest products with 32P-labeled colicin A-mRNA. The structural gene for colicin A was contained in a 2.17-kb HincII fragment.