The C-terminal, 23 kDa peptide of E. coli haemolysin 2001 contains all the information necessary for its secretion by the haemolysin (Hly) export machinery

In this paper we show the construction of a plasmid pLG609 which carries the 3'-end of the haemolysin structural gene, hlyA under tac promoter control. Expression of pLG609 in an E. coli strain carrying the haemolysin export genes hlyB and hlyD led to the efficient secretion of the C-terminal, 23 kDa peptide of haemolysin. The discovery of a C-terminal topogenic sequence, which appears to be all that is required for secretion of the whole toxin, is so far quite unique in protein export.     

Actinobacillus pleuropneumoniae haemolysin II is secreted from Escherichia coli by A. pleuropneumoniae pleurotoxin secretion gene products

Abstract Actinobacillus pleuropneumoniae serotype 2 secretes type II haemolysin and pleurotoxin activities. Here, the genes for type II haemolysin were cloned in Escherichia coli , but type II haemolysin antigen and haemolysin activity were only detected intracellularly and not exported to culture supernatant. It has been reported that the genes for type II haemolysin are not linked to functional secretion genes, while those for pleurotoxin are. In this report the means of secretion of type II haemolysis was examined by constructing a hybrid plasmid carrying the genes required for type II haemolysin expression, together with determinants which allow secretion of pleurotoxin and are linked to the pleurotoxin toxin genes. These genes facilitated the export of type II haemolysin from E. coli , and may perform this function in A. pleuropneumoniae .     

Chromosomal mutations that increase the production of a plasmid-encoded haemolysin in Escherichia coli

Transposon mutagenesis was used to isolate two Escherichia coli mutants which express very large amounts of haemolysin when carrying the multicopy plasmid pANN202-312. E. coli strain Hha-2 was isolated by Mud1 mutagenesis, and strain Hha-3 by Tn5 mutagenesis. The transposon insertion was chromosomal in both mutants and could be demonstrated to be unrelated to the haemolytic region of the plasmid. The substantial increase in both extracellular and intracellular haemolysin production was dependent upon plasmid copy number and was drastically reduced when either mutant carried the low-copy-number haemolytic plasmid pHly152. In both mutants, the marked increase in extracellular production was dependent upon the specific haemolysin transport genes, hlyB and hlyD. The lack of either gene function resulted in no external haemolysin production. SDS-PAGE analysis showed no change in the pattern of outer-membrane proteins of the mutants, although changes (differing between the two mutants) were seen in their periplasmic proteins. The mutations of both strains (termed hha-2 and hha-3) were mapped at minute 10.5 of the E. coli chromosome. No relation to any known gene affecting gene regulation in E. coli could be found.     

Flagella and Motility in Actinobacillus pleuropneumoniae

Actinobacillus pleuropneumoniae has been considered nonmotile and nonflagellate. In this work, it is demonstrated that A. pleuropneumoniae produces flagella composed of a 65-kDa protein with an N-terminal amino acid sequence that shows 100% identity with those of Escherichia coli, Salmonella, and Shigella flagellins. The DNA sequence obtained through PCR of the fliC gene in A. pleuropneumoniae showed considerable identity (93%) in its 5' and 3' ends with the DNA sequences of corresponding genes in E. coli, Salmonella enterica, and Shigella spp. The motility of A. pleuropneumoniae was observed in tryptic soy or brain heart infusion soft agar media, and it is influenced by temperature. Flagella and motility may be involved in the survival and pathogenesis of A. pleuropneumoniae in pigs.     

Characterization of the hlyB gene and its role in the production of the EI Tor haemolysin of Vibrio choierae O1

El Tor strains of Vibrio cholerae are capable of producing a haemolysin which they actively secrete into the growth medium. This requires translation to produce the protein at the surface of the cytoplasmic membrane and translocation across this membrane, the periplasmic space and the outer membrane. The mechanism by which this occurs is poorly understood. In addition to the structural gene for the haemolysin (hlyA), we have cloned a second adjacent gene, hlyB. By site-directed mutagenesis, specific hlyB mutants have been constructed. These mutants are defective in the secretion of HlyA in the early to mid-exponential phase of growth and the haemolysin becomes trapped within the cell and is only released in stationary phase. Nucleotide sequence analysis and cell fractionations reveal HlyB to be a 60.3 kD putative outer membrane-associated protein.     

Secretion of the Pasteurella leukotoxin by Escherichia coli

Nucleic acid sequence analysis has indicated that the leukotoxin determinant from Pasteurella haemolytica is related to the hemolysin determinant from E. coli. The cloning and expression in E. coli of the lktCA genes has been previously reported, but the existence of leukotoxin secretory genes equivalent to hlyBD has not been documented. In this report we demonstrate that a 4.0 kb segment of P. haemolytica genomic DNA distal to the lktA gene, when expressed in trans to the previous cloned lktCA genes, allow the synthesis and secretion of active leukotoxin from E. coli. Complementation analysis using the cloned hlyB and hlyD genes indicates that this secretory locus derived from P. haemolytica contains two genes which we designate, by analogy, lktB and lktD.     

Expression of Actinobacillus pleuropneumonia gene coding for Apx I protein in Escherichia coli

This study presents cloning and expression of Actinobacillus pleuropneumoniae Apx I toxin in Escherichia coli expression system to produce fusion protein for the subsequent immunological studies. The gene coding Apx I toxin was amplified from the A. pleuropneumoniae serotype 10 DNA using polymerase chain reaction and cloned to vector under the control of strong, inducible T7 promoter. The presence of insert was confirmed by PCR screening and sequencing after the propagation of recombinant DNA in E. coli cells. The gene coding A. pleuropneumoniae Apx I toxin was extended with a segment to encode a polyhistidine tag linked to its C-terminal sequence allowing a one-step affinity purification of the complex with Ni-NTA resin. Expression of the Apx I coding sequence in E. coli resulted in the formation of insoluble inclusion bodies purified according to a standard purification protocol. The ease of this expression system, the powerful single-step purification and low costs make it possible to produce Apx I in large amounts to further study the role of Apx I in physiological processes.     

Secretion of the Rhizobium leguminosarum nodulation protein NodO by haemolysin-type systems

The Rhizobium leguminosarum biovar viciae nodulation protein NodO is partially homologous to haemolysin of Escherichia coli and, like haemolysin, is secreted into the growth medium. The NodO protein can be secreted by a strain of E. coli carrying the cloned nodO gene plus the haemolysin secretion genes hlyBD, in a process that also requires the outer membrane protein encoded by tolC. The related protease secretion genes, prtDEF, from Erwinia chrysanthemi also enable E. coli to secrete NodO. The Rhizobium genes encoding the proteins required for NodO secretion are unlinked to nodO and are unlike other nod genes, since they do not require flavonoids or NodO for their expression. Although proteins similar to NodO were not found in rhizobia other than R. leguminosarum bv. viciae, several rhizobia and an Agrobacterium strain containing the cloned nodO gene were found to have the ability to secrete NodO. These observations indicate that a wide range of the Rhizobiaceae have a protein secretion mechanism analogous to that which secretes haemolysin and related toxins and proteases in the ENterobacteriaceae.     

Secretion of the Pasteurella leukotoxin by Escherichia coli

Abstract Nucleic acid sequence analysis has indicated that the leukotoxin determinant from Pasteurella haemolytica is related to the hemolysin determinant from E. coli . The cloning and expression in E. coli of the lktCA genes has been previously reported, but the existence of leukotoxin secretory genes equivalent to hlyBD has not been documented. In this report we demonstrate that a 4.0 kb segment of P. haemolytica genomic DNA distal to the lktA gene, when expressed in trans to the previous cloned lktCA genes, allow the synthesis and secretion of active leukotoxin from E. coli . Complementation analysis using the cloned hlyB and hlyD genes indicates that this secretory locus derived from P. haemolytica contains two genes which we designate, by analogy, lktB and lktD .     

Association of the CAMP phenomenon in Actinobacillus pleuropneumoniae with the RTX toxins ApxI, ApxII and ApxIII

Abstract A non-hemolytic mutant of Actinobacillus pleuropneumoniae serotype 5 has a deletion spanning the entire apxI operon. Therefore it does not produce ApxI and is unable to secrete ApxII. This mutant also has lost the co-hemolytic CAMP effect which is characteristic of the species A. pleuropneumoniae . The CAMP effect is restored when the mutant is complemented in trans by the apxIBD genes cloned in a broad host range vector, thus permitting secretion of ApxII, or when the entire apxI operon is cloned in the mutant, thus restoring the original toxin phenotype ApxI⁺ ApxII⁺. When the toxins ApxI, ApxII or ApxIII individually are expressed and secreted from E. coli harboring recombinant plasmids containing the genes apxICA and apxIBD or apxIICA and apxIBD or apxIIICABD , respectively, the distinct CAMP phenomenon is produced by the recombinant strains. The CAMP phenomenon is strongest by the recombinant E. coli strain expressing the non-hemolytic ApxIII, somewhat less when ApxI is expressed, and weak when ApxII is expressed. In A. pleuropneumoniae the CAMP phenomenon is also strongest in those serotypes which express ApxIII. The CAMP phenomenon of A. pleuropneumoniae is assumed to be directly caused by any of the RTX-toxins ApxI, ApxII or ApxIII. A previously reported gene from A. pleuropneumoniae , named cfp or hlyX , which provides E. coli strains with a hemolytic character and a CAMP phenomenon, shows high similarity to the E. coli global regulation gene fnr , and which is able to complement a Δfnr mutant. This gene is assumed to have a regulatory effect on the expression of yet unknown genes giving the recombinant E. coli strains a hemolytic and CAMP phenomenon like appearance.     

Cloning, nucleotide sequence, and expression of the Pasteurella haemolytica A1 glycoprotease gene.

Pasteurella haemolytica serotype A1 secretes a glycoprotease which is specific for O-sialoglycoproteins such as glycophorin A. The gene encoding the glycoprotease enzyme has been cloned in the recombinant plasmid pH1, and its nucleotide sequence has been determined. The gene (designated gcp) codes for a protein of 35.2 kDa, and an active enzyme protein of this molecular mass can be observed in Escherichia coli clones carrying pPH1. In vivo labeling of plasmid-encoded proteins in E. coli maxicells demonstrated the expression of a 35-kDa protein from pPH1. The amino-terminal sequence of the heterologously expressed protein corresponds to that predicted from the nucleotide sequence. The glycoprotease is a neutral metalloprotease, and the predicted amino acid sequence of the glycoprotease contains a putative zinc-binding site. The gene shows no significant homology with the genes for other proteases of procaryotic or eucaryotic origin. However, there is substantial homology between gcp and an E. coli gene, orfX, whose product is believed to function in the regulation of macromolecule biosynthesis.     

Cloning and characterization of the genes encoding the haemolysin of Haemophilus ducreyi

We previously identified a heat- and protease-labile haemolytic activity expressed by Haemophilus ducreyi . In order to characterize the haemolysin at the molecular level, genomic DNA from H. ducreyi was probed with haemolysin genes from other Gram-negative organisms. The haemolysin genes of Proteus mirabilis hybridized to H. ducreyi DNA suggesting that the haemolysin of H. ducreyi is related to the Proteus/Serratia pore-forming family of haemolysins. Tn 916 mutagenesis was employed to isolate haemolysin-deficient mutants. Approximately 5000 Tn 916 transposon mutants were screened for the loss of haemolytic activity and two mutants were identified. One mutant, designated 35 000-1, was further characterized. Sequences flanking the Tn 916 element in strain 35 000-1 were employed to identify clones from a λDASHII library of H. ducreyi strain 35 000 DNA. A 13 kb insert from one lambda clone was selected for further study. This 13 kb fragment was able to both confer haemolytic activity to Escherichia coli and complement the haemolysin deficiency in strain 35 000-1. The haemolysin gene cluster was cloned from this 13 kb insert and two genes, designated hhdA and hhdB , were identified. The derived amino acid sequence of these genes demonstrated homology to the haemolysin and activation/secretion proteins of P. mirabilis and Serratia marcescens .     

The Actinobacillus pleuropneumoniae hemolysin determinant: unlinked appCA and appBD loci flanked by pseudogenes.

The appBD genes encoding the secretion functions for the 110-kDa RTX hemolysin of Actinobacillus pleuropneumoniae have been cloned and sequenced. Unlike analogous genes from other RTX determinants, the appBD genes do not lie immediately downstream from the hemolysin structural gene, appA. Although isolated from a diverse group of gram-negative organisms, the appBD genes and the characterized RTX BD genes from other organisms all exhibit a high degree of homology at both the DNA and predicted amino acid sequence levels. Analysis of the DNA sequences 3' to appA and 5' to appB suggests that these regions harbor remnant RTX B and A pseudogenes, respectively. Although the appA gene is most similar to the lktA gene from Pasteurella haemolytica (Y. F. Chang, R. Young, and D. K. Struck, DNA 8:635-647, 1989), the RTX A pseudogene upstream from appB most closely resembles the hlyB gene from Escherichia coli, suggesting that the appCA and appBD operons were derived from different ancestral RTX determinants.