Characterization of bacteriophage nucleic acids obtained from Clostridium botulinum types C and D

Chemical-Biology and Metabolomics Studies in Phage-Host Interactions

For many years, several studies have explored the molecular mechanisms involved in the infection of bacteria by their specific phages to understand the main infection strategies and the host defense strategies. The modulation of the mechanisms involved in the infection, as well as the expression of key substances in the development of the different life cycles of phages, function as a natural source of strategies capable of promoting the control of different pathogens that are harmful to human and animal health. Therefore, this chapter aims to provide an overview of the mechanisms involved in virus-bacteria interaction to explore the main compounds produced or altered as a chemical survival strategy and the metabolism modulation when occurring a host-phage interaction. In this context, emphasis will be given to the chemistry of peptides/proteins and enzymes encoded by bacteriophages in the control of pathogenic bacteria and the use of secondary metabolites recently reported as active participants in the mechanisms of phage-bacteria interaction. Finally, metabolomics strategies developed to gain new insights into the metabolism involved in the phage-host interaction and the metabolomics workflow in host-phage interaction will be presented.

Bacteriophages as drivers of bacterial virulence and their potential for biotechnological exploitation

Bacteria-infecting viruses (phages) and their hosts maintain an ancient and complex relationship. Bacterial predation by lytic phages drives an ongoing phage-host arms race, whereas temperate phages initiate mutualistic relationships with their hosts upon lysogenization as prophages. In human pathogens, these prophages impact bacterial virulence in distinct ways: by secretion of phage-encoded toxins, modulation of the bacterial envelope, mediation of bacterial infectivity and the control of bacterial cell regulation. This review builds the argument that virulence-influencing prophages hold extensive, unexplored potential for biotechnology. More specifically, it highlights the development potential of novel therapies against infectious diseases, to address the current antibiotic resistance crisis. First, designer bacteriophages may serve to deliver genes encoding cargo proteins which repress bacterial virulence. Secondly, one may develop small molecules mimicking phage-derived proteins targeting central regulators of bacterial virulence. Thirdly, bacteria equipped with phage-derived synthetic circuits which modulate key virulence factors could serve as vaccine candidates to prevent bacterial infections. The development and exploitation of such antibacterial strategies will depend on the discovery of other prophage-derived, virulence control mechanisms and, more generally, on the dissection of the mutualistic relationship between temperate phages and bacteria, as well as on continuing developments in the synthetic biology field.

Human Virome and Disease: High-Throughput Sequencing for Virus Discovery, Identification of Phage-Bacteria Dysbiosis and Development of Therapeutic Approaches with Emphasis on the Human Gut

The virome is comprised of endogenous retroviruses, eukaryotic viruses, and bacteriophages and is increasingly being recognized as an essential part of the human microbiome. The human virome is associated with Type-1 diabetes (T1D), Type-2 diabetes (T2D), Inflammatory Bowel Disease (IBD), Human Immunodeficiency Virus (HIV) infection, and cancer. Increasing evidence also supports trans-kingdom interactions of viruses with bacteria, small eukaryotes and host in disease progression. The present review focuses on virus ecology and biology and how this translates mostly to human gut virome research. Current challenges in the field and how the development of bioinformatic tools and controls are aiding to overcome some of these challenges are also discussed. Finally, the present review also focuses on how human gut virome research could result in translational and clinical studies that may facilitate the development of therapeutic approaches.

High Prevalence and Genetic Diversity of Large phiCD211 (phiCDIF1296T)-Like Prophages in Clostridioides difficile

Clostridioides difficile (formerly Clostridium difficile) is a pathogenic bacterium displaying great genetic diversity. A significant proportion of this diversity is due to the presence of integrated prophages. Here, we provide an in-depth analysis of phiCD211, also known as phiCDIF1296T, the largest phage identified in C. difficile so far, with a genome of 131 kbp. It shares morphological and genomic similarity with other large siphophages, like phage 949, infecting Lactococcus lactis, and phage c-st, infecting Clostridium botulinum A PhageTerm analysis indicated the presence of 378-bp direct terminal repeats at the phiCD211 genome termini. Among striking features of phiCD211, the presence of several transposase and integrase genes suggests past recombination events with other mobile genetic elements. Several gene products potentially influence the bacterial lifestyle and fitness, including a putative AcrB/AcrD/AcrF multidrug resistance protein, an EzrA septation ring formation regulator, and a spore protease. We also identified a CRISPR locus and a cas3 gene. We screened 2,584 C. difficile genomes available and detected 149 prophages sharing ≥80% nucleotide identity with phiCD211 (5% prevalence). Overall, phiCD211-like phages were detected in C. difficile strains corresponding to 21 different multilocus sequence type groups, showing their high prevalence. Comparative genomic analyses revealed the existence of several clusters of highly similar phiCD211-like phages. Of note, large chromosome inversions were observed in some members, as well as multiple gene insertions and module exchanges. This highlights the great plasticity and gene coding potential of the phiCD211/phiCDIF1296T genome. Our analyses also suggest active evolution involving recombination with other mobile genetic elements.IMPORTANCEClostridioides difficile is a clinically important pathogen representing a serious threat to human health. Our hypothesis is that genetic differences between strains caused by the presence of integrated prophages could explain the apparent differences observed in the virulence of different C. difficile strains. In this study, we provide a full characterization of phiCD211, also known as phiCDIF1296T, the largest phage known to infect C. difficile so far. Screening 2,584 C. difficile genomes revealed the presence of highly similar phiCD211-like phages in 5% of the strains analyzed, showing their high prevalence. Multiple-genome comparisons suggest that evolution of the phiCD211-like phage community is dynamic, and some members have acquired genes that could influence bacterial biology and fitness. Our study further supports the relevance of studying phages in C. difficile to better understand the epidemiology of this clinically important human pathogen.

A new perspective on lysogeny: prophages as active regulatory switches of bacteria

Unlike lytic phages, temperate phages that enter lysogeny maintain a long-term association with their bacterial host. In this context, mutually beneficial interactions can evolve that support efficient reproduction of both phages and bacteria. Temperate phages are integrated into the bacterial chromosome as large DNA insertions that can disrupt gene expression, and they may pose a fitness burden on the cell. However, they have also been shown to benefit their bacterial hosts by providing new functions in a bacterium-phage symbiotic interaction termed lysogenic conversion. In this Opinion article, we discuss another type of bacterium-phage interaction, active lysogeny, in which phages or phage-like elements are integrated into the bacterial chromosome within critical genes or operons and serve as switches that regulate bacterial genes via genome excision.

Tubulin homolog TubZ in a phage-encoded partition system

Partition systems are responsible for the process whereby large and essential plasmids are accurately positioned to daughter cells during bacterial division. They are typically made of three components: a centromere-like DNA zone, an adaptor protein, and an assembling protein that is either a Walker-box ATPase (type I) or an actin-like ATPase (type II). A recently described type III segregation system has a tubulin/FtsZ-like protein, called TubZ, for plasmid movement. Here, we present the 2.3 Å structure and dynamic assembly of a TubZ tubulin homolog from a bacteriophage and unravel the Clostridium botulinum phage c-st type III partition system. Using biochemical and biophysical approaches, we prove that a gene upstream from tubZ encodes the partner TubR and localize the centromeric region (tubS), both of which are essential for anchoring phage DNA to the motile TubZ filaments. Finally, we describe a conserved fourth component, TubY, which modulates the TubZ-R-S complex interaction.

Molecular mechanism of acquisition of the cholera toxin genes

One of the major pathogenic determinants of Vibrio cholerae, the cholera toxin, is encoded in the genome of a filamentous phage, CTXφ. CTXφ makes use of the chromosome dimer resolution system of V. cholerae to integrate its single stranded genome into one, the other, or both V. cholerae chromosomes. Here, we review current knowledge about this smart integration process.

Molecular analysis of an extrachromosomal element containing the C2 toxin gene discovered in Clostridium botulinum type C

Clostridium botulinum cultures are classified into seven types, types A to G, based on the antigenicity of the neurotoxins produced. Of these seven types, only types C and D produce C2 toxin in addition to the neurotoxin. The C2 toxin consists of two components designated C2I and C2II. The genes encoding the C2 toxin components have been cloned, and it has been stated that they might be on the cell chromosome. The present study confirmed by using pulsed-field gel electrophoresis and subsequent Southern hybridization that these genes are on a large plasmid. The complete nucleotide sequence of this plasmid was determined by using a combination of inverse PCR and primer walking. The sequence was 106,981 bp long and contained 123 potential open reading frames, including the c2I and c2II genes. The 57 products of these open reading frames had sequences similar to those of well-known proteins. It was speculated that 9 these 57 gene products were related to DNA replication, 2 were responsible for the two-component regulatory system, and 3 were sigma factors. In addition, a total of 20 genes encoding proteins related to diverse processes in purine catabolism were found in two regions. In these regions, there were 9 and 11 genes rarely found in plasmids, indicating that this plasmid plays an important role in purine catabolism, as well as in C2 toxin production.

The genome sequence of Clostridium botulinum type C neurotoxin-converting phage and the molecular mechanisms of unstable lysogeny

Botulinum neurotoxins (BoNTXs) produced by Clostridium botulinum are among the most poisonous substances known. Of the seven types of BoNTXs, genes for type C1 and D toxins (BoNTX/C1 and D) are carried by bacteriophages. The gene for exoenzyme C3 also resides on these phages. Here, we present the complete genome sequence of c-st, a representative of BoNTX/C1-converting phages. The genome is a linear double-stranded DNA of 185,682 bp with 404-bp terminal direct repeats, the largest known temperate phage genome. We identified 198 potential protein-coding regions, including the genes for production of BoNTX/C1 and exoenzyme C3. Very exceptionally, as a viable bacteriophage, a number of insertion sequences were found on the c-st genome. By analyzing the molecular structure of the c-st genome in lysogens, we also found that it exists as a circular plasmid prophage. These features account for the unstable lysogeny of BoNTX phages, which has historically been called "pseudolysogeny." The PCR scanning analysis of other BoNTX/C1 and D phages based on the c-st sequence further revealed that BoNTX phages comprise a divergent phage family, probably generated by exchanging genomic segments among BoNTX phages and their relatives.

The gene for component-II of botulinum C2 toxin

The gene encoding component-II of the Clostridium botulinum C2 toxin was cloned from the chromosomal DNA of C. botulinum type C strain (C)-203U28, and the nucleotide sequence was determined. The gene (bc2h) encodes a protein with 721 amino acid residues and is located at 247 bp downstream of the gene for component-I. The N-terminal 16 amino acids were identical to those obtained by analysis of the purified component-II toxin. The ORF for bc2h had only 39% homology at the amino acid level with the C.perfringens iota-Ib protein and an ATP/GTP binding site which is present in the iota-Ib protein is missing from the protein encoded by bc2h. Both genes had a homologous region that predicts a transmembrane segment.

Organization of the botulinum neurotoxin C1 gene and its associated non-toxic protein genes in Clostridium botulinum C 468

A 12.3 kb DNA fragment encompassing the botulinum neurotoxin C1 (BoNT/C1) gene and an upstream flanking region was sequenced from Clostridium botulinum C 468 phage 1C. The resulting bont/C1 locus includes six genes which are organized into three transcriptional units. Cluster 1 encompasses the bont/C1 gene and an upstream gene encoding a non-toxic protein associated with the toxin (Antp139/C1). Transcriptional analysis revealed that these two genes form an operon; the bont/C1 gene can be transcribed alone or co-transcribed with antp139/C1. Cluster 2 encompasses three genes (antp33/C1, antp17/C1 and antp70/C1), which also form an operon. The corresponding proteins are similar to components of the hemagglutinin complex associated with BoNT/A and BoNT/B of C. botulinum A and B. In addition, Antp33/C1 is identical to HA-33, an hemagglutinin encoded by C. botulinum C-Stockholm phage C-St; Antp70/C1 displays some relatedness to C. perfringens enterotoxin. The third transcriptional unit consists of orf-22, which encodes a basic protein showing 29% identity with the gene product of uviA, a plasmid-encoded protein of 22 kDa which has been identified as a positive regulator of the bacteriocin production in C. perfringens. Orf-22 could be an effector controlling the expression of the bont/C1 and its antp genes in C. botulinum C 468.

Transfer of neurotoxigenicity from Clostridium butyricum to a nontoxigenic Clostridium botulinum type E-like strain

Two Clostridium butyricum strains from infant botulism cases produce a toxic molecule very similar to C. botulinum type E neurotoxin. Chromosomal, plasmid, and bacteriophage DNAs of toxigenic and nontoxigenic strains of C. butyricum and C. botulinum type E were probed with (i) a synthesized 30-mer oligonucleotide encoding part of the L chain of type E botulinum toxin and (ii) the DNA of phages lysogenizing these cultures. The toxin gene probe hybridized to the chromosomal DNA of toxigenic strains but not to their plasmid DNA. All toxigenic and most nontoxigenic strains tested were lysogenized by a prophage on the chromosome. Prophages of toxigenic strains, irrespective of species, had related or identical DNAs which differed from the DNAs of prophages in nontoxigenic strains. The prophage of toxigenic strains was adjacent or close to the toxin gene on the chromosome. Phage DNAs purified from toxigenic strains did not hybridize with the toxin gene probe but could act as the template of the polymerase chain reaction to amplify the toxin gene. The toxin gene was not transferred between C. botulinum and C. butyricum (either direction) when different pairs of a possible gene donor and a recipient strain were grown as mixed cultures. Nontoxigenic C. butyricum or C. botulinum type E-like strains did not become toxigenic when grown in broth containing the phage induced from a toxigenic strain of the other species.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparative analysis of C3 and botulinal neurotoxin genes and their environment in Clostridium botulinum types C and D

The C3 exoenzyme gene is located on a bacteriophage in Clostridium botulinum types C and D (M. R. Popoff, D. Hauser, P. Boquet, M. W. Eklund, and D. M. Gill, Infect. Immun. 59:3673-3679, 1991). A derivative CN phage from phage C of C. botulinum Stockholm (C-St) (K. Oguma, H. Iida, and K. Inoue, Jpn. J. Microbiol. 19:167-172, 1975), isolated as neurotoxin negative, also does not produce exoenzyme C3. The botulinal neurotoxin C1 gene is present on the CN phage but contains a stop mutation in the DNA region encoding the N-terminal part of the heavy chain (codon 553). The putative truncated botulinal neurotoxin C1 protein was not recovered in a C. botulinum strain harboring the CN phage. We found that the C3 gene is localized on a 21.5-kbp DNA fragment flanked by the core motif 5'-AAGGAG-3' in DNAs of phage C of C. botulinum 468 (C-468), C-St phage, and phage D of C. botulinum 1873 (D-1873). The 21.5-kbp DNA fragment is deleted in CN phage DNA, and the motif 5'-AAGGAG-3' is present only in one copy at the deletion junction, but the deletion in the CN phage could be nonspecific, since this phage was obtained by nitrosoguanidine treatment. These findings could indicate that the C3 gene is localized on a 21.5-kbp mobile element. C. botulinum type C strain 003-9 produces a C3 exoenzyme (Y. Nemoto, T. Namba, S. Kozaki, and S. Narumiya, J. Biol. Chem. 266:19312-19319, 1991), and Staphylococcus aureus E1 produces a related C3 enzyme which is named epidernmal cell differentiation inhibitor (S. Inoue, M. Sugai, Y. Murooka, S. Y. Paik, Y. M. Hong, H. Oghai, and H. Suginaka, Biochem. Biophys. Res. Comm. 174:459-464, 1991) and which shares 80.6 and 56.6% similarity, respectively with the C3 enzymes from C-468 or C-St and D-1873 phages athe amino acid level. The features of the putative 21.5-kbp transposon were not found in C. botulinum 003-9 and S. aureus E1, as determined by analysis of the C3 and epidermal cell differentiation inhibitor gene-flanking DNA regions. These data suggest a common ancestral origin and divergent evolution of the C3 genes in these three groups of bacterial strains and dissemination of a 21.5-kbp element carrying the C3 gene C-468, C-St, and D-1873 phages.

Characterization of neurotoxigenic Clostridium butyricum strain by DNA hybridization test and by in vivo and in vitro germination tests of spores

The germination of spores of a neurotoxigenic Clostridium butyricum strain (BL 6340), which was isolated from infant botulism in Italy, and that of a nontoxigenic C. butyricum type strain (NCIB 7423) were studied. The spores of BL 6340 strain were killed at 80 C for 10 min, and required the mixture of L-alanine, L-lactate, glucose and bicarbonate for their optimal germination. These characteristics are the same as those of Clostridium botulinum type E strain, but different from those of NCIB 7423 strain. In a hybridization test, however, the labeled DNAs extracted from NCIB 7423 strain highly (98%) hybridized to the DNAs of the BL 6340 strain, but little (45%) to the DNAs of C. botulinum type E strain. The biochemical properties of the BL 6340 and NCIB 7423 strains were identical, but different from those of C. botulinum type E. These data confirmed that the BL 6340 strain belongs to C. butyricum species, but that only its characteristics of toxin production, its minimum requirements for germination, and the behavior of its spores to heat treatment are the same as those of C. botulinum type E. When conventionally raised suckling mice were injected with 5 x 10(7) spores of BL 6340 strain intra- or orogastrically, botulism was not observed. However, 8- to 13-day-old mice had type E botulinum toxin in the large intestine 3 days after introduction of its spores.

Characterization of the C3 gene of Clostridium botulinum types C and D and its expression in Escherichia coli

Clostridium botulinum type C and D strains produce exoenzyme C3, which ADP-ribosylates the Rho protein, a 21-kDa regulatory GTP-binding protein. In a previous work, we demonstrated that the C3 gene is encoded by bacteriophages C and D of C. botulinum by using DNA-DNA hybridizations with oligonucleotides deduced from the C3 protein N-terminal sequence. The C3 coding gene was cloned and sequenced, but its upstream DNA region could not be studied because of its instability in Escherichia coli. In this work, the upstream DNA region of the C3 gene was directly amplified by the polymerase chain reaction and sequenced. The C3 gene encodes a polypeptide of 251 amino acids (27,823 Da) consisting of a 40-amino-acid signal peptide and a mature protein of 211 amino acids (23,546 Da). The C3 mature protein was expressed in E. coli under the control of the trc promoter. The recombinant polypeptide obtained was recognized by C3 antibodies and ADP-ribosylated the Rho protein. The C3 gene nucleotide sequence is identical on C and D phage DNAs. At the amino acid sequence level, no similarity was found among C3, other ADP-ribosylating toxins, or tetanus or botulinal A, C1, and D neurotoxins.

Clostridium botulinum types A, B, C1, and E produce proteins with or without hemagglutinating activity: do they share common amino acid sequences and genes?

Clostridium botulinum produce the antigenically distinct 150 kD neurotoxin serotypes (e.g., A, B, C1, and E) and simultaneously proteins, A Hn+, B Hn+, C Hn+, and E Hn-, that have high, low, and no hemagglutinating activity. A Hn+ and B Hn+ are serologically cross-reactive. A Hn+, B Hn+, and C Hn+ found as large aggregates (900-220 kD) can be dissociated on SDS-PAGE into multiple subunits, the smallest for A Hn+, B Hn+ is 17 kD and 27 kD for C Hn+. The 116 kD E Hn- does not aggregate. We determined the sequences of 10-33 amino terminal residues of the 17, 21.5, 35, and 57 kD subunits of A Hn+ and B Hn+. Each of these subunits have unique sequences, indicating that the larger units studies are not homomers or heteromers of smaller units. The subunits of A Hn+ and B Hn+ of comparable size have striking sequence identity (e.g., 21.5 kD subunits from the two are identical and 57 kD subunits have 80% identity). In vitro proteolysis of 116 kD E Hn- with different proteases did not impart hemagglutinating activity to the fragments. The 116 kD E Hn- and one of its proteolytic fragments (87 kD) were partially sequenced. Sixty-two base pairs downstream from the termination codon of the cloned 33 kD subunit of C Hn+, there is an initiation codon followed by an open reading frame for at least 34 amino acid residues (Tsuzuki et al., 1990). The derived amino acid sequence of this open reading frame, we found, has 73-84% sequence identity with those of the 17 kD subunits of A Hn+ and B Hn+ and significant identity with the N-terminal of E Hn-. These highly conserved sequences show existence of genetic linkage among the Hn+ and Hn- proteins.

Cloning of the structural gene for Clostridium botulinum type C1 toxin and whole nucleotide sequence of its light chain component

The toxigenicity of Clostridium botulinum type C1 is mediated by specific bacteriophages. DNA was extracted from one of these phages. Two DNA fragments, 3 and 7.8 kb, which produced the protein reacting with antitoxin serum were cloned by using bacteriophage lambda gt11 and Escherichia coli. Both DNA fragments were then subcloned into pUC118 plasmids and transferred into E. coli cells. The nucleotide sequences of the cloned DNA fragments were analyzed by the dideoxy chain termination method, and their gene products were analyzed by Western immunoblot. The 7.8-kb fragment coded for the entire light chain component and the N terminus of the heavy chain component of the toxin, whereas the 3-kb fragment coded for the remaining heavy chain component. The entire nucleotide sequence for the light chain component was determined, and the derived amino acid sequence was compared with that of tetanus toxin. It was found that the light chain component of C1 toxin possessed several amino acid regions, in addition to the N terminus, that were homologous to tetanus toxin.

The nucleotide and deduced amino acid sequences of EcoRI fragment containing the 5'-terminal region of Clostridium botulinum type E toxin gene cloned from Mashike, Iwanai and Otaru strains

Chromosomal DNAs were extracted from toxigenic three Clostridium botulinum type E strains isolated from food-borne botulism. After digestion by EcoRI, the fragments were cloned into Escherichia coli by using bacteriophage lambda gt11 and screened with monoclonal antibody recognizing the light chain component of botulinum type E toxin. The fragments (about 1 kbp size) cloned from each strain were recloned into a plasmid vector pUC118. The E. coli cells transformed with the recombinant plasmids produced 33 kDa protein with or without IPTG (isopropyl-beta-D-thiogalactopyranoside) which reacted with the monoclonal antibody. The nucleotide sequences of the cloned EcoRI fragments from the three type E strains were identical and contain the 5'-terminal region of the type E toxin gene. It was also found that there exist several highly homologous nucleotide sequences among the botulinum types A, C and E, and tetanus toxin genes in both translated and untranslated regions.

Cloning and complete nucleotide sequence of the gene for the main component of hemagglutinin produced by Clostridium botulinum type C

In Clostridium botulinum types C and D, phage conversion to toxin and hemagglutinin (HA) production has been reported. DNA was extracted from a converting type C Stockholm phage, c-st, and a fragment (7.8 kilobase pairs) coding for the parts of both toxin and HA was cloned. The gene for HA was recloned, and the complete nucleotide sequence was determined. The molecular mass of this gene product was 33 kilodaltons, and it showed HA activity. The HA preparation partially purified from a type C Stockholm culture demonstrated two major bands (33 and 53 kilodaltons) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with or without reducing agent. The amino acid sequence of the N terminus of the 33-kilodalton component of the native HA preparation, which was determined by a direct protein microsequencing procedure, was identical to that deduced from the nucleotide sequence of cloned HA gene. These data indicate that the cloned gene product (33 kilodaltons) is an important component of HA.

The complete nucleotide sequence of the gene coding for botulinum type C1 toxin in the C-ST phage genome

Two DNA fragments, 3 kbp and 7.8kbp, which encode the type C1 botulinum neurotoxin gene, were obtained from toxigenic bacteriophage DNA by treatment with a restriction enzyme. They were cloned into the plasmid vectors for nucleotide sequence determination. The nucleotide sequence contained a single open reading frame coding for 1,291 amino acids corresponding to a polypeptide with a molecular weight of 149,000. The amino acid sequence of the C1 toxin has a few regions highly homologous with tetanus toxin.

Recent advances in the genetics of the clostridia

Several laboratories around the world have started work on genetic analysis of clostridia. Interest in this diverse group of anaerobic organisms has grown with increasing awareness of the benefits that may accrue from their biotechnological exploitation. Research to date has focussed on construction of shuttle vectors containing replicons from clostridial and streptococcal plasmids, development of methods for transferring genes, and molecular cloning of genes--especially those involved in toxigenicity, fermentative metabolism and polysaccharide utilization. In selected species gene transfer by protoplast transformation, electroporation and conjugation has been accomplished and transposable elements have been introduced. It can be anticipated that our understanding of the molecular biology of these interesting organisms will grow rapidly in the future, bringing with it improved prospects for rational biotechnological exploitation.