Barry Collins

The ABC Transporter AnrAB Contributes to the Innate Resistance of Listeria monocytogenes to Nisin, Bacitracin, and Various β-Lactam Antibiotics

ABSTRACT A mariner transposon bank was used to identify loci that contribute to the innate resistance of Listeria monocytogenes to the lantibiotic nisin. In addition to highlighting the importance of a number of loci previously associated with nisin resistance (mprF, virRS, and telA), a nisin-sensitive phenotype was associated with the disruption of anrB (lmo2115), a gene encoding the permease component of an ABC transporter. The contribution of anrB to nisin resistance was confirmed by the creation of nonpolar deletion mutants. The loss of this putative multidrug resistance transporter also greatly enhanced sensitivity to bacitracin, gallidermin, and a selection of β-lactam antibiotics. A comparison of the relative antimicrobial sensitivities of a number of mutants established the ΔanrB strain as being one of the most bacitracin-sensitive L. monocytogenes strains identified to date.

TelA Contributes to the Innate Resistance of Listeria monocytogenes to Nisin and Other Cell Wall-Acting Antibiotics

ABSTRACT Nisin is a class I bacteriocin (lantibiotic), which is employed by the food and veterinary industries and exhibits potent activity against numerous pathogens. However, this activity could be further improved through the targeting and inhibition of factors that contribute to innate nisin resistance. Here we describe a novel locus, lmo1967, which is required for optimal nisin resistance in Listeria monocytogenes. The importance of this locus, which is a homologue of the tellurite resistance gene telA, was revealed after the screening of a mariner random mutant bank of L. monocytogenes for nisin-susceptible mutants. The involvement of telA in nisin resistance was confirmed through an analysis of a nonpolar deletion mutant. In addition to being 4-fold-more susceptible to nisin, the ΔtelA strain was also 8-fold-more susceptible to gallidermin and 2-fold-more susceptible to cefuroxime, cefotaxime, bacitracin, and tellurite. This is the first occasion upon which telA has been investigated in a Gram-positive organism and also represents the first example of a link being established between a telA gene and resistance to cell envelope-acting antimicrobials.

Assessing the Contributions of the LiaS Histidine Kinase to the Innate Resistance of Listeria monocytogenes to Nisin, Cephalosporins, and Disinfectants

ABSTRACT The Listeria monocytogenes LiaSR two-component system (2CS) encoded by lmo1021 and lmo1022 plays an important role in resistance to the food preservative nisin. A nonpolar deletion in the histidine kinase-encoding component (ΔliaS) resulted in a 4-fold increase in nisin resistance. In contrast, the ΔliaS strain exhibited increased sensitivity to a number of cephalosporin antibiotics (and was also altered with respect to its response to a variety of other antimicrobials, including the active agents of a number of disinfectants). This pattern of increased nisin resistance and reduced cephalosporin resistance in L. monocytogenes has previously been associated with mutation of a second histidine kinase, LisK, which is a predicted regulator of liaS and a penicillin binding protein encoded by lmo2229. We noted that lmo2229 transcription is increased in the ΔliaS mutant and in a ΔliaS ΔlisK double mutant and that disruption of lmo2229 in the ΔliaS ΔlisK mutant resulted in a dramatic sensitization to nisin but had a relatively minor impact on cephalosporin resistance. We anticipate that further efforts to unravel the complex mechanisms by which LiaSR impacts on the antimicrobial resistance of L. monocytogenes could facilitate the development of strategies to increase the susceptibility of the pathogen to these agents.

Structure and Functional analysis of the host-recognition device of Lactococcal Phage Tuc2009

ABSTRACT Many phages employ a large heteropolymeric organelle located at the tip of the tail, termed the baseplate, for host recognition. Contrast electron microscopy (EM) of the lactococcal phage Tuc2009 baseplate and its host-binding subunits, the so-called tripods, allowed us to obtain a low-resolution structural image of this organelle. Structural comparisons between the baseplate of the related phage TP901-1 and that of Tuc2009 demonstrated that they are highly similar, except for the presence of an additional protein in the Tuc2009 baseplate (BppATuc2009), which is attached to the top of the Tuc2009 tripod structure. Recombinantly produced Tuc2009 or TP901-1 tripods were shown to bind specifically to their particular host cell surfaces and are capable of almost fully and specifically eliminating Tuc2009 or TP901-1 phage adsorption, respectively. In the case of Tuc2009, such adsorption-blocking ability was reduced in tripods that lacked BppATuc2009, indicating that this protein increases the binding specificity and/or affinity of the Tuc2009 tripod to its host receptor.

A system for the random mutagenesis of the two-peptide lantibiotic lacticin 3147: analysis of mutants producing reduced antibacterial activities.

Lantibiotics are antimicrobial peptides that contain several unusual amino acids resulting from a series of enzyme-mediated posttranslational modifications. As a consequence of being gene-encoded, the implementation of peptide bioengineering systems has the potential to yield lantibiotic variants with enhanced chemical and physical properties. Here we describe a functional two-plasmid expression system which has been developed to allow random mutagenesis of the two-component lantibiotic, lacticin 3147. One of these plasmids contains a randomly mutated version of the two structural genes, ltnA1 and ltnA2, and the associated promoter, Pbac, while the other encodes the remainder of the proteins required for the biosynthesis of, and immunity to, lacticin 3147. To test this system, a bank of ∼1,500 mutant strains was generated and screened to identify mutations that have a detrimental impact on the bioactivity of lacticin 3147. This strategy established/confirmed the importance of specific residues in the structural peptides and their associated leaders and revealed that a number of alterations which mapped to the –10 or –35 regions of Pbac abolished promoter activity.

The Atomic Structure of the Phage Tuc2009 Baseplate Tripod Suggests that Host Recognition Involves Two Different Carbohydrate Binding Modules

ABSTRACT The Gram-positive bacterium Lactococcus lactis, used for the production of cheeses and other fermented dairy products, falls victim frequently to fortuitous infection by tailed phages. The accompanying risk of dairy fermentation failures in industrial facilities has prompted in-depth investigations of these phages. Lactococcal phage Tuc2009 possesses extensive genomic homology to phage TP901-1. However, striking differences in the baseplate-encoding genes stimulated our interest in solving the structure of this host’s adhesion device. We report here the X-ray structures of phage Tuc2009 receptor binding protein (RBP) and of a “tripod” assembly of three baseplate components, BppU, BppA, and BppL (the RBP). These structures made it possible to generate a realistic atomic model of the complete Tuc2009 baseplate that consists of an 84-protein complex: 18 BppU, 12 BppA, and 54 BppL proteins. The RBP head domain possesses a different fold than those of phages p2, TP901-1, and 1358, while the so-called “stem” and “neck” domains share structural features with their equivalents in phage TP901-1. The BppA module interacts strongly with the BppU N-terminal domain. Unlike other characterized lactococcal phages, Tuc2009 baseplate harbors two different carbohydrate recognition sites: one in the bona fide RBP head domain and the other in BppA. These findings represent a major step forward in deciphering the molecular mechanism by which Tuc2009 recognizes its saccharidic receptor(s) on its host. IMPORTANCE Understanding how siphophages infect Lactococcus lactis is of commercial importance as they cause milk fermentation failures in the dairy industry. In addition, such knowledge is crucial in a general sense in order to understand how viruses recognize their host through protein-glycan interactions. We report here the lactococcal phage Tuc2009 receptor binding protein (RBP) structure as well as that of its baseplate. The RBP head domain has a different fold than those of phages p2, TP901-1, and 1358, while the so-called “stem” and “neck” share the fold characteristics also found in the equivalent baseplate proteins of phage TP901-1. The baseplate structure contains, in contrast to other characterized lactococcal phages, two different carbohydrate binding modules that may bind different motifs of the host’s surface polysaccharide. Understanding how siphophages infect Lactococcus lactis is of commercial importance as they cause milk fermentation failures in the dairy industry. In addition, such knowledge is crucial in a general sense in order to understand how viruses recognize their host through protein-glycan interactions. We report here the lactococcal phage Tuc2009 receptor binding protein (RBP) structure as well as that of its baseplate. The RBP head domain has a different fold than those of phages p2, TP901-1, and 1358, while the so-called “stem” and “neck” share the fold characteristics also found in the equivalent baseplate proteins of phage TP901-1. The baseplate structure contains, in contrast to other characterized lactococcal phages, two different carbohydrate binding modules that may bind different motifs of the host’s surface polysaccharide.

The impact of nisin on sensitive and resistant mutants of Listeria monocytogenes in cottage cheese.

Aims:  Listeria monocytogenesΔgadD1 and ΔlisK mutants display enhanced and reduced sensitivity, respectively, to the food preservative nisin in laboratory media. However, the behaviour of these strains in a nisin‐containing food has not been assessed. Here we use cottage cheese as a model food to address this issue.

Genetic and functional characterisation of the lactococcal P335 phage-host interactions

BackgroundDespite continuous research efforts, bacterio(phages) infecting Lactococcus lactis starter strains persist as a major threat to dairy fermentations. The lactococcal P335 phages, which are currently classified into four sub-groups (I-IV), are the second most frequently isolated phage group in an industrial dairy context.ResultsThe current work describes the isolation and comparative genomic analysis of 17 novel P335 group phages. Detailed analysis of the genomic region of P335 phages encoding the so-called “baseplate”, which includes the receptor binding protein (RBP) was combined with a functional characterization of the RBP of sub-group III and IV phages. Additionally, calcium-dependence assays revealed a specific requirement for calcium by sub-group IV phages while host range analysis highlighted a higher number of strains with CWPS type A (11 of 39 strains) are infected by the P335 phages assessed in this study than those with a C (five strains), B (three of 39 strains) or unknown (one of 39 strains) CWPS type.ConclusionsThese analyses revealed significant divergence among RBP sequences, apparently reflecting their unique interactions with the host and particularly for strains with a type A CWPS. The implications of the genomic architecture of lactococcal P335 phages on serving as a general model for Siphoviridae phages are discussed.

Structure and assembly of TP901-1 virion unveiled by mutagenesis

Bacteriophages of the Siphoviridae family represent the most abundant viral morphology in the biosphere, yet many molecular aspects of their virion structure, assembly and associated functions remain to be unveiled. In this study, we present a comprehensive mutational and molecular analysis of the temperate Lactococcus lactis-infecting phage TP901-1. Fourteen mutations located within the structural module of TP901-1 were created; twelve mutations were designed to prevent full length translation of putative proteins by non-sense mutations, while two additional mutations caused aberrant protein production. Electron microscopy and Western blot analysis of mutant virion preparations, as well as in vitro assembly of phage mutant combinations, revealed the essential nature of many of the corresponding gene products and provided information on their biological function(s). Based on the information obtained, we propose a functional and assembly model of the TP901-1 Siphoviridae virion.

Lactococcus lactis phage TP901-1 as a model for Siphoviridae virion assembly.

ABSTRACT Phages infecting Lactococcus lactis pose a serious threat to the dairy fermentation sector. Consequently, they are among the most thoroughly characterized Gram positive-infecting phages. The majority of lactococcal phages belong to the tailed family of phages named the Siphoviridae. The coliphage lambda and the Bacillus subtilis phage SPP1 have been the predominant comparators for emerging siphophages both genomically and structurally and both phages recognize a membrane protein receptor. In contrast, the lactococcal P335 group phage TP901-1 attaches to cell wall surface polysaccharides. It is a typical “lambdoid” siphophage possessing a long non-contractile tail and a genomic architecture reminiscent of lambda and SPP1 despite low or undetectable sequence homology in many of its encoded products, especially those involved in host recognition. A functional analysis of the structural components of TP901-1 was undertaken based on the characterization of a series of mutants in the region encoding the capsid and tail morphogenetic elements. Through this analysis, it was possible to deduce that, despite the lack of sequence homology, the overall genomic architecture of Siphoviridae phages typified by functional synteny is conserved. Furthermore, a model of the TP901–1 assembly pathway was developed with potential implications for many tailed phages.