25 research outputs found
Molecular epidemiology of campylobacteriosis and evolution of Campylobacter jejuni ST-474 in New Zealand : a thesis presented in partial fullfilment [sic] of the requirements for the degree of Doctor of Philosophy at Massey University, Institute of Veterinary, Animal and Biomedical Sciences, Massey University, Palmerston North, New Zealand
Population genetics and phylogenetics have the potential to provide enormous insights into the epidemiology
and ecology of disease causing pathogens. Molecular datasets are the basis to infer population structure,
gene flow (between host populations and between different geographical locations) and to predict the
evolutionary dynamics of pathogens. Campylobacter colonisation in food producing animals has been extensively
studied and the population structure and host association of C. jejuni, the most commonly reported
gastro-enteric pathogen, has also been well defined. In contrast, host-pathogen relationships and the population
structure of C. jejuni in urban wild birds and pets have not been well defined on a wide range of spatial
and/or temporal scales. A greater understanding of these details should allow disease control authorities to
track the transmission of pathogens from one host species to another, identify the origin of pathogens and
to better understand environmental factors influencing underlying molecular mechanisms.
In the first study in this thesis the presence of C. jejuni in mallard ducks and starlings within five playgrounds
in Palmerston North, New Zealand was studied. The prevalence of Campylobacter and C. jejuni in
both species showed a bimodal seasonal pattern. The population structure and population differentiation of
C. jejuni in these species were examined using multilocus sequence typing (MLST). Rarefaction analyses
showed that the C. jejuni populations within mallard ducks were more diverse than starlings, particularly
during the winter. Pairwise fixation indices showed that the population of C. jejuni in ducks was significantly
different from that of starlings and that it differed over time. Conspicuous host association was
evident with clonal complexes of C. jejuni such as ST-1034, ST-692 and ST-1332 specific to ducks and
ST-177 and ST-682 specific to starlings. In addition, a larger proportion of C. jejuni genotypes that could
not be assigned a clonal complex were found in both ducks and starlings, particularly during the winter.
In the second study, C. jejuni from domestic pets (dogs and cats) were characterised using MLST and
by typing the cell surface antigens, porA and flaA. The ST-45 complex, a clonal complex predominantly
reported in human campylobacteriosis cases, was found to be the predominant clone present in both species.
These findings shed some light on the contribution of pets as a putative source of human campylobacteriosis
cases in New Zealand.
In the third study, the ST-474 C. jejuni genotype, considered to be the endemic strain in New Zealand, was
isolated from human cases and poultry carcasses from the Manawatu region from 2005 to 2009. Seven
samples of ST-474 were sequenced and a subset of 50 full length genes were studied. These analyses
demonstrated molecular differences between full length genes that were identical in the region used for
MLST. Further, alleles characteristic of the ST-474 genome within the investigated metabolic housekeeping
genes (n = 25) were identified. Our findings were that ST-474 genome is genetically distinct from other C.
jejuni reference genomes with respect to certain alleles. In addition, MLST alleles were found to be robust
predictors of the most recent common ancestors of a genome. The fourth study investigated the genetic
stability and vulnerability of the informational genes to various evolutionary forces within the seven ST-
474 genomes. Twenty five genes comprised of nucleotide metabolism, repair and ribosomal functions were
investigated showing a high level of genetic diversity in the DNA repair as well as nucleotide metabolic
genes such as gidA, ogt, recJ, ssb, uvrA, uvrB and xseA. In contrast, the ribosomal genes were stable
and identical across the seven genomes. The insertion of selenocysteine in three of the 25 genes indicates
the presence of horizontal gene transfer within the ST-474 genomes. It is hypothesised that the genetic
uniqueness of ST-474 may have arisen due to the geographic isolation of New Zealand, its poultry industry
and an absence of exchange of sequence types which might typically occur through international trade of
fresh poultry meat.
Collectively, the studies presented in this thesis provide a better understanding of the dynamism of C. jejuni
as a species and ST-474’s adaptational capacity and evolutionary potential (within the investigated set of
genes) in response to changing intracellular and extracellular environments. This thesis has introduced the
idea of using individual full length gene analysis, demonstrating the molecular differences between genes
that contained identical alleles at the MLST loci. The research approaches implemented in this thesis can
be readily applied to any pathogenic bacteria, particularly foodborne and emerging pathogens such as E.
coli and Salmonella. This, in turn should provide new opportunities for bacterial drug targets and vaccine
candidates
The role of probiotics in the inhibition of Campylobacter jejuni colonization and virulence attenuation
Campylobacter jejuni is one of the most common bacterial causes of human gastroenterocolitis worldwide, leading to diarrhea and other serious post-infectious complications. Probiotics form an attractive alternative intervention strategy for most of the enteric infections. However, the role of probiotics in C. jejuni infections requires detailed investigations in order to delineate the probiotic strains that are effective against C. jejuni. Although there are several biological mechanisms involved in the inhibition of pathogenic bacterial growth, the strains of probiotics and their mechanisms of actions through which they combat C. jejuni invasion have not been studied in greater detail. This mini review details the factors that are involved in the colonization and establishment of C. jejuni infection, with special reference to chickens, the natural host of C. jejuni, and the studies that have investigated the effect of different probiotic strains against C. jejuni colonization and growth. This review has collated the studies conducted using probiotics to inhibit C. jejuni colonization and growth to date to provide a collective knowledge about the role of probiotics as an alternative intervention strategy for campylobacteriosis
Faeco-prevalence of Campylobacter jejuni in urban wild birds and pets in New Zealand
Background: Greater attention has been given to Campylobacter jejuni (C. jejuni) prevalence in poultry and ruminants as they are regarded as the major contributing reservoirs of human campylobacteriosis. However, relatively little work has been done to assess the prevalence in urban wild birds and pets in New Zealand, a country with the highest campylobacteriosis notification rates. Therefore, the aim of the study was to assess the faeco-prevalence of C. jejuni in urban wild birds and pets and its temporal trend in the Manawatu region of New Zealand.
Findings: A repeated cross-sectional study was conducted from April 2008 to July 2009, where faecal samples were collected from 906 ducks, 835 starlings, 23 Canadian goose, 2 swans, 2 pied stilts, 498 dogs and 82 cats. The faecoprevalence of C. jejuni was 20% in ducks, 18% in starlings, 9% in Canadian goose, 5% in dogs and 7% in cats. The faecoprevalence of C. jejuni was relatively higher during warmer months of the year in ducks, starlings and dogs while starlings showed increased winter prevalence. No such trend could be assessed in Canadian goose, swans, pied stilts and cats as samples could not be collected for the entire study period from these species.
Conclusions: This study estimated the faeco-prevalence of C. jejuni in different animal species where the prevalence was relatively high during warmer months in general. However, there was relative increase in winter prevalence in starlings. The urban wild bird species and pets may be considered potential risk factors for human campylobacteriosis in New Zealand, particularly in small children
Gene lengths and sites of recombination in metabolic housekeeping and informational genes.
<p>The data provides the lengths of all the metabolic housekeeping genes and informational genes investigated in the study from 19 C. jejuni genomes. It also describes the recombination sites identified within the housekeeping genes and informational genes obtained from the analysis of aligned nucleotide sequences (using Geneious) from 19 C. jejuni genomes carried out in DNAsp genetic software.</p
Guanine-cytosine (GC) and GC3 contents of the individual metabolic housekeeping and informational genes.
<p>The data provides the guanine-cytosine (GC) contents for individual metabolic housekeeping genes and the individual genes investigated in the study from 19 C. jejuni genomes. It also provides the guanine-cytosine contents at the third codon position (GC3) for individual metabolic housekeeping genes and individual informational genes investigated in the study from 19 C. jejuni genomes.</p
Nucleotide sequences of informational genes from 19 C. jejuni genomes.
<p>Informational genes from 19 <i>C. jejuni</i> genomes that include seven <i>C. jejuni</i> ST-474 genomes sequenced at Institute of Veterinary, Animal and Biomedical Sciences, Massey University, Palmerston North, New Zealand. These are nucleotide sequences presented in FASTA format. CJ11168: <i>C. jejuni</i> subsp. <i>jejuni</i> 11168, CJ260.94: <i>C. jejuni</i> subsp. <i>jejuni</i> 260.90, CJ81116: <i>C. jejuni</i> subsp. <i>jejuni</i> 81116, CJ81176: <i>C. jejuni</i> subsp. <i>jejuni</i> 81-176, CJ8421: <i>C. jejuni</i> subsp. <i>jejuni</i> 84-21, CJ8425: <i>C. jejuni</i> subsp. <i>jejuni</i> 84-25, CJ8486: <i>C. jejuni</i> subsp. <i>jejuni</i> 84-26, CJ9313: <i>C. jejuni</i> subsp. <i>jejuni</i> 93-13, CJ936: <i>C. jejuni</i> subsp. <i>jejuni</i> 93-6, CJD: <i>C. jejuni</i> subsp. doylei, CJIA3902: <i>C. jejuni</i> subsp. <i>jejuni</i> IA3902, CJRM1221: <i>C. jejuni</i> subsp. <i>jejuni</i> 1221, H22082: <i>C. jejuni</i> subsp. <i>jejuni</i> ST 474 AEIO00000000.1 (H: from human clinical case), H704: <i>C. jejuni</i> subsp. <i>jejuni</i> ST 474 (H: from human clinical case), P110b: <i>C. jejuni</i> subsp. <i>jejuni</i> ST 474 000242395.2 (P: from poultry), P179a : <i>C. jejuni</i> subsp. <i>jejuni</i> ST 474 (P: from poultry), P569a: <i>C. jejuni</i> subsp. <i>jejuni</i> ST 474 (P: from poultry), P694a: <i>C. jejuni</i> subsp. <i>jejuni</i> ST 474 (P: from poultry), H73020: <i>C. jejuni</i> subsp. <i>jejuni</i> ST 474 (H: from human clinical case).</p
