Expression of Mitochondrial Stress Protein (Cpn60) in in vitro Cultured Neonatal Porcine Islet Cells

Munif, Farina

January 2006

Xenotransplantation of neonatal porcine islets have been demonstrated to be a viable alternative to exogenous insulin therapy for diabetes mellitus. The use of liberase has gained much success in islet isolation but factors such as batch-to-batch variation and deterioration of a batch with storage time have hampered the quality and reproducibility of tissue dissociation. Islet culture aims to optimise islet survival and insulin release in response to glucose challenge. However, it is difficult to recover and preserve islets in vitro. Mitochondria play a key role in the secretion of insulin from pancreatic islet cells in response to glucose stimulation. Mitochondrial dysfunction results in the induction (at mRNA and protein levels) of a molecular stress protein/heat chock protein called Cpn60. Since mitochondrial impairment will have a significant effect on the ability of in vitro cultured islet cells to function properly (i.e. release insulin in response to glucose stimulation), the expression of Cpn60 was investigated as a function of exposing neonatal porcine islet cells to various growth conditions. The best choice of media to culture neonatal porcine islet cells was found to be not heated activated serum which showed the least levels of Cpn60 expression at mRNA levels suggesting that the cells had low levels of mitochondrial stress. Neonatal porcine islet cells would be best digested in cells digested with new liberase (QC 1050) while in 2% not heat inactivated porcine serum (NPS) as this gave the lowest levels of Cpn60 expression suggesting low levels of mitochondrial stress. Although expression of Cpn60 at mRNA levels seems to be modulated during the growth of the porcine islet cells in media supplemented with different serum, heat treatment of serum and liberase content, no firm conclusion can be made with regard to the effect of the different treatments on mitochondrial health status until the porcine Cpn60 protein can be unequivocally identified.

Mitochondria

Cpn60

Diabetes Mellitus

Development of macroarray technology to profile bacterial composition of intestinal communities

Goldfinch, Angela Dawn

17 September 2007

The gastrointestinal tract is colonized by an abundant and diverse community of microorganisms which has a profound impact on the health of the host. The profiling of these microbial communities with traditional culture-based methods identifies only a fraction of microbes present with limited specificity, high labour costs and limited sample throughput. To overcome these limitations, a molecular hybridization assay was developed and characterized using the target gene chaperonin 60 (cpn60). The interspecies discriminatory ability of the hybridization assay was determined by hybridizing cpn60 gene fragments from a known species to a series of cpn60 gene fragments derived from related species with distinct but similar cpn60 sequences. Species with less than 85% cpn60 sequence identity to the probe DNA were effectively distinguished using the hybridization approach. To characterize complex microbial communities, universal PCR primers were used to amplify a fragment of 549-567 nucleotides from cpn60 (the cpn60 universal target (UT)) using template DNA extracted from the ileal contents of pigs fed diets based on corn (C), barley (B), or wheat (W), or from plasmids containing the cpn60 UT selected from a clone library generated from these contents. The intensity of hybridization signals generated using labelled probes prepared from library clones designated B1 (Bacillales-related), S1 (Streptococcus-related), C1 (Clostridiales-related), and L10 (Lactobacillales-related) and targets prepared from ileal contents of C, W, or B-fed pigs correlated closely with the number of genomes of each bacterial group as determined by quantitative PCR. Universal PCR primers were also used to amplify genomic DNA extracted from jejeunal contents of pre- and post-weaning piglets. Labelled probe DNA was prepared from S1, L10, LV (Lactobacillus vaginalis-related) and EC (E.coli) library clones. The resulting signal intensities correlated with quantitative polymerase chain reaction (qPCR) data for L10 and LV, but minimal correlation was observed for the S1 and EC groups. A cpn60- based macroarray has potential as a tool for identification and semi-quantification of shifts in colonization abundance of bacteria in complex communities, providing a similar amount of data as techniques such as denaturation gradient gel electrophoresis or terminal restriction fragment length polymorphism analysis.

macroarray

intestinal communities

cpn60

microbial ecology

Development of macroarray technology to profile bacterial composition of intestinal communities

Goldfinch, Angela Dawn

17 September 2007

The gastrointestinal tract is colonized by an abundant and diverse community of microorganisms which has a profound impact on the health of the host. The profiling of these microbial communities with traditional culture-based methods identifies only a fraction of microbes present with limited specificity, high labour costs and limited sample throughput. To overcome these limitations, a molecular hybridization assay was developed and characterized using the target gene chaperonin 60 (cpn60). The interspecies discriminatory ability of the hybridization assay was determined by hybridizing cpn60 gene fragments from a known species to a series of cpn60 gene fragments derived from related species with distinct but similar cpn60 sequences. Species with less than 85% cpn60 sequence identity to the probe DNA were effectively distinguished using the hybridization approach. To characterize complex microbial communities, universal PCR primers were used to amplify a fragment of 549-567 nucleotides from cpn60 (the cpn60 universal target (UT)) using template DNA extracted from the ileal contents of pigs fed diets based on corn (C), barley (B), or wheat (W), or from plasmids containing the cpn60 UT selected from a clone library generated from these contents. The intensity of hybridization signals generated using labelled probes prepared from library clones designated B1 (Bacillales-related), S1 (Streptococcus-related), C1 (Clostridiales-related), and L10 (Lactobacillales-related) and targets prepared from ileal contents of C, W, or B-fed pigs correlated closely with the number of genomes of each bacterial group as determined by quantitative PCR. Universal PCR primers were also used to amplify genomic DNA extracted from jejeunal contents of pre- and post-weaning piglets. Labelled probe DNA was prepared from S1, L10, LV (Lactobacillus vaginalis-related) and EC (E.coli) library clones. The resulting signal intensities correlated with quantitative polymerase chain reaction (qPCR) data for L10 and LV, but minimal correlation was observed for the S1 and EC groups. A cpn60- based macroarray has potential as a tool for identification and semi-quantification of shifts in colonization abundance of bacteria in complex communities, providing a similar amount of data as techniques such as denaturation gradient gel electrophoresis or terminal restriction fragment length polymorphism analysis.

macroarray

intestinal communities

cpn60

microbial ecology

Characterization of genomic diversity in cpn60 defined Enterococcus ecotypes

2015 September 1900

The astounding complexity of microbial communities limits the ability to study the role of genomic diversity in shaping the community composition at the species level. With the advancement and increased affordability of high-throughput sequencing methods, it is increasingly recognized that genomic diversity at the sub-species level plays an important role in selection during microbial community succession. Recent studies using the cpn60 universal target (UT) have shown that it is a high-resolution tool that provides superior resolution in comparison to 16S rRNA based tools and can predict genome relatedness. However, studies to characterize the nature and degree of genome content differences predicted by cpn60 UT sequence relationships have not been conducted. In this work, we focused on the Enterococcus community obtained from feces of healthy pigs. Enterococci are both accessible with selective culture, and interesting since the genus includes members that are significant human pathogens and others that are used as probiotics. Previous work has shown that cpn60 UT sequences can resolve pig fecal Enterococcus faecalis and E. hirae into phylogenetically and phenotypically distinct ecotypes. The utility of cpn60 UT sequences for resolution of Enterococcus species was first established in the year 2000, and this demonstration included 17 Enterococcus species. We have expanded the analysis to include all currently recognized Enterococcus species and confirmed that cpn60 UT sequences provide higher resolution than 16S rRNA sequences for identification of Enterococcus species. In addition, we showed that cpn60 UT sequences could resolve sub-groups in E. faecium consistent with results obtained from comparison of whole genome sequences. GTG rep PCR based clusters for E. faecalis and E. hirae isolates were generally consistent with the cpn60 defined Enterococcus ecotypes observed in our previous study, suggesting that cpn60 UT sequences predict overall genomic relationships. Results from analysis of CRISPR sequences provided insights into the extensive networking and transfer of genetic material that takes place within the intestinal Enterococcus community. We conducted whole genome sequencing of representative isolates to characterize further the genomic diversity in cpn60 defined E. hirae ecotypes to determine the nature and degree of genome content differences predicted by cpn60 UT sequences. Differences in phosphotransferase systems, amino acid metabolism pathways for glutamine, proline and selenocystiene, potassium-transporting ATPases, copper homeostasis systems and putative prophage associated sequences, CRISPRs and antibiotic resistance genes were observed. Results from in vitro growth competition assays showed that isolates from E. hirae-1 and E. hirae-2 were able to out-compete isolates from the E. hirae-3 ecotype, consistent with the relatively low abundance of E. hirae-3 relative to E. hirae-1 and E. hirae-2 previously observed in the pig fecal microbiome, and with observed gene content differences between the ecotypes. Results presented in this thesis provide a genomic basis for the definition of ecotypes within E. hirae and confirm the utility of the cpn60 UT sequence for high resolution profiling of complex microbial communities.

Utility of redesigned cpn60 UT primers and novel fungal specific cpn60 primers for microbial profiling

2015 December 1900

The cpn60 gene is a DNA barcode for bacteria. Recently, the PCR primers that have been used extensively to amplify the cpn60 Universal Target (UT) region of bacteria were redesigned to improve their utility for fungal taxa. Additional novel primers were designed to amplify other regions of the cpn60 gene, specifically from fungal genomes. Design of the redesigned and novel primers was based on 61 nucleotide full-length cpn60 reference sequences available in 2012, including Ascomycota (51), Basidiomycota (5), Chytridiomycota (2), Glomeromycota (1), and Oomycota (2). The research described here investigated the utility of these primers for detecting and identifying fungal taxa and for profiling mixed communities of bacteria and fungi. The redesigned primers were used to discover cpn60 UT sequences for Ascomycota (1), Basidiomycota (2), and Chytridiomycota (1). The novel primers were used to discover new cpn60 sequence data for Ascomycota (3), Basidiomycota (1), and Zygomycota (1). To be adopted for use in studies of microbial communities that are predominantly bacterial, the redesigned cpn60 UT primers must perform at least as well as the original primers for bacterial profiling. Bacterial profiles, created using the original and redesigned primers and two DNA template samples created by pooling DNA extracts from vaginal swabs from individual women, were compared. These included comparisons of diversity indices, rarefaction curve analysis and Operational Taxonomic Unit abundances. Diversity indices and rarefaction curve analysis for bacterial profiles with original and redesigned primers were similar. OTU abundance estimates with the original and redesigned primers were compared at higher and lower taxonomic levels. The overall patterns produced were similar. For one template only, the phylum Bacteroidetes had a greater apparent abundance with the original primers than with the redesigned primers. The greater apparent abundance of Bacteroidetes taxa was balanced by a lesser apparent abundance of taxa that were not assigned to a phylum. These differences may reflect differences in the performance of the two primer sets. At lower taxonomic level, most OTU were represented with apparently equal abundances with redesigned and original primers in same template. Very few OTU were represented with different proportional abundances with redesigned and original primers. Different OTU having same reference cpn60 UT sequence as best hit were sometimes represented by different proportional abundance with same primer in same template that made the analysis difficult. On the whole, the redesigned cpn60 UT primers behaved at least as good as the original cpn60 UT primers. The overall results showed that the redesigned and novel primers used in this study had substantial utility for the identification of fungal samples and mixed microbial communities.

Resolution and characterization of subgroups of Gardnerella vaginalis and description of the vaginal microbiota of women with preterm premature rupture of membranes

2015 February 1900

The vaginal microbial community is critical to a woman’s health and the health of her family. Bacterial vaginosis (BV) is a polymicrobial syndrome characterized by a shift of the vaginal microbiota from a Lactobacillus dominated community to a dense biofilm containing a complex mixture of organisms. Although BV is an important risk factor for poor reproductive health outcomes, the etiology of BV is poorly understood. Gardnerella vaginalis is a hallmark species of BV. Phylogenetic analysis of cpn60 universal target sequences from metagenomic studies of the vaginal microbiome and from G. vaginalis isolates resolved four subgroups within the species. This subdivision, supported by whole genome similarity comparisons, demonstrated that these subgroups might represent different species. Among a group of African women, only G. vaginalis subgroup B was significantly more abundant in women with BV relative to women with Nugent scores not consistent with BV. To characterize the subgroups further, several phenotypic and molecular factors of G. vaginalis subgroups were assessed. Proteomic profiles of isolates within each subgroup formed unambiguous clusters. Sialidase gene sequences were detected in all subgroups, however enzymatic activity was detected only in subgroup B. Two isolates of subgroup B isolates (N153 and N101) were incapable of growth in 7% CO2. Given the well-known relationship between an anaerobic microbiota and BV, anaerobic isolates of G. vaginalis are potentially important players in the vaginal microbial community. To determine genome content differences that could account for the phenotypic difference, whole genome sequences of four G. vaginalis subgroup B isolates representing facultative and anaerobic phenotypes were determined. Comparison of genomes led to the identification of genes predicted to encode proteins involved in cell wall biogenesis and protection from oxidative damage that might account for the observed phenotypes. The cpn60 universal target based methodology that improved resolution of the vaginal microbiota including G. vaginalis was applied in a prospective study of the vaginal microbiome of women with preterm premature rupture of membranes (PPROM). The objectives were to characterize the vaginal microbiota of women following PPROM, and to determine if microbiome composition at the time of rupture predicts latency duration and perinatal outcomes. Only 13/70 samples collected from 36 women were dominated by Lactobacillus spp., the expected profile for healthy women, while Megasphaera type 1 and Prevotella spp. were detected in all samples. Microbiome profiles at the time of membrane rupture did not cluster by gestational age at PPROM, or latency duration. Microbial profiles were unstable over the latency period, with dramatic shifts in composition between weekly samples, and an overall decrease in Lactobacillus abundance. Mollicutes were detected by PCR in 81% (29/36) of women, and these women had significantly lower gestational age at delivery and correspondingly lower birth weight infants than Mollicutes negative women. Taken together, the results presented in this thesis demonstrate the value of high resolution profiling of the vaginal microbiome using cpn60 UT sequences. The resolution of subgroups within G. vaginalis has potentially significant implications for women's health diagnostics, requiring a shift away from considering G. vaginalis as a single entity. The PPROM study provides foundational information that may lead to the identification of informative sequence patterns, providing clinicians with better tools for expectant management following PPROM.

BV

bacterial vaginosis

PPROM

preterm premature rupture of membranes

Gardnerella vaginalis

vaginal microbiome

cpn60

pyrosequencing

genome sequencing