Your search keyword '"Minchin C"' showing total 6 results

1. Detection of Eimeria acervulina using the Polymerase Chain Reaction

Author

Molloy, J. B., Eaves, F. W., Jeston, P. J., Minchin, C. M., Stewart, N. P., Lew, A. E., and Jorgensen, W. K.

Published

1998

2. Suppressive subtractive hybridization analysis of Rhipicephalus (Boophilus) microplus larval and adult transcript expression during attachment and feeding

Author

Lew-Tabor, A., Moolhuijzen, Paula, Vance, M., Kurscheid, S., Valle, M., Jarrett, S., Minchin, C., Jackson, L., Jonsson, N., Bellgard, M., Guerrero, F., Lew-Tabor, A., Moolhuijzen, Paula, Vance, M., Kurscheid, S., Valle, M., Jarrett, S., Minchin, C., Jackson, L., Jonsson, N., Bellgard, M., and Guerrero, F.

Abstract

Ticks, as blood-feeding ectoparasites, affect their hosts both directly and as vectors of viral, bacterial and protozoal diseases. The tick's mode of feeding means it must maintain intimate contact with the host in the face of host defensive responses for a prolonged time. The parasite-host interactions are characterized by the host response and parasite counter-response which result in a highly complex biological system that is barely understood. We conducted transcriptomic analyses utilizing suppressive subtractive hybridization (SSH) to identify transcripts associated with host attachment and feeding of larval, adult female and adult male ticks. Five SSH libraries resulted in 511 clones (assembled into 36 contigs and 90 singletons) from differentially expressed transcripts isolated from unattached frustrated larvae (95), feeding larvae (159), unattached frustrated adult female ticks (68), feeding adult female ticks (95) and male adult ticks (94 clones). Unattached 'frustrated' ticks were held in fabric bags affixed to cattle for up to 24 h to identify genes up-regulated prior to host penetration. Sequence analysis was based on BLAST, Panther, KOG and domain (CDD) analyses to assign functional groups for proteins including: cuticle proteins, enzymes (ATPases), ligand binding (histamine binding), molecular chaperone (prefoldin), nucleic acid binding (ribosomal proteins), putative salivary proteins, serine proteases, stress response (heat shock, glycine rich) and transporters. An additional 63% of all contigs and singletons were novel R. microplus transcripts or predicted proteins of unknown function. Expression was confirmed using quantitative real time PCR analysis of selected transcripts. This is the first comprehensive analysis of the R. microplus transcriptome from multiple stages of ticks and assists to elucidate the molecular events during tick attachment and development. Crown Copyright © 2009.

Published

2010

3. Putative RNA interference pathway in ticks

Author

Kurscheid, S., Rodriguez-Valle, M., Zhang, B., Bruyeres, A., Minchin, C., Barrero, R., Guerrero, F., Bellgard, M., Lew, A., Kurscheid, S., Rodriguez-Valle, M., Zhang, B., Bruyeres, A., Minchin, C., Barrero, R., Guerrero, F., Bellgard, M., and Lew, A.

Abstract

See Attached

Published

2008

4. Transcriptome analysis of Rhipicephalus (Boophilus) microplus

Author

Rodriguez-Valle, M., Lew-Tabor, A., Gondro, C., Kurscheid, S., Jarrett, S., Minchin, C., Moolhuijzen, P., Bellgard, M., Guerrero, F., Rodriguez-Valle, M., Lew-Tabor, A., Gondro, C., Kurscheid, S., Jarrett, S., Minchin, C., Moolhuijzen, P., Bellgard, M., and Guerrero, F.

Abstract

Ticks, as blood-feeding ectoparasites, affect their hosts both directly and as vectors of viral, bacterial and protozoal diseases. The tick’s mode of feeding means it must maintain intimate contact with the host in the face of host defensive responses for a prolonged time. The parasite:host interactions are characterized by the host response and parasite counter-response which result in a highly complex biological system that is barely understood. We conducted trancriptomic analyses utilizing both suppressive subtractive hybridization (SSH) and the Nimblegen R. microplus tick array to identify transcripts associated with host attachment and feeding on both naturally susceptible and immune breeds of cattle (Holstein-Friesian and Brahman). Five SSH libraries were established from differentially expressed transcripts isolated from unattached frustrated larvae, feeding larvae, unattached frustrated female ticks, feeding female ticks and male ticks (590 clones). Unattached frustrated ticks are those held in fabric bags affixed to cattle for up to 24 hours – thus ‘frustrated’. Approximately half of the clones were unique R. microplus transcripts or predicted proteins of unknown function. Feeding stages demonstrated an abundance of transcripts associated with ribosomal protein production and increased metabolic function. Host modifying proteases were differentially expressed by frustrated larvae and frustrated female ticks as well as males. Microarray expression analysis was conducted on unfed/unattached larvae, frustrated larvae and adult females from both Brahman and Holstein-Friesian cattle. Preliminary microarray results show that 226 genes are up and 9 down regulated by ticks on Brahman in comparison to ticks on Holstein (based on ≥3 standard deviation). Of the up-regulated transcripts, approximately 100 were unique and a further 50 similar to hypothetical proteins of unknown function. Transcripts with <1e-5 significance included putative retroviral proteins, kinases

Published

2008

5. Whole-genome comparison using complete genomes from Campylobacter fetus strains revealed single nucleotide polymorphisms on non-genomic islands for subspecies differentiation.

Author

Ong CT, Blackall PJ, Boe-Hansen GB, deWet S, Hayes BJ, Indjein L, Korolik V, Minchin C, Nguyen LT, Nordin Y, Siddle H, Turni C, Venus B, Westman ME, Zhang Z, and Tabor AE

Abstract

Introduction: Bovine Genital Campylobacteriosis (BGC), caused by Campylobacter fetus subsp. venerealis, is a sexually transmitted bacterium that significantly impacts cattle reproductive performance. However, current detection methods lack consistency and reliability due to the close genetic similarity between C. fetus subsp. venerealis and C. fetus subsp. fetus. Therefore, this study aimed to utilize complete genome analysis to distinguish genetic features between C. fetus subsp. venerealis and other subspecies, thereby enhancing BGC detection for routine screening and epidemiological studies., Methods and Results: This study reported the complete genomes of four C. fetus subsp. fetus and five C. fetus subsp. venerealis, sequenced using long-read sequencing technologies. Comparative whole-genome analyses ( n = 25) were conducted, incorporating an additional 16 complete C. fetus genomes from the NCBI database, to investigate the genomic differences between these two closely related C. fetus subspecies. Pan-genomic analyses revealed a core genome consisting of 1,561 genes and an accessory pangenome of 1,064 genes between the two C. fetus subspecies. However, no unique predicted genes were identified in either subspecies. Nonetheless, whole-genome single nucleotide polymorphisms (SNPs) analysis identified 289 SNPs unique to one or the C. fetus subspecies. After the removal of SNPs located on putative genomic islands, recombination sites, and those causing synonymous amino acid changes, the remaining 184 SNPs were functionally annotated. Candidate SNPs that were annotated with the KEGG "Peptidoglycan Biosynthesis" pathway were recruited for further analysis due to their potential association with the glycine intolerance characteristic of C. fetus subsp. venerealis and its biovar variant. Verification with 58 annotated C. fetus genomes, both complete and incomplete, from RefSeq, successfully classified these seven SNPs into two groups, aligning with their phenotypic identification as CFF ( Campylobacter fetus subsp. fetus) or CFV/CFVi ( Campylobacter fetus subsp. venerealis and its biovar variant). Furthermore, we demonstrated the application of mraY SNPs for detecting C. fetus subspecies using a quantitative PCR assay., Discussion: Our results highlighted the high genetic stability of C. fetus subspecies. Nevertheless, Campylobacter fetus subsp. venerealis and its biovar variants encoded common SNPs in genes related to glycine intolerance, which differentiates them from C. fetus subsp. fetus. This discovery highlights the potential of employing a multiple-SNP assay for the precise differentiation of C. fetus subspecies., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Ong, Blackall, Boe-Hansen, deWet, Hayes, Indjein, Korolik, Minchin, Nguyen, Nordin, Siddle, Turni, Venus, Westman, Zhang and Tabor.)

Published

2024

6. Toward Understanding Phage:Host Interactions in the Rumen; Complete Genome Sequences of Lytic Phages Infecting Rumen Bacteria.

Author

Gilbert RA, Kelly WJ, Altermann E, Leahy SC, Minchin C, Ouwerkerk D, and Klieve AV

Abstract

The rumen is known to harbor dense populations of bacteriophages (phages) predicted to be capable of infecting a diverse range of rumen bacteria. While bacterial genome sequencing projects are revealing the presence of phages which can integrate their DNA into the genome of their host to form stable, lysogenic associations, little is known of the genetics of phages which utilize lytic replication. These phages infect and replicate within the host, culminating in host lysis, and the release of progeny phage particles. While lytic phages for rumen bacteria have been previously isolated, their genomes have remained largely uncharacterized. Here we report the first complete genome sequences of lytic phage isolates specifically infecting three genera of rumen bacteria: Bacteroides, Ruminococcus , and Streptococcus . All phages were classified within the viral order Caudovirales and include two phage morphotypes, representative of the Siphoviridae and Podoviridae families. The phage genomes displayed modular organization and conserved viral genes were identified which enabled further classification and determination of closest phage relatives. Co-examination of bacterial host genomes led to the identification of several genes responsible for modulating phage:host interactions, including CRISPR/ Cas elements and restriction-modification phage defense systems. These findings provide new genetic information and insights into how lytic phages may interact with bacteria of the rumen microbiome.

Published

2017