Your search keyword '"Doig Kenneth D"' showing total 9 results

1. On the origin of Mycobacterium ulcerans, the causative agent of Buruli ulcer

Author

Doig Kenneth D, Holt Kathryn E, Fyfe Janet AM, Lavender Caroline J, Eddyani Miriam, Portaels Françoise, Yeboah-Manu Dorothy, Pluschke Gerd, Seemann Torsten, and Stinear Timothy P

Subjects

Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Mycobacterium ulcerans is an unusual bacterial pathogen with elusive origins. While closely related to the aquatic dwelling M. marinum, M. ulcerans has evolved the ability to produce the immunosuppressive polyketide toxin mycolactone and cause the neglected tropical disease Buruli ulcer. Other mycolactone-producing mycobacteria (MPM) have been identified in fish and frogs and given distinct species designations (M. pseudoshottsii, M. shinshuense, M. liflandii and M. marinum), however the evolution of M. ulcerans and its relationship to other MPM has not been defined. Here we report the comparative analysis of whole genome sequences from 30 MPM and five M. marinum. Results A high-resolution phylogeny based on genome-wide single nucleotide polymorphisms (SNPs) showed that M. ulcerans and all other MPM represent a single clonal group that evolved from a common M. marinum progenitor. The emergence of the MPM was driven by the acquisition of the pMUM plasmid encoding genes for the biosynthesis of mycolactones. This change was accompanied by the loss of at least 185 genes, with a significant overrepresentation of genes associated with cell wall functions. Cell wall associated genes also showed evidence of substantial adaptive selection, suggesting cell wall remodeling has been critical for the survival of MPM. Fine-grain analysis of the MPM complex revealed at least three distinct lineages, one of which comprised a highly clonal group, responsible for Buruli ulcer in Africa and Australia. This indicates relatively recent transfer of M. ulcerans between these continents, which represent the vast majority of the global Buruli ulcer burden. Our data provide SNPs and gene sequences that can differentiate M. ulcerans lineages, suitable for use in the diagnosis and surveillance of Buruli ulcer. Conclusions M. ulcerans and all mycolactone-producing mycobacteria are specialized variants of a common Mycobacterium marinum progenitor that have adapted to live in restricted environments. Examination of genes lost or retained and now under selective pressure suggests these environments might be aerobic, and extracellular, where slow growth, production of an immune suppressor, cell wall remodeling, loss or modification of cell wall antigens, and biofilm-forming ability provide a survival advantage. These insights will guide our efforts to find the elusive reservoir(s) of M. ulcerans and to understand transmission of Buruli ulcer.

Published

2012

2. Findings from precision oncology in the clinic: rare, novel variants are a significant contributor to scaling molecular diagnostics

Author

Doig, Kenneth D., Love, Christopher G., Conway, Thomas, Seleznev, Andrei, Ma, David, Fellowes, Andrew, Blombery, Piers, and Fox, Stephen B.

Published

2022

3. Tumour mutational burden: an overview for pathologists

Author

Doig, Kenneth D., Fellowes, Andrew, Scott, Prudence, and Fox, Stephen B.

Published

2022

4. Homologous Recombination Repair Deficiency: An Overview for Pathologists

Author

Doig, Kenneth D., primary, Fellowes, Andrew P., additional, and Fox, Stephen B., additional

Published

2023

5. Shariant platform: Enabling evidence sharing across Australian clinical genetic-testing laboratories to support variant interpretation

Author

Tudini, Emma, primary, Andrews, James, additional, Lawrence, David M., additional, King-Smith, Sarah L., additional, Baker, Naomi, additional, Baxter, Leanne, additional, Beilby, John, additional, Bennetts, Bruce, additional, Beshay, Victoria, additional, Black, Michael, additional, Boughtwood, Tiffany F., additional, Brion, Kristian, additional, Cheong, Pak Leng, additional, Christie, Michael, additional, Christodoulou, John, additional, Chong, Belinda, additional, Cox, Kathy, additional, Davis, Mark R., additional, Dejong, Lucas, additional, Dinger, Marcel E., additional, Doig, Kenneth D., additional, Douglas, Evelyn, additional, Dubowsky, Andrew, additional, Ellul, Melissa, additional, Fellowes, Andrew, additional, Fisk, Katrina, additional, Fortuno, Cristina, additional, Friend, Kathryn, additional, Gallagher, Renee L., additional, Gao, Song, additional, Hackett, Emma, additional, Hadler, Johanna, additional, Hipwell, Michael, additional, Ho, Gladys, additional, Hollway, Georgina, additional, Hooper, Amanda J., additional, Kassahn, Karin S., additional, Krishnaraj, Rahul, additional, Lau, Chiyan, additional, Le, Huong, additional, San Leong, Huei, additional, Lundie, Ben, additional, Lunke, Sebastian, additional, Marty, Anthony, additional, McPhillips, Mary, additional, Nguyen, Lan T., additional, Nones, Katia, additional, Palmer, Kristen, additional, Pearson, John V., additional, Quinn, Michael C.J., additional, Rawlings, Lesley H., additional, Sadedin, Simon, additional, Sanchez, Louisa, additional, Schreiber, Andreas W., additional, Sigalas, Emanouil, additional, Simsek, Aygul, additional, Soubrier, Julien, additional, Stark, Zornitza, additional, Thompson, Bryony A., additional, U, James, additional, Vakulin, Cassandra G., additional, Wells, Amanda V., additional, Wise, Cheryl A., additional, Woods, Rick, additional, Ziolkowski, Andrew, additional, Brion, Marie-Jo, additional, Scott, Hamish S., additional, Thorne, Natalie P., additional, Spurdle, Amanda B., additional, Akesson, Lauren, additional, Allcock, Richard, additional, Ashton, Katie, additional, Bell, Damon A., additional, Brown, Anna, additional, Buckley, Michael, additional, Burnett, John R., additional, Burrows, Linda, additional, Byrne, Alicia, additional, Chan, Eva, additional, Cliffe, Corrina, additional, Clifton-Bligh, Roderick, additional, Dooley, Susan, additional, Fernandez, Miriam Fanjul, additional, Farnsworth, Elizabeth, additional, Ha, Thuong, additional, Henry, Denae, additional, Holds, Duncan, additional, Holman, Katherine, additional, Jackson, Matilda, additional, Kang, Sinlay, additional, Luxford, Catherine, additional, McManus, Sam, additional, Mehrtens, Rachael, additional, Meldrum, Cliff, additional, Mossman, David, additional, Pantaleo, Sarah-Jane, additional, Phelan, Dean, additional, Pontikinas, Electra, additional, Ravine, Anja, additional, Roscioli, Tony, additional, Scott, Rodney, additional, Simons, Keryn, additional, and Vanwageningen, Oliver, additional

Published

2022

6. Additional file 2 of Findings from precision oncology in the clinic: rare, novel variants are a significant contributor to scaling molecular diagnostics

Author

Doig, Kenneth D., Love, Christopher G., Conway, Thomas, Seleznev, Andrei, Ma, David, Fellowes, Andrew, Blombery, Piers, and Fox, Stephen B.

Abstract

Additional file 2. Table S2: 24 variants with discordant pathogenicity classifications between CTAP and PathOS. Table S3: Correlation analysis of variant recurrence at the gene level between PathOS and publicly available datasets from ICGC and COSMIC, using Pearson’s Correlation Coefficient and log2 scale. Figure S1: Breakdown of numbers of genes in common across each analysis group and assay. (a) all genes surveyed in amplicon assays, (b) all genes surveyed in hyb-capture assays, (c) genes containing clinically reported variants only across all assays. (d-f) Displays the genes in common between assays (amplicon and hyb-capture) by analysis type. (g-i) Displays the genes containing reported variants in common between assays by analysis types. Figure S2: A gene level comparison of consequence between PathOS and VICC. The first column shows the top 20 genes in PathOS. The top row shows the genes coloured by ONC/TSG classification and the black diamond shows the number of distinct variants seen for each gene. The oncogenes have few distinct variants while TSGs and ONC/TSGs have many variants occurring in the gene. This highlights the focal nature of oncogene mutations. The third column shows varinats seen in PathOS after removing corresponding VICC variants showing that common oncogenes appear in VICC but far fewer TSGs and ONC/TSGs. Figure S3: These graphs show compare the top 20 variant loci between PathOS and VICC. The third graph shows the top 20 variant loci in PathOS after removing matching VICC variants. The predominance of TSG genes becomes apparent. Figure S4: Breakdown of novel variants not matching public cancer variant annotation resources by analysis type (n = 2,356). Each variant is classified by functional consequence and coloured by pathogenicity level. Note the high number of somatic, missense, VUS variants. Figure S5: Breakdown of PathOS only variants not matching public cancer variant annotation resources by analysis type (somatic, haematological and germline) (n = 2,356). Each variant is classified by functional consequence and coloured by pathogenicity level and separated based on classification of oncogene or TSG. Figure S6: Barplot of somatic solid variants curated by clinical contexts with > 100 variants. CUP=cancer of unknown primary, NSCLC=non-small cell lung cancer, MEL=melanoma, OVCA=ovarian cancer, PCA=prostate cancer, CRC=colorectal cancer, TCC= urothelial carcinoma, SARC=sarcoma. Figure S7: Comparison of patient counts by gene of reported variants between in-house database (PathOS), COSMIC and ICGC for the patient clinical contexts of melanoma, colorectal and haematological malignancies. Figure S8: Variant interpretation resources are not all considered equal from a somatic variant curation perspective. Resources with higher curation offer more value than observational or computationally derived resources. Figure S9: Patient samples analysed per month. A large increase in germline analysis can be observed when hyb-capture assays were implemented in 2017. There is also a steady increase over time in somatic molecular haematology (Mol_haem) samples across both assays. The number of somatic solid samples has remained relatively consistent since 2014 but an increasing number of samples were analysed with hyb-capture assays since 2017. Plotted values are calculated using a three-month rolling average.

Published

2022

7. Canary: an atomic pipeline for clinical amplicon assays

Author

Doig, Kenneth D., primary, Ellul, Jason, additional, Fellowes, Andrew, additional, Thompson, Ella R., additional, Ryland, Georgina, additional, Blombery, Piers, additional, Papenfuss, Anthony T., additional, and Fox, Stephen B., additional

Published

2017

8. PathOS: a decision support system for reporting high throughput sequencing of cancers in clinical diagnostic laboratories

Author

Doig, Kenneth D., primary, Fellowes, Andrew, additional, Bell, Anthony H., additional, Seleznev, Andrei, additional, Ma, David, additional, Ellul, Jason, additional, Li, Jason, additional, Doyle, Maria A., additional, Thompson, Ella R., additional, Kumar, Amit, additional, Lara, Luis, additional, Vedururu, Ravikiran, additional, Reid, Gareth, additional, Conway, Thomas, additional, Papenfuss, Anthony T., additional, and Fox, Stephen B., additional

Published

2017

9. Complete Genome Sequence of the Frog Pathogen Mycobacterium ulcerans Ecovar Liflandii.

Author

Tobias, Nicholas J., Doig, Kenneth D., Medema, Marnix H., Honglei Chen, Haring, Volker, Moore, Robert, Seemann, Torsten, and Stinear, Timothy P.

Subjects

*MYCOBACTERIUM, *XENOPUS, *MYCOBACTERIOSIS, *TYROSINE, *TRYPTOPHAN

Abstract

In 2004, a previously undiscovered mycobacterium resembling Mycobacterium ulcerans (the agent of Buruli ulcer) was reported in an outbreak of a lethal mycobacteriosis in a laboratory colony of the African clawed frog Xenopus tropicalis. This mycobacterium makes mycolactone and is one of several strains of M. ulcerans-like mycolactone-producing mycobacteria recovered from ectotherms around the world. Here, we describe the complete 6,399,543-bp genome of this frog pathogen (previously unofficially named "Mycobacterium liflandii"), and we show that it has undergone an intermediate degree of reductive evolution between the M. ulcerans Agy99 strain and the fish pathogen Mycobacterium marinum M strain. Like M. ulcerans Agy99, it has the pMUM mycolactone plasmid, over 200 chromosomal copies of the insertion sequence IS2404, and a high proportion of pseudogenes. However, M. liflandii has a larger genome that is closer in length, sequence, and architecture to M. marinum M than to M ulcerans Agy99, suggesting that the M. ulcerans Agy99 strain has undergone accelerated evolution. Scrutiny of the genes specifically lost suggests that M. liflandii is a tryptophan, tyrosine, and phenylalanine auxotroph. A once-extensive M. marinum-like secondary metabolome has also been diminished through reductive evolution. Our analysis shows that M. liflandii, like M. ulcerans Agy99, has the characteristics of a niche-adapted mycobacterium but also has several distinctive features in important metabolic pathways that suggest that it is responding to different environmental pressures, supporting earlier proposals that it could be considered an M. ulcerans ecotype, hence the name M. ulcerans ecovar Liflandii. [ABSTRACT FROM AUTHOR]

Published

2013