Your search keyword '"Lau, LMS"' showing total 2 results

1. qmotif: determination of telomere content from whole-genome sequence data

Author

Stamatakis, A, Holmes, O, Nones, K, Tang, YH, Loffler, KA, Lee, M, Patch, A-M, Dagg, RA, Lau, LMS, Leonard, C, Wood, S, Xu, Q, Pickett, HA, Reddel, RR, Barbour, AP, Grimmond, SM, Waddell, N, Pearson, J, Stamatakis, A, Holmes, O, Nones, K, Tang, YH, Loffler, KA, Lee, M, Patch, A-M, Dagg, RA, Lau, LMS, Leonard, C, Wood, S, Xu, Q, Pickett, HA, Reddel, RR, Barbour, AP, Grimmond, SM, Waddell, N, and Pearson, J

Abstract

MOTIVATION: Changes in telomere length have been observed in cancer and can be indicative of mechanisms involved in carcinogenesis. Most methods used to estimate telomere length require laboratory analysis of DNA samples. Here, we present qmotif, a fast and easy tool that determines telomeric repeat sequences content as an estimate of telomere length directly from whole-genome sequencing. RESULTS: qmotif shows similar results to quantitative PCR, the standard method for high-throughput clinical telomere length quantification. qmotif output correlates strongly with the output of other tools for determining telomere sequence content, TelSeq and TelomereHunter, but can run in a fraction of the time-usually under a minute. AVAILABILITY AND IMPLEMENTATION: qmotif is implemented in Java and source code is available at https://github.com/AdamaJava/adamajava, with instructions on how to build and use the application available from https://adamajava.readthedocs.io/en/latest/. SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics Advances online.

Published

2022

2. Telomere sequence content can be used to determine ALT activity in tumours

Author

Lee, M, Teber, ET, Holmes, O, Nones, K, Patch, A-M, Dagg, RA, Lau, LMS, Lee, JH, Napier, CE, Arthur, JW, Grimmond, SM, Hayward, NK, Johansson, PA, Mann, GJ, Scolyer, RA, Wilmott, JS, Reddel, RR, Pearson, JV, Waddell, N, Pickett, HA, Lee, M, Teber, ET, Holmes, O, Nones, K, Patch, A-M, Dagg, RA, Lau, LMS, Lee, JH, Napier, CE, Arthur, JW, Grimmond, SM, Hayward, NK, Johansson, PA, Mann, GJ, Scolyer, RA, Wilmott, JS, Reddel, RR, Pearson, JV, Waddell, N, and Pickett, HA

Abstract

The replicative immortality of human cancer cells is achieved by activation of a telomere maintenance mechanism (TMM). To achieve this, cancer cells utilise either the enzyme telomerase, or the Alternative Lengthening of Telomeres (ALT) pathway. These distinct molecular pathways are incompletely understood with respect to activation and propagation, as well as their associations with clinical outcomes. We have identified significant differences in the telomere repeat composition of tumours that use ALT compared to tumours that do not. We then employed a machine learning approach to stratify tumours according to telomere repeat content with an accuracy of 91.6%. Importantly, this classification approach is applicable across all tumour types. Analysis of pathway mutations that were under-represented in ALT tumours, across 1,075 tumour samples, revealed that the autophagy, cell cycle control of chromosomal replication, and transcriptional regulatory network in embryonic stem cells pathways are involved in the survival of ALT tumours. Overall, our approach demonstrates that telomere sequence content can be used to stratify ALT activity in cancers, and begin to define the molecular pathways involved in ALT activation.

Published

2018