Your search keyword '"Chris Ormandy"' showing total 3 results

1. Epigenome erosion and SOX10 drive neural crest phenotypic mimicry in triple-negative breast cancer

Author

Jodi M. Saunus, Xavier M. De Luca, Korinne Northwood, Ashwini Raghavendra, Alexander Hasson, Amy E. McCart Reed, Malcolm Lim, Samir Lal, A. Cristina Vargas, Jamie R. Kutasovic, Andrew J. Dalley, Mariska Miranda, Emarene Kalaw, Priyakshi Kalita-de Croft, Irma Gresshoff, Fares Al-Ejeh, Julia M. W. Gee, Chris Ormandy, Kum Kum Khanna, Jonathan Beesley, Georgia Chenevix-Trench, Andrew R. Green, Emad A. Rakha, Ian O. Ellis, Dan V. Nicolau, Peter T. Simpson, and Sunil R. Lakhani

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Intratumoral heterogeneity is caused by genomic instability and phenotypic plasticity, but how these features co-evolve remains unclear. SOX10 is a neural crest stem cell (NCSC) specifier and candidate mediator of phenotypic plasticity in cancer. We investigated its relevance in breast cancer by immunophenotyping 21 normal breast and 1860 tumour samples. Nuclear SOX10 was detected in normal mammary luminal progenitor cells, the histogenic origin of most TNBCs. In tumours, nuclear SOX10 was almost exclusive to TNBC, and predicted poorer outcome amongst cross-sectional (p = 0.0015, hazard ratio 2.02, n = 224) and metaplastic (p = 0.04, n = 66) cases. To understand SOX10’s influence over the transcriptome during the transition from normal to malignant states, we performed a systems-level analysis of co-expression data, de-noising the networks with an eigen-decomposition method. This identified a core module in SOX10’s normal mammary epithelial network that becomes rewired to NCSC genes in TNBC. Crucially, this reprogramming was proportional to genome-wide promoter methylation loss, particularly at lineage-specifying CpG-island shores. We propose that the progressive, genome-wide methylation loss in TNBC simulates more primitive epigenome architecture, making cells vulnerable to SOX10-driven reprogramming. This study demonstrates potential utility for SOX10 as a prognostic biomarker in TNBC and provides new insights about developmental phenotypic mimicry—a major contributor to intratumoral heterogeneity.

Published

2022

2. TNFAIP3 Reduction-of-Function Drives Female Infertility and CNS Inflammation

Author

Nathan W. Zammit, Joseph McDowell, Joanna Warren, Walter Muskovic, Joanne Gamble, Yan-Chuan Shi, Dominik Kaczorowski, Chia-Ling Chan, Joseph Powell, Chris Ormandy, David Brown, Samantha R. Oakes, and Shane T. Grey

Subjects

TNFAIP3, A20, inflammation, reproduction, fertility, neuroinflammation, Immunologic diseases. Allergy, RC581-607

Abstract

Women with autoimmune and inflammatory aetiologies can exhibit reduced fecundity. TNFAIP3 is a master negative regulator of inflammation, and has been linked to many inflammatory conditions by genome wide associations studies, however its role in fertility remains unknown. Here we show that mice harbouring a mild Tnfaip3 reduction-of-function coding variant (Tnfaip3I325N) that reduces the threshold for inflammatory NF-κB activation, exhibit reduced fecundity. Sub-fertility in Tnfaip3I325N mice is associated with irregular estrous cycling, low numbers of ovarian secondary follicles, impaired mammary gland development and insulin resistance. These pathological features are associated with infertility in human subjects. Transplantation of Tnfaip3I325N ovaries, mammary glands or pancreatic islets into wild-type recipients rescued estrous cycling, mammary branching and hyperinsulinemia respectively, pointing towards a cell-extrinsic hormonal mechanism. Examination of hypothalamic brain sections revealed increased levels of microglial activation with reduced levels of luteinizing hormone. TNFAIP3 coding variants may offer one contributing mechanism for the cause of sub-fertility observed across otherwise healthy populations as well as for the wide variety of auto-inflammatory conditions to which TNFAIP3 is associated. Further, TNFAIP3 represents a molecular mechanism that links heightened immunity with neuronal inflammatory homeostasis. These data also highlight that tuning-up immunity with TNFAIP3 comes with the potentially evolutionary significant trade-off of reduced fertility.

Published

2022

3. Using Gene Expression Arrays to Elucidate Transcriptional Profiles Underlying Prolactin Function.

Author

Sandra Gass, Jessica Harris, Chris Ormandy, and Cathrin Brisken

Abstract

Prolactin is an ancient hormone, with different functions in many species. The binding of prolactin to its receptor, a member of the cytokine receptor superfamily, results in the activation of different intracellular signaling pathways, such as JAK2/STAT5, MAP kinase, and PI3K/AKT. How prolactin elicits so many different biological responses remains unclear. Recently, microarray technology has been applied to identify prolactin target genes in different systems. Here, we attempt to summarize and compare the available data. Our comparison of the genes reported to be transcriptionally regulated by prolactin indicates that there are few genes in common between the different tissues. Among the organs studied, mammary and prostate glands displayed the largest number of overlaps in putative prolactin target genes. Some of the candidates have been implicated in tumorigenesis. The relevance and validation of microarray data, as well as comparison of the results obtained by different groups, will be discussed. [ABSTRACT FROM AUTHOR]

Published

2003