Loss of Brca1 Induces Senescence of Murine Ovarian Fibroblasts and May Contribute to Fibroblast-Mediated Ovarian Aging

Vaishnav, Het

18 August 2023

Ovarian cancer, primarily diagnosed at advanced stages of the disease, is the most lethal of all gynaecological malignancies, with a 5-year survival of only 45%. Increasing age and number of ovulations are the primary non-hereditary risk factors, with the median age of onset being 63 years. Considering that risk peaks upon onset of menopause and that 50% of all cases of ovarian cancer have non-ovarian origins, it is believed that the physiological aging of the ovary renders it an appealing pre-metastatic niche. Mutations in the tumor suppressor genes BRCA1 and BRCA2 are the primary hereditary risk factors, accounting for 20-25% of all cases. We have preliminary data showing that BRCA1 mutation carriers tend to develop ovarian fibrosis, a phenomenon that naturally accompanies ovarian aging, at premenopausal ages, whereas age-associated fibrosis becomes evident after menopause in non-carriers. Consistently, BRCA1/2 mutation carriers are at elevated risk for premature cessation of ovarian function. With the median age of cancer onset decreasing from 63 to 50 years of age in BRCA1 mutation carriers, these data collectively suggest accelerated ovarian aging in these women and highlights an association between ovarian aging and increased risk for cancer. As such, we hypothesized that loss of Brca1 in murine ovarian fibroblasts (MOFs) may accelerate the onset of ovarian fibrosis through fibroblast hyperactivation, contributing to ovarian aging. Using primary MOFs isolated from Brca1 LoxP/LoxP mice and adenoviral cre mediated recombination, we generated Brca1 deficient MOFs. RNA sequencing was used to characterize the transcriptomic changes associated with the loss of Brca1. Our findings suggest that Brca1 deficiency in MOFs induces cellular senescence and enhances their myofibroblastic function, likely yielding increased stiffness of the ovarian extracellular matrix due to the dysregulated synthesis and degradation of its constitutive components, contributing to accelerated ovarian aging.

Ovarian cancer

Mutation carriers

The Identification of BRCA1 and BRCA2 Mutation Carriers Using Functional Genomic Assays

Michel, CLAIRE S.

14 April 2009

An estimated 5-10% of breast cancers are hereditary in nature and are due to the presence of a mutation in a breast cancer predisposition gene; approximately half of these cases possess a mutation in BRCA1 or BRCA2. Many BRCA1/BRCA2 mutations result in a truncated protein and hence are unequivocally disease-causing. However another class of mutations, the Variants of Unknown Significance (VUS), are more problematic as the effect of these mutations on protein function is unclear. The inability to classify these mutations as disease causing generates significant problems in risk evaluation, counseling and preventive care. Accordingly we sought to determine whether carriers of either a BRCA1 or BRCA2 mutation could be identified from non-carriers based on the gene expression patterns of non-cancerous cells. EBV-transformed lymphoblastoid cell lines established from BRCA1/BRCA2 mutation carriers and normal individuals were obtained through the NIH Breast Cancer Family Registries. Cell lines were mock-irradiated or treated with ionizing radiation (2 Gy). Following a recovery period of 6 hours total RNA was extracted and whole genome gene expression profiling was carried out. Molecular classifiers comparing the baseline expression profiles and the radiation-dependent expression profiles of BRCA1/BRCA2 mutation carriers to control individuals were created using a Support Vector Machine (SVM) coupled with a recursive feature removal (RFR) algorithm. Our results suggest that cell populations derived from BRCA1/BRCA2 mutation carriers display unique expression phenotypes from those of control individuals in both the basal and radiation-induced cases. In the task of classification using baseline expression, the BRCA1-classifier correctly classified 15/18 test samples using feature selection based on the training set only, while feature selection using the entire dataset (AD) improved classification to 16/18 samples. The BRCA2-baseline classifier correctly classified 13/17 and 14/17 (AD) samples, respectively. In the task of radiation-dependent classification, the BRCA1-IR classifier correctly classified 12/18 and 16/18 (AD) test samples respectively while the BRCA2-IR classifier correctly classified 13/17 and 16/17 (AD) test samples respectively. These results suggest the possibility of development of this assay into a novel hereditary breast cancer screening diagnostic able to accurately identify the presence of BRCA1 or BRCA2 mutations via a functional assay thereby improving patient outcomes. / Thesis (Master, Pathology & Molecular Medicine) -- Queen's University, 2008-03-27 15:38:19.269 / Canadian Breast Cancer Foundation-Ontario Chapter, Department of Pathology & Molecular Medicine Clinical Trust Fund

BRCA1

BRCA2

Hereditary Breast Cancer

Microarrays

Cancer Screening

Mutation Carriers