Your search keyword '"Hammet F"' showing total 106 results

1. Expanded genetic analysis of a PALB2 c.3113G>A mutation carrying multiple-case breast cancer family via exome sequencing

Author

Teo ZL, Park DJ, Odefrey F, Hammet F, Nguyen-Dumont T, Tsimiklis H, Pope BJ, Lonie A, Winship I, Giles GG, Hopper JL, and Southey MC

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Genetics, QH426-470

Published

2012

2. Early exploration of two candidate breast cancer susceptibility genes identified by whole-exome sequencing

Author

Blanc R, Jammot A, Nguyen-Dumont T, Teo ZL, Odefrey FA, Hammet F, Goldgar DE, Park DJ, and Southey MC

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Genetics, QH426-470

Published

2012

3. Identification of new breast cancer predisposition genes via whole exome sequencing

Author

Southey MC, Park DJ, Lesueur F, Odefrey F, Nguyen-Dumont T, Hammet F, Neuhausen SL, John EM, Andrulis IL, Chenevix-Trench G, Baglietto L, Le Calvez-Kelm F, Pertesi M, Lonie A, Pope B, Sinilnikova O, Tsimiklis H, Giles GG, Hopper JL, Tavtigian SV, and Goldgar DE

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Genetics, QH426-470

Published

2012

4. Population-based estimates of breast cancer risk for carriers of pathogenic variants identified by gene-panel testing.

Author

Southey M.C., Dowty J.G., Riaz M., Steen J.A., Renault A.-L., Tucker K., Kirk J., James P., Winship I., Pachter N., Poplawski N., Grist S., Park D.J., Pope B.J., Mahmood K., Hammet F., Mahmoodi M., Tsimiklis H., Theys D., Rewse A., Willis A., Morrow A., Speechly C., Harris R., Sebra R., Schadt E., Lacaze P., McNeil J.J., Giles G.G., Milne R.L., Hopper J.L., Nguyen-Dumont T., Southey M.C., Dowty J.G., Riaz M., Steen J.A., Renault A.-L., Tucker K., Kirk J., James P., Winship I., Pachter N., Poplawski N., Grist S., Park D.J., Pope B.J., Mahmood K., Hammet F., Mahmoodi M., Tsimiklis H., Theys D., Rewse A., Willis A., Morrow A., Speechly C., Harris R., Sebra R., Schadt E., Lacaze P., McNeil J.J., Giles G.G., Milne R.L., Hopper J.L., and Nguyen-Dumont T.

Abstract

Population-based estimates of breast cancer risk for carriers of pathogenic variants identified by gene-panel testing are urgently required. Most prior research has been based on women selected for high-risk features and more data is needed to make inference about breast cancer risk for women unselected for family history, an important consideration of population screening. We tested 1464 women diagnosed with breast cancer and 862 age-matched controls participating in the Australian Breast Cancer Family Study (ABCFS), and 6549 healthy, older Australian women enroled in the ASPirin in Reducing Events in the Elderly (ASPREE) study for rare germline variants using a 24-gene-panel. Odds ratios (ORs) were estimated using unconditional logistic regression adjusted for age and other potential confounders. We identified pathogenic variants in 11.1% of the ABCFS cases, 3.7% of the ABCFS controls and 2.2% of the ASPREE (control) participants. The estimated breast cancer OR [95% confidence interval] was 5.3 [2.1-16.2] for BRCA1, 4.0 [1.9-9.1] for BRCA2, 3.4 [1.4-8.4] for ATM and 4.3 [1.0-17.0] for PALB2. Our findings provide a population-based perspective to gene-panel testing for breast cancer predisposition and opportunities to improve predictors for identifying women who carry pathogenic variants in breast cancer predisposition genes.Copyright © 2021, The Author(s).

Published

2022

5. Repeatability of methylation measures using a QIAseq targeted methyl panel and comparison with the Illumina HumanMethylation450 assay.

Author

Yu C., Dugue P.-A., Dowty J.G., Hammet F., Joo J.E., Wong E.M., Hosseinpour M., Giles G.G., Hopper J.L., Nguyen-Dumont T., MacInnis R.J., Southey M.C., Yu C., Dugue P.-A., Dowty J.G., Hammet F., Joo J.E., Wong E.M., Hosseinpour M., Giles G.G., Hopper J.L., Nguyen-Dumont T., MacInnis R.J., and Southey M.C.

Abstract

OBJECTIVE: In previous studies using Illumina Infinium methylation arrays, we have identified DNA methylation marks associated with cancer predisposition and progression. In the present study, we have sought to find appropriate technology to both technically validate our data and expand our understanding of DNA methylation in these genomic regions. Here, we aimed to assess the repeatability of methylation measures made using QIAseq targeted methyl panel and to compare them with those obtained from the Illumina HumanMethylation450 (HM450K) assay. We included in the analysis high molecular weight DNA extracted from whole blood (WB) and DNA extracted from formalin-fixed paraffin-embedded tissues (FFPE). RESULT(S): The repeatability of QIAseq-methylation measures was assessed at 40 CpGs, using the Intraclass Correlation Coefficient (ICC). The mean ICCs and 95% confidence intervals (CI) were 0.72 (0.62-0.81), 0.59 (0.47-0.71) and 0.80 (0.73-0.88) for WB, FFPE and both sample types combined, respectively. For technical replicates measured using QIAseq and HM450K, the mean ICCs (95% CI) were 0.53 (0.39-0.68), 0.43 (0.31-0.56) and 0.70 (0.59-0.80), respectively. Bland-Altman plots indicated good agreement between QIAseq and HM450K measurements. These results demonstrate that the QIAseq targeted methyl panel produces reliable and reproducible methylation measurements across the 40 CpGs that were examined.Copyright © 2021. The Author(s).

Published

2021

6. Population-based estimates of the age-specific cumulative risk of breast cancer for pathogenic variants in CHEK2: Findings from the australian breast cancer family registry.

Author

Southey M.C., Tsimiklis H., Winship I.M., Giles G.G., Milne R.L., Hopper J.L., Nguyen-dumont T.U., Dowty J.G., Steen J.A., Renault A.-L., Hammet F., Mahmoodi M., Theys D., Rewse A., Southey M.C., Tsimiklis H., Winship I.M., Giles G.G., Milne R.L., Hopper J.L., Nguyen-dumont T.U., Dowty J.G., Steen J.A., Renault A.-L., Hammet F., Mahmoodi M., Theys D., and Rewse A.

Abstract

Case-control studies of breast cancer have consistently shown that pathogenic variants in CHEK2 are associated with about a 3-fold increased risk of breast cancer. Information about the recurrent protein-truncating variant CHEK2 c.1100delC dominates this estimate. There have been no formal estimates of age-specific cumulative risk of breast cancer for all CHEK2 pathogenic (in-cluding likely pathogenic) variants combined. We conducted a population-based case-control-fam-ily study of pathogenic CHEK2 variants (26 families, 1071 relatives) and estimated the age-specific cumulative risk of breast cancer using segregation analysis. The estimated hazard ratio for carriers of pathogenic CHEK2 variants (combined) was 4.9 (95% CI 2.5-9.5) relative to non-carriers. The HR for carriers of the CHEK2 c.1100delC variant was estimated to be 3.5 (95% CI 1.02-11.6) and the HR for carriers of all other CHEK2 variants combined was estimated to be 5.7 (95% CI 2.5-12.9). The age-specific cumulative risk of breast cancer was estimated to be 18% (95% CI 11-30%) and 33% (95% CI 21-48%) to age 60 and 80 years, respectively. These findings provide important information for the clinical management of breast cancer risk for women carrying pathogenic variants in CHEK2.Copyright © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

Published

2021

7. Rare germline pathogenic variants identified by multigene panel testing and the risk of aggressive prostate cancer.

Author

Milne R.L., Giles G.G., Nguyen-Dumont T., Dowty J.G., Macinnis R.J., Steen J.A., Riaz M., Dugue P.-A., Renault A.-L., Hammet F., Mahmoodi M., Theys D., Tsimiklis H., Severi G., Bolton D., Lacaze P., Sebra R., Schadt E., McNeil J., Southey M.C., Milne R.L., Giles G.G., Nguyen-Dumont T., Dowty J.G., Macinnis R.J., Steen J.A., Riaz M., Dugue P.-A., Renault A.-L., Hammet F., Mahmoodi M., Theys D., Tsimiklis H., Severi G., Bolton D., Lacaze P., Sebra R., Schadt E., McNeil J., and Southey M.C.

Abstract

While gene panel sequencing is becoming widely used for cancer risk prediction, its clinical utility with respect to predicting aggressive prostate cancer (PrCa) is limited by our current understanding of the genetic risk factors associated with predisposition to this potentially lethal disease phenotype. This study included 837 men diagnosed with aggressive PrCa and 7261 controls (unaffected men and men who did not meet criteria for aggressive PrCa). Rare germline pathogenic variants (including likely pathogenic variants) were identified by targeted sequencing of 26 known or putative cancer predisposition genes. We found that 85 (10%) men with aggressive PrCa and 265 (4%) controls carried a pathogenic variant (p < 0.0001). Aggressive PrCa odds ratios (ORs) were estimated using unconditional logistic regression. Increased risk of aggressive PrCa (OR (95% confidence interval)) was identified for pathogenic variants in BRCA2 (5.8 (2.7-12.4)), BRCA1 (5.5 (1.8-16.6)), and ATM (3.8 (1.6-9.1)). Our study provides further evidence that rare germline pathogenic variants in these genes are associated with increased risk of this aggressive, clinically relevant subset of PrCa. These rare genetic variants could be incorporated into risk prediction models to improve their precision to identify men at highest risk of aggressive prostate cancer and be used to identify men with newly diagnosed prostate cancer who require urgent treatment.Copyright © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

Published

2021

8. Vtrna2-1: Genetic variation, heritable methylation and disease association.

Author

Dugue P.-A., Yu C., McKay T., Wong E.M., Joo J.E., Tsimiklis H., Hammet F., Mahmoodi M., Theys D., Kconfab, Hopper J.L., Giles G.G., Milne R.L., Steen J.A., Dowty J.G., Nguyen-dumont T., Southey M.C., Dugue P.-A., Yu C., McKay T., Wong E.M., Joo J.E., Tsimiklis H., Hammet F., Mahmoodi M., Theys D., Kconfab, Hopper J.L., Giles G.G., Milne R.L., Steen J.A., Dowty J.G., Nguyen-dumont T., and Southey M.C.

Abstract

VTRNA2-1 is a metastable epiallele with accumulating evidence that methylation at this region is heritable, modifiable and associated with disease including risk and progression of cancer. This study investigated the influence of genetic variation and other factors such as age and adult lifestyle on blood DNA methylation in this region. We first sequenced the VTRNA2-1 gene region in multiple-case breast cancer families in which VTRNA2-1 methylation was identified as heritable and associated with breast cancer risk. Methylation quantitative trait loci (mQTL) were investigated using a prospective cohort study (4500 participants with genotyping and methylation data). The cis-mQTL analysis (334 variants +/- 50 kb of the most heritable CpG site) identified 43 variants associated with VTRNA2-1 methylation (p < 1.5 x 10-4 ); however, these explained little of the methylation variation (R2 < 0.5% for each of these variants). No genetic variants elsewhere in the genome were found to strongly influence VTRNA2-1 methylation. SNP-based heritability estimates were consistent with the mQTL findings (h2 = 0, 95%CI: -0.14 to 0.14). We found no evidence that age, sex, country of birth, smoking, body mass index, alcohol consumption or diet influenced blood DNA methylation at VTRNA2-1. Genetic factors and adult lifestyle play a minimal role in explaining methylation var-iability at the heritable VTRNA2-1 cluster.Copyright © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

Published

2021

9. Population-based estimates of breast cancer risk for carriers of pathogenic variants identified by gene-panel testing

Author

Southey, MC, Dowty, JG, Riaz, M, Steen, JA, Renault, A-L, Tucker, K, Kirk, J, James, P, Winship, I, Pachter, N, Poplawski, N, Grist, S, Park, DJ, Pope, BJ, Mahmood, K, Hammet, F, Mahmoodi, M, Tsimiklis, H, Theys, D, Rewse, A, Willis, A, Morrow, A, Speechly, C, Harris, R, Sebra, R, Schadt, E, Lacaze, P, McNeil, JJ, Giles, GG, Milne, RL, Hopper, JL, Nguyen-Dumont, T, Southey, MC, Dowty, JG, Riaz, M, Steen, JA, Renault, A-L, Tucker, K, Kirk, J, James, P, Winship, I, Pachter, N, Poplawski, N, Grist, S, Park, DJ, Pope, BJ, Mahmood, K, Hammet, F, Mahmoodi, M, Tsimiklis, H, Theys, D, Rewse, A, Willis, A, Morrow, A, Speechly, C, Harris, R, Sebra, R, Schadt, E, Lacaze, P, McNeil, JJ, Giles, GG, Milne, RL, Hopper, JL, and Nguyen-Dumont, T

Abstract

Population-based estimates of breast cancer risk for carriers of pathogenic variants identified by gene-panel testing are urgently required. Most prior research has been based on women selected for high-risk features and more data is needed to make inference about breast cancer risk for women unselected for family history, an important consideration of population screening. We tested 1464 women diagnosed with breast cancer and 862 age-matched controls participating in the Australian Breast Cancer Family Study (ABCFS), and 6549 healthy, older Australian women enroled in the ASPirin in Reducing Events in the Elderly (ASPREE) study for rare germline variants using a 24-gene-panel. Odds ratios (ORs) were estimated using unconditional logistic regression adjusted for age and other potential confounders. We identified pathogenic variants in 11.1% of the ABCFS cases, 3.7% of the ABCFS controls and 2.2% of the ASPREE (control) participants. The estimated breast cancer OR [95% confidence interval] was 5.3 [2.1-16.2] for BRCA1, 4.0 [1.9-9.1] for BRCA2, 3.4 [1.4-8.4] for ATM and 4.3 [1.0-17.0] for PALB2. Our findings provide a population-based perspective to gene-panel testing for breast cancer predisposition and opportunities to improve predictors for identifying women who carry pathogenic variants in breast cancer predisposition genes.

Published

2021

10. Population-Based Estimates of the Age-Specific Cumulative Risk of Breast Cancer for Pathogenic Variants in CHEK2: Findings from the Australian Breast Cancer Family Registry

Author

Nguyen-Dumont, T, Dowty, JG, Steen, JA, Renault, A-L, Hammet, F, Mahmoodi, M, Theys, D, Rewse, A, Tsimiklis, H, Winship, IM, Giles, GG, Milne, RL, Hopper, JL, Southey, MC, Nguyen-Dumont, T, Dowty, JG, Steen, JA, Renault, A-L, Hammet, F, Mahmoodi, M, Theys, D, Rewse, A, Tsimiklis, H, Winship, IM, Giles, GG, Milne, RL, Hopper, JL, and Southey, MC

Abstract

Case-control studies of breast cancer have consistently shown that pathogenic variants in CHEK2 are associated with about a 3-fold increased risk of breast cancer. Information about the recurrent protein-truncating variant CHEK2 c.1100delC dominates this estimate. There have been no formal estimates of age-specific cumulative risk of breast cancer for all CHEK2 pathogenic (including likely pathogenic) variants combined. We conducted a population-based case-control-family study of pathogenic CHEK2 variants (26 families, 1071 relatives) and estimated the age-specific cumulative risk of breast cancer using segregation analysis. The estimated hazard ratio for carriers of pathogenic CHEK2 variants (combined) was 4.9 (95% CI 2.5-9.5) relative to non-carriers. The HR for carriers of the CHEK2 c.1100delC variant was estimated to be 3.5 (95% CI 1.02-11.6) and the HR for carriers of all other CHEK2 variants combined was estimated to be 5.7 (95% CI 2.5-12.9). The age-specific cumulative risk of breast cancer was estimated to be 18% (95% CI 11-30%) and 33% (95% CI 21-48%) to age 60 and 80 years, respectively. These findings provide important information for the clinical management of breast cancer risk for women carrying pathogenic variants in CHEK2.

Published

2021

11. Repeatability of methylation measures using a QIAseq targeted methyl panel and comparison with the Illumina HumanMethylation450 assay

Author

Yu, C, Dugue, P-A, Dowty, JG, Hammet, F, Joo, JE, Wong, EM, Hosseinpour, M, Giles, GG, Hopper, JL, Tu, N-D, MacInnis, RJ, Southey, MC, Yu, C, Dugue, P-A, Dowty, JG, Hammet, F, Joo, JE, Wong, EM, Hosseinpour, M, Giles, GG, Hopper, JL, Tu, N-D, MacInnis, RJ, and Southey, MC

Abstract

OBJECTIVE: In previous studies using Illumina Infinium methylation arrays, we have identified DNA methylation marks associated with cancer predisposition and progression. In the present study, we have sought to find appropriate technology to both technically validate our data and expand our understanding of DNA methylation in these genomic regions. Here, we aimed to assess the repeatability of methylation measures made using QIAseq targeted methyl panel and to compare them with those obtained from the Illumina HumanMethylation450 (HM450K) assay. We included in the analysis high molecular weight DNA extracted from whole blood (WB) and DNA extracted from formalin-fixed paraffin-embedded tissues (FFPE). RESULTS: The repeatability of QIAseq-methylation measures was assessed at 40 CpGs, using the Intraclass Correlation Coefficient (ICC). The mean ICCs and 95% confidence intervals (CI) were 0.72 (0.62-0.81), 0.59 (0.47-0.71) and 0.80 (0.73-0.88) for WB, FFPE and both sample types combined, respectively. For technical replicates measured using QIAseq and HM450K, the mean ICCs (95% CI) were 0.53 (0.39-0.68), 0.43 (0.31-0.56) and 0.70 (0.59-0.80), respectively. Bland-Altman plots indicated good agreement between QIAseq and HM450K measurements. These results demonstrate that the QIAseq targeted methyl panel produces reliable and reproducible methylation measurements across the 40 CpGs that were examined.

Published

2021

12. Rare Germline Pathogenic Variants Identified by Multigene Panel Testing and the Risk of Aggressive Prostate Cancer

Author

Nguyen-Dumont, T, Dowty, JG, MacInnis, RJ, Steen, JA, Riaz, M, Dugue, P-A, Renault, A-L, Hammet, F, Mahmoodi, M, Theys, D, Tsimiklis, H, Severi, G, Bolton, D, Lacaze, P, Sebra, R, Schadt, E, McNeil, J, Giles, GG, Milne, RL, Southey, MC, Nguyen-Dumont, T, Dowty, JG, MacInnis, RJ, Steen, JA, Riaz, M, Dugue, P-A, Renault, A-L, Hammet, F, Mahmoodi, M, Theys, D, Tsimiklis, H, Severi, G, Bolton, D, Lacaze, P, Sebra, R, Schadt, E, McNeil, J, Giles, GG, Milne, RL, and Southey, MC

Abstract

While gene panel sequencing is becoming widely used for cancer risk prediction, its clinical utility with respect to predicting aggressive prostate cancer (PrCa) is limited by our current understanding of the genetic risk factors associated with predisposition to this potentially lethal disease phenotype. This study included 837 men diagnosed with aggressive PrCa and 7261 controls (unaffected men and men who did not meet criteria for aggressive PrCa). Rare germline pathogenic variants (including likely pathogenic variants) were identified by targeted sequencing of 26 known or putative cancer predisposition genes. We found that 85 (10%) men with aggressive PrCa and 265 (4%) controls carried a pathogenic variant (p < 0.0001). Aggressive PrCa odds ratios (ORs) were estimated using unconditional logistic regression. Increased risk of aggressive PrCa (OR (95% confidence interval)) was identified for pathogenic variants in BRCA2 (5.8 (2.7-12.4)), BRCA1 (5.5 (1.8-16.6)), and ATM (3.8 (1.6-9.1)). Our study provides further evidence that rare germline pathogenic variants in these genes are associated with increased risk of this aggressive, clinically relevant subset of PrCa. These rare genetic variants could be incorporated into risk prediction models to improve their precision to identify men at highest risk of aggressive prostate cancer and be used to identify men with newly diagnosed prostate cancer who require urgent treatment.

Published

2021

13. VTRNA2-1: Genetic Variation, Heritable Methylation and Disease Association

Author

Dugue, P-A, Yu, C, McKay, T, Wong, EM, Joo, JE, Tsimiklis, H, Hammet, F, Mahmoodi, M, Theys, D, Hopper, JL, Giles, GG, Milne, RL, Steen, JA, Dowty, JG, Nguyen-Dumont, T, Southey, MC, Dugue, P-A, Yu, C, McKay, T, Wong, EM, Joo, JE, Tsimiklis, H, Hammet, F, Mahmoodi, M, Theys, D, Hopper, JL, Giles, GG, Milne, RL, Steen, JA, Dowty, JG, Nguyen-Dumont, T, and Southey, MC

Abstract

VTRNA2-1 is a metastable epiallele with accumulating evidence that methylation at this region is heritable, modifiable and associated with disease including risk and progression of cancer. This study investigated the influence of genetic variation and other factors such as age and adult lifestyle on blood DNA methylation in this region. We first sequenced the VTRNA2-1 gene region in multiple-case breast cancer families in which VTRNA2-1 methylation was identified as heritable and associated with breast cancer risk. Methylation quantitative trait loci (mQTL) were investigated using a prospective cohort study (4500 participants with genotyping and methylation data). The cis-mQTL analysis (334 variants ± 50 kb of the most heritable CpG site) identified 43 variants associated with VTRNA2-1 methylation (p < 1.5 × 10-4); however, these explained little of the methylation variation (R2 < 0.5% for each of these variants). No genetic variants elsewhere in the genome were found to strongly influence VTRNA2-1 methylation. SNP-based heritability estimates were consistent with the mQTL findings (h2 = 0, 95%CI: -0.14 to 0.14). We found no evidence that age, sex, country of birth, smoking, body mass index, alcohol consumption or diet influenced blood DNA methylation at VTRNA2-1. Genetic factors and adult lifestyle play a minimal role in explaining methylation variability at the heritable VTRNA2-1 cluster.

Published

2021

14. Genetic testing in Poland and Ukraine: Should comprehensive germline testing of BRCA1 and BRCA2 be recommended for women with breast and ovarian cancer?.

Author

Nguyen-Dumont T., Steen J.A., Theys D., Hammet F., Tsimiklis H., Park D.J., Pope B.J., Slezak R., Stembalska A., Pesz K., Kitsera N., Siekierzynska A., Southey M.C., Myszka A., Karpinski P., Sasiadek M.M., Akopyan H., Nguyen-Dumont T., Steen J.A., Theys D., Hammet F., Tsimiklis H., Park D.J., Pope B.J., Slezak R., Stembalska A., Pesz K., Kitsera N., Siekierzynska A., Southey M.C., Myszka A., Karpinski P., Sasiadek M.M., and Akopyan H.

Abstract

PurposeTo characterize the spectrum of BRCA1 and BRCA2 pathogenic germline variants in women from south-west Poland and west Ukraine affected with breast or ovarian cancer. Testing in women at high risk of breast and ovarian cancer in these regions is currently mainly limited to founder mutations.MethodsUnrelated women affected with breast and/or ovarian cancer from Poland (n = 337) and Ukraine (n = 123) were screened by targeted sequencing. Excluded from targeted sequencing were 34 Polish women who had previously been identified as carrying a founder mutation in BRCA1. No prior testing had been conducted among the Ukrainian women. Thus, this study screened BRCA1 and BRCA2 in the germline DNA of 426 women in total.ResultsWe identified 31 and 18 women as carriers of pathogenic/likely pathogenic (P/LP) genetic variants in BRCA1 and BRCA2, respectively. We observed five BRCA1 and eight BRCA2 P/LP variants (13/337, 3.9%) in the Polish women. Combined with the 34/337 (10.1%) founder variants identified prior to this study, the overall P/LP variant frequency in the Polish women was thus 14% (47/337). Among the Ukrainian women, 16/123 (13%) women were identified as carrying a founder mutation and 20/123 (16.3%) were found to carry non-founder P/LP variants (10 in BRCA1 and 10 in BRCA2).ConclusionsThese results indicate that genetic testing in women at high risk of breast and ovarian cancer in Poland and Ukraine should not be limited to founder mutations. Extended testing will enhance risk stratification and management for these women and their families. Copyright © The Author(s), 2020. Published by Cambridge University Press.

Published

2020

15. Mismatch repair gene pathogenic germline variants in a population-based cohort of breast cancer.

Author

Hopper J.L., Tsimiklis H., Theys D., Clendenning M., Giles G.G., Southey M.C., Nguyen-Dumont T., Steen J.A., Winship I., Park D.J., Pope B.J., Hammet F., Mahmoodi M., Hopper J.L., Tsimiklis H., Theys D., Clendenning M., Giles G.G., Southey M.C., Nguyen-Dumont T., Steen J.A., Winship I., Park D.J., Pope B.J., Hammet F., and Mahmoodi M.

Abstract

The advent of gene panel testing is challenging the previous practice of using clinically defined cancer family syndromes to inform single-gene genetic screening. Individual and family cancer histories that would have previously indicated testing of a single gene or a small number of related genes are now, increasingly, leading to screening across gene panels that contain larger numbers of genes. We have applied a gene panel test that included four DNA mismatch repair (MMR) genes (MLH1, MSH2, MSH6 and PMS2) to an Australian population-based case-control-family study of breast cancer. Altogether, eight pathogenic variants in MMR genes were identified: six in 1421 case-families (0.4%, 4 MSH6 and 2 PMS2) and two in 833 control-families (0.2%, one each of MLH1 and MSH2). This testing highlights the current and future challenges for clinical genetics in the context of anticipated gene panel-based population-based screening that includes the MMR genes. This testing is likely to provide additional opportunities for cancer prevention via cascade testing for Lynch syndrome and precision medicine for breast cancer treatment.Copyright © 2020, Springer Nature B.V.

Published

2020

16. Rare germline genetic variants and risk of aggressive prostate cancer.

Author

Southey M.C., Nguyen-Dumont T.U., MacInnis R.J., Steen J.A., Theys D., Tsimiklis H., Hammet F., Mahmoodi M., Mahmood K., Severi G., Bolton D., Milne R.L., Giles G.G., Pope B.J., Park D.J., Southey M.C., Nguyen-Dumont T.U., MacInnis R.J., Steen J.A., Theys D., Tsimiklis H., Hammet F., Mahmoodi M., Mahmood K., Severi G., Bolton D., Milne R.L., Giles G.G., Pope B.J., and Park D.J.

Abstract

Few genetic risk factors have been demonstrated to be specifically associated with aggressive prostate cancer (PrCa). Here, we report a case-case study of PrCa comparing the prevalence of germline pathogenic/likely pathogenic (P/LP) genetic variants in 787 men with aggressive disease and 769 with nonaggressive disease. Overall, we observed P/LP variants in 11.4% of men with aggressive PrCa and 9.8% of men with nonaggressive PrCa (two-tailed Fisher's exact tests, P =.28). The proportion of BRCA2 and ATM P/LP variant carriers in men with aggressive PrCa exceeded that observed in men with nonaggressive PrCa; 18/787 carriers (2.3%) and 4/769 carriers (0.5%), P =.004, and 14/787 carriers (0.02%) and 5/769 carriers (0.01%), P =.06, respectively. Our findings contribute to the extensive international effort to interpret the genetic variation identified in genes included on gene-panel tests, for which there is currently an insufficient evidence-base for clinical translation in the context of PrCa risk.Copyright © 2020 UICC

Published

2020

17. Rare germline genetic variants and risk of aggressive prostate cancer

Author

Nguyen-Dumont, T, MacInnis, RJ, Steen, JA, Theys, D, Tsimiklis, H, Hammet, F, Mahmoodi, M, Pope, BJ, Park, DJ, Mahmood, K, Severi, G, Bolton, D, Milne, RL, Giles, GG, Southey, MC, Nguyen-Dumont, T, MacInnis, RJ, Steen, JA, Theys, D, Tsimiklis, H, Hammet, F, Mahmoodi, M, Pope, BJ, Park, DJ, Mahmood, K, Severi, G, Bolton, D, Milne, RL, Giles, GG, and Southey, MC

Abstract

Few genetic risk factors have been demonstrated to be specifically associated with aggressive prostate cancer (PrCa). Here, we report a case-case study of PrCa comparing the prevalence of germline pathogenic/likely pathogenic (P/LP) genetic variants in 787 men with aggressive disease and 769 with nonaggressive disease. Overall, we observed P/LP variants in 11.4% of men with aggressive PrCa and 9.8% of men with nonaggressive PrCa (two-tailed Fisher's exact tests, P = .28). The proportion of BRCA2 and ATM P/LP variant carriers in men with aggressive PrCa exceeded that observed in men with nonaggressive PrCa; 18/787 carriers (2.3%) and 4/769 carriers (0.5%), P = .004, and 14/787 carriers (0.02%) and 5/769 carriers (0.01%), P = .06, respectively. Our findings contribute to the extensive international effort to interpret the genetic variation identified in genes included on gene-panel tests, for which there is currently an insufficient evidence-base for clinical translation in the context of PrCa risk.

Published

2020

18. Genetic testing in Poland and Ukraine: should comprehensive germline testing of BRCA1 and BRCA2 be recommended for women with breast and ovarian cancer?

Author

Nguyen-Dumont, T, Karpinski, P, Sasiadek, MM, Akopyan, H, Steen, JA, Theys, D, Hammet, F, Tsimiklis, H, Park, DJ, Pope, BJ, Slezak, R, Stembalska, A, Pesz, K, Kitsera, N, Siekierzynska, A, Southey, MC, Myszka, A, Nguyen-Dumont, T, Karpinski, P, Sasiadek, MM, Akopyan, H, Steen, JA, Theys, D, Hammet, F, Tsimiklis, H, Park, DJ, Pope, BJ, Slezak, R, Stembalska, A, Pesz, K, Kitsera, N, Siekierzynska, A, Southey, MC, and Myszka, A

Abstract

PURPOSE: To characterize the spectrum of BRCA1 and BRCA2 pathogenic germline variants in women from south-west Poland and west Ukraine affected with breast or ovarian cancer. Testing in women at high risk of breast and ovarian cancer in these regions is currently mainly limited to founder mutations. METHODS: Unrelated women affected with breast and/or ovarian cancer from Poland (n = 337) and Ukraine (n = 123) were screened by targeted sequencing. Excluded from targeted sequencing were 34 Polish women who had previously been identified as carrying a founder mutation in BRCA1. No prior testing had been conducted among the Ukrainian women. Thus, this study screened BRCA1 and BRCA2 in the germline DNA of 426 women in total. RESULTS: We identified 31 and 18 women as carriers of pathogenic/likely pathogenic (P/LP) genetic variants in BRCA1 and BRCA2, respectively. We observed five BRCA1 and eight BRCA2 P/LP variants (13/337, 3.9%) in the Polish women. Combined with the 34/337 (10.1%) founder variants identified prior to this study, the overall P/LP variant frequency in the Polish women was thus 14% (47/337). Among the Ukrainian women, 16/123 (13%) women were identified as carrying a founder mutation and 20/123 (16.3%) were found to carry non-founder P/LP variants (10 in BRCA1 and 10 in BRCA2). CONCLUSIONS: These results indicate that genetic testing in women at high risk of breast and ovarian cancer in Poland and Ukraine should not be limited to founder mutations. Extended testing will enhance risk stratification and management for these women and their families.

Published

2020

19. Hi-PLEX2: A simple and robust approach to targeted sequencing-based genetic screening.

Author

Couch F.J., Lonie A., Nathanson K.L., Pope B.J., Park D.J., Hammet F., Mahmood K., Green T.R., Nguyen-Dumont T., Southey M.C., Buchanan D.D., Couch F.J., Lonie A., Nathanson K.L., Pope B.J., Park D.J., Hammet F., Mahmood K., Green T.R., Nguyen-Dumont T., Southey M.C., and Buchanan D.D.

Abstract

We have previously reported Hi-Plex, a multiplex PCR methodology for building targeted DNA sequencing libraries that offers a low-cost protocol compatible with high-throughput processing. Here, we detail an improved protocol, Hi-Plex2, that more effectively enables the robust construction of small-to-medium panel-size libraries while maintaining low cost, simplicity and accuracy benefits of the Hi-Plex platform. Hi-Plex2 was applied to three panels, comprising 291, 740 and 1193 amplicons, targeting genes associated with risk for breast and/or colon cancer. We show substantial reduction of off-target amplification to enable library construction for small-to-medium sized design panels not possible using the previous Hi-Plex chemistry.Copyright © 2019 Future Science. All rights reserved.

Published

2019

20. Hi-Plex2: A simple and robust approach to targeted sequencing-based genetic screening.

Author

Buchanan D.D., Couch F.J., Nathanson K.L., Hammet F., Mahmood K., Green T.R., Nguyen-Dumont T., Southey M.C., Lonie A., Park D.J., Pope B.J., Buchanan D.D., Couch F.J., Nathanson K.L., Hammet F., Mahmood K., Green T.R., Nguyen-Dumont T., Southey M.C., Lonie A., Park D.J., and Pope B.J.

Abstract

We have previously reported Hi-Plex, a multiplex PCR methodology for building targeted DNA sequencing libraries that offers a low-cost protocol compatible with high-throughput processing. Here, we detail an improved protocol, Hi-Plex2, that more effectively enables the robust construction of small-to-medium panel-size libraries while maintaining low cost, simplicity and accuracy benefits of the Hi-Plex platform. Hi-Plex2 was applied to three panels, comprising 291, 740 and 1193 amplicons, targeting genes associated with risk for breast and/or colon cancer. We show substantial reduction of off-target amplification to enable library construction for small-to-medium sized design panels not possible using the previous Hi-Plex chemistry.Copyright © 2019 Daniel Park.

Published

2019

21. Is RNASEL: P.Glu265* a modifier of early-onset breast cancer risk for carriers of high-risk mutations?.

Author

Park D.J., Pope B.J., Lonie A., Kapuscinski M.K., Mahmood K., Goldgar D.E., Southey M.C., Hopper J.L., Winship I., Giles G.G., Nguyen-Dumont T., Teo Z.L., Hammet F., Roberge A., Mahmoodi M., Tsimiklis H., Park D.J., Pope B.J., Lonie A., Kapuscinski M.K., Mahmood K., Goldgar D.E., Southey M.C., Hopper J.L., Winship I., Giles G.G., Nguyen-Dumont T., Teo Z.L., Hammet F., Roberge A., Mahmoodi M., and Tsimiklis H.

Abstract

Background: Breast cancer risk for BRCA1 and BRCA2 pathogenic mutation carriers is modified by risk factors that cluster in families, including genetic modifiers of risk. We considered genetic modifiers of risk for carriers of high-risk mutations in other breast cancer susceptibility genes. Method(s): In a family known to carry the high-risk mutation PALB2:c.3113G>A (p.Trp1038*), whole-exome sequencing was performed on germline DNA from four affected women, three of whom were mutation carriers. Result(s): RNASEL:p.Glu265* was identified in one of the PALB2 carriers who had two primary invasive breast cancer diagnoses before 50 years. Gene-panel testing of BRCA1, BRCA2, PALB2 and RNASEL in the Australian Breast Cancer Family Registry identified five carriers of RNASEL:p.Glu265* in 591 early onset breast cancer cases. Three of the five women (60%) carrying RNASEL:p.Glu265* also carried a pathogenic mutation in a breast cancer susceptibility gene compared with 30 carriers of pathogenic mutations in the 586 non-carriers of RNASEL:p.Glu265* (5%) (p<0.002). Taqman genotyping demonstrated that the allele frequency of RNASEL:p.Glu265* was similar in affected and unaffected Australian women, consistent with other populations. Conclusion(s): Our study suggests that RNASEL:p.Glu265* may be a genetic modifier of risk for early-onset breast cancer predisposition in carriers of high-risk mutations. Much larger case-case and case-control studies are warranted to test the association observed in this report.Copyright © 2018 The Author(s).

Published

2018

22. FANCM and RECQL genetic variants and breast cancer susceptibility: relevance to South Poland and West Ukraine

Author

Tu, N-D, Myszka, A, Karpinski, P, Sasiadek, MM, Akopyan, H, Hammet, F, Tsimiklis, H, Park, DJ, Pope, BJ, Slezak, R, Kitsera, N, Siekierzynska, A, Southey, MC, Tu, N-D, Myszka, A, Karpinski, P, Sasiadek, MM, Akopyan, H, Hammet, F, Tsimiklis, H, Park, DJ, Pope, BJ, Slezak, R, Kitsera, N, Siekierzynska, A, and Southey, MC

Abstract

BACKGROUND: FANCM and RECQL have recently been reported as breast cancer susceptibility genes and it has been suggested that they should be included on gene panel tests for breast cancer predisposition. However, the clinical value of testing for mutations in RECQL and FANCM remains to be determined. In this study, we have characterised the spectrum of FANCM and RECQL mutations in women affected with breast or ovarian cancer from South-West Poland and West Ukraine. METHODS: We applied Hi-Plex, an amplicon-based enrichment method for targeted massively parallel sequencing, to screen the coding exons and proximal intron-exon junctions of FANCM and RECQL in germline DNA from unrelated women affected with breast cancer (n = 338) and ovarian cancer (n = 89) from Poland (n = 304) and Ukraine (n = 123). These women were at high-risk of carrying a genetic predisposition to breast and/or ovarian cancer due to a family history and/or early-onset disease. RESULTS: Among 427 women screened, we identified one carrier of the FANCM:c.1972C > T nonsense mutation (0.23%), and two carriers of the frameshift insertion FANCM:c.1491dup (0.47%). None of the variants we observed in RECQL were predicted to be loss-of-function mutations by standard variant effect prediction tools. CONCLUSIONS: Our study of the Polish and Ukrainian populations has identified a carrier frequency of truncating mutations in FANCM consistent with previous reports. Although initial reports suggesting that mutations in RECQL could be associated with increased breast cancer risk included women from Poland and identified the RECQL:c.1667_1667 + 3delAGTA mutation in 0.23-0.35% of breast cancer cases, we did not observe any carriers in our study cohort. Continued screening, both in research and diagnostic settings, will enable the accumulation of data that is needed to establish the clinical utility of including RECQL and FANCM on gene panel tests.

Published

2018

23. Is RNASEL:p.Glu265*a modifier of early-onset breast cancer risk for carriers of high-risk mutations?

Author

Nguyen-Dumont, T, Teo, ZL, Hammet, F, Roberge, A, Mahmoodi, M, Tsimiklis, H, Park, DJ, Pope, BJ, Lonie, A, Kapuscinski, MK, Mahmood, K, Goldgar, DE, Giles, GG, Winship, I, Hopper, JL, Southey, MC, Nguyen-Dumont, T, Teo, ZL, Hammet, F, Roberge, A, Mahmoodi, M, Tsimiklis, H, Park, DJ, Pope, BJ, Lonie, A, Kapuscinski, MK, Mahmood, K, Goldgar, DE, Giles, GG, Winship, I, Hopper, JL, and Southey, MC

Abstract

BACKGROUND: Breast cancer risk for BRCA1 and BRCA2 pathogenic mutation carriers is modified by risk factors that cluster in families, including genetic modifiers of risk. We considered genetic modifiers of risk for carriers of high-risk mutations in other breast cancer susceptibility genes. METHODS: In a family known to carry the high-risk mutation PALB2:c.3113G>A (p.Trp1038*), whole-exome sequencing was performed on germline DNA from four affected women, three of whom were mutation carriers. RESULTS: RNASEL:p.Glu265* was identified in one of the PALB2 carriers who had two primary invasive breast cancer diagnoses before 50 years. Gene-panel testing of BRCA1, BRCA2, PALB2 and RNASEL in the Australian Breast Cancer Family Registry identified five carriers of RNASEL:p.Glu265* in 591 early onset breast cancer cases. Three of the five women (60%) carrying RNASEL:p.Glu265* also carried a pathogenic mutation in a breast cancer susceptibility gene compared with 30 carriers of pathogenic mutations in the 586 non-carriers of RNASEL:p.Glu265* (5%) (p < 0.002). Taqman genotyping demonstrated that the allele frequency of RNASEL:p.Glu265* was similar in affected and unaffected Australian women, consistent with other populations. CONCLUSION: Our study suggests that RNASEL:p.Glu265* may be a genetic modifier of risk for early-onset breast cancer predisposition in carriers of high-risk mutations. Much larger case-case and case-control studies are warranted to test the association observed in this report.

Published

2018

24. Targeted massively parallel sequencing characterises the mutation spectrum of PALB2 in breast and ovarian cancer cases from Poland and Ukraine

Author

Myszka, A, Tu, N-D, Karpinski, P, Sasiadek, MM, Akopyan, H, Hammet, F, Tsimiklis, H, Park, DJ, Pope, BJ, Slezak, R, Kitsera, N, Siekierzynska, A, Southey, MC, Myszka, A, Tu, N-D, Karpinski, P, Sasiadek, MM, Akopyan, H, Hammet, F, Tsimiklis, H, Park, DJ, Pope, BJ, Slezak, R, Kitsera, N, Siekierzynska, A, and Southey, MC

Abstract

Loss-of-function germline mutations in the PALB2 gene are associated with an increase of breast cancer risk. The purpose of this study was to characterise the spectrum of PALB2 mutations in women affected with breast or ovarian cancer from South-West Poland and West Ukraine. We applied Hi-Plex, an amplicon-based enrichment method for targeted massively parallel sequencing, to screen the coding exons and proximal intron-exon junctions of PALB2 in germline DNA from unrelated women affected with breast cancer (n = 338) and ovarian cancer (n = 89) from Poland (n = 304) and Ukraine (n = 123). These women were at high-risk of carrying a genetic predisposition to breast and/or ovarian cancer due to a family history and/or early-onset disease. Targeted-sequencing identified two frameshift deletions: PALB2:c.509_510del; p.R170Ifs in three women affected with breast cancer and PALB2:c.172_175del;p.Q60Rfs in one woman affected with ovarian cancer. A number of other previously described missense (some predicted to be damaging by PolyPhen-2 and CADD) and synonymous mutations were also identified in this population. This study is consistent with previous reports that PALB2:c.509_510del and PALB2:c.172_175del are recurrent mutations associated with breast cancer predisposition in Polish women with a family history of the disease. Our study contributes to the accumulating evidence indicating that PALB2 should be included in genetic testing for breast cancer susceptibility in these populations to enhance risk assessment and management of women at high-risk of developing breast cancer. This data could also contribute to ongoing work that is assessing the possible association between ovarian cancer risk and PALB2 mutations for which there is currently no evidence.

Published

2018

25. Mutation screening of ACKR3 and COPS8 in kidney cancer cases from the CONFIRM study

Author

Mahmoodi, M, Tu, N-D, Hammet, F, Pope, BJ, Park, DJ, Southey, MC, Darlow, JM, Bruinsma, F, Winship, I, Mahmoodi, M, Tu, N-D, Hammet, F, Pope, BJ, Park, DJ, Southey, MC, Darlow, JM, Bruinsma, F, and Winship, I

Abstract

An apparently balanced t(2;3)(q37.3;q13.2) translocation that appears to segregate with renal cell carcinoma (RCC) has indicated potential areas to search for the elusive genetic basis of clear cell RCC. We applied Hi-Plex targeted sequencing to analyse germline DNA from 479 individuals affected with clear cell RCC for this breakpoint translocation and genetic variants in neighbouring genes on chromosome 2, ACKR3 and COPS8. While only synonymous variants were found in COPS8, one of the missense variants in ACKR3:c.892C>T, observed in 4/479 individuals screened (0.8%), was predicted likely to damage ACKR3 function. Identification of causal genes for RCC has potential clinical utility, where risk assessment and risk management can offer better outcomes, with surveillance for at-risk relatives and nephron sparing surgery through earlier intervention.

Published

2017

26. Rare Mutations in XRCC2 Increase the Risk of Breast Cancer

Author

Park, D.J., Lesueur, F., Nguyen-Dumont, T., Pertesi, M., Odefrey, F., Hammet, F., Neuhausen, S.L., John, E.M., Andrulis, I.L., Terry, M.B., Daly, M., Buys, S., Calvez-Kelm, F. le, Lonie, A., Pope, B.J., Tsimiklis, H., Voegele, C., Hilbers, F.M., Hoogerbrugge, N., Barroso, A., Osorio, A., Giles, G.G., Devilee, P., Benitez, J., Hopper, J.L., Tavtigian, S.V., Goldgar, D.E., Southey, M.C., Breast Canc Family Registry, and Kathleen Cuningham Fdn Consortium

Subjects

Adult, Male, Risk, Hereditary cancer and cancer-related syndromes Genetics and epigenetic pathways of disease [ONCOL 1], Population, Breast Neoplasms, Biology, medicine.disease_cause, Germline mutation, Breast cancer, Report, Genetics, medicine, Humans, Missense mutation, Exome, Genetic Predisposition to Disease, Genetics(clinical), Homologous Recombination, education, Genetics (clinical), education.field_of_study, Mutation, Massive parallel sequencing, Hereditary cancer and cancer-related syndromes [ONCOL 1], Middle Aged, medicine.disease, Pedigree, DNA-Binding Proteins, Case-Control Studies, RAD51C, Female

Abstract

Item does not contain fulltext An exome-sequencing study of families with multiple breast-cancer-affected individuals identified two families with XRCC2 mutations, one with a protein-truncating mutation and one with a probably deleterious missense mutation. We performed a population-based case-control mutation-screening study that identified six probably pathogenic coding variants in 1,308 cases with early-onset breast cancer and no variants in 1,120 controls (the severity grading was p < 0.02). We also performed additional mutation screening in 689 multiple-case families. We identified ten breast-cancer-affected families with protein-truncating or probably deleterious rare missense variants in XRCC2. Our identification of XRCC2 as a breast cancer susceptibility gene thus increases the proportion of breast cancers that are associated with homologous recombination-DNA-repair dysfunction and Fanconi anemia and could therefore benefit from specific targeted treatments such as PARP (poly ADP ribose polymerase) inhibitors. This study demonstrates the power of massively parallel sequencing for discovering susceptibility genes for common, complex diseases.

Published

2012

27. Breast cancer risk and 6q22.33: Combined results from breast cancer association consortium and consortium of investigators on modifiers of brca1/2

Author

Kirchhoff, T., Gaudet, M.M., Antoniou, A.C., McGuffog, L., Humphreys, M.K., Dunning, A.M., Bojesen, S.E., Nordestgaard, B.G., Flyger, H., Kang, D., Yoo, K.Y., Noh, D.Y., Ahn, S.H., Dork, T., Schurmann, P., Karstens, J.H., Hillemanns, P., Couch, F.J., Olson, J., Vachon, C., Wang, X.S., Cox, A., Brock, I., Elliott, G., Reed, M.W.R., Burwinkel, B., Meindl, A., Brauch, H., Hamann, U., Ko, Y.D., Broeks, A., Schmidt, M.K., Veer, L.J. van 't, Braaf, L.M., Johnson, N., Fletcher, O., Gibson, L., Peto, J., Turnbull, C., Seal, S., Renwick, A., Rahman, N., Wu, P.E., Yu, J.C., Hsiung, C.N., Shen, C.Y., Southey, M.C., Hopper, J.L., Hammet, F., Dorpe, T. van, Dieudonne, A.S., Hatse, S., Lambrechts, D., Andrulis, I.L., Bogdanova, N., Antonenkova, N., Rogov, J.I., Prokofieva, D., Bermisheva, M., Khusnutdinova, E., Asperen, C.J. van, Tollenaar, R.A.E.M., Hooning, M.J., Devilee, P., Margolin, S., Lindblom, A., Milne, R.L., Arias, J.I., Zamora, M.P., Benitez, J., Severi, G., Baglietto, L., Giles, G.G., Spurdle, A.B., Beesley, J., Chen, X.Q., Holland, H., Healey, S., Wang-Gohrke, S., Chang-Claude, J., Mannermaa, A., Kosma, V.M., Kauppinen, J., Kataja, V., Agnarsson, B.A., Caligo, M.A., Godwin, A.K., Nevanlinna, H., Heikkinen, T., Fredericksen, Z., Lindor, N., Nathanson, K.L., Domchek, S.M., Loman, N., Karlsson, P., Askmalm, M.S., Melin, B., Wachenfeldt, A. von, Hogervorst, F.B.L., Verheus, M., Rookus, M.A., Seynaeve, C., Oldenburg, R.A., Ligtenberg, M.J., Ausems, M.G.E.M., Aalfs, C.M., Gille, H.J.P., Wijnen, J.T., Garcia, E.B.G., Peock, S., Cook, M., Oliver, C.T., Frost, D., Luccarini, C., Pichert, G., Davidson, R., Chu, C., Eccles, D., Ong, K.R., Cook, J., Douglas, F., Hodgson, S., Evans, D.G., Eeles, R., Gold, B., Pharoah, P.D.P., Offit, K., Chenevix-Trench, G., Easton, D.F., GENICA Network, kConFab, AOCS Study Grp, SWE-BRCA, HEBON, EMBRACE, BCAC-CIMBA, Medical Oncology, Clinical Genetics, Genetica & Celbiologie, RS: GROW - School for Oncology and Reproduction, Human genetics, CCA - Oncogenesis, Department of Obstetrics and Gynecology, Women's Health Research Program, Human Genetics, Cancer Center Amsterdam, and Amsterdam Reproduction & Development (AR&D)

Subjects

Oncology, Genetics and Molecular Biology (all), Medicin och hälsovetenskap, Alleles, BRCA1 Protein, BRCA2 Protein, Breast Neoplasms, Chromosomes, Human, Pair 6, Confidence Intervals, Female, Genetic Association Studies, Heterozygote, Humans, Middle Aged, Odds Ratio, Polymorphism, Single Nucleotide, Proportional Hazards Models, Receptors, Estrogen, Risk Factors, Genetic Predisposition to Disease, Medicine (all), Biochemistry, Genetics and Molecular Biology (all), Agricultural and Biological Sciences (all), Epidemiology, Genome-wide association study, VARIANTS, Bioinformatics, Medical and Health Sciences, Biochemistry, 0302 clinical medicine, Breast Tumors, Genotype, Receptors, skin and connective tissue diseases, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), 0303 health sciences, education.field_of_study, variants, Multidisciplinary, Cancer Risk Factors, Obstetrics and Gynecology, Single Nucleotide, 3. Good health, Genetic Epidemiology, 030220 oncology & carcinogenesis, alleles, Medicine, Pair 6, Cancer Epidemiology, Research Article, Human, medicine.medical_specialty, SUSCEPTIBILITY LOCI, Science, Genetic Causes of Cancer, Population, Hereditary cancer and cancer-related syndromes Genetics and epigenetic pathways of disease [ONCOL 1], education, Single-nucleotide polymorphism, Chromosomes, 03 medical and health sciences, Breast cancer, SDG 3 - Good Health and Well-being, Translational research [ONCOL 3], Internal medicine, Breast Cancer, Genetics, Cancer Genetics, Genome-Wide Association Studies, medicine, GENOME-WIDE ASSOCIATION, Polymorphism, Genetics and epigenetic pathways of disease Translational research [NCMLS 6], gene, Biology, 030304 developmental biology, Cancer och onkologi, Population Biology, Hereditary cancer and cancer-related syndromes [ONCOL 1], Proportional hazards model, business.industry, Cancers and Neoplasms, Odds ratio, medicine.disease, GENE, Estrogen, susceptibility loci, Minor allele frequency, Cancer and Oncology, FGFR2, genome-wide association, 3111 Biomedicine, business

Abstract

Recently, a locus on chromosome 6q22.33 (rs2180341) was reported to be associated with increased breast cancer risk in the Ashkenazi Jewish (AJ) population, and this association was also observed in populations of non-AJ European ancestry. In the present study, we performed a large replication analysis of rs2180341 using data from 31,428 invasive breast cancer cases and 34,700 controls collected from 25 studies in the Breast Cancer Association Consortium (BCAC). In addition, we evaluated whether rs2180341 modifies breast cancer risk in 3,361 BRCA1 and 2,020 BRCA2 carriers from 11 centers in the Consortium of Investigators of Modifiers of BRCA1/2 (CIMBA). Based on the BCAC data from women of European ancestry, we found evidence for a weak association with breast cancer risk for rs2180341 (per-allele odds ratio (OR) = 1.03, 95% CI 1.00-1.06, p = 0.023). There was evidence for heterogeneity in the ORs among studies (I-2 = 49.3%; p = less than0.004). In CIMBA, we observed an inverse association with the minor allele of rs2180341 and breast cancer risk in BRCA1 mutation carriers (per-allele OR = 0.89, 95% CI 0.80-1.00, p = 0.048), indicating a potential protective effect of this allele. These data suggest that that 6q22.33 confers a weak effect on breast cancer risk.

Published

2012

28. ROVER variant caller: read-pair overlap considerate variant-calling software applied to PCR-based massively parallel sequencing datasets

Author

Pope, BJ, Nguyen-Dumont, T, Hammet, F, Park, DJ, Pope, BJ, Nguyen-Dumont, T, Hammet, F, and Park, DJ

Abstract

BACKGROUND: We recently described Hi-Plex, a highly multiplexed PCR-based target-enrichment system for massively parallel sequencing (MPS), which allows the uniform definition of library size so that subsequent paired-end sequencing can achieve complete overlap of read pairs. Variant calling from Hi-Plex-derived datasets can thus rely on the identification of variants appearing in both reads of read-pairs, permitting stringent filtering of sequencing chemistry-induced errors. These principles underly ROVER software (derived from Read Overlap PCR-MPS variant caller), which we have recently used to report the screening for genetic mutations in the breast cancer predisposition gene PALB2. Here, we describe the algorithms underlying ROVER and its usage. RESULTS: ROVER enables users to quickly and accurately identify genetic variants from PCR-targeted, overlapping paired-end MPS datasets. The open-source availability of the software and threshold tailorability enables broad access for a range of PCR-MPS users. METHODS: ROVER is implemented in Python and runs on all popular POSIX-like operating systems (Linux, OS X). The software accepts a tab-delimited text file listing the coordinates of the target-specific primers used for targeted enrichment based on a specified genome-build. It also accepts aligned sequence files resulting from mapping to the same genome-build. ROVER identifies the amplicon a given read-pair represents and removes the primer sequences by using the mapping co-ordinates and primer co-ordinates. It considers overlapping read-pairs with respect to primer-intervening sequence. Only when a variant is observed in both reads of a read-pair does the signal contribute to a tally of read-pairs containing or not containing the variant. A user-defined threshold informs the minimum number of, and proportion of, read-pairs a variant must be observed in for a 'call' to be made. ROVER also reports the depth of coverage across amplicons to facilitate the identificatio

Published

2014

29. FAVR (Filtering and Annotation of Variants that are Rare): methods to facilitate the analysis of rare germline genetic variants from massively parallel sequencing datasets

Author

Pope, BJ, Tu, N-D, Odefrey, F, Hammet, F, Bell, R, Tao, K, Tavtigian, SV, Goldgar, DE, Lonie, A, Southey, MC, Park, DJ, Pope, BJ, Tu, N-D, Odefrey, F, Hammet, F, Bell, R, Tao, K, Tavtigian, SV, Goldgar, DE, Lonie, A, Southey, MC, and Park, DJ

Abstract

BACKGROUND: Characterising genetic diversity through the analysis of massively parallel sequencing (MPS) data offers enormous potential to significantly improve our understanding of the genetic basis for observed phenotypes, including predisposition to and progression of complex human disease. Great challenges remain in resolving genetic variants that are genuine from the millions of artefactual signals. RESULTS: FAVR is a suite of new methods designed to work with commonly used MPS analysis pipelines to assist in the resolution of some of the issues related to the analysis of the vast amount of resulting data, with a focus on relatively rare genetic variants. To the best of our knowledge, no equivalent method has previously been described. The most important and novel aspect of FAVR is the use of signatures in comparator sequence alignment files during variant filtering, and annotation of variants potentially shared between individuals. The FAVR methods use these signatures to facilitate filtering of (i) platform and/or mapping-specific artefacts, (ii) common genetic variants, and, where relevant, (iii) artefacts derived from imbalanced paired-end sequencing, as well as annotation of genetic variants based on evidence of co-occurrence in individuals. We applied conventional variant calling applied to whole-exome sequencing datasets, produced using both SOLiD and TruSeq chemistries, with or without downstream processing by FAVR methods. We demonstrate a 3-fold smaller rare single nucleotide variant shortlist with no detected reduction in sensitivity. This analysis included Sanger sequencing of rare variant signals not evident in dbSNP131, assessment of known variant signal preservation, and comparison of observed and expected rare variant numbers across a range of first cousin pairs. The principles described herein were applied in our recent publication identifying XRCC2 as a new breast cancer risk gene and have been made publically available as a suite of software

Published

2013

30. Hi-Plex for high-throughput mutation screening: application to the breast cancer susceptibility gene PALB2

Author

Tu, N-D, Teo, ZL, Pope, BJ, Hammet, F, Mahmoodi, M, Tsimiklis, H, Sabbaghian, N, Tischkowitz, M, Foulkes, WD, Giles, GG, Hopper, JL, Southey, MC, Park, DJ, Tu, N-D, Teo, ZL, Pope, BJ, Hammet, F, Mahmoodi, M, Tsimiklis, H, Sabbaghian, N, Tischkowitz, M, Foulkes, WD, Giles, GG, Hopper, JL, Southey, MC, and Park, DJ

Abstract

BACKGROUND: Massively parallel sequencing (MPS) has revolutionised biomedical research and offers enormous capacity for clinical application. We previously reported Hi-Plex, a streamlined highly-multiplexed PCR-MPS approach, allowing a given library to be sequenced with both the Ion Torrent and TruSeq chemistries. Comparable sequencing efficiency was achieved using material derived from lymphoblastoid cell lines and formalin-fixed paraffin-embedded tumour. METHODS: Here, we report high-throughput application of Hi-Plex by performing blinded mutation screening of the coding regions of the breast cancer susceptibility gene PALB2 on a set of 95 blood-derived DNA samples that had previously been screened using Sanger sequencing and high-resolution melting curve analysis (n = 90), or genotyped by Taqman probe-based assays (n = 5). Hi-Plex libraries were prepared simultaneously using relatively inexpensive, readily available reagents in a simple half-day protocol followed by MPS on a single MiSeq run. RESULTS: We observed that 99.93% of amplicons were represented at ≥10X coverage. All 56 previously identified variant calls were detected and no false positive calls were assigned. Four additional variant calls were made and confirmed upon re-analysis of previous data or subsequent Sanger sequencing. CONCLUSIONS: These results support Hi-Plex as a powerful approach for rapid, cost-effective and accurate high-throughput mutation screening. They further demonstrate that Hi-Plex methods are suitable for and can meet the demands of high-throughput genetic testing in research and clinical settings.

Published

2013

31. A high-plex PCR approach for massively parallel sequencing

Author

Tu, N-D, Pope, BJ, Hammet, F, Southey, MC, Park, DJ, Tu, N-D, Pope, BJ, Hammet, F, Southey, MC, and Park, DJ

Abstract

Current methods for targeted massively parallel sequencing (MPS) have several drawbacks, including limited design flexibility, expense, and protocol complexity, which restrict their application to settings involving modest target size and requiring low cost and high throughput. To address this, we have developed Hi-Plex, a PCR-MPS strategy intended for high-throughput screening of multiple genomic target regions that integrates simple, automated primer design software to control product size. Featuring permissive thermocycling conditions and clamp bias reduction, our protocol is simple, cost- and time-effective, uses readily available reagents, does not require expensive instrumentation, and requires minimal optimization. In a 60-plex assay targeting the breast cancer predisposition genes PALB2 and XRCC2, we applied Hi-Plex to 100 ng LCL-derived DNA, and 100 ng and 25 ng FFPE tumor-derived DNA. Altogether, at least 86.94% of the human genome-mapped reads were on target, and 100% of targeted amplicons were represented within 25-fold of the mean. Using 25 ng FFPE-derived DNA, 95.14% of mapped reads were on-target and relative representation ranged from 10.1-fold lower to 5.8-fold higher than the mean. These results were obtained using only the initial automatically-designed primers present in equal concentration. Hi-Plex represents a powerful new approach for screening panels of genomic target regions.

Published

2013

32. Cross-platform compatibility of Hi-Plex, a streamlined approach for targeted massively parallel sequencing

Author

Tu, N-D, Pope, BJ, Hammet, F, Mahmoodi, M, Tsimiklis, H, Southey, MC, Park, DJ, Tu, N-D, Pope, BJ, Hammet, F, Mahmoodi, M, Tsimiklis, H, Southey, MC, and Park, DJ

Abstract

Although per-base sequencing costs have decreased during recent years, library preparation for targeted massively parallel sequencing remains constrained by high reagent cost, limited design flexibility, and protocol complexity. To address these limitations, we previously developed Hi-Plex, a polymerase chain reaction (PCR) massively parallel sequencing strategy for screening panels of genomic target regions. Here, we demonstrate that Hi-Plex applied with hybrid adapters can generate a library suitable for sequencing with both the Ion Torrent and the TruSeq chemistries and that adjusting primer concentrations improves coverage uniformity. These results expand Hi-Plex capabilities as an accurate, affordable, flexible, and rapid approach for various genetic screening applications.

Published

2013

33. Breast cancer risk and 6q22.33: Combined results from breast cancer association consortium and consortium of investigators on modifiers of brca1/2

Author

Kircchoff, T. (Tomas), Offit, K. (Kenneth), Gaudet, M.M. (Mia), Pharoah, P.D.P. (Paul), Easton, D.F. (Douglas), Antoniou, A.C. (Antonis), McGuffog, L. (Lesley), Humphreys, M.K. (Manjeet), Dunning, A.M. (Alison), Bojesen, S.E. (Stig), Nordestgaard, B.G. (Børge), Flyger, H. (Henrik), Kang, D. (Daehee), Yoo, K-Y. (Keun-Young), Noh, D-Y. (Dong-Young), Ahn, S.-H. (Sei-Hyun), Dörk, T. (Thilo), Schürmann, P. (Peter), Karstens, J.H. (Johann), Hillemanns, P. (Peter), Couch, F.J. (Fergus), Olson, J.E. (Janet), Vachon, C. (Celine), Cox, A. (Angela), Brock, I.W. (Ian), Elliott, G. (Graeme), Reed, M.W.R. (Malcolm), Burwinkel, B. (Barbara), Meindl, A. (Alfons), Brauch, H. (Hiltrud), Justenhoven, C. (Christina), Hamann, U. (Ute), Ko, Y-D. (Yon-Dschun), Fischer, H.-P., Brüning, T. (Thomas), Pesch, B. (Beate), Harth, V. (Volker), Rabstein, S. (Sylvia), Broeks, A. (Annegien), Schmidt, M.K. (Marjanka), Veer, L.J. (Laura) van 't, Braaf, L.M. (Linde), Johnson, N. (Nichola), Fletcher, O. (Olivia), Gibson, L.J. (Lorna), Peto, J. (Julian), Turnbull, C. (Clare), Seal, S. (Sheila), Renwick, A. (Anthony), Rahman, N. (Nazneen), Wu, P.-E. (Pei-Ei), Yu, J-C. (Jyh-Cherng), Hsiung, C.-N. (Chia-Ni), Shen, C-Y. (Chen-Yang), Southey, M.C. (Melissa), Hopper, J.L. (John), Hammet, F. (Fleur), Dorpe, T. (Thijs) van, Dieudonné, A.-S. (Anne-Sophie), Hatse, S. (Sigrid), Lambrechts, D. (Diether), Andrulis, I.L. (Irene), Bogdanova, N.V. (Natalia), Antonenkova, N.N. (Natalia), Rogov, J.I. (Juri), Prokofieva, D. (Daria), Bermisheva, M. (Marina), Khusnutdinova, E.K. (Elza), Asperen, C.J. (Christi) van, Tollenaar, R.A.E.M. (Rob), Hooning, M.J. (Maartje), Devilee, P. (Peter), Margolin, S. (Sara), Lindblom, A. (Annika), Milne, R.L. (Roger), Arias Pérez, J.I. (José Ignacio), Zamora, M.P. (Pilar), Benítez, J. (Javier), Severi, G. (Gianluca), Baglietto, L. (Laura), Giles, G.G. (Graham), Chenevix-Trench, G. (Georgia), Spurdle, A.B. (Amanda), Beesley, J. (Jonathan), Chen, X. (Xiaoqing), Holland, H. (Helene), Healey, S. (Sue), Wang-Gohrke, S. (Shan), Chang-Claude, J. (Jenny), Mannermaa, A. (Arto), Kosma, V-M. (Veli-Matti), Kauppinen, J. (Jaana), Kataja, V. (Vesa), Agnarsson, B.A. (Bjarni), Caligo, M.A. (Maria), Godwin, A.K. (Andrew), Nevanlinna, H. (Heli), Heikinen, T. (Tuomas), Fredericksen, Z. (Zachary), Lindor, N.M. (Noralane), Nathanson, K.L. (Katherine), Domchek, S.M. (Susan), Loman, N. (Niklas), Karlsson, P. (Per), Askmalm, M.S. (Marie), Melin, B. (Beatrice), Wachenfeldt, A. (Anna) von, Hogervorst, F.B.L. (Frans), Verheus, M. (Martijn), Rookus, M.A. (Matti), Seynaeve, C.M. (Caroline), Oldenburg, R.A. (Rogier), Ligtenberg, M.J. (Marjolijn), Ausems, M.G.E.M. (Margreet), Aalfs, C.M. (Cora), Gille, H.J.P. (Hans), Wijnen, J.T. (Juul), Gómez García, E.B. (Encarna), Peock, S. (Susan), Cook, M. (Margaret), Oliver, C.T. (Clare), Frost, D. (Debra), Luccarini, C. (Craig), Pichert, G. (Gabriella), Davidson, R. (Rosemarie), Eccles, D. (Diana), Ong, K.-R. (Kai-Ren), Cook, J. (Jackie), Douglas, F. (Fiona), Hodgson, S.V. (Shirley), Evans, D.G. (Gareth), Eeles, R. (Rosalind), Gold, B. (Bert), Wang, X. (Xianshu), Chu, C. (Carol), Kircchoff, T. (Tomas), Offit, K. (Kenneth), Gaudet, M.M. (Mia), Pharoah, P.D.P. (Paul), Easton, D.F. (Douglas), Antoniou, A.C. (Antonis), McGuffog, L. (Lesley), Humphreys, M.K. (Manjeet), Dunning, A.M. (Alison), Bojesen, S.E. (Stig), Nordestgaard, B.G. (Børge), Flyger, H. (Henrik), Kang, D. (Daehee), Yoo, K-Y. (Keun-Young), Noh, D-Y. (Dong-Young), Ahn, S.-H. (Sei-Hyun), Dörk, T. (Thilo), Schürmann, P. (Peter), Karstens, J.H. (Johann), Hillemanns, P. (Peter), Couch, F.J. (Fergus), Olson, J.E. (Janet), Vachon, C. (Celine), Cox, A. (Angela), Brock, I.W. (Ian), Elliott, G. (Graeme), Reed, M.W.R. (Malcolm), Burwinkel, B. (Barbara), Meindl, A. (Alfons), Brauch, H. (Hiltrud), Justenhoven, C. (Christina), Hamann, U. (Ute), Ko, Y-D. (Yon-Dschun), Fischer, H.-P., Brüning, T. (Thomas), Pesch, B. (Beate), Harth, V. (Volker), Rabstein, S. (Sylvia), Broeks, A. (Annegien), Schmidt, M.K. (Marjanka), Veer, L.J. (Laura) van 't, Braaf, L.M. (Linde), Johnson, N. (Nichola), Fletcher, O. (Olivia), Gibson, L.J. (Lorna), Peto, J. (Julian), Turnbull, C. (Clare), Seal, S. (Sheila), Renwick, A. (Anthony), Rahman, N. (Nazneen), Wu, P.-E. (Pei-Ei), Yu, J-C. (Jyh-Cherng), Hsiung, C.-N. (Chia-Ni), Shen, C-Y. (Chen-Yang), Southey, M.C. (Melissa), Hopper, J.L. (John), Hammet, F. (Fleur), Dorpe, T. (Thijs) van, Dieudonné, A.-S. (Anne-Sophie), Hatse, S. (Sigrid), Lambrechts, D. (Diether), Andrulis, I.L. (Irene), Bogdanova, N.V. (Natalia), Antonenkova, N.N. (Natalia), Rogov, J.I. (Juri), Prokofieva, D. (Daria), Bermisheva, M. (Marina), Khusnutdinova, E.K. (Elza), Asperen, C.J. (Christi) van, Tollenaar, R.A.E.M. (Rob), Hooning, M.J. (Maartje), Devilee, P. (Peter), Margolin, S. (Sara), Lindblom, A. (Annika), Milne, R.L. (Roger), Arias Pérez, J.I. (José Ignacio), Zamora, M.P. (Pilar), Benítez, J. (Javier), Severi, G. (Gianluca), Baglietto, L. (Laura), Giles, G.G. (Graham), Chenevix-Trench, G. (Georgia), Spurdle, A.B. (Amanda), Beesley, J. (Jonathan), Chen, X. (Xiaoqing), Holland, H. (Helene), Healey, S. (Sue), Wang-Gohrke, S. (Shan), Chang-Claude, J. (Jenny), Mannermaa, A. (Arto), Kosma, V-M. (Veli-Matti), Kauppinen, J. (Jaana), Kataja, V. (Vesa), Agnarsson, B.A. (Bjarni), Caligo, M.A. (Maria), Godwin, A.K. (Andrew), Nevanlinna, H. (Heli), Heikinen, T. (Tuomas), Fredericksen, Z. (Zachary), Lindor, N.M. (Noralane), Nathanson, K.L. (Katherine), Domchek, S.M. (Susan), Loman, N. (Niklas), Karlsson, P. (Per), Askmalm, M.S. (Marie), Melin, B. (Beatrice), Wachenfeldt, A. (Anna) von, Hogervorst, F.B.L. (Frans), Verheus, M. (Martijn), Rookus, M.A. (Matti), Seynaeve, C.M. (Caroline), Oldenburg, R.A. (Rogier), Ligtenberg, M.J. (Marjolijn), Ausems, M.G.E.M. (Margreet), Aalfs, C.M. (Cora), Gille, H.J.P. (Hans), Wijnen, J.T. (Juul), Gómez García, E.B. (Encarna), Peock, S. (Susan), Cook, M. (Margaret), Oliver, C.T. (Clare), Frost, D. (Debra), Luccarini, C. (Craig), Pichert, G. (Gabriella), Davidson, R. (Rosemarie), Eccles, D. (Diana), Ong, K.-R. (Kai-Ren), Cook, J. (Jackie), Douglas, F. (Fiona), Hodgson, S.V. (Shirley), Evans, D.G. (Gareth), Eeles, R. (Rosalind), Gold, B. (Bert), Wang, X. (Xianshu), and Chu, C. (Carol)

Abstract

Recently, a locus on chromosome 6q22.33 (rs2180341) was reported to be associated with increased breast cancer risk in the Ashkenazi Jewish (AJ) population, and this association was also observed in populations of non-AJ European ancestry. In the present study, we performed a large replication analysis of rs2180341 using data from 31,428 invasive breast cancer cases and 34,700 controls collected from 25 studies in the Breast Cancer Association Consortium (BCAC). In addition, we evaluated whether rs2180341 modifies breast cancer risk in 3,361 BRCA1 and 2,020 BRCA2 carriers from 11 centers in the Consortium of Investigators of Modifiers of BRCA1/2 (CIMBA). Based on the BCAC data from women of European ancestry, we found evidence for a weak association with breast cancer risk for rs2180341 (per-allele odds ratio (OR) = 1.03, 95% CI 1.00-1.06, p = 0.023). There was evidence for heterogeneity in the ORs among studies (I2 = 49.3%; p = <0.004). In CIMBA, we observed an inverse association with the minor allele of rs2180341 and breast cancer risk in BRCA1 mutation carriers (per-allele OR = 0.89, 95%CI 0.80-1.00, p = 0.048), indicating a potential protective effect of this allele. These data suggest that that 6q22.33 confers a weak effect on breast cancer risk.

Published

2012

34. Identification of new breast cancer predisposition genes via whole exome sequencing

Author

Southey, MC, Park, DJ, Lesueur, F, Odefrey, F, Nguyen-Dumont, T, Hammet, F, Neuhausen, SL, John, EM, Andrulis, IL, Chenevix-Trench, G, Baglietto, L, Le Calvez-Kelm, F, Pertesi, M, Lonie, A, Pope, B, Sinilnikova, O, Tsimiklis, H, Giles, GG, Hopper, JL, Tavtigian, SV, Goldgar, DE, Southey, MC, Park, DJ, Lesueur, F, Odefrey, F, Nguyen-Dumont, T, Hammet, F, Neuhausen, SL, John, EM, Andrulis, IL, Chenevix-Trench, G, Baglietto, L, Le Calvez-Kelm, F, Pertesi, M, Lonie, A, Pope, B, Sinilnikova, O, Tsimiklis, H, Giles, GG, Hopper, JL, Tavtigian, SV, and Goldgar, DE

Published

2012

35. Breast Cancer Risk and 6q22.33: Combined Results from Breast Cancer Association Consortium and Consortium of Investigators on Modifiers of BRCA1/2

Author

Prokunina-Olsson, L, Kirchhoff, T, Gaudet, MM, Antoniou, AC, McGuffog, L, Humphreys, MK, Dunning, AM, Bojesen, SE, Nordestgaard, BG, Flyger, H, Kang, D, Yoo, K-Y, Noh, D-Y, Ahn, S-H, Dork, T, Schuermann, P, Karstens, JH, Hillemanns, P, Couch, FJ, Olson, J, Vachon, C, Wang, X, Cox, A, Brock, I, Elliott, G, Reed, MWR, Burwinkel, B, Meindl, A, Brauch, H, Hamann, U, Ko, Y-D, Broeks, A, Schmidt, MK, Van 't Veer, LJ, Braaf, LM, Johnson, N, Fletcher, O, Gibson, L, Peto, J, Turnbull, C, Seal, S, Renwick, A, Rahman, N, Wu, P-E, Yu, J-C, Hsiung, C-N, Shen, C-Y, Southey, MC, Hopper, JL, Hammet, F, Van Dorpe, T, Dieudonne, A-S, Hatse, S, Lambrechts, D, Andrulis, IL, Bogdanova, N, Antonenkova, N, Rogov, JI, Prokofieva, D, Bermisheva, M, Khusnutdinova, E, van Asperen, CJ, Tollenaar, RAEM, Hooning, MJ, Devilee, P, Margolin, S, Lindblom, A, Milne, RL, Ignacio Arias, J, Pilar Zamora, M, Benitez, J, Severi, G, Baglietto, L, Giles, GG, Spurdle, AB, Beesley, J, Chen, X, Holland, H, Healey, S, Wang-Gohrke, S, Chang-Claude, J, Mannermaa, A, Kosma, V-M, Kauppinen, J, Kataja, V, Agnarsson, BA, Caligo, MA, Godwin, AK, Nevanlinna, H, Heikkinen, T, Fredericksen, Z, Lindor, N, Nathanson, KL, Domchek, SM, Loman, N, Karlsson, P, Askmalm, MS, Melin, B, von Wachenfeldt, A, Hogervorst, FBL, Verheus, M, Rookus, MA, Seynaeve, C, Oldenburg, RA, Ligtenberg, MJ, Ausems, MGEM, Aalfs, CM, Gille, HJP, Wijnen, JT, Garcia, EBG, Peock, S, Cook, M, Oliver, CT, Frost, D, Luccarini, C, Pichert, G, Davidson, R, Chu, C, Eccles, D, Ong, K-R, Cook, J, Douglas, F, Hodgson, S, Evans, DG, Eeles, R, Gold, B, Pharoah, PDP, Offit, K, Chenevix-Trench, G, Easton, DF, Prokunina-Olsson, L, Kirchhoff, T, Gaudet, MM, Antoniou, AC, McGuffog, L, Humphreys, MK, Dunning, AM, Bojesen, SE, Nordestgaard, BG, Flyger, H, Kang, D, Yoo, K-Y, Noh, D-Y, Ahn, S-H, Dork, T, Schuermann, P, Karstens, JH, Hillemanns, P, Couch, FJ, Olson, J, Vachon, C, Wang, X, Cox, A, Brock, I, Elliott, G, Reed, MWR, Burwinkel, B, Meindl, A, Brauch, H, Hamann, U, Ko, Y-D, Broeks, A, Schmidt, MK, Van 't Veer, LJ, Braaf, LM, Johnson, N, Fletcher, O, Gibson, L, Peto, J, Turnbull, C, Seal, S, Renwick, A, Rahman, N, Wu, P-E, Yu, J-C, Hsiung, C-N, Shen, C-Y, Southey, MC, Hopper, JL, Hammet, F, Van Dorpe, T, Dieudonne, A-S, Hatse, S, Lambrechts, D, Andrulis, IL, Bogdanova, N, Antonenkova, N, Rogov, JI, Prokofieva, D, Bermisheva, M, Khusnutdinova, E, van Asperen, CJ, Tollenaar, RAEM, Hooning, MJ, Devilee, P, Margolin, S, Lindblom, A, Milne, RL, Ignacio Arias, J, Pilar Zamora, M, Benitez, J, Severi, G, Baglietto, L, Giles, GG, Spurdle, AB, Beesley, J, Chen, X, Holland, H, Healey, S, Wang-Gohrke, S, Chang-Claude, J, Mannermaa, A, Kosma, V-M, Kauppinen, J, Kataja, V, Agnarsson, BA, Caligo, MA, Godwin, AK, Nevanlinna, H, Heikkinen, T, Fredericksen, Z, Lindor, N, Nathanson, KL, Domchek, SM, Loman, N, Karlsson, P, Askmalm, MS, Melin, B, von Wachenfeldt, A, Hogervorst, FBL, Verheus, M, Rookus, MA, Seynaeve, C, Oldenburg, RA, Ligtenberg, MJ, Ausems, MGEM, Aalfs, CM, Gille, HJP, Wijnen, JT, Garcia, EBG, Peock, S, Cook, M, Oliver, CT, Frost, D, Luccarini, C, Pichert, G, Davidson, R, Chu, C, Eccles, D, Ong, K-R, Cook, J, Douglas, F, Hodgson, S, Evans, DG, Eeles, R, Gold, B, Pharoah, PDP, Offit, K, Chenevix-Trench, G, and Easton, DF

Abstract

Recently, a locus on chromosome 6q22.33 (rs2180341) was reported to be associated with increased breast cancer risk in the Ashkenazi Jewish (AJ) population, and this association was also observed in populations of non-AJ European ancestry. In the present study, we performed a large replication analysis of rs2180341 using data from 31,428 invasive breast cancer cases and 34,700 controls collected from 25 studies in the Breast Cancer Association Consortium (BCAC). In addition, we evaluated whether rs2180341 modifies breast cancer risk in 3,361 BRCA1 and 2,020 BRCA2 carriers from 11 centers in the Consortium of Investigators of Modifiers of BRCA1/2 (CIMBA). Based on the BCAC data from women of European ancestry, we found evidence for a weak association with breast cancer risk for rs2180341 (per-allele odds ratio (OR) = 1.03, 95% CI 1.00-1.06, p = 0.023). There was evidence for heterogeneity in the ORs among studies (I(2) = 49.3%; p = <0.004). In CIMBA, we observed an inverse association with the minor allele of rs2180341 and breast cancer risk in BRCA1 mutation carriers (per-allele OR = 0.89, 95%CI 0.80-1.00, p = 0.048), indicating a potential protective effect of this allele. These data suggest that that 6q22.33 confers a weak effect on breast cancer risk.

Published

2012

36. Breast Cancer Risk and 6q22.33: Combined Results from Breast Cancer Association Consortium and Consortium of Investigators on Modifiers of BRCA1/2

Author

Kirchhoff, T, Gaudet, MM, Antoniou, AC, McGuffog, L, Humphreys, MK, Dunning, AM, Bojesen, SE, Nordestgaard, BG, Flyger, H, Kang, D, Yoo, KY, Noh, DY, Ahn, SH, Dork, T, Schurmann, P, Karstens, JH, Hillemanns, P, Couch, FJ, Olson, J, Vachon, C, Wang, XS, Cox, A, Brock, I, Elliott, G, Reed, MWR, Burwinkel, B, Meindl, A, Brauch, H, Hamann, U, Ko, YD, Broeks, A, Schmidt, Marjanka K, van 't Veer, LJ (Laura), Braaf, LM, Johnson, N, Fletcher, O, Gibson, L, Peto, J, Turnbull, C, Seal, S, Renwick, A, Rahman, N, Wu, PE, Yu, JC, Hsiung, CN, Shen, CY, Southey, MC, Hopper, JL, Hammet, F, Van Dorpe, T, Dieudonne, AS, Hatse, S, Lambrechts, D, Andrulis, IL, Bogdanova, N, Antonenkova, N, Rogov, JI, Prokofieva, D, Bermisheva, M, Khusnutdinova, E, van Asperen, CJ, Tollenaar, RAEM, Hooning, Maartje, Devilee, P, Margolin, S, Lindblom, A, Milne, RL, Arias, JI, Zamora, MP, Benitez, J, Severi, G, Baglietto, L, Giles, GG, Spurdle, AB, Beesley, J, Chen, XQ, Holland, H, Healey, S, Wang-Gohrke, S, Chang-Claude, J, Mannermaa, A, Kosma, VM, Kauppinen, J, Kataja, V, Agnarsson, BA, Caligo, MA, Godwin, AK, Nevanlinna, H, Heikkinen, T, Fredericksen, Z, Lindor, N, Nathanson, KL, Domchek, SM, Loman, N, Karlsson, P, Askmalm, MS, Melin, B, von Wachenfeldt, A, Hogervorst, FBL, Verheus, M, Rookus, MA, Seynaeve, Caroline, Oldenburg, Rogier, Ligtenberg, MJ, Ausems, MGEM, Aalfs, CM, Gille, HJP, Wijnen, JT, Garcia, EBG, Peock, S, Cook, M, Oliver, CT, Frost, D, Luccarini, C, Pichert, G, Davidson, R, Chu, C, Eccles, D, Ong, KR, Cook, J, Douglas, F, Hodgson, S, Evans, DG, Eeles, R, Gold, B, Pharoah, PDP, Offit, K, Chenevix-Trench, G, Easton, DF, Kirchhoff, T, Gaudet, MM, Antoniou, AC, McGuffog, L, Humphreys, MK, Dunning, AM, Bojesen, SE, Nordestgaard, BG, Flyger, H, Kang, D, Yoo, KY, Noh, DY, Ahn, SH, Dork, T, Schurmann, P, Karstens, JH, Hillemanns, P, Couch, FJ, Olson, J, Vachon, C, Wang, XS, Cox, A, Brock, I, Elliott, G, Reed, MWR, Burwinkel, B, Meindl, A, Brauch, H, Hamann, U, Ko, YD, Broeks, A, Schmidt, Marjanka K, van 't Veer, LJ (Laura), Braaf, LM, Johnson, N, Fletcher, O, Gibson, L, Peto, J, Turnbull, C, Seal, S, Renwick, A, Rahman, N, Wu, PE, Yu, JC, Hsiung, CN, Shen, CY, Southey, MC, Hopper, JL, Hammet, F, Van Dorpe, T, Dieudonne, AS, Hatse, S, Lambrechts, D, Andrulis, IL, Bogdanova, N, Antonenkova, N, Rogov, JI, Prokofieva, D, Bermisheva, M, Khusnutdinova, E, van Asperen, CJ, Tollenaar, RAEM, Hooning, Maartje, Devilee, P, Margolin, S, Lindblom, A, Milne, RL, Arias, JI, Zamora, MP, Benitez, J, Severi, G, Baglietto, L, Giles, GG, Spurdle, AB, Beesley, J, Chen, XQ, Holland, H, Healey, S, Wang-Gohrke, S, Chang-Claude, J, Mannermaa, A, Kosma, VM, Kauppinen, J, Kataja, V, Agnarsson, BA, Caligo, MA, Godwin, AK, Nevanlinna, H, Heikkinen, T, Fredericksen, Z, Lindor, N, Nathanson, KL, Domchek, SM, Loman, N, Karlsson, P, Askmalm, MS, Melin, B, von Wachenfeldt, A, Hogervorst, FBL, Verheus, M, Rookus, MA, Seynaeve, Caroline, Oldenburg, Rogier, Ligtenberg, MJ, Ausems, MGEM, Aalfs, CM, Gille, HJP, Wijnen, JT, Garcia, EBG, Peock, S, Cook, M, Oliver, CT, Frost, D, Luccarini, C, Pichert, G, Davidson, R, Chu, C, Eccles, D, Ong, KR, Cook, J, Douglas, F, Hodgson, S, Evans, DG, Eeles, R, Gold, B, Pharoah, PDP, Offit, K, Chenevix-Trench, G, and Easton, DF

Abstract

Recently, a locus on chromosome 6q22.33 (rs2180341) was reported to be associated with increased breast cancer risk in the Ashkenazi Jewish (AJ) population, and this association was also observed in populations of non-AJ European ancestry. In the present study, we performed a large replication analysis of rs2180341 using data from 31,428 invasive breast cancer cases and 34,700 controls collected from 25 studies in the Breast Cancer Association Consortium (BCAC). In addition, we evaluated whether rs2180341 modifies breast cancer risk in 3,361 BRCA1 and 2,020 BRCA2 carriers from 11 centers in the Consortium of Investigators of Modifiers of BRCA1/2 (CIMBA). Based on the BCAC data from women of European ancestry, we found evidence for a weak association with breast cancer risk for rs2180341 (per-allele odds ratio (OR) = 1.03, 95% CI 1.00-1.06, p = 0.023). There was evidence for heterogeneity in the ORs among studies (I-2 = 49.3%; p = <0.004). In CIMBA, we observed an inverse association with the minor allele of rs2180341 and breast cancer risk in BRCA1 mutation carriers (per-allele OR = 0.89, 95% CI 0.80-1.00, p = 0.048), indicating a potential protective effect of this allele. These data suggest that that 6q22.33 confers a weak effect on breast cancer risk.

Published

2012

37. Low penetrance breast cancer susceptibility loci are associated with specific breast tumor subtypes: findings from the Breast Cancer Association Consortium

Author

Broeks, A., Schmidt, M.K., Sherman, M.E., Couch, F.J., Hopper, J.L., Dite, G.S., Apicella, C., Smith, L.D., Hammet, F., Southey, M.C., Veer, L.J. van 't, Groot, R. de, Smit, V.T., Fasching, P.A., Beckmann, M.W., Jud, S., Ekici, A.B., Hartmann, A., Hein, A., Schulz-Wendtland, R., Burwinkel, B., Marme, F., Schneeweiss, A., Sinn, H.P., Sohn, C., Tchatchou, S., Bojesen, S.E., Nordestgaard, B.G., Flyger, H., Orsted, D.D., Kaur-Knudsen, D., Milne, R.L., Perez, J.I., Zamora, P., Rodriguez, P.M., Benitez, J., Brauch, H., Justenhoven, C., Ko, Y.D., Hamann, U., Fischer, H.P., Bruning, T., Pesch, B., Chang-Claude, J., Wang-Gohrke, S., Bremer, M., Karstens, J.H., Hillemanns, P., Dork, T., Nevanlinna, H.A., Heikkinen, T., Heikkila, P., Blomqvist, C., Aittomaki, K., Aaltonen, K., Lindblom, A., Margolin, S., Mannermaa, A., Kosma, V.M., Kauppinen, J.M., Kataja, V., Auvinen, P., Eskelinen, M., Soini, Y., Chenevix-Trench, G., Spurdle, A.B., Beesley, J., Chen, X., Holland, H., Lambrechts, D., Claes, B., Vandorpe, T., Neven, P., Wildiers, H., Flesch-Janys, D., Hein, R., Loning, T., Kosel, M., Fredericksen, Z.S., Wang, X., Giles, G.G., Baglietto, L., Severi, G., McLean, C., Haiman, C.A., Henderson, B.E., Marchand, L. le, Kolonel, L.N., Alnaes, G.G., Kristensen, V., Borresen-Dale, A.L., Hunter, D.J., Hankinson, S.E., Andrulis, I.L., Mulligan, A.M., O'Malley, F.P., Devilee, P., Huijts, P.E., Tollenaar, R.A.E.M., Asperen, C.J. van, Broeks, A., Schmidt, M.K., Sherman, M.E., Couch, F.J., Hopper, J.L., Dite, G.S., Apicella, C., Smith, L.D., Hammet, F., Southey, M.C., Veer, L.J. van 't, Groot, R. de, Smit, V.T., Fasching, P.A., Beckmann, M.W., Jud, S., Ekici, A.B., Hartmann, A., Hein, A., Schulz-Wendtland, R., Burwinkel, B., Marme, F., Schneeweiss, A., Sinn, H.P., Sohn, C., Tchatchou, S., Bojesen, S.E., Nordestgaard, B.G., Flyger, H., Orsted, D.D., Kaur-Knudsen, D., Milne, R.L., Perez, J.I., Zamora, P., Rodriguez, P.M., Benitez, J., Brauch, H., Justenhoven, C., Ko, Y.D., Hamann, U., Fischer, H.P., Bruning, T., Pesch, B., Chang-Claude, J., Wang-Gohrke, S., Bremer, M., Karstens, J.H., Hillemanns, P., Dork, T., Nevanlinna, H.A., Heikkinen, T., Heikkila, P., Blomqvist, C., Aittomaki, K., Aaltonen, K., Lindblom, A., Margolin, S., Mannermaa, A., Kosma, V.M., Kauppinen, J.M., Kataja, V., Auvinen, P., Eskelinen, M., Soini, Y., Chenevix-Trench, G., Spurdle, A.B., Beesley, J., Chen, X., Holland, H., Lambrechts, D., Claes, B., Vandorpe, T., Neven, P., Wildiers, H., Flesch-Janys, D., Hein, R., Loning, T., Kosel, M., Fredericksen, Z.S., Wang, X., Giles, G.G., Baglietto, L., Severi, G., McLean, C., Haiman, C.A., Henderson, B.E., Marchand, L. le, Kolonel, L.N., Alnaes, G.G., Kristensen, V., Borresen-Dale, A.L., Hunter, D.J., Hankinson, S.E., Andrulis, I.L., Mulligan, A.M., O'Malley, F.P., Devilee, P., Huijts, P.E., Tollenaar, R.A.E.M., and Asperen, C.J. van

Abstract

Contains fulltext : 96071.pdf (publisher's version ) (Closed access), Breast cancers demonstrate substantial biological, clinical and etiological heterogeneity. We investigated breast cancer risk associations of eight susceptibility loci identified in GWAS and two putative susceptibility loci in candidate genes in relation to specific breast tumor subtypes. Subtypes were defined by five markers (ER, PR, HER2, CK5/6, EGFR) and other pathological and clinical features. Analyses included up to 30 040 invasive breast cancer cases and 53 692 controls from 31 studies within the Breast Cancer Association Consortium. We confirmed previous reports of stronger associations with ER+ than ER- tumors for six of the eight loci identified in GWAS: rs2981582 (10q26) (P-heterogeneity = 6.1 x 10(-18)), rs3803662 (16q12) (P = 3.7 x 10(-5)), rs13281615 (8q24) (P = 0.002), rs13387042 (2q35) (P = 0.006), rs4973768 (3p24) (P = 0.003) and rs6504950 (17q23) (P = 0.002). The two candidate loci, CASP8 (rs1045485, rs17468277) and TGFB1 (rs1982073), were most strongly related with the risk of PR negative tumors (P = 5.1 x 10(-6) and P = 4.1 x 10(-4), respectively), as previously suggested. Four of the eight loci identified in GWAS were associated with triple negative tumors (P

Published

2011

38. Distinct molecular pathogeneses of early-onset breast cancers in BRCA1 and BRCA2 mutation carriers: a population-based study

Author

Armes JE, Giles GG, Hopper JL, Venter DJ, Trute L, White D, Southey MC, Hammet F, Tesoriero A, Hutchins AM, Dite GS, and McCredie MR

Subjects

analysis, Etiology - Endogenous Factors in the Origin and Cause of Cancer, Loss of Heterozygosity, Breast Neoplasms, Genetics,Population, cancer, Humans, Family, genetics, Women, Neoplasm Invasiveness, Age of Onset, breast, Research Support,Non-U.S.Gov't, BRCA2 Protein, BRCA1 Protein, Research, Australia, Immunohistochemistry, Neoplasm Proteins, Phenotype, Genetics, Population, Mutation, pathology, Cancer Type - Breast Cancer, Female, history, physiopathology, Tumor Suppressor Protein p53, Carcinoma in Situ, Transcription Factors

Abstract

Breast cancers arising in women with and without a germline mutation in the BRCA1 or BRCA2 gene display different histological features, which suggests unique mechanisms of molecular pathogenesis: We used a molecular pathological analysis to define the genetic abnormalities relevant to these specific pathogeneses. Tumor material was studied from 40 women with breast cancer diagnosed before 40 years of age, sampled from a population-based study and stratified by BRCA1 and BRCA2 germline mutation status. Cases were not selected for family history or ethnic origin, and none were known to be genetically related. Thus, germline mutation itself is likely to impact on the molecular pathogenesis of these tumors, with no substantial influence due to modifying genetic or environmental factors. Breast cancers occurring in BRCA1 mutation carriers had significantly higher levels of p53 expression, including the preinvasive (carcinoma in situ) stage of disease, compared with cancers occurring in BRCA2 mutation carriers or women with no detectable germline mutation. These cancers also had a higher proliferation rate as measured by Ki-67 antibody. Expression of the prognostic factors c-erbB-2, cyclin D1, and estrogen receptor was significantly less common in BRCA1 mutation carriers. Lower levels of cyclin D1 were also found in cancers from BRCA2 mutation carriers compared with non-mutation carriers. Direct p53 mutation analysis revealed mutations in 18% of all of the early-onset breast cancers within the study and included rare insertion and deletional mutations in cancers from BRCA1 mutation carriers. Our data indicate that a BRCA1 breast cancer phenotype may be recognized by an exceptionally high proliferation rate and early and frequent p53 overexpression but infrequent selection for overexpression of several other prognostic factor proteins known to be involved in breast oncogenesis. In contrast, breast cancers arising in BRCA2 mutation carriers have a more heterogeneous phenotypic profile.

Published

1999

39. Genetic aberrations detected by comparative genomic hybridisation in vulvar cancers

Author

Allen, D, Hutchins, AM, Hammet, F, White, DJ, Scurry, J, Tabrizi, S, Garland, SM, Armes, JE, Allen, D, Hutchins, AM, Hammet, F, White, DJ, Scurry, J, Tabrizi, S, Garland, SM, and Armes, JE

Abstract

Squamous cell carcinoma of the vulva is a disease of significant clinical importance, which arises in the presence or absence of human papillomavirus. We used comparative genomic hybridisation to document non-random chromosomal gains and losses within human papillomavirus positive and negative vulvar cancers. Gain of 3q was significantly more common in human papillomavirus-positive cancers compared to human papillomavirus-negative cancers. The smallest area of gain was 3q22-25, a chromosome region which is frequently gained in other human papillomavirus-related cancers. Chromosome 8q was more commonly gained in human papillomavirus-negative compared to human papillomavirus-positive cancers. 8q21 was the smallest region of gain, which has been identified in other, non-human papillomavirus-related cancers. Chromosome arms 3p and 11q were lost in both categories of vulvar cancer. This study has demonstrated chromosome locations important in the development of vulvar squamous cell carcinoma. Additionally, taken together with previous studies of human papillomavirus-positive cancers of other anogenital sites, the data indicate that one or more oncogenes important in the development and progression of human papillomavirus-induced carcinomas are located on 3q. The different genetic changes seen in human papillomavirus-positive and negative vulvar squamous cell carcinomas support the clinicopathological data indicating that these are different cancer types.

Published

2002

40. Genetic aberrations detected by comparative genomic hybridisation in vulvar cancers

Author

Allen, D G, primary, Hutchins, A-M, additional, Hammet, F, additional, White, D J, additional, Scurry, J P, additional, Tabrizi, S N, additional, Garland, S M, additional, and Armes, J E, additional

Published

2002

41. Down the Rat-Hole

Author

HAMMET, F. S., primary

Published

1949

42. Hi-Plex targeted sequencing is effective using DNA derived from archival dried blood spots.

Author

Nguyen-Dumont, T., Mahmoodi, M., Hammet, F., Tran, T., Tsimiklis, H., Kathleen Cuningham Foundation Consortium for Research into Familial Breast Cancer (kConFab), null, Giles, G.G., Hopper, J.L., Australian Breast Cancer Family Registry, null, Southey, M.C., and Park, D.J.

Subjects

*GENE targeting, *NUCLEOTIDE sequencing, *DNA derivatives, *DRIED blood spot testing, *GENETIC epidemiology, *GENETIC testing, *BREAST cancer

Abstract

Many genetic epidemiology resources have collected dried blood spots (predominantly as Guthrie Cards) as an economical and efficient means of archiving sources of DNA, conferring great value to genetic screening methods that are compatible with this medium. We applied Hi-Plex to screen the breast cancer predisposition gene PALB2 in 93 Guthrie Card-derived DNA specimens previously characterized for PALB2 genetic variants via DNA derived from lymphoblastoid cell lines, whole blood, and buffy coat. Of the 93 archival Guthrie Card-derived DNAs, 92 (99%) were processed successfully and sequenced using approximately half of a MiSeq run. From these 92 DNAs, all 59 known variants were detected and no false-positive variant calls were yielded. Fully 98.13% of amplicons (5417/5520) were represented within 15-fold of the median coverage (2786 reads), and 99.98% of amplicons (5519/5520) were represented at a depth of 10 read-pairs or greater. With Hi-Plex, we show for the first time that a High-Plex amplicon-based massively parallel sequencing (MPS) system can be applied effectively to DNA prepared from dried blood spot archival specimens and, as such, can dramatically increase the scopes of both method and resource. [ABSTRACT FROM AUTHOR]

Published

2015

43. Maternal SARS-CoV-2 exposure alters infant DNA methylation.

Author

Hill RA, Gibbons A, Han U, Suwakulsiri W, Taseska A, Hammet F, Southey M, Malhotra A, Fahey M, Palmer KR, Hunt RW, Lim I, Newman-Morris V, and Sundram S

Abstract

Background: Infection during pregnancy can increase the risk of neurodevelopmental disorders in offspring. The impact of maternal SARS-CoV-2 infection on infant neurodevelopment is poorly understood. The maternal immune response to infection may be mimicked in rodent models of maternal immune activation which recapitulate altered neurodevelopment and behavioural disturbances in the offspring. In these models, epigenetic mechanisms, in particular DNA methylation, are one pathway through which this risk is conferred in utero to offspring. We hypothesised that in utero exposure to SARS-CoV-2 in humans may alter infant DNA methylation, particularly in genes associated with neurodevelopment. We aimed to test this hypothesis in a pilot sample of children in Victoria, Australia, who were exposed in utero to SARS-CoV-2., Methods: DNA was extracted from buccal swab specimens from (n = 4) SARS-CoV-2 in utero exposed and (n = 4) non-exposed infants and methylation status assessed across 850,000 methylation sites using an Illumina EPIC BeadChip. We also conducted an exploratory enrichment analysis using Gene Ontology annotations., Results: 1962 hypermethylated CpG sites were identified with an unadjusted p-value of 0.05, where 1133 CpGs mapped to 959 unique protein coding genes, and 716 hypomethylated CpG sites mapped to 559 unique protein coding genes in SARS-CoV-2 exposed infants compared to non-exposed. One differentially methylated position (cg06758191), located in the gene body of AFAP1 that was hypomethylated in the SARS-CoV-2 exposed cohort was significant after correction for multiple testing (FDR-adjusted p-value <0.00083). Two significant differentially methylated regions were identified; a hypomethylated intergenic region located in chromosome 6p proximal to the genes ZP57 and HLA-F (fwer <0.004), and a hypomethylated region in the promoter and body of the gene GAREM2 (fwer <0.036). Gene network enrichment analysis revealed differential methylation in genes corresponding to pathways relevant to neurodevelopment, including the ERBB pathway., Conclusion: These pilot data suggest that exposure to SARS-CoV-2 in utero differentially alters methylation of genes in pathways that play a role in human neurodevelopment., Competing Interests: The authors declare no conflicts of interest., (© 2022 Published by Elsevier Inc.)

Published

2023

44. Population-based estimates of breast cancer risk for carriers of pathogenic variants identified by gene-panel testing.

Author

Southey MC, Dowty JG, Riaz M, Steen JA, Renault AL, Tucker K, Kirk J, James P, Winship I, Pachter N, Poplawski N, Grist S, Park DJ, Pope BJ, Mahmood K, Hammet F, Mahmoodi M, Tsimiklis H, Theys D, Rewse A, Willis A, Morrow A, Speechly C, Harris R, Sebra R, Schadt E, Lacaze P, McNeil JJ, Giles GG, Milne RL, Hopper JL, and Nguyen-Dumont T

Abstract

Population-based estimates of breast cancer risk for carriers of pathogenic variants identified by gene-panel testing are urgently required. Most prior research has been based on women selected for high-risk features and more data is needed to make inference about breast cancer risk for women unselected for family history, an important consideration of population screening. We tested 1464 women diagnosed with breast cancer and 862 age-matched controls participating in the Australian Breast Cancer Family Study (ABCFS), and 6549 healthy, older Australian women enroled in the ASPirin in Reducing Events in the Elderly (ASPREE) study for rare germline variants using a 24-gene-panel. Odds ratios (ORs) were estimated using unconditional logistic regression adjusted for age and other potential confounders. We identified pathogenic variants in 11.1% of the ABCFS cases, 3.7% of the ABCFS controls and 2.2% of the ASPREE (control) participants. The estimated breast cancer OR [95% confidence interval] was 5.3 [2.1-16.2] for BRCA1, 4.0 [1.9-9.1] for BRCA2, 3.4 [1.4-8.4] for ATM and 4.3 [1.0-17.0] for PALB2. Our findings provide a population-based perspective to gene-panel testing for breast cancer predisposition and opportunities to improve predictors for identifying women who carry pathogenic variants in breast cancer predisposition genes., (© 2021. The Author(s).)

Published

2021

45. Repeatability of methylation measures using a QIAseq targeted methyl panel and comparison with the Illumina HumanMethylation450 assay.

Author

Yu C, Dugué PA, Dowty JG, Hammet F, Joo JE, Wong EM, Hosseinpour M, Giles GG, Hopper JL, Nguyen-Dumont T, MacInnis RJ, and Southey MC

Subjects

Genomics, Oligonucleotide Array Sequence Analysis, Paraffin Embedding, DNA Methylation, High-Throughput Nucleotide Sequencing

Abstract

Objective: In previous studies using Illumina Infinium methylation arrays, we have identified DNA methylation marks associated with cancer predisposition and progression. In the present study, we have sought to find appropriate technology to both technically validate our data and expand our understanding of DNA methylation in these genomic regions. Here, we aimed to assess the repeatability of methylation measures made using QIAseq targeted methyl panel and to compare them with those obtained from the Illumina HumanMethylation450 (HM450K) assay. We included in the analysis high molecular weight DNA extracted from whole blood (WB) and DNA extracted from formalin-fixed paraffin-embedded tissues (FFPE)., Results: The repeatability of QIAseq-methylation measures was assessed at 40 CpGs, using the Intraclass Correlation Coefficient (ICC). The mean ICCs and 95% confidence intervals (CI) were 0.72 (0.62-0.81), 0.59 (0.47-0.71) and 0.80 (0.73-0.88) for WB, FFPE and both sample types combined, respectively. For technical replicates measured using QIAseq and HM450K, the mean ICCs (95% CI) were 0.53 (0.39-0.68), 0.43 (0.31-0.56) and 0.70 (0.59-0.80), respectively. Bland-Altman plots indicated good agreement between QIAseq and HM450K measurements. These results demonstrate that the QIAseq targeted methyl panel produces reliable and reproducible methylation measurements across the 40 CpGs that were examined., (© 2021. The Author(s).)

Published

2021

46. Rare Germline Pathogenic Variants Identified by Multigene Panel Testing and the Risk of Aggressive Prostate Cancer.

Author

Nguyen-Dumont T, Dowty JG, MacInnis RJ, Steen JA, Riaz M, Dugué PA, Renault AL, Hammet F, Mahmoodi M, Theys D, Tsimiklis H, Severi G, Bolton D, Lacaze P, Sebra R, Schadt E, McNeil J, Giles GG, Milne RL, and Southey MC

Abstract

While gene panel sequencing is becoming widely used for cancer risk prediction, its clinical utility with respect to predicting aggressive prostate cancer (PrCa) is limited by our current understanding of the genetic risk factors associated with predisposition to this potentially lethal disease phenotype. This study included 837 men diagnosed with aggressive PrCa and 7261 controls (unaffected men and men who did not meet criteria for aggressive PrCa). Rare germline pathogenic variants (including likely pathogenic variants) were identified by targeted sequencing of 26 known or putative cancer predisposition genes. We found that 85 (10%) men with aggressive PrCa and 265 (4%) controls carried a pathogenic variant ( p < 0.0001). Aggressive PrCa odds ratios (ORs) were estimated using unconditional logistic regression. Increased risk of aggressive PrCa (OR (95% confidence interval)) was identified for pathogenic variants in BRCA2 (5.8 (2.7-12.4)), BRCA1 (5.5 (1.8-16.6)), and ATM (3.8 (1.6-9.1)). Our study provides further evidence that rare germline pathogenic variants in these genes are associated with increased risk of this aggressive, clinically relevant subset of PrCa. These rare genetic variants could be incorporated into risk prediction models to improve their precision to identify men at highest risk of aggressive prostate cancer and be used to identify men with newly diagnosed prostate cancer who require urgent treatment.

Published

2021

47. Population-Based Estimates of the Age-Specific Cumulative Risk of Breast Cancer for Pathogenic Variants in CHEK2 : Findings from the Australian Breast Cancer Family Registry.

Author

Nguyen-Dumont T, Dowty JG, Steen JA, Renault AL, Hammet F, Mahmoodi M, Theys D, Rewse A, Tsimiklis H, Winship IM, Giles GG, Milne RL, Hopper JL, and Southey MC

Abstract

Case-control studies of breast cancer have consistently shown that pathogenic variants in CHEK2 are associated with about a 3-fold increased risk of breast cancer. Information about the recurrent protein-truncating variant CHEK2 c.1100delC dominates this estimate. There have been no formal estimates of age-specific cumulative risk of breast cancer for all CHEK2 pathogenic (including likely pathogenic) variants combined. We conducted a population-based case-control-family study of pathogenic CHEK2 variants (26 families, 1071 relatives) and estimated the age-specific cumulative risk of breast cancer using segregation analysis. The estimated hazard ratio for carriers of pathogenic CHEK2 variants (combined) was 4.9 (95% CI 2.5-9.5) relative to non-carriers. The HR for carriers of the CHEK2 c.1100delC variant was estimated to be 3.5 (95% CI 1.02-11.6) and the HR for carriers of all other CHEK2 variants combined was estimated to be 5.7 (95% CI 2.5-12.9). The age-specific cumulative risk of breast cancer was estimated to be 18% (95% CI 11-30%) and 33% (95% CI 21-48%) to age 60 and 80 years, respectively. These findings provide important information for the clinical management of breast cancer risk for women carrying pathogenic variants in CHEK2 .

Published

2021

48. VTRNA2-1 : Genetic Variation, Heritable Methylation and Disease Association.

Author

Dugué PA, Yu C, McKay T, Wong EM, Joo JE, Tsimiklis H, Hammet F, Mahmoodi M, Theys D, kConFab, Hopper JL, Giles GG, Milne RL, Steen JA, Dowty JG, Nguyen-Dumont T, and Southey MC

Subjects

Aged, Breast Neoplasms genetics, Case-Control Studies, CpG Islands genetics, Female, Genome-Wide Association Study methods, Humans, Male, Middle Aged, Prospective Studies, Quantitative Trait Loci genetics, DNA Methylation genetics, MicroRNAs genetics, Polymorphism, Single Nucleotide genetics

Abstract

VTRNA2-1 is a metastable epiallele with accumulating evidence that methylation at this region is heritable, modifiable and associated with disease including risk and progression of cancer. This study investigated the influence of genetic variation and other factors such as age and adult lifestyle on blood DNA methylation in this region. We first sequenced the VTRNA2-1 gene region in multiple-case breast cancer families in which VTRNA2-1 methylation was identified as heritable and associated with breast cancer risk. Methylation quantitative trait loci (mQTL) were investigated using a prospective cohort study (4500 participants with genotyping and methylation data). The cis -mQTL analysis (334 variants ± 50 kb of the most heritable CpG site) identified 43 variants associated with VTRNA2-1 methylation ( p < 1.5 × 10 -4 ); however, these explained little of the methylation variation (R 2 < 0.5% for each of these variants). No genetic variants elsewhere in the genome were found to strongly influence VTRNA2-1 methylation. SNP-based heritability estimates were consistent with the mQTL findings (h 2 = 0, 95%CI: -0.14 to 0.14). We found no evidence that age, sex, country of birth, smoking, body mass index, alcohol consumption or diet influenced blood DNA methylation at VTRNA2-1 . Genetic factors and adult lifestyle play a minimal role in explaining methylation variability at the heritable VTRNA2-1 cluster.

Published

2021

49. Rare germline genetic variants and risk of aggressive prostate cancer.

Author

Nguyen-Dumont T, MacInnis RJ, Steen JA, Theys D, Tsimiklis H, Hammet F, Mahmoodi M, Pope BJ, Park DJ, Mahmood K, Severi G, Bolton D, Milne RL, Giles GG, and Southey MC

Subjects

Aged, BRCA2 Protein genetics, Cohort Studies, Genetic Predisposition to Disease genetics, Genetic Testing methods, Genotype, Humans, Male, Middle Aged, Prostate pathology, Prostate-Specific Antigen genetics, Prostatic Neoplasms pathology, Germ Cells metabolism, Germ-Line Mutation genetics, Prostatic Neoplasms genetics

Abstract

Few genetic risk factors have been demonstrated to be specifically associated with aggressive prostate cancer (PrCa). Here, we report a case-case study of PrCa comparing the prevalence of germline pathogenic/likely pathogenic (P/LP) genetic variants in 787 men with aggressive disease and 769 with nonaggressive disease. Overall, we observed P/LP variants in 11.4% of men with aggressive PrCa and 9.8% of men with nonaggressive PrCa (two-tailed Fisher's exact tests, P = .28). The proportion of BRCA2 and ATM P/LP variant carriers in men with aggressive PrCa exceeded that observed in men with nonaggressive PrCa; 18/787 carriers (2.3%) and 4/769 carriers (0.5%), P = .004, and 14/787 carriers (0.02%) and 5/769 carriers (0.01%), P = .06, respectively. Our findings contribute to the extensive international effort to interpret the genetic variation identified in genes included on gene-panel tests, for which there is currently an insufficient evidence-base for clinical translation in the context of PrCa risk., (© 2020 UICC.)

Published

2020

50. Genetic testing in Poland and Ukraine: should comprehensive germline testing of BRCA1 and BRCA2 be recommended for women with breast and ovarian cancer?

Author

Nguyen-Dumont T, Karpinski P, Sasiadek MM, Akopyan H, Steen JA, Theys D, Hammet F, Tsimiklis H, Park DJ, Pope BJ, Slezak R, Stembalska A, Pesz K, Kitsera N, Siekierzynska A, Southey MC, and Myszka A

Subjects

Breast Neoplasms epidemiology, Breast Neoplasms pathology, Female, High-Throughput Nucleotide Sequencing methods, Humans, Ovarian Neoplasms epidemiology, Ovarian Neoplasms pathology, Poland epidemiology, Ukraine epidemiology, BRCA1 Protein genetics, BRCA2 Protein genetics, Breast Neoplasms genetics, Genetic Predisposition to Disease, Genetic Testing methods, Germ-Line Mutation, Ovarian Neoplasms genetics

Abstract

Purpose: To characterize the spectrum of BRCA1 and BRCA2 pathogenic germline variants in women from south-west Poland and west Ukraine affected with breast or ovarian cancer. Testing in women at high risk of breast and ovarian cancer in these regions is currently mainly limited to founder mutations., Methods: Unrelated women affected with breast and/or ovarian cancer from Poland (n = 337) and Ukraine (n = 123) were screened by targeted sequencing. Excluded from targeted sequencing were 34 Polish women who had previously been identified as carrying a founder mutation in BRCA1. No prior testing had been conducted among the Ukrainian women. Thus, this study screened BRCA1 and BRCA2 in the germline DNA of 426 women in total., Results: We identified 31 and 18 women as carriers of pathogenic/likely pathogenic (P/LP) genetic variants in BRCA1 and BRCA2, respectively. We observed five BRCA1 and eight BRCA2 P/LP variants (13/337, 3.9%) in the Polish women. Combined with the 34/337 (10.1%) founder variants identified prior to this study, the overall P/LP variant frequency in the Polish women was thus 14% (47/337). Among the Ukrainian women, 16/123 (13%) women were identified as carrying a founder mutation and 20/123 (16.3%) were found to carry non-founder P/LP variants (10 in BRCA1 and 10 in BRCA2)., Conclusions: These results indicate that genetic testing in women at high risk of breast and ovarian cancer in Poland and Ukraine should not be limited to founder mutations. Extended testing will enhance risk stratification and management for these women and their families.

Published

2020