Clinical Pathology - Research Publications

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Author: Southey, Melissa × Start date: 2005 × End date: 2009 ×

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    Heterogeneity of breast cancer associations with five susceptibility loci by clinical and pathological characteristics
    Garcia-Closas, M ; Hall, P ; Nevanlinna, H ; Pooley, K ; Morrison, J ; Richesson, DA ; Bojesen, SE ; Nordestgaard, BG ; Axelsson, CK ; Arias, JI ; Milne, RL ; Ribas, G ; Gonzalez-Neira, A ; Benitez, J ; Zamora, P ; Brauch, H ; Justenhoven, C ; Hamann, U ; Ko, Y-D ; Bruening, T ; Haas, S ; Doerk, T ; Schuermann, P ; Hillemanns, P ; Bogdanova, N ; Bremer, M ; Karstens, JH ; Fagerholm, R ; Aaltonen, K ; Aittomaki, K ; Von Smitten, K ; Blomqvist, C ; Mannermaa, A ; Uusitupa, M ; Eskelinen, M ; Tengstrom, M ; Kosma, V-M ; Kataja, V ; Chenevix-Trench, G ; Spurdle, AB ; Beesley, J ; Chen, X ; Devilee, P ; Van Asperen, CJ ; Jacobi, CE ; Tollenaar, RAEM ; Huijts, PEA ; Klijn, JGM ; Chang-Claude, J ; Kropp, S ; Slanger, T ; Flesch-Janys, D ; Mutschelknauss, E ; Salazar, R ; Wang-Gohrke, S ; Couch, F ; Goode, EL ; Olson, JE ; Vachon, C ; Fredericksen, ZS ; Giles, GG ; Baglietto, L ; Severi, G ; Hopper, JL ; English, DR ; Southey, MC ; Haiman, CA ; Henderson, BE ; Kolonel, LN ; Le Marchand, L ; Stram, DO ; Hunter, DJ ; Hankinson, SE ; Cox, DG ; Tamimi, R ; Kraft, P ; Sherman, ME ; Chanock, SJ ; Lissowska, J ; Brinton, LA ; Peplonska, B ; Klijn, JGM ; Hooning, MJ ; Meijers-Heijboer, H ; Collee, JM ; Van den Ouweland, A ; Uitterlinden, AG ; Liu, J ; Lin, LY ; Yuqing, L ; Humphreys, K ; Czene, K ; Cox, A ; Balasubramanian, SP ; Cross, SS ; Reed, MWR ; Blows, F ; Driver, K ; Dunning, A ; Tyrer, J ; Ponder, BAJ ; Sangrajrang, S ; Brennan, P ; Mckay, J ; Odefrey, F ; Gabrieau, V ; Sigurdson, A ; Doody, M ; Struewing, JP ; Alexander, B ; Easton, DF ; Pharoah, PD ; Leal, SM (PUBLIC LIBRARY SCIENCE, 2008-04)
    A three-stage genome-wide association study recently identified single nucleotide polymorphisms (SNPs) in five loci (fibroblast growth receptor 2 (FGFR2), trinucleotide repeat containing 9 (TNRC9), mitogen-activated protein kinase 3 K1 (MAP3K1), 8q24, and lymphocyte-specific protein 1 (LSP1)) associated with breast cancer risk. We investigated whether the associations between these SNPs and breast cancer risk varied by clinically important tumor characteristics in up to 23,039 invasive breast cancer cases and 26,273 controls from 20 studies. We also evaluated their influence on overall survival in 13,527 cases from 13 studies. All participants were of European or Asian origin. rs2981582 in FGFR2 was more strongly related to ER-positive (per-allele OR (95%CI) = 1.31 (1.27-1.36)) than ER-negative (1.08 (1.03-1.14)) disease (P for heterogeneity = 10(-13)). This SNP was also more strongly related to PR-positive, low grade and node positive tumors (P = 10(-5), 10(-8), 0.013, respectively). The association for rs13281615 in 8q24 was stronger for ER-positive, PR-positive, and low grade tumors (P = 0.001, 0.011 and 10(-4), respectively). The differences in the associations between SNPs in FGFR2 and 8q24 and risk by ER and grade remained significant after permutation adjustment for multiple comparisons and after adjustment for other tumor characteristics. Three SNPs (rs2981582, rs3803662, and rs889312) showed weak but significant associations with ER-negative disease, the strongest association being for rs3803662 in TNRC9 (1.14 (1.09-1.21)). rs13281615 in 8q24 was associated with an improvement in survival after diagnosis (per-allele HR = 0.90 (0.83-0.97). The association was attenuated and non-significant after adjusting for known prognostic factors. Our findings show that common genetic variants influence the pathological subtype of breast cancer and provide further support for the hypothesis that ER-positive and ER-negative disease are biologically distinct. Understanding the etiologic heterogeneity of breast cancer may ultimately result in improvements in prevention, early detection, and treatment.
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    An international initiative to identify genetic modifiers of cancer risk in BRCA1 and BRCA2 mutation carriers:: the Consortium of Investigators of Modifiers of BRCA1 and BRCA2(CIMBA)
    Chenevix-Trench, G ; Milne, RL ; Antoniou, AC ; Couch, FJ ; Easton, DF ; Goldgar, DE (BIOMED CENTRAL LTD, 2007)
    BRCA1 and BRCA2 mutations exhibit variable penetrance that is likely to be accounted for, in part, by other genetic factors among carriers. However, studies aimed at identifying these factors have been limited in size and statistical power, and have yet to identify any convincingly validated modifiers of the BRCA1 and BRCA2 phenotype. To generate sufficient statistical power to identify modifier genes, the Consortium of Investigators of Modifiers of BRCA1 and BRCA2 (CIMBA) has been established. CIMBA contains about 30 affiliated groups who together have collected DNA and clinical data from approximately 10,000 BRCA1 and 5,000 BRCA2 mutation carriers. Initial efforts by CIMBA to identify modifiers of breast cancer risk for BRCA1 and BRCA2 mutation carriers have focused on validation of common genetic variants previously associated with risk in smaller studies of carriers or unselected breast cancers. Future studies will involve replication of findings from pathway-based and genome-wide association studies in both unselected and familial breast cancer. The identification of genetic modifiers of breast cancer risk for BRCA1 and BRCA2 mutation carriers will lead to an improved understanding of breast cancer and may prove useful for the determination of individualized risk of cancer amongst carriers.
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    Are the so-called low penetrance breast cancer genes, ATM, BRIP1, PALB2 and CHEK2, high risk for women with strong family histories?
    Byrnes, GB ; Southey, MC ; Hopper, JL (BMC, 2008)
    A woman typically presents for genetic counselling because she has a strong family history and is interested in knowing the probability she will develop disease in the future; that is, her absolute risk. Relative risk for a given factor refers to risk compared with either population average risk (sense a), or risk when not having the factor, with all other factors held constant (sense b). Not understanding that these are three distinct concepts can result in failure to correctly appreciate the consequences of studies on clinical genetic testing. Several studies found that the frequencies of mutations in ATM, BRIP1, PALB2 and CHEK2 were many times greater for cases with a strong family history than for controls. To account for the selected case sampling (ascertainment), a statistical model that assumes that the effect of any measured variant multiplies the effect of unmeasured variants was applied. This multiplicative polygenic model in effect estimated the relative risk in the sense b, not sense a, and found it was in the range of 1.7 to 2.4. The authors concluded that the variants are "low penetrance". They failed to note that their model fits predicted that, for some women, absolute risk may be as high as for BRCA2 mutation carriers. This is because the relative risk multiplies polygenic risk, and the latter is predicted by family history. Therefore, mutation testing of these genes for women with a strong family history, especially if it is of early onset, may be as clinically relevant as it is for BRCA1 and BRCA2.
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    The BOADICEA model of genetic susceptibility to breast and ovarian cancers: updates and extensions
    Antoniou, AC ; Cunningham, AP ; Peto, J ; Evans, DG ; Lalloo, F ; Narod, SA ; Risch, HA ; Eyfjord, JE ; Hopper, JL ; Southey, MC ; Olsson, H ; Johannsson, O ; Borg, A ; Passini, B ; Radice, P ; Manoukian, S ; Eccles, DM ; Tang, N ; Olah, E ; Anton-Culver, H ; Warner, E ; Lubinski, J ; Gronwald, J ; Gorski, B ; Tryggvadottir, L ; Syrjakoski, K ; Kallioniemi, O-P ; Eerola, H ; Nevanlinna, H ; Pharoah, PDP ; Easton, DF (NATURE PUBLISHING GROUP, 2008-04-22)
    Multiple genetic loci confer susceptibility to breast and ovarian cancers. We have previously developed a model (BOADICEA) under which susceptibility to breast cancer is explained by mutations in BRCA1 and BRCA2, as well as by the joint multiplicative effects of many genes (polygenic component). We have now updated BOADICEA using additional family data from two UK population-based studies of breast cancer and family data from BRCA1 and BRCA2 carriers identified by 22 population-based studies of breast or ovarian cancer. The combined data set includes 2785 families (301 BRCA1 positive and 236 BRCA2 positive). Incidences were smoothed using locally weighted regression techniques to avoid large variations between adjacent intervals. A birth cohort effect on the cancer risks was implemented, whereby each individual was assumed to develop cancer according to calendar period-specific incidences. The fitted model predicts that the average breast cancer risks in carriers increase in more recent birth cohorts. For example, the average cumulative breast cancer risk to age 70 years among BRCA1 carriers is 50% for women born in 1920-1929 and 58% among women born after 1950. The model was further extended to take into account the risks of male breast, prostate and pancreatic cancer, and to allow for the risk of multiple cancers. BOADICEA can be used to predict carrier probabilities and cancer risks to individuals with any family history, and has been implemented in a user-friendly Web-based program (http://www.srl.cam.ac.uk/genepi/boadicea/boadicea_home.html).
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    Evaluation of models to predict BRCA germline mutations
    Kang, HH ; Williams, R ; Leary, J ; Ringland, C ; Kirk, J ; Ward, R (NATURE PUBLISHING GROUP, 2006-10-09)
    The selection of candidates for BRCA germline mutation testing is an important clinical issue yet it remains a significant challenge. A number of risk prediction models have been developed to assist in pretest counselling. We have evaluated the performance and the inter-rater reliability of four of these models (BRCAPRO, Manchester, Penn and the Myriad-Frank). The four risk assessment models were applied to 380 pedigrees of families who had undergone BRCA1/2 mutation analysis. Sensitivity, specificity, positive and negative predictive values, likelihood ratios and area under the receiver operator characteristic (ROC) curve were calculated for each model. Using a greater than 10% probability threshold, the likelihood that a BRCA test result was positive in a mutation carrier compared to the likelihood that the same result would be expected in an individual without a BRCA mutation was 2.10 (95% confidence interval (CI) 1.66-2.67) for Penn, 1.74 (95% CI 1.48-2.04) for Myriad, 1.35 (95% CI 1.19-1.53) for Manchester and 1.68 (95% CI 1.39-2.03) for BRCAPRO. Application of these models, therefore, did not rule in BRCA mutation carrier status. Similar trends were observed for separate BRCA1/2 performance measures except BRCA2 assessment in the Penn model where the positive likelihood ratio was 5.93. The area under the ROC curve for each model was close to 0.75. In conclusion, the four models had very little impact on the pre-test probability of disease; there were significant clinical barriers to using some models and risk estimates varied between experts. Use of models for predicting BRCA mutation status is not currently justified for populations such as that evaluated in the current study.
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    Low frequency of CHEK2 1100delC allele in Australian multiple-case breast cancer families:: functional analysis in heterozygous individuals
    Jekimovs, CR ; Chen, X ; Arnold, J ; Gatei, M ; Richard, DJ ; Spurdle, AB ; Khanna, KK ; Chenevix-Trench, G (NATURE PUBLISHING GROUP, 2005-02-28)
    A protein-truncating variant of CHEK2, 1100delC, is associated with a moderate increase in breast cancer risk. We have determined the prevalence of this allele in index cases from 300 Australian multiple-case breast cancer families, 95% of which had been found to be negative for mutations in BRCA1 and BRCA2. Only two (0.6%) index cases heterozygous for the CHEK2 mutation were identified. All available relatives in these two families were genotyped, but there was no evidence of co-segregation between the CHEK2 variant and breast cancer. Lymphoblastoid cell lines established from a heterozygous carrier contained approximately 20% of the CHEK2 1100delC mRNA relative to wild-type CHEK2 transcript. However, no truncated CHK2 protein was detectable. Analyses of expression and phosphorylation of wild-type CHK2 suggest that the variant is likely to act by haploinsufficiency. Analysis of CDC25A degradation, a downstream target of CHK2, suggests that some compensation occurs to allow normal degradation of CDC25A. Such compensation of the 1100delC defect in CHEK2 might explain the rather low breast cancer risk associated with the CHEK2 variant, compared to that associated with truncating mutations in BRCA1 or BRCA2.
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    Genomewide high-density SNP linkage analysis of non-BRCA1/2 breast cancer families identifies various candidate regions and has greater power than microsatellite studies
    Gonzalez-Neira, A ; Rosa-Rosa, JM ; Osorio, A ; Gonzalez, E ; Southey, M ; Sinilnikova, O ; Lynch, H ; Oldenburg, RA ; van Asperen, CJ ; Hoogerbrugge, N ; Pita, G ; Devilee, P ; Goldgar, D ; Benitez, J (BMC, 2007-08-30)
    BACKGROUND: The recent development of new high-throughput technologies for SNP genotyping has opened the possibility of taking a genome-wide linkage approach to the search for new candidate genes involved in heredity diseases. The two major breast cancer susceptibility genes BRCA1 and BRCA2 are involved in 30% of hereditary breast cancer cases, but the discovery of additional breast cancer predisposition genes for the non-BRCA1/2 breast cancer families has so far been unsuccessful. RESULTS: In order to evaluate the power improvement provided by using SNP markers in a real situation, we have performed a whole genome screen of 19 non-BRCA1/2 breast cancer families using 4720 genomewide SNPs with Illumina technology (Illumina's Linkage III Panel), with an average distance of 615 Kb/SNP. We identified six regions on chromosomes 2, 3, 4, 7, 11 and 14 as candidates to contain genes involved in breast cancer susceptibility, and additional fine mapping genotyping using microsatellite markers around linkage peaks confirmed five of them, excluding the region on chromosome 3. These results were consistent in analyses that excluded SNPs in high linkage disequilibrium. The results were compared with those obtained previously using a 10 cM microsatellite scan (STR-GWS) and we found lower or not significant linkage signals with STR-GWS data compared to SNP data in all cases. CONCLUSION: Our results show the power increase that SNPs can supply in linkage studies.
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    The AIB1 glutamine repeat polymorphism is not associated with risk of breast cancer before age 40 years in Australian women
    Montgomery, KG ; Chang, JH ; Gertig, DM ; Dite, GS ; McCredie, MR ; Giles, GG ; Southey, MC ; Hopper, JL ; Campbell, IG (BMC, 2005)
    INTRODUCTION: AIB1, located at 20q12, is a member of the steroid hormone coactivator family. It contains a glutamine repeat (CAG/CAA) polymorphism at its carboxyl-terminal region that may alter the transcriptional activation of the receptor and affect susceptibility to breast cancer through altered sensitivity to hormones. METHODS: We evaluated this repeat polymorphism in the context of early-onset disease by conducting a case-control study of 432 Australian women diagnosed with breast cancer before the age of 40 years and 393 population-based control individuals who were frequency matched for age. Genotyping was performed using a scanning laser fluorescence imager. RESULTS: There were no differences in genotype frequencies between cases and control individuals, or between cases categorized by family history or by BRCA1 and BRCA2 germline mutation status. There was no evidence that the presence of one or two alleles of 26 glutamine repeats or fewer was associated with breast cancer (odds ratio = 1.03, 95% confidence interval = 0.73-1.44), or that women with alleles greater than 29 repeats were at increased risk of breast cancer. Exclusion of women who carried a BRCA1 or BRCA2 mutation (24 cases) and non-Caucasian women (44 cases) did not alter the risk estimates or inferences. We present raw data, including that on mutation carriers, to allow pooling with other studies. CONCLUSION: There was no evidence that risk of breast cancer depends on AIB1 CAG/CAA polymorphism status, even if affected women carry a mutation in BRCA1 or BRCA2.
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    CYP17 genetic polymorphism, breast cancer, and breast cancer risk factors:: Australian Breast Cancer Family Study
    Chang, JH ; Gertig, DM ; Chen, XQ ; Dite, GS ; Jenkins, MA ; Milne, RL ; Southey, MC ; McCredie, MRE ; Giles, GG ; Chenevix-Trench, G ; Hopper, JL ; Spurdle, AB (BMC, 2005)
    INTRODUCTION: Because CYP17 can influence the degree of exposure of breast tissues to oestrogen, the interaction between polymorphisms in this gene and hormonal risk factors is of particular interest. We attempted to replicate the findings of studies assessing such interactions with the -34T-->C polymorphism. METHODS: Risk factor and CYP17 genotyping data were derived from a large Australian population-based case-control-family study of 1,284 breast cancer cases and 679 controls. Crude and adjusted odds ratio (OR) estimates and 95% confidence intervals (CIs) were calculated by unconditional logistic regression analyses. RESULTS: We found no associations between the CYP17 genotype and breast cancer overall. Premenopausal controls with A2/A2 genotype had a later age at menarche (P < 0.01). The only associations near statistical significance were that postmenopausal women with A1/A1 (wild-type) genotype had an increased risk of breast cancer if they had ever used hormone replacement therapy (OR 2.40, 95% CI 1.0 to 5.7; P = 0.05) and if they had menopause after age 47 years (OR 2.59, 95% CI 1.0 to 7.0; P = 0.06). We found no associations in common with any other studies, and no evidence for interactions. CONCLUSION: We observed no evidence of effect modification of reproductive risk factors by CYP17 genotype, although the experiment did not have sufficient statistical power to detect small main effects and modest effects in subgroups. Associations found only in subgroup analyses based on relatively small numbers require cautious interpretation without confirmation by other studies. This emphasizes the need for replication in multiple and large population-based studies to provide convincing evidence for gene-environment interactions.
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    The androgen receptor CAG repeat polymorphism and modification of breast cancer risk in BRCA1 and BRCA2 mutation carriers
    Spurdle, AB ; Antoniou, AC ; Duffy, DL ; Pandeya, N ; Kelemen, L ; Chen, XQ ; Peock, S ; Cook, MR ; Smith, PL ; Purdie, DM ; Newman, B ; Dite, GS ; Apicella, C ; Southey, MC ; Giles, GG ; Hopper, JL ; Chenevix-Trench, G ; Easton, DF (BMC, 2005)
    INTRODUCTION: The androgen receptor (AR) gene exon 1 CAG repeat polymorphism encodes a string of 9-32 glutamines. Women with germline BRCA1 mutations who carry at least one AR allele with 28 or more repeats have been reported to have an earlier age at onset of breast cancer. METHODS: A total of 604 living female Australian and British BRCA1 and/or BRCA2 mutation carriers from 376 families were genotyped for the AR CAG repeat polymorphism. The association between AR genotype and disease risk was assessed using Cox regression. AR genotype was analyzed as a dichotomous covariate using cut-points previously reported to be associated with increased risk among BRCA1 mutation carriers, and as a continuous variable considering smaller allele, larger allele and average allele size. RESULTS: There was no evidence that the AR CAG repeat polymorphism modified disease risk in the 376 BRCA1 or 219 BRCA2 mutation carriers screened successfully. The rate ratio associated with possession of at least one allele with 28 or more CAG repeats was 0.74 (95% confidence interval 0.42-1.29; P = 0.3) for BRCA1 carriers, and 1.12 (95% confidence interval 0.55-2.25; P = 0.8) for BRCA2 carriers. CONCLUSION: The AR exon 1 CAG repeat polymorphism does not appear to have an effect on breast cancer risk in BRCA1 or BRCA2 mutation carriers.