Mark R. Crompton

p53 mutation with frequent novel codons but not a mutator phenotype in BRCA1- and BRCA2-associated breast tumours

The status of p53 was investigated in breast tumours arising in germ-line carriers of mutant alleles of BRCA1 and BRCA2 and in a control series of sporadic breast tumours. p53 expression was detected in 20/26 (77%) BRCA1-, 10/22 (45%) BRCA2-associated and 25/72 (35%) grade-matched sporadic tumours. Analysis of p53 sequence revealed that the gene was mutant in 33/50 (66%) BRCA-associated tumours, whereas 7/20 (35%) sporadic grade-matched tumours contained p53 mutation (P<0.05). A number of the mutations detected in the BRCA-associated tumours have not been previously described in human cancer databases, whilst others occur extremely rarely. Analysis of additional genes, p16INK4, Ki-ras and β-globin revealed absence or very low incidence of mutations, suggesting that the higher frequency of p53 mutation in the BRCA-associated tumours does not reflect a generalized increase in susceptibility to the acquisition of somatic mutation. Furthermore, absence of frameshift mutations in the polypurine tracts present in the coding sequence of the TGF β type II receptor (TGF β IIR) and Bax implies that loss of function of BRCA1 or BRCA2 does not confer a mutator phenotype such as that found in tumours with microsatellite instability (MSI). p21Waf1 was expressed in BRCA-associated tumours regardless of p53 status and, furthermore, some tumours expressing wild-type p53 did not express detectable p21Waf1. These data do not support, therefore, the simple model based on studies of BRCA−/− embryos, in which mutation of p53 in BRCA-associated tumours results in loss of p21Waf1 expression and deregulated proliferation. Rather, they imply that proliferation of such tumours will be subject to multiple mechanisms of growth regulation.

BRK tyrosine kinase expression in a high proportion of human breast carcinomas

BRK is a recently described non receptor protein tyrosine kinase whose mRNA was found to be expressed in human breast tumours and breast cancer cell lines. Expression of BRK in fibroblasts and mammary epithelial cells has been shown to enhance their ability to grow anchorage independently, and mammary epithelial cells expressing BRK acquire a potentiated mitogenic response to epidermal growth factor. In order to investigate further the expression of BRK in breast cancers, we have isolated monoclonal antibodies specifically recognising the protein. Whereas BRK expression was low or undetectable in normal mammary tissue and benign lesions, approximately two-thirds of breast tumours expressed appreciable levels, and 27% of tumours over expressed BRK by fivefold or more (up to 43×). This expression pattern was mirrored in a comparison of cell lines derived either from normal mammary epithelial cells or from carcinomas. BRK expression was found to be constant throughout the cell cycle, and did not vary with cell proliferation rate. A consideration of this expression data, in conjunction with BRKs demonstrated ability to deregulate the proliferation of mammary epithelial cells, supports the hypothesis that the over expression of BRK in a high proportion of breast carcinomas is a functionally important factor in their evolution.

Brk, a Breast Tumor-derived Non-receptor Protein-tyrosine Kinase, Sensitizes Mammary Epithelial Cells to Epidermal Growth Factor

brk (breast tumor kinase) shows homology to the src family of non-receptor protein-tyrosine kinases and is expressed in breast carcinomas. In order to investigate the role of brk in breast tumor development, we have examined the growth and transformation properties of human mammary epithelial cells engineered to overexpress Brk. Interestingly, like c-Src, overexpression of Brk leads to sensitization to EGF, and also results in a partially transformed phenotype. Further investigation of the latter activity was attempted by mutational analysis, targeting key residues known to affect tyrosine kinase activity in Src-like kinases. Mutation of amino acid residue Lys-219 to Met, by analogy to Src, abolished both kinase activity and transformation capacity. Mutation of amino acid residue Tyr-447 to Phe, however, resulted in a decrease in transforming potential without affecting kinase activity. These results suggest that while Src and Brk share some functional properties, they act differently during transformation. These differences are discussed in the context of the mechanisms underlying breast cancer development.

Expression of the BRK tyrosine kinase in mammary epithelial cells enhances the coupling of EGF signalling to PI 3-kinase and Akt, via erbB3 phosphorylation

A high proportion of human breast cancers, in contrast with normal mammary tissue, express the intracellular tyrosine kinase BRK. BRK expression enhances the mitogenic response of mammary epithelial cells to epidermal growth factor, and conferment of a proliferative advantage through this mechanism may account for the frequent elevation of BRK expression in tumours. Here we report that BRK expression in mammary epithelial cells, at pathologically relevant levels, results in an enhanced phosphorylation of the epidermal growth factor receptor-related receptor erbB3 in response to epidermal growth factor. As a consequence, erbB3 recruits increased levels of phosphoinositide 3-kinase, and this is associated with a potentiated activation of Akt. This effect of BRK on the regulation of phosphoinositide 3-kinase and Akt activity may account for BRKs ability to enhance mammary cell mitogenesis, and raises the possibility that breast tumours expressing BRK may acquire a resistance to pro-apoptotic signals.

Novel p53 mutants selected in BRCA-associated tumours which dissociate transformation suppression from other wild-type p53 functions.

Inheritance of germ-line mutant alleles of BRCA1 and BRCA2 confers a markedly increased risk of breast cancer and we have previously reported a higher incidence of p53 mutations in these tumours than in grade matched sporadic tumours. We have now characterized these p53 mutants. The results of these studies identify a novel class of p53 mutants previously undescribed in human cancer yet with multiple occurrences in BRCA-associated tumours which retain a profile of p53-dependent activities in terms of transactivation, growth suppression and apoptosis induction which is close or equal to wild-type. However, these mutants fail to suppress transformation and exhibit gain of function transforming activity in rat embryo fibroblasts. These mutants therefore fall into a novel category of p53 mutants which dissociate transformation suppression from other wild-type functions. The rarity of these mutants in human cancer and their multiple occurrence in BRCA-associated breast tumours suggests that these novel p53 mutants are selected during malignant progression in the unique genetic background of BRCA1- and BRCA2-associated tumours.

A novel adaptor-like protein which is a substrate for the non-receptor tyrosine kinase, BRK

The brk gene encodes a non-receptor tyrosine kinase that has been found to be overexpressed in approximately two thirds of breast tumours. Using a yeast two-hybrid based screen, we have cloned cDNAs encoding a novel protein, BKS, that is a substrate for the kinase activity of BRK and has the characteristics of an adaptor protein. BKS possesses an N-terminal PH-like domain followed by an SH2-like domain. In co-transfection experiments, high levels of phosphotyrosine were observed on BKS and BRK was found to be associated with BKS, both of which were dependent on the catalytic activity of BRK. The phosphorylation of and association with BKS by BRK was also dependent on the SH2-like domain present within BKS. In addition, BKS recruited an unidentified 100 kDa protein that was also phosphorylated on tyrosine residues in the presence of BRK. We have determined that the BKS protein is expressed in most adult human tissues.

Use of RNA interference to validate Brk as a novel therapeutic target in breast cancer: Brk promotes breast carcinoma cell proliferation

Brk (PTK6) is a nonreceptor protein tyrosine kinase, which is expressed in over 60% of breast carcinoma tissue samples and breast tumour cell lines, but not normal mammary tissue or benign lesions. Since experimental Brk expression in nontransformed mammary epithelial cells enhances their mitogenic response to epidermal growth factor, it was important to determine the role Brk plays in the proliferation of breast carcinoma cells and validate it as a therapeutic target. We have used RNA interference to efficiently and specifically downregulate Brk protein levels in breast carcinoma cells, and determined that this results in a significant suppression of their proliferation. Additionally, through the expression of a kinase-inactive mutant, we have determined that Brk can mediate promotion of proliferation via a kinase-independent mechanism, potentially functioning as an ‘adapter’. These data identify Brk as a novel target for antiproliferative therapy in the majority of breast cancers, and illustrate the power of RNA interference for rapidly validating candidate therapeutic targets.

Brk Protects Breast Cancer Cells from Autophagic Cell Death Induced by Loss of Anchorage

Brk, a tyrosine kinase expressed in a majority of breast tumors, but not normal mammary tissue, promotes breast carcinoma cell proliferation. Normal epithelial cells are dependent on cell-cell or cell-matrix interactions for survival and undergo apoptosis after disruption of these interactions. Tumor cells are less sensitive to the induction of apoptosis and are predicted to have the potential to disseminate. We investigated whether Brk has further roles in breast tumor progression by relating its expression to tumor grade and demonstrating its role in the regulation of carcinoma cell survival under non-adherent conditions. Brk expression was determined by reverse transcription PCR on RNA extracted from surgical samples of human breast cancers. Breast carcinoma cell survival in suspension culture was examined when Brk protein levels were suppressed by RNA interference. Additionally, the effect of experimentally overexpressing Brk in otherwise Brk-negative breast carcinoma cells was assessed. Brk mRNA expression was notably higher in grade 3 breast tumors, as compared with lower tumor grades. In suspension culture, Brk suppression increased the rate of cell death, as compared with controls, and this cell death program exhibited characteristics of autophagy but not of apoptosis. Conversely, experimental expression of Brk in Brk-negative cells increased cell survival whereas kinase-inactive Brk did not. Therefore, Brk enhances breast carcinoma cell survival in suspension, suggesting a role for Brk in supporting breast cancer cell dissemination.

Characterisation and chromosome mapping of the human non receptor tyrosine kinase gene, brk.

The brk gene encodes a non-receptor protein tyrosine kinase that consists of single SH3, SH2 and catalytic domains. Although BRK shows strongest sequence similarity to members of the SRC family of PTKs, there are several key structural and regulatory differences that place it on its own amongst non-receptor PTKs. In this study we have isolated genomic DNA clones corresponding to the human brk locus and used these to determine the intron-exon structure of the brk gene. The genomic structure of brk consists of 8 exons, whose boundaries are distinct from other non-receptor PTK family members, again indicating a structural and functional divergence. Alternate splicing of the primary brk transcript generates a distinct mRNA which encodes a truncated protein consisting of an SH3 domain and a novel C-terminal proline rich sequence. Using an antiserum raised to the SH3 domain, we have demonstrated that the product of this alternate brk transcript is expressed in the human breast tumour cell line T-47D. We have previously reported that expression of a tumour derived brk cDNA in mouse embryonic fibroblasts and human mammary epithelial cells supports anchorage independent growth, and in the latter potentiates the mitogenic response to epidermal growth factor. The protein encoded by the genomic sequence derived from normal human tissue is identical to that encoded by the tumour derived cDNA, and therefore the altered growth regulation is not associated with mutations within brk. In addition, we have identified a 5′ genomic region that has promoter activity. The brk gene has been assigned to chromosome 19q 13.3-13.4 using fluorescence in situ hybridisation (FISH).

Targeting primary human leukaemia cells with RNA interference: Bcr-Abl targeting inhibits myeloid progenitor self- renewal in chronic myeloid leukaemia cells

We have investigated functional outcome of challenging primary chronic myeloid leukaemia (CML) cells with Bcr‐Abl fusion sequence‐directed RNA interference (RNAi). We targeted the Bcr‐Abl b3a2 variant, by RNAi, in primary chronic phase CML cells, and detected strikingly reduced proliferation of myeloid precursor cells expressing this variant. Lack of an effect in cells expressing a distinct Bcr‐Abl variant confirmed the specificity of the response. Through the functional targeting of an oncogene in primary human tumour cells, we have demonstrated that Bcr‐Abl enhances CML progenitor cell amplification, and that RNAi may be suitable for development as a specific anti‐leukaemia treatment.