Matthew Brimmell

BAX frameshift mutations in cell lines derived from human haemopoietic malignancies are associated with resistance to apoptosis and microsatellite instability

Bax suppresses tumorigenesis in a mouse model system and Bax-deficient mice exhibit lymphoid hyperplasia suggesting that BAX functions as a tumour suppressor in human haemopoietic cells. We examined BAX expression in 20 cell lines derived from human haemopoietic malignancies and consistent with a potential tumour suppressor function, identified two cell lines, DG75 (a Burkitt lymphoma cell line) and Jurkat (a T-cell leukaemia line), which lacked detectable BAX expression. Apoptosis of DG75 cells induced by low serum or ionomycin was significantly delayed relative to similar Burkitt lymphoma cell lines with normal BAX levels. Although DG75 and Jurkat cells expressed several BAX RNA species including the prototypical BAX α RNA, the absence of BAX protein was due to single base deletions and additions in a polyguanine tract within the BAX open reading frame. These frameshift mutations result in premature termination of translation and have recently also been identified in some colon cancers with microsatellite instability. Although mismatch repair defects are not considered a common feature of haemopoietic malignancies, DG75 and Jurkat cells had widespread microsatellite instability and did not express detectable levels of MSH2. In Jurkat cells, lack of MSH2 expression was due to a point mutation in exon 13 of MSH2 resulting in premature termination of translation. Our results suggest that a pathway linking mismatch repair defects, BAX tumour suppressor frameshift mutations and resistance to apoptosis may be a key feature of some lymphomas and leukaemias.

Mcl-1 is required for Akata6 B-lymphoma cell survival and is converted to a cell death molecule by efficient caspase-mediated cleavage

Enforced expression of the antiapoptotic Bcl-2 family protein Mcl-1 promotes lymphomagenesis in the mouse; however, the functional role of Mcl-1 in human B-cell lymphoma remains unclear. We demonstrate that Mcl-1 is widely expressed in malignant B-cells, and high-level expression of Mcl-1 is required for B-lymphoma cell survival, since transfection of Mcl-1-specific antisense oligodeoxynucleotides was sufficient to promote apoptosis in Akata6 lymphoma cells. Mcl-1 was efficiently cleaved by caspases at evolutionarily conserved aspartic acid residues in vitro, and during cisplatin-induced apoptosis in B-lymphoma cell lines and spontaneous apoptosis of primary malignant B-cells. Overexpression of the Mcl-1 cleavage product that accumulated during apoptosis was sufficient to kill cells. Therefore, Mcl-1 is an essential survival molecule for B-lymphoma cells and is cleaved by caspases to a death-promoting molecule during apoptosis. In contrast to Mcl-1, Bcl-2 and Bcl-XL were relatively resistant to caspase cleavage in vitro and in intact cells. Interfering with Mcl-1 function appears to be an effective means of inducing apoptosis in Mcl-1-positive B-cell lymphoma, and the unique sensitivity of Mcl-1 to caspase-mediated cleavage suggests an attractive strategy for converting it to a proapoptotic molecule.

BAG-1: a multifunctional regulator of cell growth and survival

BAG-1 is multifunctional protein which interacts with a wide range of cellular targets to regulate growth control pathways important for normal and malignant cells, including apoptosis, signaling, proliferation, transcription and cell motility. Of particular relevance to tumour cells, BAG-1 interacts with the anti-apoptotic BCL-2 protein, various nuclear hormone receptors and the 70 kDa heat shock proteins, Hsc70 and Hsp70. Interaction with chaperones may account for many of the pleiotropic effects associated with BAG-1 overexpression. Recent studies have shown that BAG-1 expression is frequently altered in malignant cells, and BAG-1 expression may have clinical value as a prognostic/predictive marker. This review summarises current understanding of molecular mechanisms of BAG-1 expression and function.

The nuclear BAG-1 isoform, BAG-1L, enhances oestrogen-dependent transcription

BAG-1 is a multifunctional protein that interacts with a wide range of cellular targets including heat-shock proteins and some nuclear hormone receptors. BAG-1 exists as three major isoforms, BAG-1L, BAG-1M and BAG-1S. BAG-1L contains a nuclear localization signal, which is not present in the other isoforms, and is predominantly localized in the cell nucleus. Here we have investigated the effects of BAG-1 on function of the oestrogen receptor (ER), a key growth control molecule and target for hormonal therapy in breast cancer. We demonstrate that BAG-1L, but not BAG-1S or BAG-1M, increased oestrogen-dependent transcription in breast cancer cells. BAG-1L interacted with and stimulated the activity of both ER α and β. Although BAG-1L and ERs colocalize to the nucleus, fusing BAG-1S to an heterologous nuclear localization sequence was not sufficient to stimulate transcription. Consistent with an important effect on receptor function, nuclear BAG-1 expression in breast cancers was associated with expression of the progesterone receptor, a transcriptional target of ERα, and was associated with improved survival in patients treated with hormonal therapy. These data suggest that BAG-1L is an important determinant of ER function in vitro and in human breast cancer.

BAG-1 expression and function in human cancer

BAG-1 is a multifunctional protein that interacts with a wide range of target molecules to regulate apoptosis, proliferation, transcription, metastasis and motility. Interaction with chaperone molecules may mediate many of the effects of BAG-1. The pathways regulated by BAG-1 play key roles in the development and progression of cancer and determining response to therapy, and there has been considerable interest in determining the clinical significance of BAG-1 expression in malignant cells. There is an emerging picture that BAG-1 expression is frequently altered in a range of human cancers relative to normal cells and a recent report suggests the exciting possibility that BAG-1 expression may have clinical utility as a prognostic marker in early breast cancer. However, other studies of BAG-1 expression in breast cancer and other cancer types have yielded differing results. It is important to view these findings in the context of current knowledge of BAG-1 expression and function. This review summarises recent progress in understanding the clinical significance of BAG-1 expression in cancer in light of our understanding of BAG-1 function.

BAG-1 in carcinogenesis.

BAG-1 is a multifunctional protein that exists as several differentially localised and functionally distinct isoforms. BAG-1 isoforms interact with a diverse array of molecular targets and regulate a wide range of cellular processes, including proliferation, survival, transcription, apoptosis, metastasis and motility. The BAG domain of BAG-1 interacts with chaperone molecules and this is considered important for many BAG-1 functions. The ability of BAG-1 to regulate such a wide variety of cellular processes suggests it might play an important role in many cancer types. For example, regulation of nuclear hormone receptor function and susceptibility to apoptosis might have a major impact on cancer development, progression and response to therapy. There is also increasing evidence that BAG-1 expression is altered in a variety of human malignancies relative to normal cells, and with further understanding of BAG-1 function it might become a powerful prognostic/predictive marker in human cancer. This review describes the structure and function of BAG-1 isoforms and the potential clinical implications of their expression in tumour cells.

Identification of a novel human BCL-X promoter and exon

BCL-XL is a key anti-apoptotic BCL-2 family protein that is widely expressed in human cancer cells and is induced in response to diverse survival signals. The translation initiation codon for BCL-XL is located in BCL-X exon II and previous analyses have indicated that BCL-XL RNAs initiate close to the start of exon II or additionally contain a non-coding first exon (exon IA) spliced to exon II. Using 5′ RACE we have now identified a novel BCL-X non-coding exon (exon IB) which is spliced directly to exon II in place of exon IA. Exon IB-containing RNAs encoded BCL-XL and were detected in non-malignant lymphocytes and lymphoma cells from lymph node biopsies and were expressed at significant levels in cell lines derived from ovarian, colon and breast cancers. We identified two TATA-box sequences upstream of exon IB and demonstrated that surrounding genomic sequences contained strong promoter activity in lymphoma cells (approximately 300-fold active relative to controls). We have therefore identified a powerful new BCL-X promoter and a novel exon that contributes to BCL-XL expression.

The Bcl-w promoter is activated by β-catenin/TCF4 in human colorectal carcinoma cells

The antiapoptotic BCL-2 family protein BCL-W is often overexpressed in colorectal carcinoma (CRC) where it correlates with advanced stage and expression of p53. In this work we have analysed the Bcl-w promoter to identify potential regulators of BCL-W expression in CRC cells. The Bcl-w promoter was highly active in cell lines derived from CRC as well as other cancer types. Although expression of p53 and BCL-W correlate in CRC, overexpression of wild type or mutant p53 did not significantly alter Bcl-w promoter activity, and deletion of endogenous p53 did not alter the expression of Bcl-w RNA in HCT116 cells. Promoter deletion analysis lead to the identification of a potential binding site for TCF/LEF factors, obligate binding partners for beta-catenin, a downstream target of the WNT signalling pathway. TCF4 and beta-catenin interacted with the Bcl-w promoter in intact HCT116 cells and mutation of this site significantly decreased promoter activity. The activity of the Bcl-w promoter was increased or decreased, respectively, by overexpression of beta-catenin or dominant negative TCF4. beta-catenin is activated in the majority of CRC and these results suggest that BCL-W may function as a downstream effector of inappropriate WNT/beta-catenin signalling.

The BAG-1 cochaperone is a negative regulator of p73-dependent transcription

High-level expression of Bcl-2 associated athanogene (BAG-1) protects cancer cells from stress-induced cell death and growth inhibition. These protective effects of BAG-1 are dependent on interactions with the HSC70 and HSP70 chaperones. However, the key stress-response molecules that are regulated by a BAG-1/chaperone mechanism have not been identified. In this study, we investigated the effects of BAG-1 overexpression on the function of p53 family proteins, p53, p63 and p73. Overexpression of BAG-1 isoforms interfered with the transactivating activity of p73 and p63, but had modest and variable effects on p53-dependent transcription. p73 and BAG-1 interacted in intact cells and overexpression of BAG-1 decreased the expression of p73. siRNA-mediated ablation of endogenous BAG-1 increased the activity of a p73-responsive promoter and this was reversed by knock-down of p73. The ability of BAG-1 to modulate p73 activity and expression, and to interact with p73 were dependent on amino acid residues required for the interaction of BAG-1 with HSC70 and HSP70. These results show that BAG-1 inhibits the transactivating functions of p73 and provide new insight into the mechanisms that control the expression of p73. Inhibition of p73 function may be one mechanism that contributes to the pro-survival activity of BAG-1.

Synthesis and analysis of spiruchostatin A, a potent bicyclic tetrapeptide histone deacetylase inhibitor

Introduction: Articular cartilage of higher animals does not regenerate, but under some circumstances mesenchymal cells can be inducted to behave phenotypically as chondrocytes. Tissue engineering has produced only partial cartilage repair and inconsistent outcomes. This study reports full thickness articular cartilage regeneration induced by freeze-dried particulate cartilage. Methods and Materials: Full thickness cartilage defects in the femoral condyles of 22 baboons were filled with freeze-dried cartilage particles. Defects in two animals were filled with frozen cartilage particles. Four animals served as controls. Experimental animals were sacrificed at 2 weeks (2), 6 weeks (6), 9 weeks (1) 12 weeks (3), 14-16 weeks (4) and at 7 and 14 months. The knees were photographed and x-rayed. The condyles were frozen, sectioned, photographed again, fixed, decalcified and processed for histology. To determine if cartilage preparations were osteogenic samples were implanted intramusculary in 16 athymic rats. The specimens were examined at 1,2,4 & 8 weeks. Cartilage particles were also implanted intraosseously into 2 baboons. Regenerating cartilage was graded in accordance with a modified Mankin’s method. Results: Cartilage regeneration proceeded from the edges of the defect. The 12 week and older defects were covered with smooth and glistening new cartilage. Control defects remained open or contained uneven patches of cartilage. Animals with frozen cartilage implants appeared identical to controls. Cartilage particles implanted into athymic rats remained inert and elicited neither osteogenesis nor chondrogenesis, as did cartilage placed intramedullary in baboons. Conclusions: The data demonstrates induction of articular cartilage regeneration by freeze-dried hyaline cartilage particles implanted orthotopically.