A polymorphic tetranucleotide repeat in the CYP19 gene and male breast cancer

The CYP19 gene codes for the aromatase enzyme that is involved in the synthesis of oestrogens. This case-control study examines the relationship between a tetranucleotide repeat sequence in the CYP19 gene and the development of male breast cancer. No significant differences were found between male breast cancer cases and controls.

Heterogeneity studies identify a subset of sporadic colorectal cancers without evidence for chromosomal or microsatellite instability

Two apparently independent mechanisms of instability are recognized in colorectal cancer, microsatellite instability and chromosomal instability. Evidence from colorectal cancer cell lines indicates the presence of either, or both, types of instability in the vast majority. Here, we sought to determine the prevalence of such instability in primary sporadic colorectal cancers. Microsatellite instability was established by demonstration of ovel clonal, nongerm-line alleles in at least two of four tested loci. Chromosomal abnormalities were identified by comparative genomic hybridization (CGH) and flow cytometric analysis of nuclear DNA content. Tumours harbouring chromosomal instability were distinguished from those with stable but aneuploid karyotypes by comparing chromosomal defects at multiple sites throughout each cancer. This analysis allowed assessment of both the number of chromosomal abnormalities and their heterogeneity throughout the tumour. The results confirm that microsatellite instability is consistently associated with multiple, repeated changes in microsatellites throughout the growth of the affected colorectal carcinomas. There were also several carcinomas in which major structural or numerical abnormalities in chromosomes had clearly continued to arise during tumour growth. However, a substantial subset of tumours showed neither microsatellite instability nor multiple, major chromosomal abnormalities. We suggest that the development of a proportion of colorectal cancers proceeds via a different pathway of carcinogenesis not associated with either of the currently recognized forms of genomic instability.

Dysregulated expression of beta-catenin marks early neoplastic change in Apc mutant mice, but not all lesions arising in Msh2 deficient mice

We have analysed the pattern of beta-catenin expression by immunohistochemistry in mice singly or multiply mutant for Apc, p53 and Msh2. We observed increased expression of beta-catenin in all intestinal lesions arising on an ApcMin+/- background. In all categories of lesion studied mosaic patterns of beta-catenin expression were observed, with the proportion of cells showing enhanced expression decreasing with increasing lesion size. p53 status did not alter these patterns. We also show that beta-catenin dysregulation marks pancreatic abnormalities occurring in ApcMin+/- and (ApcMin+/-, p53-/-) mice. In these mice both adenomas and adenocarcinomas of the pancreas arose and were characterized by increased expression of beta-catenin. We have extended these analyses to intestinal lesions arising in mice mutant for the mismatch repair gene Msh2. In these mice, increased expression of beta-catenin was again observed. However, in contrast with ApcMin+/- mice, a subset of lesions retained normal expression. Taken together, these findings show that increased expression of beta-catenin is an efficient marker of early neoplastic change in both murine intestine and pancreas in Apc mutant mice. However, we also show that dysregulation of beta-catenin is not an obligate step in the development of intestinal lesions, and therefore that genetic events other than the loss of Apc function may initiate the transition from normal to neoplastic epithelium.

A polymorphism in the CYP17 gene is associated with male breast cancer

The CYP17 gene codes for the cytochrome P450c17alpha enzyme that is involved in the synthesis of oestrogens. This case-control study from the South East of Scotland shows that a polymorphism of the CYP17 gene is associated with an increased risk of male breast cancer.

Frequent microsatellite instability and mismatch repair gene mutations in young Chinese patients with colorectal cancer

BACKGROUND

The incidence of colorectal cancer in persons under 46 years of age is substantially higher in Hong Kong than in Scotland and many other countries. Consequently, we examined whether there is a hereditary predisposition for colorectal cancer in this Southern Chinese population.

METHODS

We investigated the incidence of microsatellite instability (MSI) at 10 DNA sites in 117 colorectal cancer specimens from Chinese patients of various ages. Those tumors with new alleles at 40% or more of the sites investigated were identified as highly unstable MSI (MSI-H). In young patients, we also searched for germline mutations in three mismatch repair genes (hMSH2, hMLH1, and hMSH6).

RESULTS

The incidence of MSI-H varied statistically significantly with age, being observed in more than 60% of those younger than age 31 years at diagnosis and in fewer than 15% of those age 46 years or older. In 15 patients (<46 years old) whose colorectal cancers showed MSI-H, eight possessed germline mutations in either hMSH2 or hMLH1. When mutations in hMSH6 were included, more than 80% of Chinese colorectal cancer patients younger than 31 years had germline mutations in mismatch repair genes. We found a novel germline missense mutation in hMSH6 in a 29-year-old man whose tumor showed no MSI. Two patients had a 4-base-pair insertion in exon 10 causing a truncated protein; this insertion is a common polymorphism with a population allele frequency in Chinese of 5.6%.

CONCLUSIONS

Our results indicate that germline mutations in mismatch repair genes contribute substantially to the pathogenesis and high incidence of colorectal cancer in young Hong Kong Chinese. However, because young Chinese and Caucasians show similar proportions of colorectal cancers with MSI-H, despite the higher incidence in the former, additional factors may underlie the high susceptibility of young Chinese to colorectal cancer.

Apoptosis and carcinogenesis

Apoptosis has long been known to be effected through a common sequence of structural changes, despite the wide variety of initiating stimuli. These common structural events appear to depend upon activation of a set of enzymes (caspases) which direct a strongly conserved, terminal effector pathway. The regulation of this pathway, and in particular its coupling to DNA damage, appears to be critical in maintaining at low levels the number of mutated cells within tissues. The frequency with which tumours (experimental and human) bear deficiency in p53 or MSH-2 repair function may indicate the importance of these proteins in coupling DNA damage to apoptosis.

Identification of a region of frequent loss of heterozygosity at 11q24 in colorectal cancer

Loss of heterozygosity (LOH) at 11q23-qter occurs frequently in ovarian and other cancers, but for colorectal cancer, the evidence is conflicting. Seven polymorphic loci were analyzed between D11S897 and D11S969 in 50 colorectal tumors. Two distinct LOH regions were detected, suggesting possible sites for tumor-suppressor genes involved in colorectal neoplasia: a large centromeric region between D11S897 and D11S925, and a telomeric 4.9-Mb region between D11S912 and D11S969. There was no correlation with clinicopathological features. This analysis describes a region of LOH in the region 11q23.3-24.3 for the first time in colorectal cancer and provides complementary evidence for the ongoing effort to identify the gene(s) involved.

Msh2 status modulates both apoptosis and mutation frequency in the murine small intestine

Deficiency in genes involved in DNA mismatch repair increases susceptibility to cancer, particularly of the colorectal epithelium. Using Msh2 null mice, we demonstrate that this genetic defect renders normal intestinal epithelial cells susceptible to mutation in vivo at the Dlb-1 locus. Compared with wild-type mice, Msh2-deficient animals had higher basal levels of mutation and were more sensitive to the mutagenic effects of temozolomide. Experiments using Msh2-deficient cells in vitro suggest that an element of this effect is attributable to increased clonogenicity. Indeed, we show that Msh2 plays a role in the in vivo initiation of apoptosis after treatment with temozolomide, N-methyl-N'-nitro-N-nitrosoguanidine, and cisplatin. This was not influenced by the in vivo depletion of O6-alkylguanine-DNA-alkyltransferase after administration of O6-benzylguanine. By analyzing mice mutant for both Msh2 and p53, we found that the Msh2-dependent apoptotic response was primarily mediated through a p53-dependent pathway. Msh2 also was required to signal delayed p53-independent death. Taken together, these studies characterize an in vivo Msh2-dependent apoptotic response to methylating agents and raise the possibility that Msh2 deficiency may predispose to malignancy not only through failed repair of mismatch DNA lesions but also through the failure to engage apoptosis.

Role of BAX mutations in mismatch repair-deficient colorectal carcinogenesis

BAX gene mutations occur in approximately 50% of RER+ colorectal cancers. To determine the role of these mutations in tumour progression we analysed multiple different tumour sites from RER+ colorectal cancers for BAX mutations. Sixty colorectal carcinomas were analysed for microsatellite instability at loci BAT-26, L-myc, TGF betaRII, D13S160 and D2S123. Twelve out of 60 tumours (20%) were RER+. Forty-five different tumour sites from the 12 RER+ carcinomas were analysed for BAX mutations at the [(G)8] tract in exon 3. Six out of 12 (50%) RER+ tumours showed BAX mutations, four of which showed a homogenous pattern of such mutations detected in all tumour sites. In the other two cases, BAX mutations were present in some but not all tumour sites sampled from the same patient. In contrast, TGF betaRII mutations were found in 9/12 cases (75%) and in each of these were present in all the sampled sites. Two cases showed neither BAX nor TGF betaRII mutation. These data suggest that mutations in TGF betaRII may occur at a very early stage in tumour progression, perhaps in the founder clone. BAX mutations, however, are clearly not necessary for formation of the founder clone and can occur for the first time later in tumour progression.

P53-dependent and -independent links between DNA-damage, apoptosis and mutation frequency in ES cells

The hypothesis that p53 deficiency enhances the survival of DNA-damage bearing cells was investigated in wild-type and p53 mutant embryonic stem (ES) cells. Following UV-C irradiation, p53 is rapidly induced in wild-type cells and p53-dependent apoptosis follows within 8 h, resulting in the death of the majority of cells within 36 h. Increasing doses of UV-irradiation resulted in enhanced clonogenic survival of null cells as compared to wild-type. Amongst surviving clones, the Hprt mutation frequency was found to be dependent upon UV dose and influenced by p53 status. Treatment with ionizing radiation led to enhanced expression of p53 but resulted in little induction of apoptosis irrespective of p53 status. However, clonogenic potential was considerably reduced, particularly in wild-type cells which showed a tenfold lower survival than null cells. In contrast to the effects of UV-irradiation, the incidence of Hprt mutation did not differ significantly between wild-type and p53 null survivors. The data confirm that p53 restricts the numbers of cells bearing mutations that survive DNA damage induced by either agent, albeit by different mechanisms.

Caspase-mediated cleavage of APC results in an amino-terminal fragment with an intact armadillo repeat domain

During the effector phase of apoptosis, caspase activation appears to be responsible for the distinctive structural changes of apoptosis and perhaps for some of the changes in function of the doomed cells. There is therefore interest in identifying caspase substrates and the details of the cleavage events. Here we define precisely the event responsible for generation of a stable 90 kDa fragment from the oncosuppressor protein adenomatous polyposis coli (APC). Using synthetic radiolabeled APC peptides as substrate, we demonstrate cleavage by cytosolic extracts from preapoptotic cells. This cleavage was reproduced by recombinant caspase-3 and blocked by a tetrapeptide inhibitor Ac-DEVD-CHO, which is specific for caspase-3 family members. Inhibitors specific for caspase-1 and -8 however, were less effective in blocking APC cleavage. Mutation of a candidate DNID caspase-3 target site completely abolished cleavage. This cleavage may be of biological importance since the 90 kDa fragment consists of a sequence that is highly conserved in the human, rat, mouse, Xenopus, and Drosophila APC, although wide sequence divergence is observed in Drosophila immediately carboxy-terminal to the DNID site. Furthermore, cleavage at this site separates two significant functional domains: an amino-terminal armadillo repeat and an adjacent series of beta-catenin binding sites. Further circumstantial evidence for the significance of APC-related pathways in apoptosis is provided by the observation that apoptosis also induces cleavage of beta-catenin itself, a protein known to accumulate in cells depleted in functional APC and that appears to link cell-cell signaling to changes in transcription and cell movement.

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Microsomal epoxide hydrolase gene polymorphism and susceptibility to colon cancer

We examined polymorphisms in exons 3 and 4 of microsomal epoxide hydrolase in 101 patients with colon cancer and compared the results with 203 control samples. The frequency of the exon 3 T to C mutation was higher in cancer patients than in controls (odds ratio 3.8; 95% confidence intervals 1.8-8.0). This sequence alteration changes tyrosine residue 113 to histidine and is associated with lower enzyme activity when expressed in vitro. This suggests that putative slow epoxide hydrolase activity may be a risk factor for colon cancer. This appears to be true for both right- and left-sided tumours, but was more apparent for tumours arising distally (odds ratio 4.1; 95% confidence limits 1.9-9.2). By contrast, there was no difference in prevalence of exon 4 A to G transition mutation in cancer vs controls. This mutation changes histidine residue 139 to arginine and produces increased enzyme activity. There was no association between epoxide hydrolase genotype and abnormalities of p53 or Ki-Ras.

p53-independent DNA repair and cell cycle arrest in embryonic stem cells

The role of p53 in DNA repair and cell cycle checkpoint after ultraviolet irradiation was investigated in an embryonic stem cell line homozygous for a targeted deletion of p53. Results indicate that loss of p53 does not alter the capacity of ES cells to respond to DNA damage. Wild-type and p53-deficient cells showed similar cessation of DNA synthesis after UV damage and similar ultimate capacity to repair a transiently transfected reporter plasmid. Interestingly, in the absence of DNA damaging treatment, the transit of p53-deficient cells through S phase was slower than wild-type cells. We suggest that this may result from the absence of a p53-dependent response to endogenous DNA damage: without p53 sensing endogenous damage leading to immediate repair, such damage may persist and thus delay DNA synthesis.

N-acetyl transferase 1: two polymorphisms in coding sequence identified in colorectal cancer patients

Increased cancer risk has been associated with functional polymorphisms that occur within the genes coding for the N-acetyltransferase enzymes NAT1 and NAT2. We detected two NAT1 polymorphisms in colorectal cancer patients by heteroduplex analysis. DNA sequencing revealed the wild-type sequence (NAT1*4) and two single base substitutions at adjacent positions 999 bp (C to T, NAT1*14) and 1000 bp (G to A, NAT1*15) of the gene, changing Arg187 to a stop codon and Arg187 to Gln respectively. NAT1 alleles NAT1*4 (0.98) and NAT1*15 (0.02) were present at a similar frequency in patients with colorectal cancer (n=260) and in a Scottish control group (n=323). The third allele, NAT1*14, was present only in the colorectal cancer group at a frequency of 0.006. NAT1 genotype NAT1*4/ NAT1*15 was significantly less frequent in individuals that had a slow NAT2 genotype. This was observed in both cancer and control groups and suggests that this association was unrelated to cancer risk. We conclude that polymorphisms within the coding region of the NAT1 gene are infrequent and do not appear to have an independent association with colorectal cancer risk. However, the relationship between NAT1 and NAT2 polymorphisms appears non-random, suggesting a linkage between these enzymes.

UV but not gamma-irradiation induces specific transcriptional activity of p53 in primary hepatocytes

The mechanisms are poorly understood by which p53 can stimulate different downstream events, including growth arrest, DNA repair, and apoptosis, after DNA damage. Changes in protein levels do not predict a particular p53 response, but it is possible that differences in functional activities such as transactivation are important. The present report describes the successful use of a specific p53 reporter plasmid transfected into primary murine hepatocytes to evaluate p53 transactivation activity over time after two different genotoxic injuries (gamma-irradiation, 15 Gy and UV-c irradiation, 10 J/m2) known to produce p53-dependent growth arrest in this cell type. The results show that UV injury to hepatocytes was followed by a transient increase in transcriptional activation of the reporter plasmid by p53 and that this response preceded changes in p53 protein levels, as assessed by immunocytochemistry. By contrast, gamma-irradiation injury failed to induce detectable changes in either transactivation activity or hepatocyte p53 protein levels. The data show that p53 responses to DNA damage are dependent on both cell and injury type and suggest that in hepatocytes they can be independent of protein concentration and specific transcriptional activity. The results have implications for how particular dysfunctional p53 mutations in carcinogenesis could alter hepatocyte responses to different DNA injuries.

N-acetyltransferase 2 genotype in colorectal cancer and selective gene retention in cancers with chromosome 8p deletions

BACKGROUND

Genetic polymorphisms in N-acetyltransferase (NAT2) can change the normally fast acetylation of substrates to slow acetylation, and have been associated with the development of some cancers. The NAT2 locus may also suffer dysregulation during cancer progression, as the gene resides on chromosome 8p22, a region which is frequently deleted in colorectal cancer.

SUBJECTS AND METHODS

A polymerase chain reaction based method was used to determine NAT2 genotype in 275 patients with colon cancer and 343 normal control DNAs. Within the cancer group, 65 cases known to contain deletions in chromosome 8p were examined for loss of heterozygosity at the NAT2 locus.

RESULTS

Overall, there was no statistical difference in frequency or distribution of NAT2 alleles and genotype between colon cancer and control groups. There was a significant association between the slow acetylation genotype and early age of onset. NAT2 genotype did not vary with other clinical features of colon cancer, which included Dukes's stage, site of tumour, and sex. Of 48 informative cases, only three (6%) showed loss of heterozygosity, indicating that the NAT2 locus is not commonly deleted in colorectal cancer. This suggests that NAT2 is retained during the process of allele loss possibly because of its proximity to a gene necessary for cell viability.

CONCLUSIONS

NAT2 does not play a major role in colorectal cancer risk, but may influence risk in some age groups. The nature of the loss of heterozygosity at the chromosome 8p site is complex and is worthy of further study.

APC expression in normal human tissues

The tumour suppressor gene APC codes for a 2843-amino acid protein whose precise functions are still poorly understood. This paper describes the development of two new antisera to APC (to amino- and carboxy-terminal epitopes) which permit localization of the protein by immunohistochemistry in archival paraffin sections. The protein is expressed in a wide variety of normal epithelial tissues. Its distribution frequently coincides with the location of post-replicative cells within tissues. Staining patterns demonstrate that the APC protein, although often diffusely cytoplasmic in distribution, may also accumulate in the apical and immediately subapical regions, or along the lateral margins of certain cells. These results indicate that APC is significant in many tissues in addition to the colorectal epithelium. They are compatible with a function related to signalling at the adherens junction and possibly with other more complex roles in cells committed to terminal differentiation.

Apoptosis and carcinogenesis

This article attempts to summarize the rapidly advancing field of apoptosis and its regulation, with particular reference to cancer. The long-recognized stereotyped morphology of apoptosis is seen to be the result of convergence of biochemical pathways on common effector mechanisms in which a major element is activation of cysteine proteases with a preference for cleavage at aspartate residues (caspases). The substrates of this reaction are widely dispersed in the nucleus, cytoplasm and cytoskeleton. Caspase activation is the end result of protean stimuli, physiological and pathological. Pathological stimuli include damage to cell membranes, mitochondrial function, DNA and possibly other critical intracellular organelles. Several, distinct agents are known that may be part of the signaling pathways that couple injury to these cellular components to apoptosis: ceramide, collapse of mitochondrial transmembrane potential, p53 activation. Other stimuli are signaled through cytokine receptors (such as fas/APO-1/CD 95 and TNFRI and II) or transcription factors (such as p53, IRF-1 and rb). The transduction of these stimuli into caspase activation is regulated by a large family of proteins (the bcl-2 family). Cancer and apoptosis are related in many ways. In particular, this article explores the possibility that defective apoptosis may permit the persistence of damaged, mutated cells that would otherwise have been deleted. The conditions that lead to this scenario appear to be tissue-specific.

p53 Deficiency in liver reduces local control of survival and proliferation, but does not affect apoptosis after DNA damage

Despite good evidence for p53 dysfunction in human hepatocellular carcinomas, little is known of the significance of p53 to normal hepatocytes and whether p53 dysfunction is relevant to early hepatocarcinogenesis. We have therefore examined the consequences of targeted p53 deficiency in hepatocytes for regulation of apoptosis, proliferation, and ploidy. p53 deficiency was silent in normal liver and did not affect progression from diploidy to polyploidy in the aging liver. However, in primary culture the absence of p53 resulted in increased hepatocyte proliferation indices and decreased sensitivity to proliferation inhibition by TGFbeta. Moreover, p53-deficient cells continued to survive and proliferate under conditions of minimal trophic support that led to growth arrest and apoptosis of wild-type cells. In vivo, p53-deficient mice had enhanced proliferative responses to both xenobiotic hepatomitogen and CCl4-induced liver necrosis, although lack of persistent proliferation showed that other control mechanisms are important. There was no simple relationship between p53 and apoptosis after DNA damage because UV irradiation led to p53-independent apoptosis, even though p53 was stabilized. However, p53 did couple DNA damage to growth arrest, and abnormal mitoses after gamma-irradiation of regenerating p53 null livers demonstrated circumstances where loss of G1 and G2 checkpoints may generate abnormal ploidy. Thus p53 becomes important when hepatocytes are released from G0 and stressed, sensitizing them to mitogen and cytokine regulators of cell cycle progression and apoptosis. Hence p53 deficiency is likely to be significant in an environment of persistent regenerative stimuli and unfavorable trophic support or in the presence of other enabling genetic lesions. This model is relevant to human hepatocarcinogenesis, which almost always occurs against a background of chronic hepatocellular destruction in hepatitis and cirrhosis. In that context, by reducing the need for cytokine support and disabling DNA damage-induced growth arrest, p53 deficiency should facilitate the expansion of preneoplastic clones in chronic liver disease.

The pattern of K-ras mutation in pulmonary adenocarcinoma defines a new pathway of tumour development in the human lung

Codon 12 of the K-ras oncogene was screened for mutations in 65 surgically-resected primary pulmonary adenocarcinomas and in 32 tissue foci of alveolar atypical hyperplasia (AAH) by a polymerase chain reaction (PCR)-based method. Mutations in either position 1 or position 2 of codon 12 were detected in 16 tumours (25 per cent). When analysed by site of origin, mutations were seen in 9/26 (35 per cent) parenchymal and in 0/12 bronchial adenocarcinomas (P < 0-02), K-ras mutations were seen in five AAH lesions from four patients. DNA sequencing showed that the great majority of mutations in both adenocarcinomas and AAH were G-T transversions. These findings provide support for the classification of pulmonary adenocarcinomas into bronchial and parenchymal subtypes and also provide molecular evidence to support the importance of AAH in the development of parenchymal cancers.