Detection of high incidence of K-ras oncogenes during human colon tumorigenesis

p53 protein expression in ulcerative colitis-associated colorectal dysplasia and carcinoma

The frequency and timing of p53 inactivation in ulcerative colitis (UC)-associated tumorigenesis were investigated using immunohistochemistry (IHC) to detect p53 protein overexpression in 56 carcinomas and 40 dysplastic epithelia derived from 58 patients with UC undergoing colectomy for neoplasia. p53 DNA in 25 of the carcinomas also was evaluated by single-strand conformation polymorphism analysis (SSCP) to detect point mutations in exons 5-8 and by loss of heterozygosity analysis to detect allelic deletions. Point mutations were detected in 20 of the 25 carcinomas (80.0%) undergoing both IHC and DNA analysis. One carcinoma contained an allelic deletion but no mutations of the corresponding allele within the region tested. p53 overexpression occurred in 16 (76.2%) of the 21 carcinomas with point mutations and/or allelic deletions but not in any of those with wild type DNA. Of the 56 carcinomas evaluated by IHC, p53 overexpression occurred in 34 carcinomas (60.7%). The proportion of positive tumors was independent of stage, anatomic location, differentiation, and histological subtype. Overexpression was observed in nine of 20 dysplastic masses devoid of and situated remote from carcinoma (45.0%) and correlated positively with increasing grade of dysplasia (P < .025). In contrast, overexpression occurred in 16 of 20 dysplastic epithelia situated adjacent to carcinoma (80.0%) and correlated with overexpression by the corresponding carcinomas but not with the grade of dysplasia present (P = .013). It is concluded that p53 overexpression can be detected by IHC in most, although not all, UC-associated carcinomas with p53 mutations and/or allelic deletions. Based on this method, p53 overexpression occurs frequently in UC-associated carcinomas regardless of stage and pathological characteristics, in noncancerous dysplastic masses with high grade dysplasia, and in dysplasias of all grades situated adjacent to carcinomas. These findings implicate p53 inactivation in the progression from dysplasia to carcinoma in UC and suggest that its occurrence in dysplastic epithelium may be an independent marker of malignant potential.

Point mutation of K-ras gene codon 12 in biliary tract tumors

BACKGROUND/AIMS

Point mutations of the K-ras gene have been reported in a wide variety of human tumors. However, there might be conflicting data about its presence or incidence in biliary tract tumors. The aim of this study is to elucidate the presence and types of point mutation in biliary tract tumors, including gallbladder carcinoma and adenoma, extrahepatic bile duct carcinoma, and ampullary carcinoma.

METHODS

Mutation bands detected in modified two-step polymerase chain reaction were eluted from agarose gel and analyzed by dideoxy sequencing method.

RESULTS

Of 20 biliary tract tumors showing a mutation band, G to A single base substitutions were confirmed in 15 cases as the most frequent changes, which were divided into changes for aspartic acid (GAT) and (14) serine (AGT) (1). Changes for valine (GTT) were found in two cases. In extrahepatic bile duct carcinoma, duplicate mutations (GA/TT) were found in two cases and triplicate mutation (A/GA/TT) in one case. The adenoma portion of one "cancer in adenoma" case of gallbladder showed the single base transition (GAT) in the second position, same as in the carcinoma portion.

CONCLUSIONS

Most of the biliary tract tumors comprised point mutation in K-ras gene codon 12, and G to A transition was the most frequent.

Clonal variation of tumorigenic potential in v-Ha-ras-transformed human bronchial epithelial cells: relationship to ras oncogene expression and CAD gene amplification

Infection of an SV40 large-T antigen-"immortalized" human bronchial epithelial cell line with a Zip-v-Ha-ras retroviral vector resulted in a mass culture that was tumorigenic in athymic nude mice. A tumor cell line derived from passage of the mass culture in vivo, however, exhibited increased tumorigenicity and v-Ha-ras expression. To examine and compare the molecular events involving the ras oncogene during cell transformation in vitro and subsequent tumor formation in vivo, clonal cell populations were isolated from the v-Ha-ras-transformed mass culture. While the clonal cell lines exhibited diverse tumorigenic profiles, these differences did not correlate with v-Ha-ras expression. However, the expression of the activated ras gene, while not necessary for growth in vitro, did appear to be associated with a selective growth advantage in vivo. In addition, the modulation of gene amplification ability in these cells was not associated with the induction of tumorigenicity or v-Ha-ras expression.

p53 mutations in flat- and polypoid-type colorectal tumors detected by temperature-gradient gel electrophoresis

Reports of cases of flat-type colorectal tumors are increasing in Japan, but almost nothing has been elucidated about the genetic abnormalities of these tumors. In this study, we have examined p53 mutations in six cases of colon cancer cell lines, 22 cases of flat-type colorectal tumors, and 27 cases of polypoid-type colorectal tumors using the polymerase chain reaction (PCR) and temperature-gradient gel electrophoresis (TGGE); the latter has recently been developed as a screening method for gene mutations. p53 mutations were observed in four colon cancer cell lines, six flat-type colorectal tumors, and three polypoid-type colorectal tumors, all of which were analyzed by direct sequencing. These mutations were observed only in adenomas with high-grade dysplasia and in colorectal cancers but not in adenomas with low-grade dysplasia. These observations suggest that p53 gene mutations are involved in flat-type as well as polypoid-type colorectal tumors at relatively later stages of carcinogenesis and that TGGE seems to be useful as one of the rapid screening methods.

Ki-ras oncogene activation in transplantable rat thyroid carcinoma induced by N-bis(2-hydroxypropyl)nitrosamine

We have established 17 transplantable rat thyroid carcinoma cell lines from primary thyroid tumors of rats induced by N-bis(2-hydroxypropyl)nitrosamine (DHPN) (Cancer Res. (1993) 53, 4408-4412). The present study was designed to evaluate point mutations in the murine c-Ki-ras gene of these carcinoma cell lines. Using PCR amplification and direct sequencing, we found that the activated form of the Ki-ras oncogene was present in 4 (23%) of a total of 17 cell lines, all the Ki-ras gene mutations being GC-->AT transitions. In three of the cell lines, the mutations occurred in codon 12 (GTP-binding domain), and in the remaining one the first nucleotide of codon 63 was affected. Histologically, three of the carcinomas with Ki-ras mutation were diagnosed as well-differentiated carcinomas, and the other as poorly differentiated carcinoma. Mutations of the ras gene are relatively uncommon in tumors of these histological types. From these experimental results, we suggest that the mutation induced by DHPN is due to damage to guanine in cellular DNA. In addition, Ki-ras activation may play an important role in the initiation of thyroid carcinogenesis.

Molecular genetic profiles of colitis-associated neoplasms

BACKGROUND/AIMS

A major long-term risk for patients with chronic idiopathic colitis is the development of colorectal dysplasia and adenocarcinoma. The presence or absence of specific genetic changes in these lesions will provide important insights into the relationship of colitis-associated dysplasia and the development of carcinoma.

METHODS

A case-study approach was used to develop detailed molecular genetic profiles of advanced dysplasias and carcinomas from six patients with ulcerative colitis or Crohn's colitis.

RESULTS

Numerous genetic alterations were identified in each of the dysplasias and carcinomas profiled. These genetic alterations involved many of the same targets found in sporadic colorectal tumors and included multiple sites of allelic deletion, microsatellite instabilities, and mutations of the K-ras, p53, and APC genes. The progression of dysplasia to carcinoma was often accompanied by an accumulation of these mutations.

CONCLUSIONS

Genetic alterations are common in colitis-associated neoplasia, just as in sporadic colorectal neoplasia. This could have important implications for the evaluation and treatment of patients with colitis.

Mutations in ras genes in cells cultured from mouse skin tumors induced by ultraviolet irradiation

Mutations in ras oncogenes were detected in cultured cells of mouse skin tumors induced by near-UV irradiation. DNA extracted from the UV-induced tumor cells was transfected to golden hamster embryo cells, and focus-forming ability was confirmed in 22 of 26 cell strains, 15 of which had the repetitive mouse sequence. Mouse ras genes were detected in 10 of these 22 cell strains. Point mutations in the ras genes were at Ha-ras codon 13 (GGC-->GTC in two strains, GGC-->AGC in one strain), Ki-ras codon 61 (CAA-->GAA in two strains), and N-ras codon 61 (CAA-->CAT in two strains, CAA-->AAA in two strains). In one tumor cell strain no base change was directed. Most mutations occurred at dipyrimidine sites. Pyrimidine dimers or pyrimidine(6-4)pyrimidone photoproducts are the likely cause of the skin cancers. The base change occurred preferentially at G.C base pairs, and transversions predominated.

K-ras gene point mutation: a stable tumor marker in non-small cell lung carcinoma

K-ras gene point mutation is a highly frequent event in human malignancy. About one third of non-small cell lung cancer (NSCLC) patients harbor K-ras gene point mutational activations. This study investigates the prevalence of K-ras mutation in autopsy tumors with NSCLC, and the correlation of K-ras gene point mutations between primary tumors and metastases in NSCLC. Formalin-fixed, paraffin-embedded tissue sections of 15 primary lung tumors and their metastases, (obtained from autopsy), were examined for the presence of point mutations in K-ras gene codon 12, 13 and 61 by oligodeoxynucleotide hybridization analysis of DNA fragments, amplified by polymerase chain reaction (PCR). K-ras gene point mutations were detected in five cases of lung carcinoma, of which four were adenocarcinomas and one was squamous cell carcinoma. In each of these cases, identical K-ras gene mutations were found in the DNA of both the primary tumor and its corresponding distant metastases. Activating K-ras base-substitutions correlate well between the primary tumor and its corresponding metastases in NSCLC. In the negative cases where no K-ras mutation was found in the primary tumors, no newly acquired K-ras mutation appeared in the metastases. Our study indicates that K-ras point mutation serves as a stable tumor marker in NSCLC.

Colorectal cancer: lessons for genetic counselling and care for families

Cancers of the colon and the rectum are the second leading cause of malignancy in European countries with similar incidence rates for men and women and, therefore, one of the major health concerns. Emphasis is placed on the early detection of a developing neoplasm in order to improve the life expectancy of patients and their quality of life. Colorectal cancer (CRC) is an excellent model for studying the etiology and pathogenesis of a common malignancy and the complex multistage process of carcinogenesis. Abundant clinical and pathological evidence suggests that CRC arises from benign adenomas that proceed through a series of steps to metastatic carcinomas. Following the discovery of oncogenes and, more importantly tumor suppressor genes, Fearon & Vogelstein (1990) proposed a scheme of genetic events which are associated with colorectal tumorigenesis. Genetic linkage studies have recently identified another type of gene for colon cancer susceptibility that seems to act by destabilising the genome.

Frequency of H-ras mutations in human bladder cancer detected by direct sequencing

OBJECTIVE

To determine the frequency of mutations of the H-ras gene in transitional cell carcinomas of the human urinary bladder using direct DNA sequencing based on the polymerase chain reaction (PCR) method and to compare the results with those of other methods. In addition, the relationship of the mutation frequency to tumour stage and grade was examined.

PATIENTS AND METHODS

Bladder tumour samples, taken by cystoscopic resection from 50 patients with newly diagnosed transitional cell carcinoma of the urinary bladder, were analysed by PCR-based direct DNA sequencing for point mutations in the H-ras gene at codon 12.

RESULTS

Point mutations were found in 9 of 50 tumours examined (18%). The most frequent mutation (8/9) was a G to T transversion converting GGC to GTC, which would result in a glycine to valine substitution. The remaining mutations was a G to A transition altering GGC to GAC, producing a glycine to aspartic acid substitution, which has not previously been reported in bladder cancer. In all tumour samples examined the wild-type allele (GGC) was also evident. Variation in the proportion of wild-type to mutated sequence was found within tumour samples. No relationship between mutations and tumor grade and stage was apparent.

CONCLUSION

The frequency of H-ras mutations detected in this first large scale study using the highly sensitive and rapid PCR-based sequencing method was comparable to that reported by earlier studies with the nude mouse tumorigenesis variation of the 3T3 transfection assay. H-ras mutations can be early events in the development and progression of a significant proportion of human bladder cancer cases.

Non-involvement of ras mutations in flat colorectal adenomas and carcinomas

Ras gene mutations occur relatively early during colorectal tumor development and have been observed in 40-50% of malignant colorectal tumors. Advances in endoscopic techniques have made it possible to detect small, flat colorectal tumors that could not be detected by standard examinations. To determine whether ras gene mutations are also involved in the genesis of small, flat colorectal tumors, we examined ras point mutations in 34 cases of small polypoid or flat elevated colorectal tumors (32 adenomas, 2 carcinomas) and in 26 cases of small, flat colorectal tumors (13 adenomas, 13 carcinomas) by means of the polymerase chain reaction (PCR) and dot-blot hybridization. Ras gene point mutations were observed in 16 of the 34 tumors of the former type (47%), but in none of the 26 tumors of the latter type, even though the grade of dysplasia was severe in the flat tumors. Our results suggest that different genetic pathways for tumor progression may exist for polypoid and for flat colorectal carcinomas.

Molecular genetics for clinical management of colorectal carcinoma. 17p, 18q, and 22q loss of heterozygosity and decreased DCC expression are correlated with the metastatic potential

BACKGROUND

The molecular genetic changes associated with colorectal carcinoma are among the best understood of any common human cancer. The genetic changes during the late stages of colorectal carcinomas may be useful in clinical management for determining the metastatic potential of the carcinoma.

METHODS

Tumor tissues were evaluated by restriction fragment length polymorphism (RFLP) analysis of chromosomes 5q, 17p, 18q, and 22q (n = 98), by reverse transcription-polymerase chain reaction (RT-PCR) analysis of messenger RNA expression of the DCC gene (deleted in colorectal carcinoma) (n = 27) and by immunohistochemical analysis of p53 protein expression (n = 44).

RESULTS

Loss of heterozygosity (LOH) on chromosomes 17p, 18q, and 22q, but not on 5q, was much more frequently detected in advanced carcinomas than in intramucosal carcinomas (P < 0.01). 17p LOH was significantly correlated with vascular invasion (P < 0.001), whereas 18q LOH was correlated with lymphatic invasion and hepatic metastasis (P < 0.01), and 22q LOH was correlated with lymph node metastasis (P < 0.05). LOH on 5q did not show a significant correlation with any factors of tumor invasion or metastasis. DCC expression was not observed in any of five hepatic metastasis or in five of seven advanced carcinomas that were accompanied by hepatic metastasis (10 of 12). However, a similar lack of expression was observed in only 5 of 15 carcinomas without hepatic metastasis (P < 0.05). p53 Expression was found to vary in both primary and metastatic carcinomas by immunohistochemistry.

CONCLUSIONS

The clinical application of molecular genetics (i.e., RFLP analysis of chromosome 17p, 18q, and 22q and RT-PCR analysis of DCC expression into messenger RNA) can be used to determine the metastatic potential of colorectal carcinomas.

Genomic instability in repeated sequences is an early somatic event in colorectal tumorigenesis that persists after transformation

Genomic instability at simple repeated sequences (SRS) is a landmark for some sporadic and hereditary cancers of the colon. We have identified several human tumour cell lines with up to 1,000-fold increases in mutation rates for endogenous microsatellite sequences, relative to normal cells or tumour cells without the mutator phenotype and show that they are very early events in tumorigenesis. Our in vivo and in vitro results show that the genomic instability persists after transformation and that microsatellite mutations accumulate as consecutive somatic slippage events of a single or a few repeated units. This mechanism may account for the repeat expansions in triplet hereditary diseases and the same defect in replication fidelity in non-polyposis colon cancer could also contribute to the non-mendelian anticipation in these diseases.

Two-dimensional electrophoretic analysis of proteins expressed by normal and cancerous human crypts: application of mass spectrometry to peptide-mass fingerprinting

Protein patterns of normal human colonic crypts, isolated from different regions of the large intestine, and several colorectal cancer cell lines were compared using two-dimensional electrophoresis gels (2-DE). As detected by intrinsic radiolabeling and Coomassie Brilliant Blue staining, the protein patterns for normal crypts isolated from the ascending, and descending, regions of the colon and the rectum, were almost (> 95%) identical. While 75-80% of the protein spots from normal crypts and the colorectal cancer cell line (LIM 1863), a cell line that grows as organoids and differentiates spontaneously into crypt-like structures in vitro, can be matched, the relative expression levels of a large number of proteins differ. At least two protein spots (undetectable in the protein pattern from normal cells), proteins a (M(r) approximately 18,000, pI 6.7-6.9) and b (M(r) approximately 24,000, pI 5.9-6.0), were detected in the 2-DE gel protein pattern in the three cell lines LIM 1863, LIM 1215 and LIM 1899. The identity of these proteins is not yet known and further studies are required before they can be considered as potential colon tumor markers. Approximately 60% of the cellular proteins from LIM 1215 cells, a colon carcinoma cell line that exhibits many properties associated with columnar cells, can be matched with LIM 1863 cells. The results presented here represent an initial phase in our efforts to develop a comprehensive protein database for normal human colon cells and several colorectal cancer cell lines. While our initial protein identification relied on microsequencing methodologies, we are presently evaluating peptide-mass fingerprinting, utilizing capillary reversed-phase high-performance liquid chromatography (RP-HPLC) and electrospray mass spectrometry, as a means for rapid identification of proteins at subpicomole levels. Using this approach, protein #3 (M(r) approximately 66,000, pI 6.2) was identified as heat shock protein 60 from as few as seven tryptic peptide masses when they were screened against the molecular weight search (MOWSE) peptide-mass database.

Detection of c-Ki-ras gene mutation in paraffin sections of adenocarcinoma and atypical bronchioloalveolar cell hyperplasia of human lung

DNA of minute specimens taken from formalin-fixed and paraffin-embedded tissue was used as a template for the polymerase chain reaction (PCR) to examine whether the c-Ki-ras gene is activated in atypical bronchioloalveolar cell hyperplasia (ABH) of human lung. The c-Ki-ras gene was successfully amplified on 131 samples from 29 cases of lung adenocarcinoma (87.3% of all samples used as templates) by the nested PCR method. Point mutations at codon 12 of the c-Ki-ras gene could be detected in carcinoma tissue of 6 cases (20.7% of all cases), also detected in ABHs showing moderate to severe atypia of 2 cases. PCR amplification is a useful technique for studying pin-point pathological lesions in a routine paraffin section at the molecular level.

Activation of c-fos expression by transforming Ha-ras in HC11 mouse mammary epithelial cells is PKC-dependent and mediated by the serum response element

The mechanism by which transforming Ha-ras induces c-fos expression in HC11 mouse mammary epithelial cells was investigated with regard to controversial data concerning the role of protein kinase C (PKC) and the required promoter elements of the fos gene. HC11 cells carrying a glucocorticoid-inducible Ha-ras (val12) construct were transfected with a chloramphenicol acetyltransferase (CAT) reporter gene under the control of a human fos promoter which includes the serum response element (SRE), the adjacent c-fos AP-1 site (FAP) and the cAMP response element (CRE). Induction of the Ha-ras gene by dexamethasone lead to a transactivation of expression of the transfected fos promoter construct which was inhibited by the PKC inhibitor BM41440 and abrogated in PKC-'depleted' cells. A similar transactivation was observed when the fos promoter construct was co-transfected with a constitutively active ras expression vector. Again, this effect was depressed by the PKC inhibitor and abolished in PKC-'depleted' cells. 'PKC-depletion' was achieved by long-term exposure to 12-O-tetradecanoylphorbol-13-acetate. This procedure was shown to deplete cells of PKC alpha and to reduce significantly PKC epsilon. Long-term exposure to bryostatin 1 selectively depletes PKC alpha. Depletion of PKC alpha by bryostatin 1 does not reduce the transcriptional activation of the SRE-FAP-TK-CAT (TK: thymidine kinase) construct by Ha-ras. In order to delineate the promoter elements mediating the transcriptional activation, constructs which lack the FAP and the CRE sites but contain an intact SRE were co-transfected with the ras construct. Elimination of the FAP and CRE sequences did not affect the transcriptional activation by Ha-ras (val12). It is concluded that in HC11 cells, transforming Ha-ras activates c-fos expression in a PKC-dependent manner, presumably implying PKC epsilon, and that the SRE is sufficient to mediate transcriptional activation.

Comparison of the low energy conformations of an oncogenic and a non-oncogenic p21 protein, neither of which binds GTP or GDP

Oncogenic p21 protein, encoded by the ras-oncogene, that causes malignant transformation of normal cells and many human tumors, is almost identical in sequence to its normal protooncogene-encoded counterpart protein, except for the substitution of arbitrary amino acids for the normally occurring amino acids at critical positions such as Gly 12 and Gln 61. Since p21 is normally activated by the binding of GTP in place of GDP, it has been postulated that oncogenic forms must retain bound GTP for prolonged time periods. However, two multiply substituted p21 proteins have been cloned, neither of which binds GDP or GTP. One of these mutant proteins with Val for Gly 10, Arg for Gly 12, and Thr for Ala 59 causes cell transformation, while the other, similar protein with Gly 10, Arg 12, Val for Gly 13 and Thr 59 does not transform cells. To define the critical conformational changes that occur in the p21 protein that cause it to become oncogenic, we have calculated the low energy conformations of the two multiply substituted mutant p21 proteins using a new adaptation of the electrostatically driven Monte Carlo (EDMC) technique, based on the program ECEPP. We have used this method to explore the conformational space available to both proteins and to compute the average structures for both using statistical mechanical averaging. Comparison of the average structures allows us to detect the major differences in conformation between the two proteins. Starting structures for each protein were calculated using the recently deposited x-ray crystal coordinates for the p21 protein, that was energy-refined using ECEPP, and then perturbed using the EDMC method to compute its average structure. The specific amino acid substitutions for both proteins were then generated into the lowest energy structure generated by this procedure, subjected to energy minimization and then to full EDMC perturbations. We find that both mutant proteins exhibit major differences in conformation in specific regions, viz., residues 35-47, 55-78, 81-93, 96-110, 115-126, and 123-134, compared with the EDMC-refined x-ray structure of the wild-type protein. These regions have been found to be the most flexible in the p21 protein bound to GDP from prior molecular dynamics calculations (Dykes et al., 1993). Comparison of the EDMC-average structure of the transforming mutant with that of the nontransforming mutant reveals major structural differences at residues 10-16, 32-40, and 60-68. These structural differences appear to be the ones that are critical in activation of the p21 protein.(ABSTRACT TRUNCATED AT 400 WORDS)

Mutations of Ki-ras oncogene codon 12 in betel quid chewing-related human oral squamous cell carcinoma in Taiwan

In Taiwan, there are two million people who have a betel quid chewing habit, and approximately 80% of all oral cancer deaths are associated with this habit. To investigate the incidence and types of Ki-ras codon 12 mutations in oral cancer associated with betel quid chewing, we used a sensitive mutation-specific two-stage polymerase chain reaction (PCR) technique to examine human oral squamous cell carcinomas from formalin-fixed, paraffin-embedded tissues. DNA sequence analysis of PCR products revealed that 6 of 33 (18%) tumour specimens contained Ki-ras codon 12 mutations. Four of the tumours contained more than one mutation. Three different base changes were detected, resulting from a substitution of wild type glycine (GGT) to either serine (AGT), aspartic acid (GAT) or cysteine (TAT). These results indicate that Ki-ras oncogene activation may play a role in the oncogenesis of betel quid chewing-related human oral squamous cell carcinomas.

Conserved cis-elements bind a protein complex that regulates Drosophila ras2/rop bidirectional expression

The Drosophila ras2 promoter region exhibits bidirectional activity, as has been demonstrated for the human c-Ha-ras1 and the mouse c-Ki-ras. Here we address a unique case of ras regulation, as Drosophila ras2 provides the only example to date in which the flanking gene (rop) and its product have been isolated. A linking mechanism of control suggests a mutual interaction between the two gene products. Our studies indicate that the Drosophila ras2 promoter region shares with the human c-Ha-ras1 promoter a CACCC box and an AP-1-like sequence. A 14 bp promoter fragment which holds a CACCC element is demonstrated to interact with a specific transcription factor (factor B). This CACCC promoter element represents a stretch of imperfect palindrome. We present evidence that this factor can form a complex with another specific DNA-binding protein (factor A). The binding sites (A + B) for these protein factors are essential for 95% expression of both genes flanking the promoter (ras2 and rop). Region A consists of four overlapping consensus sequences: a TATA-like element, a DSE-like motif (the core sequence of the serum response element), a DRE octamer, which has been shown to play a role in cell proliferation, and a 5 bp direct repeat representing the GATA consensus sequence. Factor A has a very weak affinity to the full promoter region, but when complexed with factor B binding efficiency is enhanced. We also show that alterations of DNA-protein binding specificities can be achieved by supplementing the growth media with different sera.

Lower incidence of K-ras codon 12 mutation in flat colorectal adenomas than in polypoid adenomas

In order to clarify genetic changes in flat adenomas, K-ras codon 12 point mutations were examined in 56 flat adenomas, 81 polypoid adenomas and 42 cancers of colon and rectum. The mutation frequency in flat adenomas was 23% (13/56), significantly lower than that in polypoid adenomas (67%: 54/81) and cancers (76%: 32/42). Even mildly dysplastic adenomas or small (less than 5 mm) adenomas showed higher mutation incidence in polypoid type (62%, 57%) than in flat type (23%, 19%). Among flat adenomas, flat elevated lesions exhibited relatively higher mutation frequency than completely flat or depressed ones. As for cancers, 14 tumors (33%) contained mutations only in a minor tumor cell population, indicating that these mutations occur at a late stage of tumorigenesis. These results suggest that the adenoma-carcinoma sequence through flat adenomas may be different from that through polypoid adenomas, and genetic changes may be heterogeneous in colorectal carcinogenesis.

Primary retroperitoneal mucinous cystoadenocarcinomas: an immunohistochemical and molecular study

Special immunohistochemical stains for the identification of gastroenteropancreatic antigens in two cases of primary retroperitoneal mucinous cystoadenocarcinomas (PRMC) show that these tumours have patterns similar to ovarian mucinous tumours. Markers of pyloric type gastric mucosa differentiation (M1, cathepsin E, concavavalin A, pepsinogen II) are mostly positive in benign and borderline areas with endocervical type differentiation, while immunoreactivity for intestinal cell markers (M3SI and CAR-5) and for DU-PAN-2 is present mainly in frankly malignant areas, regardless of differentiation type. DNA analysis shows a point mutation of K-ras oncogene at codon 12 (GGT to CGT) in one case. The immunohistochemical and genotypic similarity of PRMC and ovarian mucinous tumours may indicate similar mechanisms in their histogenesis.

The detection of the c-myc and ras oncogenes in nasopharyngeal carcinoma by immunohistochemistry

Forty-one paraffin embedded specimens of primary nasopharyngeal carcinoma (NPC) were examined to investigate the expression of c-myc and ras oncogenes. Sections were stained with the monoclonal antibodies myc 1-9E10 or ras Y13-259 and binding was detected using the ABC method. The intensity of staining for each tumour was assessed as nil, moderate or intense. The results indicated that 9 (22%) had intense staining for the c-myc oncogene, 28 (68%) had moderate staining and only 4 (10%) showed no staining. For the ras oncogene, 8 (19%) had intense staining, 22 (54%) moderate staining and 11 (27%) showed no staining. The patient's clinical data indicated no correlation between the expression of either c-myc or ras p21 and age, sex, smoking, tumour stage, antibody titre to EBV, or family history. No correlation was found between ras p21 expression and survival; however, overexpression of the c-myc oncogene correlated with a poor prognosis (p < 0.05). This study is consistent with investigations demonstrating that c-myc expression correlates with poor survival in head and neck tumours.

Neoplastic progression of human and rat intestinal cell lines after transfer of the ras and polyoma middle T oncogenes

BACKGROUND

Activation of the p21ras and pp60c-src oncoproteins occurred at high incidence in the early stage of human colorectal carcinogenesis. Our study aimed to investigate the role of these signal-transduction pathways in the process of initiation and promotion of the malignant phenotype in intestinal cells.

METHODS

The human Ha-ras and the polyoma middle T (Py-MT) viral oncogenes were transferred into large T oncogene of simian virus 40 immortalized rat intestinal epithelial SLC-44 cells and human colonic adenocarcinoma Caco-2 cells.

RESULTS

These transfers conferred the tumorigenic and invasive phenotypes on immortalized SLC-44 cells and potentiated the tumorigenicity of Caco-2 cells and markedly repressed the terminal differentiation of this cell line. In SLC-44T cells, induction of the invasive phenotype by the activated Ha-ras oncogene correlated with weak expression of E-cadherin and reduced accumulation of the transcripts encoding the basement membrane components alpha 1 (IV) collagen, nidogen, and BM40, which might result partly from the inactivation of the transforming growth factor beta signaling pathway. The down-regulation of the alpha 1 (IV) collagen messenger RNA in SLC-44T cells was not due to the protein kinase C-dependent pathways or the secretion of autocrine factor(s).

CONCLUSIONS

These results suggest that the activation of the p21ras and Py-MT/pp60c-src oncogenic pathways are critical effectors at different stages of colorectal carcinogenesis and in Caco-2 cells interferes with the program of enterocyte differentiation.

Molecular dynamics of the H-ras gene-encoded p21 protein; identification of flexible regions and possible effector domains

We previously reported a complete computer-based three-dimensional structure for residues 1-171 of the Gly 12-containing ras-gene-encoded p21 protein complexed with GDP. This structure was subsequently shown to closely agree with a high-resolution x-ray crystallographic structure of p21. In this communication, we report a molecular dynamics stimulation of the modelled structure in an explicit shell of water molecules to identify domains within the protein that are unusually flexible. These domains represent regions which are most likely to undergo important conformational changes when the protein is activated by binding to GTP or by oncogenic amino acid substitutions such as Val for Gly 12. The starting structure was surrounded with water molecules, temperature-equilibrated and then followed over a 100 ps trajectory during which time the energy converged after about 50 ps. Regions of the protein that were found to have the largest coordinate fluctuations involved residues 12-16, 30-35, 40-52, 60-73, 85-89, 101-109, 119-123, and 127-131. Many of these sequences with high flexibility have been implicated in the functioning of this protein. Since the overall largest fluctuations were observed for residues 101-106 and 119-123, p21 peptides containing these residues (96-110 and 115-126) were synthesized and were found to inhibit strongly the effects of oncogenic p21 protein in an oocyte maturation assay. These results indicate that the flexible p21 sequences may constitute critical functional domains of the activated protein and that this general approach may be useful for identification of important functional domains in proteins.

Transgenic mouse models that explore the multistep hypothesis of intestinal neoplasia

SV-40 T antigen (TAg), human K-rasVal12, and a dominant negative mutant of human p53 (p53Ala143) have been expressed singly and in all possible combinations in postmitotic enterocytes distributed throughout the duodenal-colonic axis of 1-12-mo-old FVB/N transgenic mice to assess the susceptibility of this lineage to gene products implicated in the pathogenesis of human gut neoplasia. SV-40 TAg produces re-entry into the cell cycle. Transgenic pedigrees that produce K-rasVal12 alone, p53Ala143 alone, or K-rasVal12 and p53Ala143 have no detectable phenotypic abnormalities. However, K-rasVal12 cooperates with SV-40 TAg to generate marked proliferative and dysplastic changes in the intestinal epithelium. These abnormalities do not progress to form adenomas or adenocarcinomas over a 9-12-mo period despite sustained expression of the transgenes. Addition of p53Ala143 to enterocytes that synthesize SV-40 TAg and K-rasVal12 does not produce any further changes in proliferation or differentiation. Mice that carry one, two, or three of these transgenes were crossed to animals that carry Min, a fully penetrant, dominant mutation of the Apc gene associated with the development of multiple small intestinal and colonic adenomas. A modest (2-5-fold) increase in tumor number was noted in animals which express SV-40 TAg alone, SV-40 TAg and K-rasVal12, or SV-40 TAg, K-rasVal12 and p53Ala143. However, the histopathologic features of the adenomas were not altered and the gut epithelium located between tumors appeared similar to the epithelium of their single transgenic, bi-transgenic, or tri-transgenic parents without Min. These results suggest that (a) the failure of the dysplastic gut epithelium of SV-40 TAg X K-rasVal12 mice to undergo further progression to adenomas or adenocarcinomas is due to the remarkable protective effect of a continuously and rapidly renewing epithelium, (b) initiation of tumorigenesis in Min mice typically occurs in crypts rather than in villus-associated epithelial cell populations, and (c) transgenic mouse models of neoplasia involving members of the enterocytic lineage may require that gene products implicated in tumorigenesis be directed to crypt stem cells or their immediate descendants. Nonetheless, directing K-rasVal12 production to proliferating and nonproliferating cells in the lower and upper half of small intestinal and colonic crypts does not result in any detectable abnormalities.

Genetics, molecular biology and colorectal cancer

Colorectal cancer (CRC) develops through several histologically well-defined stages, reflecting the sequential acquisition of genetic alterations. Several frequently mutated genes have been identified which probably contribute to the development of both hereditary and sporadic cancer (reviewed in Bishop and Thomas, 1990; Fearon and Vogelstein, 1990; Fearon and Jones, 1992; Hamilton, 1992). Several generalizations emerge from this work. Mutations are observed in the earliest detectable stages of cancer development. Specific genes tend to be mutated in a given order, but it is the accumulation of a critical number of lesions which governs the appearance of neoplasia. Mutations actively promote neoplastic character by activating oncogenes and eliminate restraints on neoplastic character by inactivating tumour suppressor genes.

Carcinogenic factors in food with relevance to colon cancer development

The diet contains various mutagens and carcinogens that can be classified into three groups: naturally occurring chemicals, synthetic compounds and compounds produced by cooking. The first group includes mycotoxins and plant alkaloids while the second is exemplified by food additives and pesticides. The third includes polycyclic aromatic hydrocarbons and heterocyclic amines (HCAs). HCAs are mutagenic to microbes and eukaryotes and their precursors are creatine or creatinine, sugars, and amino acids in meat and fish. Among 10 HCAs so far examined for carcinogenicity in rodents, 2-amino-6-methyldipyrido[1,2-a:3',2'-d]imidazole (Glu-P-1), 2-aminodipyrido[1,2-a:3',2'-d]imidazole (Glu-P-2), 2-amino-3-methylimidazo[4,5-f]quinoline (IQ), 2-amino-3,4-dimethylimidazo[4,5-f]quinoline (MeIQ) and 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) induced colon cancer in rats. PhIP is an especially interesting compound inducing colon tumors specifically in male F344 rats and only very rarely in females, which develop mammary carcinomas at high frequency instead. Since induced DNA adduct levels, determined by the 32P-postlabeling method, were found to be almost the same in male and female F344 rats adduct formation in itself is not directly responsible for carcinogenesis. We established, however, that PhIP causes increased cell proliferation in colon mucosa but not in the non-target liver or kidney of male rats. Induction of cell proliferation is therefore possibly an additional important factor determining carcinogenic organ specificity. In terms of molecular alteration ras family gene mutations are very rare and no mutations are evident in the p53 gene in colon tumors induced by HCAs. Their development due to HCAs can thus be considered an appropriate experimental model for human colon tumors in which ras or p53 gene activation is not involved. Since HCAs are genotoxic compounds, a causal role in some stage of human colon carcinogenesis is plausible. Exposure to HCAs should accordingly be avoided as far as possible.

The point mutation of c-Ki-ras at codon 12 in carcinoma of the pancreatic head region and in intraductal mucin-hypersecreting neoplasm of the pancreas

In order to clarify whether the detection of a point mutation in the c-Ki-ras gene at codon 12 in tumor tissues can assist in predicting the tumor's biological grade of malignancy, two types of tumors were investigated; one was called "carcinoma in the pancreatic head region," and the other was intraductal mucin-hypersecreting neoplasm of the pancreas (IMHN). Dot hybridization and a modified PCR technique developed by Haliassos et al. were employed. Among 16 cases of tumors in the pancreatic head region, the point mutation was detected with a high frequency only in pancreatic ductal cell carcinomas (five out of six cases, 83.3%), but was not detected in extrahepatic bile duct carcinomas (0/5) or in ampullary carcinomas (0/5). In pancreatic ductal cell carcinomas, no relation was found between the occurrence of the point mutation and the histological type of the tumor. Among 20 cases of IMHNs, the point mutation was found in 11 cases (55%). No relation was found between the occurrence of the mutation and the size of IMHNs. However, as the grade of cell atypia increased, the frequency of the mutation tended to become higher. These results suggest that detection of this point mutation might be useful for distinguishing pancreatic ductal cell carcinoma from those of other origins in the pancreatic head region, and for the determination of the histopathological grade of malignancy in IMHNs.

Point mutation of the ras oncogene in human ovarian cancer

The ras oncogene exists in a variety of human cancers, including carcinomas of bladder, breast, colon, kidney, liver, lung, ovary, pancreas, and stomach. The ras genes acquire transforming activity either by enhanced expression or by a single point mutation. A single base-pair mutation at specific sites within ras genes endows them with the capacity to transform certain cell lines in vitro. In this study, we showed the patterns of point mutations in codons 12, 13, and 61 of ras genes in human ovarian cancer. The experimental procedures were isolation of genomic DNA from normal ovary and ovarian cancer tissue specimens, amplification of a genomic DNA segment (about 100 bp) using different 5' and 3' extension primers in the polymerase chain reaction (PCR), labeling and purification of synthetic mutation-specific oligonucleotide probes, slot-blot hybridization, and autoradiography. The three reaction steps for the PCR cycle were: 96 degrees C for 1 min in step 1, 56 degrees C for 1 min in step 2, and 74 degrees C for 1 min in step 3. The PCR reaction was repeated totally for 30 cycles. In 28 tissue specimens of human ovarian cancer examined, one specimen was found with a c-Ha-ras point mutation at codon 12, two had a c-Ki-ras mutation at codon 12, and one had a c-Ki-ras mutation at codon 13.

Identification of K-ras oncogene mutations in the pure pancreatic juice of patients with ductal pancreatic cancers

Pancreatic cancer is detected on the basis of morphological changes delineated by means of various image-diagnostic methods. However, differentiation between chronic pancreatitis and pancreatic cancer, especially at the early stage, is not always simple when based upon the morphological changes alone. Therefore, we attempted to elucidate K-ras mutations in the sediment of pure pancreatic juice (PPJ) containing exfoliated ductal pancreatic cancer cells. PPJ was collected endoscopically from 20 patients with pancreatic cancer (PC) and 18 patients with chronic pancreatitis (CP). Polymerase chain reaction and allele specific oligonucleotide dot blot hybridization for K-ras mutations were performed with the DNA extracted from these samples. A K-ras mutation at codon 12 was identified in the PPJ of 11/20 (55%) of the patients with PC. On the other hand, the same mutation was not identified in the PPJ of any patient with CP. Moreover, K-ras mutations at codons 13 and 61 were not recognized in the PPJ of any patient with either PC or CP. These findings suggested that the presence of a K-ras mutation at codon 12 in PPJ would be useful in confirming the diagnosis of PC.

Chromosome 12 alterations and c-Ki-ras mutations in colorectal tumors

c-Ki-ras mutations and gains of chromosome 12, where this gene is mapped, were both studied in a series of 47 colorectal cancers. Mutations at codon 12 and 13 were detected in 17 (36%) and gains of chromosome 12 in 7 (15%) cases. In this sample, gains of chromosome 12 occur in tumors either with or without c-Ki-ras mutations, suggesting that gains of chromosome 12 are independent from the mutation of c-Ki-ras.

T-cell immunity to oncogenic proteins including mutated ras and chimeric bcr-abl

The process of malignant transformation can be ascribed to a series of characteristics and definable mutations of genes which encode proteins that control cell growth and differentiation. During the course of malignant transformation the cancer-related genes are altered by a variety of mechanisms including translocations, deletions, and point mutations which commonly result in the expression of aberrant proteins. Our laboratory has focused on determining the extent to which cancer-specific proteins expressed by aberrant cancer-related genes can function as tumor-specific antigens. The current paper reviews our studies with two prototype cancer-specific proteins, mutated p21ras protein and chimeric p210bcr-abl protein. Ras protooncogenes are activated by point mutation in approximately 20% of human malignancies. The mutations occur primarily at codons 12 or 61 and result in the expression of p21ras proteins with single substituted amino acids. Only a limited number of amino acid substitutions occur. Murine studies demonstrate that immunization with synthetic peptides corresponding to the mutated segment can elicit both class II restricted CD4+ helper/inducer T-cell responses and class I restricted CD8+ cytotoxic T-cell responses specific for mutated p21ras protein. In addition, the existence in vivo of tumors expressing mutated ras proteins can be detected by assaying for T-cell immunity to the mutated segment of ras protein. Preliminary human studies show that some patients with colon cancer have existent antibody responses to p21ras protein, implying the possible existence of autochthonous T-cell immunity to mutated ras proteins in those patients. In chronic myelogenous leukemia the human c-abl protooncogene from chromosome 9 is translocated to the specific breakpoint cluster (bcr) region on chromosome 22. The translocation results in the formation of a bcr-abl fusion gene that encodes at 210-kD chimeric protein. The joining region segment of chimeric bcr-abl protein is composed of a unique combination of c-abl and bcr amino acids and is expressed only by malignant cells. Studies demonstrate that immunization of mice with synthetic peptides corresponding to the joining region segment can elicit class II restricted CD4+ T-cell responses to p210bcr-abl proteins. Preliminary studies show that bcr-abl peptides can bind in the groove of both murine and human class I MHC molecules and can elicit bcr-abl peptide-specific cytotoxic T lymphocytes (CTL). Whether bcr-abl peptide-specific CTL can lyse cells expressing bcr-abl protein is a yet unknown. In summary, the results of the studies reviewed confirm that cancer-specific oncogenic proteins can serve as tumor-specific antigens.

Molecular and cellular features of esophageal cancer cells

More than 70 cell lines were established from esophageal cancer, including 15 TE-series cell lines established by the authors. This article reviews molecular and cellular features of esophageal cancer cells from studies using these cell lines as well as primary tumors. The subjects reviewed include primary cultures of normal epithelium of the esophagus and of esophageal tumors, their growth and differentiation properties, chromosomal aberrations, protein kinase C, growth factors and their receptors, oncogenes, and tumor-suppressor genes. Lesions of genetic loci in esophageal cancer include the absence of mutations in ras genes in primary tumors, amplification and overexpression of the c-erbB gene, co-amplification of hst-1 and int-2 genes, mutations, and allelic loss of tumor suppressor genes, p53, Rb, APC, and MCC. Future clinical improvement will be achieved on the basis of the understanding of molecular and cellular features of esophageal cancer cells.

Over-expression of the c-myc proto-oncogene in colorectal carcinoma

Alterations in the c-myc proto-oncogene in colorectal cancer were studied at the level of RNA expression, gene amplification and rearrangements. One hundred cases of colorectal cancer, stratified by Dukes' stage were examined. The level of messenger RNA expression was measured in tumours and matched normal mucosa from the same patient. Between 5 and 400 fold over-expression was found in 66% of tumours. Neither the presence nor the level of over-expression correlated with tumour staging. A significant correlation (P < 0.01) was found between over-expression of c-myc in tumours and the presence of synchronous adenomas elsewhere in the colon. In contrast to other tumours, no rearrangements of the gene were found on Southern analysis of colorectal cancers. Similarly, amplification of the gene was not found in the cancers examined.

Comparative clinical evaluation of biochemical and genomic tumor markers

The clinical utilities of established biochemical tumor markers and of emerging genomic markers are compared by six formal criteria: [1] tests negative in health or benign disease, [2] produced exclusively by specific tumor cells, [3] present frequently in the targeted malignancy, [4] detectable in occult disease, [5] degree of expression reflects tumor burden and prognosis, and [6] degree of expression correlates with therapeutic result. Evaluation of eight widely accepted marker systems combining a biochemical indicator with a specific cancer, on the one hand, and five representative genomic marker-target combinations involving chromosomal translocation, gene amplification and mutation, on the other hand, produces three main conclusions: First, specified applications are sufficiently well documented for the best biochemical markers to now tailor analytical performance goals to these uses. Second, further clinical trials of genomic markers are needed to document the useful linkage of specific indicators with specific clinical problems. Third, the different profiles of marker characteristics defining the two classes of indicators suggest some mutually complementary uses.

K-ras oncogene activation in lung adenocarcinomas from former smokers. Evidence that K-ras mutations are an early and irreversible event in the development of adenocarcinoma of the lung

BACKGROUND

Point mutations in codon 12 of the K-ras protooncogene occur more frequently in lung adenocarcinomas from smokers (30%) than they do in lung adenocarcinomas from nonsmokers (7%), suggesting that smoking is an important factor in the induction of these mutations. The lack of well defined "early" premalignant or in situ glandular neoplasms of the lung, however, has not permitted direct evaluation of the chronology of ras activation in the development of lung adenocarcinomas. To circumvent the need to evaluate precursor lesions, we examined lung adenocarcinomas from former smokers for point mutations in K-ras.

METHODS

Mutations in codon 12 of K-ras were detected using polymerase chain reaction amplification and mutation-specific oligonucleotide probes. The types and frequencies of mutations found in adenocarcinomas obtained from 57 former smokers were compared to those found in 27 adenocarcinomas from patients who never smoked and to those found in 27 adenocarcinomas from patients who were current smokers.

RESULTS

The overall prevalence of K-ras point mutations in lung adenocarcinomas obtained from former smokers (32%) was not different from that seen in adenocarcinomas from patients who were current smokers (30%, P = 0.83), and was greater than that seen in adenocarcinomas from patients who never smoked (7%, P = 0.015). This pattern was independent of the duration of abstinence from smoking. Furthermore, the predominant type of mutation found in tumors from former smokers was a guanine-to-thymine transversion, the specific type of mutation induced by benzo(a)pyrene, one of the chemical carcinogens found in tobacco smoke.

CONCLUSIONS

These findings support previous findings that suggest that codon 12 of the K-ras oncogene may be a specific target of the mutagenic activity of tobacco smoke, and suggest that DNA alterations at this site can occur early and irreversibly during the development of adenocarcinomas of the lung.

Genetics of cancer predisposition and progression

The development of human cancer is a multistep process that entails a progressively more malignant phenotype through the evolution of cellular subsets with increasing numbers of genetic alterations. Here we review the molecular genetics of human cancer predisposition and progression and describe paradigmatic cancer types and cancer syndromes. We also briefly consider the future impact of molecular biology on cancer diagnosis and treatment.

Prevalence of G-to-T transversions among K-ras oncogene mutations in human colorectal tumors in Yugoslavia

Human colorectal carcinoma tissue sampled from 37 patients, routinely graded into Dukes' stages A, B and C and histologically examined for the level of differentiation, were analyzed for the presence of point mutations in the K-ras oncogene. Seventeen cases out of the 37 analyzed were found to have a mutation in either the 12th or the 13th codon of the K-ras gene, giving an overall frequency of mutation of 46%. The incidence of mutations in Dukes' stages A, B and C was 33, 46 and 58% respectively. Although the frequency of mutation appears to be similar to that reported for the USA population, the spectrum of point mutations in codons 12 and 13 of the K-ras gene in the Yugoslav population appears to differ significantly. G-to-T transversions make up 77% of all mutations present, with the distribution as follows: 18% at the first base and 59% at the second base of codons 12 and 13. G-to-A transitions at the second base is the only other mutation identified, occurring mainly in codon 13 in colorectal tumors of all 3 stages.

Clues to the pathogenesis of familial colorectal cancer

A predisposition to colorectal cancer is shown to be linked to markers on chromosome 2 in some families. Molecular features of "familial" cancers were compared with those of sporadic colon cancers. Neither the familial nor sporadic cancers showed loss of heterozygosity for chromosome 2 markers, and the incidence of mutations in KRAS, P53, and APC was similar in the two groups of tumors. Most of the familial cancers, however, had widespread alterations in short repeated DNA sequences, suggesting that numerous replication errors had occurred during tumor development. Thirteen percent of sporadic cancers had identical abnormalities and these cancers shared biologic properties with the familial cases. These data suggest a mechanism for familial tumorigenesis different from that mediated by classic tumor suppressor genes.

Association between ATL and non-hematopoietic neoplasms

A high incidence of multiple primary neoplasms has been observed in our patients with ATL in comparison to persons with other forms of hematologic malignancy who we have observed during the past 23 years (1963-1985). Five of 15 patients with ATL (33.3 per cent) have had at least one other associated neoplasm in comparison to only 44 of 1156 patients with other forms of hematological malignancy (3.8 per cent). The incidence figures for secondary neoplasms associated with the other hematologic malignancies were 4.3 per cent (16/370) for acute non-lymphocytic leukemia (ANLL), 2.2 per cent (2/90) for acute lymphocytic leukemia (ALL), 4.8 per cent (1/21) for acute unclassifiable leukemia, 2.2 per cent (5/225) for chronic myelogenous leukemia, 4.7 per cent (2/43) for chronic lymphocytic leukemia, 5.9 per cent (8/136) for malignant monoclonal gammopathy and 3.7 per cent (10/271) for malignant lymphoma. The incidence of multiple neoplasms in patients with ATL in comparison to those with other hematological malignancies was statistically significant (p < 0.01 or p < 0.001). The neoplasms associated with ATL have been adenocarcinoma of the thyroid or stomach, and squamous cell carcinoma of the larynx, lip or lung. We identified ATL-derived factor (ADF) in the cytoplasm of the secondary neoplasms of the ATL patients by means of indirect immunofluoroscopy and immunohistochemical techniques utilizing anti-ADF antibody. We also identified ras p21 products in these neoplasms by means of p21 ras monoclonal antibody studies. The possibility that HTLV-I was the cause of the secondary neoplasms thus was investigated. HTLV-I provirus genome was not found in all the six cases of non-ATL leukemic cells of the patients with anti-HTLV-I antibodies as determined by means of Southern blot analysis utilizing pX DNA probe. These findings suggest that there is some association between ATL cells and pre-malignant cells through ADF or other unknown factors in the activation of ras oncogenes. Subsequent suppression of host immune defence mechanisms in ATL patients permits evolution of the secondary neoplasms.

p53 expression and K-ras mutation in colorectal adenomas

The frequency of p53 overexpression and K-ras codon 12 mutation was investigated in a series of colorectal adenomas. p53 was detected by immunohistochemistry in only 5% of tumours, whereas K-ras mutation was found in eight of 30 adenomas examined. In vitro, mutant p53 and ras genes cooperate to transform primary rat cells into a tumourigenic cell line. The presence of both p53 overexpression and K-ras mutation in a benign tubulovillous polyp in the present series suggests that in vivo this combination of events is insufficient to cause malignant transformation of a large bowel adenoma.

Chromosome analysis of adenomatous polyps of the colon: possible existence of two differently evolving cytogenetic groups

A chromosomal study of 42 colonic adenomatous polyps was performed using a technique of direct chromosome analysis derived from the prenatal procedure for diagnosing chromosomal alterations from chorionic villi sampling. Abnormal karyotypes were found in 22 cases. Trisomy 7, the most frequently found alteration, was found in 13 cases, followed by trisomy 13 (nine cases). Monosomy 18 was observed in two cases; in one of these, that of a polyp which had degenerated into an intra-mucosal adenocarcinoma, it was associated with 17p monosomy. Interestingly, these two types of alterations (trisomy 7 versus 18 and 17p monosomy) were not found together in the same lesion. This suggests that there could be two distinct chromosomal behaviors which might be related to the two cytogenetic groups described for colorectal adenocarcinoma. However, the respective frequencies of such cytogenetic groups varied inversely between adenomas and adenocarcinomas, thus suggesting that they evolve differently.

Identification of a colon mucosa gene that is down-regulated in colon adenomas and adenocarcinomas

A cDNA, which we call DRA (for down-regulated in adenoma) has been isolated. Its mRNA is expressed exclusively in normal colon tissue, probably only in the mucosal epithelia. Expression of the DRA gene is significantly decreased in adenomas (polyps) and adenocarcinomas of the colon. The DRA gene appears to be a single-copy gene present on chromosome 7, a chromosome associated with colorectal tumorigenesis. The predicted DRA polypeptide is an 84,500-Da protein that contains charged clusters of amino acids, primarily at the NH2 and COOH termini. Together with potential nuclear targeting motifs, an acidic transcriptional activation domain, and a homeobox domain, these elements suggest a transcription factor or a protein that may interact with transcription factors. Such a function may be consistent with a role in tissue-specific gene expression and/or as a candidate tumor-suppressor gene.

Altered growth of human colon cancer cell lines disrupted at activated Ki-ras

Point mutations that activate the Ki-ras proto-oncogene are presented in about 50 percent of human colorectal tumors. To study the functional significance of these mutations, the activated Ki-ras genes in two human colon carcinoma cell lines, DLD-1 and HCT 116, were disrupted by homologous recombination. Compared with parental cells, cells disrupted at the activated Ki-ras gene were morphologically altered, lost the capacity for anchorage-independent growth, grew more slowly both in vitro and in nude mice, and showed reduced expression of c-myc. Thus, the activated Ki-ras gene plays a key role in colorectal tumorigenesis through altered cell differentiation and cell growth.

Prognostic significance of K-ras mutations in colorectal carcinoma

BACKGROUND

Mutations at codons 12, 13, and 61 of the ras genes have been found in a variety of human tumors and may have prognostic significance. K-ras mutations have been shown in 40%-50% of colorectal cancers.

METHODS

Using a simple nonradioactive polymerase chain reaction-based technique, we have investigated the possible prognostic significance of point mutations of the K-ras gene in patients with human colorectal carcinomas. The prevalence and the type of ras mutations were compared between a group of 35 patients having recurrent disease within 5 years and a group of 64 patients who were disease free 5 years following surgery.

RESULTS

First, we found that the overall prevalence of mutations within codons 12 and 13 of the K-ras gene was 25% in the nonrecurring group vs. 71% in the patients with recurrent disease (P < 0.0001) and, second, that mutations other than GGT to GAT occurred, with one exception, exclusively in recurring tumors.

CONCLUSIONS

In Dukes' B and C primary tumors, mutations other than GGT to GAT identify patients at very high risk for recurrence. Our results indicate that determining the K-ras mutations provides a good prognostic factor in patients with advanced colorectal carcinoma.