Phosphorylation of eIF4E promotes EMT and metastasis via translational control of SNAIL and MMP-3.

The progression of cancers from primary tumors to invasive and metastatic stages accounts for the overwhelming majority of cancer deaths. Understanding the molecular events which promote metastasis is thus critical in the clinic. Translational control is emerging as an important factor in tumorigenesis. The messenger RNA (mRNA) cap-binding protein eIF4E is an oncoprotein that has an important role in cancer initiation and progression. eIF4E must be phosphorylated to promote tumor development. However, the role of eIF4E phosphorylation in metastasis is not known. Here, we show that mice in which eukaryotic translation initiation factor 4E (eIF4E) cannot be phosphorylated are resistant to lung metastases in a mammary tumor model, and that cells isolated from these mice exhibit impaired invasion. We also demonstrate that transforming growth factor-beta (TGFß) induces eIF4E phosphorylation to promote the translation of Snail and Mmp-3 mRNAs, and the induction of epithelial-to-mesenchymal transition (EMT). Furthermore, we describe a new model wherein EMT induced by TGFß requires translational activation via the non-canonical TGFß signaling branch acting through eIF4E phosphorylation.

Human F-box protein hCdc4 targets cyclin E for proteolysis and is mutated in a breast cancer cell line.

Cyclin E, one of the activators of the cyclin-dependent kinase Cdk2, is expressed near the G1-S phase transition and is thought to be critical for the initiation of DNA replication and other S-phase functions. Accumulation of cyclin E at the G1-S boundary is achieved by periodic transcription coupled with regulated proteolysis linked to autophosphorylation of cyclin E. The proper timing and amplitude of cyclin E expression seem to be important, because elevated levels of cyclin E have been associated with a variety of malignancies and constitutive expression of cyclin E leads to genomic instability. Here we show that turnover of phosphorylated cyclin E depends on an SCF-type protein-ubiquitin ligase that contains the human homologue of yeast Cdc4, which is an F-box protein containing repeated sequences of WD40 (a unit containing about 40 residues with tryptophan (W) and aspartic acid (D) at defined positions). The gene encoding hCdc4 was found to be mutated in a cell line derived from breast cancer that expressed extremely high levels of cyclin E.

Deregulated cyclin E induces chromosome instability.

Cyclin E, a regulatory subunit of cyclin-dependent kinase 2 (Cdk2), is an important regulator of entry into S phase in the mammalian cell cycle. In normal dividing cells, cyclin E accumulates at the G1/S-phase boundary and is degraded as cells progress through S phase. However, in many human tumours cyclin E is overexpressed and the levels of protein and kinase activity are often deregulated relative to the cell cycle. It is not understood how alterations in expression of cyclin E contribute to tumorigenesis. Here we show that constitutive cyclin-E overexpression in both immortalized rat embryo fibroblasts and human breast epithelial cells results in chromosome instability (CIN). In contrast, analogous expression of cyclin D1 or A does not increase the frequency of CIN. Cyclin-E-expressing cells that exhibit CIN have normal centrosome numbers. However, constitutive overexpression of cyclin E impairs S-phase progression, indicating that aberrant regulation of this process may be responsible for the CIN observed. These results indicate that downregulation of cyclin-E/Cdk2 kinase activity following the G1/S-phase transition may be necessary for the maintenance of karyotypic stability.

Evidence for multiclonality in multicentric Kaposi's sarcoma.

Kaposi's sarcoma (KS) develops in a variety of clinical states and is the most common tumor seen in patients with HIV-1 infection. KS develops as a multifocal mucocutaneous disease with subsequent spread to visceral organs, and it has been argued to be a benign proliferation caused by its multifocality at initial presentation, lack of aneuploidy, and spontaneous regression upon withdrawal of immunosuppressive agents in iatrogenically induced disease. We wished to determine whether KS lesions are clonal, indicative of a true neoplasm. Also, we tested whether multifocal KS lesions are clonally related, derived from a common progenitor cell or of independent cellular origin. We studied the X-chromosome inactivation pattern of the human androgen receptor gene in tumor biopsies of women with KS. This procedure tests for the clonality of a tissue specimen, a hallmark of neoplasia. Each specimen was microdissected to minimize normal cell contamination. Of 12 evaluable cases, 10 were HIV-seropositive and 2 were HIV-seronegative. Twenty-four biopsies from the 12 patients were examined. Five cases were consistent with individual KS lesions being clonal. In two cases, multiple KS specimens derived from the individual patients had different androgen receptor alleles inactivated, proving unequivocally that these KS lesions arose independently from distinct transformed cells. In seven cases, only a polyclonal pattern of inactivation was observed, whereas two others had tumor areas of both clonal and polyclonal inactivation patterns. These findings suggest that KS can be a clonal neoplasm, and in some of the cases multiple KS lesions in a given patient can arise from independent cellular origins and acquire clonal characteristics. The polyclonal inactivation pattern observed in other KS lesions may represent a premalignant stage or false negative results.

Presence of p53 mutations in primary nasopharyngeal carcinoma (NPC) in non-Asians of Los Angeles, California, a low-risk population for NPC.

Mutatins of the p53 tumor suppressor gene are rare in nasopharyngeal carcinoma (NPC) patients who reside in high-risk areas, such as Southeastern China. Among this high-risk group, a pre-existing infection with the EBV and consumption of Cantonese salted fish are closely associated with NPC. We investigated the prevalence of p53 mutations in 28 primary NPC specimens from white (including Hispanic) and African-American patients in Los Angeles, who are at low risk for NPC. Using PCR-based single-strand conformational polymorphism and direct sequencing, we found four mutations (14%) in exons 5-8 of the p53 gene in four patients. All were C-to-T transition mutations: two were present in exon 5-one at codon 142 [CCT (Pro)-->CTT (Leu)] and another at codon 144 [CAG (Gln)-->TAG (stop codon)]. The other two mutations were identified in exon 8: one at codon 273 [CGT (Arg)-->CAT (His)], a CpG site, and one at codon 271, a silent mutation [GAG (Glu)-->GAA (Glu)]. This is the first report investigating the presence of p53 missense mutations in NPC among a low-risk population. Our data indicate that p53 is also an infrequent event among NPC patients at low risk for the disease.

Identification and characterization of differentially methylated regions of genomic DNA by methylation-sensitive arbitrarily primed PCR.

We have developed a simple and reproducible fingerprinting method for screening the genome for regions of DNA that have altered patterns of DNA methylation associated with oncogenic transformation. Restriction enzymes with different sensitivities to cytosine methylation in their recognition sites were used to digest genomic DNAs from primary tumors, cell lines, and normal tissues prior to arbitrarily primed PCR amplification. Fragments that showed differential methylation were cloned and sequenced after resolving the PCR products on high-resolution polyacrylamide gels. The cloned fragments were then used as probes for Southern analysis to confirm differential methylation of these regions in colon tissues and cell lines. Forty-four DNA fragments associated with a total of five different regions of genomic DNA containing methylation sites were detected in 10 matched sets of normal and tumor colon DNAs and 7 colon cancer cell lines. A novel CpG island was also isolated that was found to be frequently hypermethylated in bladder and colon tumors. We have demonstrated that this technique is a rapid and efficient method that can be used to screen for altered methylation patterns in genomic DNA and to isolate specific sequences associated with these changes.

Evidence for two tumor suppressor loci associated with proximal chromosome 9p to q and distal chromosome 9q in bladder cancer and the initial screening for GAS1 and PTC mutations.

The most common genetic alteration identified to date in bladder cancer is loss of heterozygosity (LOH) of chromosome 9, suggesting the presence of possible tumor suppressor genes on this chromosome. We attempted to map the location of these genes by analyzing 69 primary transitional cell carcinomas of the bladder with a panel of microsatellite markers for LOH on chromosome 9. Monosomy 9 (defined by LOH of all informative markers analyzed on 9p and 9q) was detected in 26 of 69 (38%) tumors, and 22 of 69 (32%) tumors showed subchromosomal deletions. Twelve tumors (17%) demonstrated partial LOH of chromosome 9 and indicated two distinct regions of LOH. Eight tumors showed distal allelic loss of 9q with a minimal region of common deletion flanked proximally by marker GSN on 9q33. Six tumors showed proximal allelic loss of 9p and 9q with a minimal area of common deletion flanked by markers D9S970 on 9p12 and D9S283 on 9q21. Two tumors showed loss of both the distal region of 9q and the proximal region of 9p and 9q, which were separated by a possible 6-44 cM of retained genetic material. The proximal minimal area of common deletion excluded 9q22.3-q31 to where two putative tumor suppressor genes, the nevoid basal cell carcinoma syndrome and multiple self-healing squamous epithelioma (ESS1) genes, have been mapped. The growth arrest-specific gene (GAS1), a candidate tumor suppressor gene, was included within the proximal minimal region. We evaluated the GAS1 gene for its potential role in bladder cancer using single-strand conformational polymorphism to screen for mutations in GAS1 in 10 bladder cancer cell lines and 14 primary bladder tumors. A polymorphism at codon 88 was noted in one primary bladder tumor, but no other abnormalities were found, suggesting that another potential tumor suppressor gene important to bladder cancer resides in these minimally deleted regions. Because the nevoid basal cell carcinoma syndrome gene has long been speculated to be a putative tumor suppressor gene in bladder cancer and this gene has recently been characterized as the human homologue of the Drosophila patched gene (PTC), 20 primary bladder tumors with chromosome 9q LOH were screened for mutations in PTC using single-strand conformational polymorphism and heteroduplex analysis. No alterations were found in any of the samples analyzed. Furthermore, 4 of 37 noninvasive papillary (Ta) tumors demonstrated loss of all 9q markers with retention of 9p, whereas no Ta tumor showed loss of 9p with retention of all 9q markers, suggesting that LOH of 9q is the earlier event in bladder tumorigenesis. In summary, our results indicate two tumor suppressor loci associated with proximal chromosome 9p to q and distal chromosome 9q that may be important in bladder cancer. GAS1 and PTC do not seem to be frequently mutated in bladder cancer.

High frequency of chromosome 9p allelic loss and CDKN2 tumor suppressor gene alterations in squamous cell carcinoma of the bladder.

BACKGROUND: In the Western Hemisphere, 90% of bladder cancers are transitional cell carcinomas, while only 7% are classified as squamous cell carcinomas. In contrast, in Egypt and regions of the Middle East and Africa, where infection by the trematode Schistosoma haematobium is endemic, squamous cell carcinoma is the most common bladder cancer as well as the most common cancer in men. PURPOSE: We planned experiments to understand the genetic defects underlying the development of squamous cell carcinoma and to determine if the morphologically and clinically distinct squamous cell carcinoma and transitional cell carcinoma of the bladder evolve following different genetic alterations. METHODS: Squamous cell carcinoma specimens from high-risk (Egypt, n = 19) and low-risk (Sweden, n = 12) populations were examined for genetic defects known to be involved in transitional cell carcinoma tumorigenesis. Homozygous deletions of the CDKN2 tumor suppressor gene were detected by comparative multiplex polymerase chain reaction. Mutations in the CDKN2 and p53 (also known as TP53) genes were analyzed by single-strand conformation polymorphism and DNA sequencing. Immunohistochemical staining of p53 protein was also performed. Allelic losses in chromosome arms 9p, 9q, and 17p were determined by microsatellite analysis. RESULTS: Homozygous deletions and sequence mutations in the CDKN2 gene were found in 67% (eight of 12) of squamous cell carcinoma specimens, a frequency three times higher than that reported for uncultured transitional cell carcinomas (P = .009). Hemizygous and homozygous deletions in 9p, where CDKN2 resides, were found in 92% (11 of 12) of uncultured squamous cell carcinomas, while only about 39% (35 of 90) of transitional cell carcinomas showed these losses (P = .001). Deletions in 9p with no change in 9q were found in 92% (10 of 11) of squamous cell carcinomas compared with only 10% (11 of 110) of transitional cell carcinomas (P < .001) reported in the literature. The frequency of p53 mutations in squamous cell carcinomas was similar to that reported for invasive transitional cell carcinomas (60%), but the type and position of mutations differed between the two tumor types. Allelic losses in chromosome arm 17p, where the p53 gene resides, were found to be less frequent in squamous cell carcinomas (38%) than in invasive transitional cell carcinomas (60%). CONCLUSIONS: Our results suggest that a putative tumor suppressor gene on 9p, possibly CDKN2, may contribute to squamous cell carcinoma tumorigenesis. Our data on squamous cell carcinoma and previously reported data on transitional cell carcinoma indicate that these two bladder carcinomas differ in their genetic alterations, suggesting that distinct underlying genetic defects may explain, at least in part, the pathological differences between the two tumors of the bladder epithelium. IMPLICATIONS: Development of diagnostic and therapeutic strategies for squamous cell carcinoma of the bladder based on its distinct genetic alterations is warranted.

Mosaicism in human epithelium: macroscopic monoclonal patches cover the urothelium.

Previous studies of chimeric animals and human tissues have shown the clonal nature of organ development, giving clues as to the normal development of organs and also to abnormal developments, such as atheromatous plaques. The clonal nature of bladder cancer in female patients has been demonstrated, but little has been known of the clonal development of the normal urothelium. Using an X chromosome inactivation analysis of cells microdissected from histologic slides from the female human bladder, macroscopic urothelial patches of monoclonality were detected. These patches are about 120 mm.2 in size, contain about 2 x 10(6) cells each and reflect the presence of coherent cellular families composed of stem cells and their differentiated derivatives. The large size of these patches was surprising when compared with previously reported patch sizes in other organ systems. The patches most probably are composed of the descendants of the original founder cells, which would suggest that only 200 to 300 cells participated in the formation of the urothelium. The limited number of stem cells, each giving rise to millions of cells may provide an explanation for the "field defect" that is often referred to in the pathogenesis of bladder cancer, as different cell patches may possess different predispositions to tumorigenesis.

Progressive increases in the methylation status and heterochromatinization of the myoD CpG island during oncogenic transformation.

Alterations in DNA methylation patterns are one of the earliest and most common events in tumorigenesis. Overall levels of genomic methylation often decrease during transformation, but localized regions of increased methylation have been observed in the same tumors. We have examined changes in the methylation status of the muscle determination gene myoD, which contains a CpG island, as a function of oncogenic transformation. This CpG island underwent de novo methylation during immortalization of 10T1/2 cells, and progressively more sites became methylated during the subsequent transformation of the cells to oncogenicity. The greatest increase in methylation occurred in the middle of the CpG island in exon 1 during transformation. Interestingly, no methylation was apparent in the putative promoter of myoD in either the 10T1/2 cell line or its transformed derivative. The large number of sites in the CpG island that became methylated during transformation was correlated with heterochromatinization of myoD as evidenced by a decreased sensitivity to cleavage of DNA in nuclei by MspI. A site in the putative promoter also became insensitive to MspI digestion in nuclei, suggesting that the chromatin structural changes extended beyond the areas of de novo methylation. Unlike Lyonized genes on the inactive X chromosome, whose timing of replication is shifted to late S phase, myoD replicated early in S phase in the transformed cell line. Methylation analysis of myoD in DNAs from several human tumors, which presumably do not express the gene, showed that hypermethylation also frequently occurs during carcinogenesis in vivo. Thus, the progressive increase in methylation of myoD during immortalization and transformation coinciding with a change in chromatin structure, as illustrated by the in vitro tumorigenic model, may represent a common mechanism in carcinogenesis for permanently silencing the expression of genes which can influence cell growth and differentiation.

Mutational spectrum in the p53 gene in bladder tumors from the endemic area of black foot disease in Taiwan.

An elevated risk of bladder cancer has been reported in the endemic region of 'black foot disease' on the southwest coast of Taiwan and may be related to high arsenic levels in artesian well water. Thirteen urothelial tumors from this endemic region were examined for mutations in exons 5-8 of the p53 gene to identify the effects of possible exogenous factors at the DNA level. DNA was extracted from archival tissue after microdissection of tumors and analyzed by PCR-SSCP (polymerase chain reaction-based single strand conformation polymorphism), followed by direct sequencing. Eight cases (62%) showed mutations and 9 of the 10 point mutations observed were transitions. The type and position of the mutations were not significantly different when compared with the spectra of p53 mutations previously reported for transitional cell carcinomas (TCCs). However, two of the mutations were CGC-->CAC base changes at codon 175, a mutational hotspot for many tumor types but previously unreported in TCCs except in cases associated with inflammatory agents. Three of the tumors examined were found to contain double mutations, a relatively rare mutagenic event in human cancers. Our results suggest that the agents responsible for the high risk of bladder cancer in the black foot disease region may operate through an inflammation-based mechanism which increases the amount of DNA damage per mutagenic event.

Two molecular pathways to transitional cell carcinoma of the bladder.

Noninvasive transitional cell carcinomas of the bladder can have two distinct morphologies suggesting they contain different genetic alterations. Papillary transitional cell carcinomas (T(a) tumors) are often multifocal and only occasionally progress, whereas flat tumors (carcinomas in situ, CIS), frequently progress to invasive disease. We examined 216 bladder tumors of various stages and histopathologies for two genetic alterations previously described to be of importance in bladder tumorigenesis. Loss of heterozygosity of chromosome 9 was observed in 24 of 70 (34%) T(a) tumors but was present in only 3 of 24 (12%) CIS and dysplasia lesions (P = 0.04). In contrast, only 1 of 36 (3%) T(a) tumors contained a p53 gene mutation compared to 15 of 23 (65%) CIS and dysplasias (P < 0.001), a frequency comparable to that observed in muscle invasive tumors (25 of 49; 51%). The presence of p53 mutations in CIS and dysplasia could explain their propensities to progress since these mutations are known to destabilize the genome. Analysis of several tumor pairs involving a CIS and an invasive cancer provided evidence that the chromosome 9 alteration may in some cases be involved in the progression of CIS to more invasive tumors, in addition to its role in the initiation of T(a) tumors. However, the CIS and secondary tumor were found to contain different genetic alterations in some patients suggesting divergent progression pathways. Bladder carcinogenesis may therefore proceed through two distinct genetic alteration pathways responsible for generating superficial tumors with differing morphologies and pathologies.

Microsatellite instability in bladder cancer.

Somatic instability at microsatellite repeats was detected in 6 of 200 transitional cell carcinomas of the bladder. Instabilities were apparent as changes in (GT)n repeat lengths on human chromosome 9 for four tumors and as alterations in a (CAG)n repeat in the androgen receptor gene on the X chromosome for three tumors. Single locus alterations were detected in three tumors, while three other tumors revealed changes in two or more loci. In one tumor we found microsatellite instability in all five loci analyzed on chromosome 9. The alterations detected were either minor 2-base pair changes or larger (> 2 base pairs) alterations in repeat length. All six tumors were low stage (Ta-T1), suggesting that these alterations can occur early in bladder tumorigenesis.

p53 nuclear protein accumulation correlates with mutations in the p53 gene, tumor grade, and stage in bladder cancer.

Seventy-three transitional cell carcinomas of the bladder were analyzed by immunohistochemistry for p53 nuclear accumulation, and the results were compared to mutations detected in the p53 gene by single strand conformational polymorphism analysis (SSCP) and DNA sequence analysis. Immunohistochemical studies were performed on formalin-fixed, paraffin-embedded tissue sections. A highly significant association between the presence of p53 mutations and p53 nuclear reactivity as detected by immunohistochemistry was found (P = 0.0001). Of 32 tumors that demonstrated p53 mutations by SSCP, 27 (84%) showed p53 nuclear reactivity. Of the five cases that did not demonstrate p53 nuclear reactivity, four had mutations in exon 5. However, of 41 tumors with no evidence of p53 mutation by molecular analysis, 12 (29%) showed p53 immunoreactivity. This indicates that immunohistochemical methods may be more sensitive than SSCP in detecting p53 mutations or that discordant cases represent tumors with accumulation of wild type p53 protein, without mutations at the p53 locus. Of the 15 tumors that were found to have mutations at exon 8, 13 demonstrated high-intensity homogeneous p53 nuclear reactivity by immunohistochemistry, and all mutations located at codon 280 demonstrated high-intensity homogeneous immunoreactivity. However, three of three tumors with exon 6 mutations demonstrated low-level p53 immunoreactivity, and four of six tumors with mutations in exon 5 showed no detectable p53 nuclear reactivity. This indicates that the heterogeneity of immunoreactivity observed when analyzing p53 nuclear accumulation may be related to the site of the p53 gene mutation. Information on tumor grade, stage, lymph node status, disease-free interval, and overall survival were available in 54 patients who had undergone cystectomy. A significant association was observed between p53 alterations (detected by immunohistochemistry and SSCP) and histological tumor grade (P = 0.003) and stage (P = 0.01). We conclude that the immunohistochemical detection of p53 nuclear accumulation in formalin-fixed, paraffin-embedded tissue is highly associated with mutations in the p53 gene; this association has now been demonstrated in a large number of tumors. The heterogeneity of p53 nuclear reactivity seems to be related to the site of mutation in the p53 gene. A small proportion of tumors with a p53 gene mutation do not demonstrate immunohistochemically detectable p53 nuclear accumulation. Furthermore, a small but substantial proportion of tumors demonstrate p53 nuclear reactivity but do not show detectable mutations in the p53 gene by SSCP. Finally, both grade and stage of bladder cancer are related to p53 alterations, detected by immunohistochemistry or molecular methods.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of chromosome 9 in human bladder cancer.

The tumors of 20 patients with multifocal primary transitional cell carcinoma of the bladder or lymph node metastases were examined for molecular genetic defects which we have previously found to be present in > 50% of invasive tumors. These included loss of heterozygosity (LOH) of chromosome 9, which occurs in superficial as well as invasive bladder tumors, and LOH of chromosome 17p and p53 mutations, which are commonly found only in invasive tumors. Analysis of multiple or recurrent primary tumors in 7 patients for these markers was generally consistent with recently published data that the tumors are monoclonal in origin and that p53 mutations occur as a late event in the generation of invasive bladder cancers. Comparison of the primary tumors and metastases to regional lymph nodes in 14 patients demonstrated a complete concordance between the molecular genetic defects present, showing that LOH of chromosomes 9 and 17p and p53 mutations occurred in the primary tumors before metastasis. Because of the importance of chromosome 9 in bladder cancer, we mapped the location of a putative tumor suppressor gene by restriction fragment length polymorphism analysis of 123 cases obtained in this and earlier studies. Most of the tumors showed LOH for more than one marker on chromosome 9. Results of mapping of 4 tumors with partial deletion of chromosome 9 suggests that the tumor suppressor gene is located between 9p12 and 9q34.1.

Distinct pattern of p53 mutations in bladder cancer: relationship to tobacco usage.

A distinct mutational spectrum for the p53 tumor suppressor gene in bladder carcinomas was established in patients with known exposures to cigarette smoke. Single-strand conformational polymorphism analysis of exons 5 through 8 of the p53 gene showed inactivating mutations in 16 of 40 (40%) bladder tumors from smokers and 13 of 40 (33%) tumors from lifetime nonsmokers. Overall, 13 of the 50 (26%) total point mutations discovered in this and previous work were G:C-->C:G transversions, a relatively rare mutational type in human tumors. In six tumors, identical AGA (Arg)-->ACA (Thr) point mutations at codon 280 were observed, suggesting a mutational hotspot in these tumors. Comparison of the mutational spectra from smokers and nonsmokers revealed no obvious differences in the types or positions of inactivating mutations; however, 5 of 15 tumors containing point mutations from cigarette smokers had double mutations, four of which were tandem mutations on the same allele. No double mutations were found in tumors from nonsmoking patients. None of the mutations in smokers were G:C-->T:A transversions, which would be anticipated for exposure to the suspected cigarette smoke carcinogen 4-aminobiphenyl. The results suggest that, although cigarette smoke exposure may not significantly alter the kinds of mutations sustained in the p53 gene, it may act to increase the extent of DNA damage per mutagenic event.

Absence of p53 gene mutations in primary nasopharyngeal carcinomas.

Alterations in the p53 tumor suppressor gene and Epstein-Barr virus status were investigated in 15 nasopharyngeal carcinoma (NPC) biopsies, 4 xenografts, and 2 cell lines from the Cantonese region of southern China. One other established NPC cell line obtained from a northern Chinese patient was also studied. Restriction fragment length polymorphism analysis revealed a loss of heterozygosity for chromosome 17p, where the p53 gene resides, in only one of 15 NPC biopsies. Polymerase chain reaction-single-stranded conformational polymorphism analysis and direct sequencing failed to detect sequence alterations in exons 5 through 8 of the p53 gene in the 15 tumors and in the 4 NPC xenografts, all of which tested positive for Epstein-Barr virus. In contrast, the 3 NPC cell lines were all negative for Epstein-Barr virus and contained G----C transversions in the p53 gene, with cell lines CNE-1 and CNE-2 harboring identical AGA (arginine) to ACA (threonine) changes at codon 280. These results suggest that p53 inactivation is not a necessary component of nasopharyngeal carcinogenesis in Cantonese but may be important in the establishment of cell lines derived from these tumors.

Specific genetic analysis of microscopic tissue after selective ultraviolet radiation fractionation and the polymerase chain reaction.

A method using selective ultraviolet radiation fractionation followed by polymerase chain reaction (PCR) can analyze specific cell subsets present on a microscope section. Direct ultraviolet radiation of fixed and stained tissue sections prevents subsequent amplification by PCR. An "umbrella" or dot placed physically over small numbers of pure cell populations selected by microscopic examination protects these cells from the ultraviolet inactivation. The DNA in these protected cells can be specifically amplified while no signal is derived from the unprotected surrounding cells. Specific amplification was demonstrated by detecting human papillomavirus sequences only if infected cells were protected. Similarly, loss of heterozygosity at the p53 locus was documented by selective dotting of normal or tumor cells. The method allows the specific and sensitive molecular genetic analysis of small numbers of cells histologically identified and selected under the microscope.