Ty1 proteolytic cleavage sites are required for transposition: all sites are not created equal.

The retroviral protease is a key enzyme in a viral multienzyme complex that initiates an ordered sequence of events leading to virus assembly and propagation. Viral peptides are initially synthesized as polyprotein precursors; these precursors undergo a number of proteolytic cleavages executed by the protease in a specific and presumably ordered manner. To determine the role of individual protease cleavage sites in Ty1, a retrotransposon from Saccharomyces cerevisiae, the cleavage sites were systematically mutagenized. Altering the cleavage sites of the yeast Ty1 retrotransposon produces mutants with distinct retrotransposition phenotypes. Blocking the Gag/PR site also blocks cleavage at the other two cleavage sites, PR/IN and IN/RT. In contrast, mutational block of the PR/IN or IN/RT sites does not prevent cleavage at the other two sites. Retrotransposons with mutations in each of these sites have transposition defects. Mutations in the PR/IN and IN/RT sites, but not in the Gag/PR site, can be complemented in trans by endogenous Ty1 copies. Hence, the digestion of the Gag/PR site and release of the protease N terminus is a prerequisite for processing at the remaining sites; cleavage of PR/IN is not required for the cleavage of IN/RT, and vice versa. Of the three cleavage sites in the Gag-Pol precursor, the Gag/PR site is processed first. Thus, Ty1 Gag-Pol processing proceeds by an ordered pathway.

Genetic selection of intragenic suppressor mutations that reverse the effect of common p53 cancer mutations.

Several lines of evidence suggest that the presence of the wild-type tumor suppressor gene p53 in human cancers correlates well with successful anti-cancer therapy. Restoration of wild-type p53 function to cancer cells that have lost it might therefore improve treatment outcomes. Using a systematic yeast genetic approach, we selected second-site suppressor mutations that can overcome the deleterious effects of common p53 cancer mutations in human cells. We identified several suppressor mutations for the V143A, G245S and R249S cancer mutations. The beneficial effects of these suppressor mutations were demonstrated using mammalian reporter gene and apoptosis assays. Further experiments showed that these suppressor mutations could override additional p53 cancer mutations. The mechanisms of such suppressor mutations can be elucidated by structural studies, ultimately leading to a framework for the discovery of small molecules able to stabilize p53 mutants.

A transposon-based strategy for sequencing repetitive DNA in eukaryotic genomes.

Repetitive DNA is a significant component of eukaryotic genomes. We have developed a strategy to efficiently and accurately sequence repetitive DNA in the nematode Caenorhabditis elegans using integrated artificial transposons and automated fluorescent sequencing. Mapping and assembly tools represent important components of this strategy and facilitate sequence assembly in complex regions. We have applied the strategy to several cosmid assembly gaps resulting from repetitive DNA and have accurately recovered the sequences of these regions. Analysis of these regions revealed six novel transposon-like repetitive elements, IR-1, IR-2, IR-3, IR-4, IR-5, and TR-1. Each of these elements represents a middle-repetitive DNA family in C. elegans containing at least 3-140 copies per genome. Copies of IR-1, IR-2, IR-4, and IR-5 are located on all (or most) of the six nematode chromosomes, whereas IR-3 is predominantly located on chromosome X. These elements are almost exclusively interspersed between predicted genes or within the predicted introns of these genes, with the exception of a single IR-5 element, which is located within a predicted exon. IR-1, IR-2, and IR-3 are flanked by short sequence duplications resembling the target site duplications of transposons. We have established a website database (http:(/)/www.welch.jhu.edu/approximately devine/RepDNAdb.html) to track and cross-reference these transposon-like repetitive elements that contains detailed information on individual element copies and provides links to appropriate GenBank records. This set of tools may be used to sequence, track, and study repetitive DNA in model organisms and humans.

High frequency of p16 (CDKN2/MTS-1/INK4A) inactivation in head and neck squamous cell carcinoma.

The tumor suppressor gene p16 (CDKN2/MTS-1/INK4A) can be inactivated by multiple genetic mechanisms. We analyzed 29 invasive primary head and neck squamous cell carcinomas (HNSCC) for p16 inactivation with immunohistochemistry utilizing a new monoclonal antibody (mAb), DCS-50. p16 staining of the primary lesions was correlated with genetic analysis including: (a) detailed microsatellite analysis of markers at the p16 locus to detect homozygous deletion; (b) sequence analysis of p16; and (c) Southern blot analysis to determine the methylation status of the 5' CpG island of p16. Twenty-four of 29 (83%) head and neck squamous cell carcinoma tumors displayed an absence of p16 nuclear staining using immunohistochemistry. Of these 24 tumors, we found that 16 (67%) harbored homozygous deletions, 5 (21%) were methylated, 1 displayed a rearrangement at the p16 locus, and 1 displayed a frameshift mutation in exon 1. These data suggest that: (a) inactivation of the p16 tumor suppressor gene is a frequent event in squamous cell carcinomas of the head and neck; (b) p16 is inactivated by several distinct and exclusive events including homozygous deletion, point mutation, and promoter methylation; and (c) immunohistochemical analysis for expression of the p16 gene product is an accurate and relatively simple method for evaluating p16 gene inactivation.

Frequency of homozygous deletion at p16/CDKN2 in primary human tumours.

Many tumour types have been reported to have deletion of 9p21 (refs 1-6). A candidate target suppressor gene, p16 (p16INK4a/MTS-1/CDKN2), was recently identified within the commonly deleted region in tumour cell lines. An increasing and sometimes conflicting body of data has accumulated regarding the frequency of homozygous deletion and the importance of p16 in primary tumours. We tested 545 primary tumours by microsatellite analysis with existing and newly cloned markers around the p16 locus. We have now found that small homozygous deletions represent the predominant mechanism of inactivation at 9p21 in bladder tumours and are present in other tumour types, including breast and prostate cancer. Moreover, fine mapping of these deletions implicates a 170 kb minimal region that includes p16 and excludes p15.

Association between cigarette smoking and mutation of the p53 gene in squamous-cell carcinoma of the head and neck.

BACKGROUND: Although epidemiologic studies have long associated tobacco and alcohol use with the development of squamous-cell carcinoma of the head and neck, the molecular targets of these carcinogens have yet to be identified. We performed a molecular analysis to determine the pattern of mutations in the p53 gene in neoplasms from patients with squamous-cell carcinoma of the head and neck and a history of tobacco or alcohol use. METHODS: Sequence analysis of the conserved regions of the p53 gene was performed in tumor samples from 129 patients with primary squamous-cell carcinoma of the head and neck. We then used statistical analysis to identify any patient characteristics associated with mutation of the p53 gene. RESULTS: We found p53 mutations in 42 percent of the patients (54 of 129). Fifty-eight percent of the patients who smoked cigarettes and used alcohol (37 of 64; 95 percent confidence interval, 45 to 70 percent), 33 percent of the patients who smoked but abstained from alcohol (13 of 39; 95 percent confidence interval, 19 to 50 percent), and 17 percent of the patients who neither smoked nor drank alcohol (4 of 24, 95 percent confidence interval, 5 to 37 percent) had p53 mutations (P = 0.001). (Two patients used alcohol but did not smoke, and neither had a p53 mutation.) Furthermore, 100 percent of the mutations in the patients who neither drank nor smoked occurred at sites containing cytidine phosphate guanosine dinucleotides (potentially representing endogenous mutations) within the p53 gene (5 of 5 mutations; 95 percent confidence interval, 48 to 100 percent), whereas only 23 percent of those in cigarette smokers consisted of such changes (12 of 53 mutations; 95 percent confidence interval, 12 to 36 percent; P = 0.001). CONCLUSIONS: In our study, a history of tobacco and alcohol use was associated with a high frequency of p53 mutations in patients with squamous-cell carcinoma of the head and neck. Preliminary evidence linked cigarette smoking to p53 mutations at nonendogenous mutation sites. Our findings suggest a role for tobacco in the molecular progression of squamous-cell carcinoma of the head and neck and support the epidemiologic evidence that abstinence from smoking is important to prevent head and neck cancer.

Molecular assessment of histopathological staging in squamous-cell carcinoma of the head and neck.

BACKGROUND: Surgical oncologists rely heavily on the histopathological assessment of surgical margins to ensure total excision of the tumor in patients with head and neck cancer. However, current techniques may not detect small numbers of cancer cells at the margins of resection or in cervical lymph nodes. METHODS: We used molecular techniques to determine whether clonal populations of infiltrating tumor cells harboring mutations of the p53 gene could be detected in histopathologically negative surgical margins and cervical lymph nodes of patients with squamous-cell carcinoma of the head and neck. RESULTS: We identified 25 patients with primary squamous-cell carcinoma of the head and neck containing a p53 mutation who appeared to have had complete tumor resection on the basis of a negative histopathological assessment. In 13 of these 25 patients, molecular analysis was positive for a p53 mutation in at least one tumor margin. In 5 of 13 patients with positive margins by this method (38 percent), the carcinoma has recurred locally, as compared with none of 12 patients with negative margins (P = 0.02 by the log-rank test). Furthermore, molecular analysis identified neoplastic cells in 6 of 28 lymph nodes (21 percent) that were initially negative by histopathological assessment. CONCLUSIONS: Among specimens initially believed to be negative by light microscopy, a substantial percentage of the surgical margins and lymph nodes from patients with squamous-cell carcinoma of the head and neck contained p53 mutations specific for the primary tumor. Patients with these positive margins appear to have a substantially increased risk of local recurrence. Molecular analysis of surgical margins and lymph nodes can augment standard histopathological assessment and may improve the prediction of local tumor recurrence.

Localization of tumor suppressor loci on chromosome 9 in primary human renal cell carcinomas.

To investigate the potential loss of tumor suppressor gene loci on chromosome 9 in human renal cell tumorigenesis we analyzed 42 paired normal and tumor DNAs with 18 polymorphic microsatellite markers spanning this chromosome. Fourteen of 42 (33%) tumors showed partial or complete deletion of chromosome 9. Deletion mapping provided evidence for the presence of a suppressor locus on both the short and long arm of chromosome 9. Homozygous deletion at 9p21-22 in one renal tumor and a selective deletion of distal 9q in another tumor localized the critical regions. The CDKN2/p16 gene was further investigated as a candidate suppressor locus on 9p21-22 by multiplex PCR, Southern analysis, and exon sequencing. We found no additional cases of homozygous deletion nor any rearrangements or point mutations of CDKN2/p16. This is the first report of 9p loss of heterozygosity, homozygous deletion of 9p21-22 and selective deletion of 9q in primary renal cell carcinomas. Understanding the molecular genetic basis of renal cell progression will require the isolation and characterization of additional tumor suppressor genes on chromosome 9.

Homozygous deletions of 9p21 in primary human bladder tumors detected by comparative multiplex polymerase chain reaction.

Deletion mapping studies of primary bladder tumors have identified nonoverlapping areas of loss on each arm of chromosome 9, indicating that two distinct tumor suppressor loci are located on this chromosome. The deleted region on the p arm overlaps an area of 9p previously reported to be lost in a variety of neoplasms. Detailed loss of heterozygosity analysis of 9p in 112 primary bladder tumors using 12 microsatellite markers identified a minimal area of loss around the alpha-interferon locus at 9p21-22. Frequent homozygous deletions of the alpha-interferon locus were then identified in these tumors by a novel, comparative, multiplex polymerase chain reaction assay and were subsequently confirmed by Southern analysis. Based on these deletions, a putative tumor suppressor gene locus involved in bladder tumorigenesis was localized to a 10 cM region (flanked by D9S162 and D9S171), previously implicated in the progression of many neoplasms. Application of the multiplex polymerase chain reaction-based assay will allow rapid identification of homozygous deletions in many neoplasms and thus aid in mapping studies of critical suppressor genes.

The incidence of p53 mutations increases with progression of head and neck cancer.

To establish a genetic model of the progression of head and neck squamous carcinoma we have defined the incidence and timing of p53 mutations in this type of cancer. We sequenced the conserved regions of the p53 gene in 102 head and neck squamous carcinoma lesions. These included 65 primary invasive carcinomas and 37 noninvasive archival specimens consisting of 13 severe dysplasias and 24 carcinoma in situ lesions. The incidence of p53 mutations in noninvasive lesions was 19% (7/37) and increased to 43% (28/65) in invasive carcinomas. These data suggest that p53 mutations can precede invasion in primary head and neck cancer. Furthermore, the spectrum of codon hotspots is similar to that seen in squamous carcinoma of the lung and 64% of mutations are at G nucleotides, implicating carcinogens from tobacco smoke in the etiology of head and neck squamous carcinoma.