Pdcd4 is a novel transformation suppressor that is highly expressed in promotion-resistant (P7) mouse epidermal JB6 cells but not in susceptible (P+) cells. Overexpression of pdcd4 cDNA in stably transfected P+ cells rendered cells resistant to tumor promoter-induced transformation, indicating that elevated expression of Pdcd4 protein is su cient to suppress neoplastic transformation. To determine whether Pdcd4 suppresses neoplastic transformation through inhibiting known transformation required events, we examined the possibility that pdcd4 inhibited the activation of AP-1 or NF-kB dependent transcription or of ornithine decarboxylase (ODC) activity. Activation of AP-1-dependent transcriptional activity was inhibited by pdcd4 expression in a concentration dependent manner. In contrast, Pdcd4 slightly increased NF-kB-dependent transcription and did not alter ODC enzymatic activity. Previous studies suggested that activation of AP-1 was required for P+ cell transformation as well as for tumor promotion in vivo. These results indicate that Pdcd4 functions as a transformation suppressor, possibly through inhibiting AP-1 activation in combination with other factors such as enhancing NF-kB activation. Pdcd4 may thus constitute a useful molecular target for cancer prevention. Oncogene (2001) 20, 669 ± 676.
An mRNA differential display comparison of mouse JB6 promotionsensitive (P؉) and -resistant (P؊) cells identified a novel gene product that inhibits neoplastic transformation. The JB6 P؉ and P؊ cells are genetic variants that differ in their transformation response to tumor promoters; P؉ cells form anchorage-independent colonies that are tumorigenic, and P؊ cells do not. A differentially displayed fragment, A7-1, was preferentially expressed in P؊ cells at levels >10-fold those in P؉ cells, making its mRNA a candidate inhibitor of neoplastic transformation. An A7-1 cDNA was isolated that was identical to murine Pdcd4 gene cDNAs, also known as MA-3 or TIS, and analogous to human H731 and 197͞15a. Until now, the function of the Pdcd4 protein has been unknown. Paralleling the mRNA levels, Pdcd4 protein levels were greater in P؊ than in P؉ cells. Pdcd4 mRNA was also expressed at greater levels in the less progressed keratinocytes of another mouse skin neoplastic progression series. To test the hypothesis that Pdcd4 inhibits tumor promoter-induced transformation, stable cell lines expressing antisense Pdcd4 were generated from parental P؊ cells. The reduction of Pdcd4 proteins in antisense lines was accompanied by acquisition of a transformation-sensitive (P؉) phenotype. The antisense-transfected cells were reverted to their initial P؊ phenotype by overexpression of a Pdcd4 sense fragment. These observations demonstrate that the Pdcd4 protein inhibits neoplastic transformation.
The mutagenicity of 1,2-dibromoethane is highly dependent upon its conjugation to glutathione by the enzyme glutathione S-transferase. The conjugates thus formed can react with DNA and yield almost exclusively N7-guanyl adducts. We have synthesized the S-haloethyl conjugates of cysteine and glutathione, as well as selected methyl ester and N-acetyl derivatives, and compared them for ability to produce N7-guanyl adducts with calf thymus DNA. The cysteine compounds were found to be more reactive toward calf thymus DNA and yielded higher adduct levels than did the glutathione compounds. Adduct levels tended to be suppressed when there was a net charge on the compound and were not affected by substitution of bromine for chlorine, as expected for a mechanism known to involve an intermediate episulfonium ion. Sequence-selective alkylation of fragments of pBR322 DNA was investigated. The compounds produced qualitatively similar patterns of alkylation, with higher levels of alkylation at runs of guanines. The compounds were also tested for their ability to act as direct mutagens in Salmonella typhimurium TA98 and TA100. None of the compounds caused mutations in the TA98 frameshift mutagenesis assay. In the strain TA100, where mutation of a specific guanine by base-pair substitution produces reversion, all compounds were found to produce mutations, but the levels of mutagenicity did not correlate at all with the levels of DNA alkylation. The ratio of mutations to adducts varied at least 14-fold among the various N7-guanyl adducts examined.(ABSTRACT TRUNCATED AT 250 WORDS)
Electrophoretic separation of oligonucleotides in denaturing polyacrylamide gels is primarily a function of length-dependent mobility. The 3' terminal nucleotide sequence of the oligonucleotide is a significant, secondary determinant of mobility and separation. Oligomers with 3'-ddT migrate more slowly than expected on the basis of length alone, and thus are better separated from the preceding, shorter oligomers in the sequencing ladder. Oligomers with 3'-ddC are relatively faster than expected, and are therefore less separated. At the 3' penultimate position, -dC- increases and -dT- reduces separation. Purines at the 3' terminal or penultimate positions of oligonucleotides affect separation less than the pyrimidines. These results suggest specific interactions among neighboring nucleotides with important effects on the conformation of oligonucleotides during electrophoresis. These interactions are compared to compression artifacts, which represent more extreme anomalies of length-dependent separation of oligonucleotides. Knowledge of base-specific effects on electrophoretic behavior of DNA oligomers supplements the usual information available for determination of sequences; additionally it provides an avenue to thermodynamic and hydrodynamic investigations of DNA structure.
The United States Department of Defense Blast Injury Research Program Coordinating Office organized the 2015 International State-of-the-Science meeting to explore links between blast-related head injury and the development of chronic traumatic encephalopathy (CTE). Before the meeting, the planning committee examined articles published between 2005 and October 2015 and prepared this literature review, which summarized broadly CTE research and addressed questions about the pathophysiological basis of CTE and its relationship to blast- and nonblast-related head injury. It served to inform participants objectively and help focus meeting discussion on identifying knowledge gaps and priority research areas. CTE is described generally as a progressive neurodegenerative disorder affecting persons exposed to head injury. Affected individuals have been participants primarily in contact sports and military personnel, some of whom were exposed to blast. The symptomatology of CTE overlaps with Alzheimer's disease and includes neurological and cognitive deficits, psychiatric and behavioral problems, and dementia. There are no validated diagnostic criteria, and neuropathological evidence of CTE has come exclusively from autopsy examination of subjects with histories of exposure to head injury. The perivascular accumulation of hyperphosphorylated tau (p-tau) at the depths of cortical sulci is thought to be unique to CTE and has been proposed as a diagnostic requirement, although the contribution of p-tau and other reported pathologies to the development of clinical symptoms of CTE are unknown. The literature on CTE is limited and is focused predominantly on head injuries unrelated to blast exposure (e.g., football players and boxers). In addition, comparative analyses of clinical case reports has been challenging because of small case numbers, selection biases, methodological differences, and lack of matched controls, particularly for blast-exposed individuals. Consequently, the existing literature is not sufficient to determine whether the development of CTE is associated with head injury frequency (e.g., single vs. multiple exposures) or head injury type (e.g., impact, nonimpact, blast-related). Moreover, the incidence and prevalence of CTE in at-risk populations is unknown. Future research priorities should include identifying additional risk factors, pursuing population-based longitudinal studies, and developing the ability to detect and diagnose CTE in living persons using validated criteria.
Most molecular biology and biochemical analyses use cultured cells grown in anchorage-dependent monolayer conditions. The standard oncogenic transformation assay for cell lines is usually performed in soft agar rather than in monolayers because of the higher transformation efficiency of cells in soft agar. However, cells suspended in soft agar cannot be readily recovered for studying inducible biochemical and molecular events. We developed an over-agar assay that enables us to study tumor promoter-induced cell transformation and the associated biochemical or molecular events under anchorage-independent conditions.
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