Antisense rescue defines specialized and generalized functional domains for c-Fos protein

Depletion of the AP-1 repressor JDP2 induces cell death similar to apoptosis

JDP2 is a ubiquitously expressed nuclear protein that efficiently represses the activity of the transcription factor AP-1. Thus far, all studies of JDP2 function have relied on the ectopic expression of the protein. In this study, we use a different approach: depletion of JDP2 from cells. Specific depletion of JDP2 resulted in p53-independent cell death that resembles apoptosis and was evident at 72 h. The death mechanism was caspase dependent as the cells could be rescued by treatment with caspase inhibitor zVAD. Our studies suggest that JDP2 functions as a general survival protein, not only following UV-irradiation, as reported earlier, but also under normal culture conditions. Thus, our data support that JDP2 is a cellular survival protein whose presence is necessary for normal cellular function.

Antisense c-myc retroviral vector suppresses established human prostate cancer

Prostate cancer eventually becomes androgen resistant, resumes growth, and kills the patient. Characterization of genetic events that lead to androgen refractory prostatic neoplasia has revealed the frequent overexpression of c-myc and uncontrolled prostate cancer proliferation. A novel strategy to combat advanced prostate cancer utilized a replication incompetent retrovirus that contained the mouse mammary tumor virus (MMTV) promoter within the retroviral vector to allow transcription of antisense c-myc gene within target prostate tumor cells. The transduction of cultured DU145 cells by XM6:MMTV-antisense c-myc RNA retrovirus did not affect cell proliferation in culture, yet a single direct injection of MMTV-antisense c-myc viral media into established DU145 tumors in nude mice produced a 94.5% reduction in tumor size compared to tumors treated with control virus MTMV sense fos and untreated tumor by 70 days. Two animals in the antisense c-myc-treated group had complete regression of their tumors. Histopathological examination of the tumors revealed that MMTV-antisense c-myc-transduced DU145 tumors had increased tumor cell differentiation, decreased invasion, and a marked stromal response. The mechanism for the antitumor effect of MMTV-antisense c-myc retrovirus appears to be suppression of c-myc mRNA and protein, and decreased bcl-2 protein. The in vivo transduction of prostate cancer cells with MMTV-antisense c-myc retroviruses reduced tumor growth by suppressing c-myc, resulting in the down-regulation of bcl-2 protein. Consequently, the MMTV-antisense c-myc retrovirus may be useful for gene therapy against advanced, hormone-refractory prostate cancer.

Brain substrates activated by electroacupuncture (EA) of different frequencies (II): Role of Fos/Jun proteins in EA-induced transcription of preproenkephalin and preprodynorphin genes

Antisense oligodeoxynucleotides (ODNs) of c-fos and/or c-jun were used in this study to investigate the role of Fos and Jun proteins in electroacupuncture (EA)-induced transcription of the opioid genes, preproenkephalin (PPE), preprodynorphin (PPD) and proopiomelanocortin (POMC). As the results showed, EA-induced Fos and fun expression was blocked efficiently and specifically by e-fos and c-jun antisense ODNs, respectively. This treatment significantly prevented EA-induced PPD, but not PPE, mRNA expression. These results suggest that Fos and Jun proteins are involved in PPD rather than PPE gene transcription activated by EA stimulation.

Analysis of gene function in Dictyostelium

Over the past ten years, powerful molecular genetic techniques have been developed to analyze gene function in Dictyostelium. DNA-mediated transformation using a variety of selections and vectors has allowed the introduction of wild-type or modified genes that are under various forms of transcriptional control. Homologous recombination is efficient and can be used to modify the genome in precise ways. In addition, it is now possible to clone genes based on their mutant phenotype alone, either by insertional mutagenesis, or by screening antisense expression cDNA libraries. Finally, a nearly complete physical map of the genome is available and so genes are easily mapped by physical techniques. We discuss many of these advances within the context of major research problems presently under study.