Heterologous HIV-nef mRNA trans-splicing: a new principle how mammalian cells generate hybrid mRNA and protein molecules.

Heterologous trans-splicing is a messenger RNA (mRNA) processing mechanism, that joins RNA segments from separate transcripts to generate functional mRNA molecules. We present here for the first time experimental evidence that the proximal segment of the HIV-nef RNA segment can be trans-spliced to both viral (e.g. SV40 T-antigen) and cellular transcripts. Following either microinjection of in vitro synthesized HIV-nef and SV40 T-antigen pre-mRNA or transfection of the HIV-nef DNA into T-antigen positive cells (CV1-B3; Cos7), it was found that recipient cells synthesized HIV-nef/T-antigen hybrid mRNA and protein molecules. To generate the hybrid mRNA, the cells utilized the 5' cryptic splice sites of the HIV-nef (5'cry 66 and 5'cry 74) and the SV40 T/t-antigen 3' splice site. To demonstrate that heterologous trans-splicing also occurs between the HIV-nef RNA and cellular transcripts, a cDNA library was established from HIV-nef positive CV1-B3 cells (CV1-B3/13 cells) and screened for hybrid mRNA molecules. Reverse transcription-PCR and Northern blot analysis revealed that a significant portion of the HIV-nef transcript is involved in heterologous trans-splicing. To date, eight independent HIV-nef/cellular hybrid mRNA molecules have been identified. Five of these isolates contain segments from known cellular genes (KIAA1454, PTPkappa, Alu and transposon gene families), while three hybrid segments contain sequences of not yet known cellular genes (genes 1-3).

The SV40 small t-antigen prevents mammary gland differentiation and induces breast cancer formation in transgenic mice; truncated large T-antigen molecules harboring the intact p53 and pRb binding region do not have this effect.

We report here for the first time, that the SV40 small t-antigen inhibits mammary gland differentiation during mid-pregnancy and that about 10% of multiparous WAP-SVt transgenic animals develop breast tumors with latencies ranging from 10-17 months. Cyclin D1 is deregulated and over expressed in the small t-antigen positive mammary gland epithelial cells (ME-cells) and in the breast tumor cells. SV40 small t-antigen immortalized ME-cells (t-ME-cells) exhibit a strong intranuclear cyclin D1 staining, also in the absence of external growth factors and the cells continue to divide for several days without serum. In addition, the expression rate of cyclin E and p21(Waf1) but not of p53 is increased. Coimmunoprecipitation experiments revealed that p21(Waf1) is mainly associated with the cyclin D/CDK4 but not with the cyclin E/CDK2 complex. WAP-SVT transgenic animals exhibit an almost regular mammary gland development until late pregnancy but the majority of the ME-cells are eliminated by apoptosis during the early lactation period. Tumor formation is delayed and less efficient than in T/t-antigen positive animals. Sequestration of p53 and pRb by the N-terminal truncated T-antigen molecules (T1-antigen and T2-antigen) does not affect mammary gland differentiation and the transgenic animals (WAP-SVBst-Bam) do not develop breast tumors.

SV40 T/t-antigen induces premature mammary gland involution by apoptosis and selects for p53 missense mutation in mammary tumors.

We recently established transgenic animals (WAP-SV-T/t) carrying the early coding region of Simian Virus 40 (SV40) under the transcriptional control of the whey acidic milk protein promoter (WAP), which restricts the expression of the transgene to mammary gland epithelial cells (ME-cells). SV40 T/t-antigen synthesis causes premature mammary gland involution during late pregnancy by inducing apoptosis and leads to development of mammary tumors after the first lactation period in both p53 positive (WAP-SV-T/t) and p53 negative double transgenic animals (WAP-SV-T/t.p53-/-). The high apoptotic rate persists in all of the T/t-antigen positive breast tumor cells, as well as in established ME-tissue culture cell lines. ME-cells which spontaneously switch off the expression of the WAP-SV-T/t transgene do not undergo apoptosis. However, these cells again exhibit an extensive DNA fragmentation when SV40 T/t-antigen synthesis is reintroduced, which indicates that it is the expression of T/t antigen which is the critical factor for induction of apoptosis. In addition, we isolated several ME-cell lines from different breast tumors which have spontaneously lost the T/t-antigen yet remain maximally transformed. Strikingly, these cells contain a missense mutation of the p53 gene at codon 242 (p53(242)), which substitutes alanine for glycine. This mutation increases p53 stability and it reduces the transactivating function of p53, albeit without affecting the ability of the protein to interact with the DNA. This indicates that p53 missense mutations are selected for in breast tumors initially expressing T/t-antigen. Therefore, the p53(242) mutation is sufficient to maintain the transformed state after the ME-cells have switched off the WAP-SV-T/t transgene. Interestingly, the p53 minus state per se is not sufficient to induce ME-cell transformation since homozygous null mice for the p53 gene (p53-/-) fail to develop breast cancer.

Mouse DNA methyltransferase (MTase) deletion mutants that retain the catalytic domain display neither de novo nor maintenance methylation activity in vivo.

The mammalian genome encodes a DNA cytosine-5-methyltransferase (MTase) of about 170 kDa that is apparently responsible for both de novo and maintenance methylation at CpG sites. Both methylation activities have to be regulated accurately to ensure correct developmental and cell type-specific gene activity. Distorted DNA methylation patterns have been associated with cell aging and diseases such as cancer and fragile X syndrome. Structural and functional in vitro studies of the mouse MTase have indicated that the enzyme has both a regulatory and a catalytic region located in the N-terminal and C-terminal parts of the protein, respectively. The regulatory region includes the nuclear localization signal (NLS), the sequence for DNA targeting and the Zn-binding domain. The catalytic domain carries the ten consensus sequence motifs specific for all known pro- and eukaryotic DNA cytosine-5-methyltransferases. In an attempt to separate regulatory and catalytic functions of the enzyme in vivo, we have tested various deletion mutations by means of transient and stable cell transfection experiments. Expression of the transgenes, all of which retained the C-terminal catalytic domain, was monitored by immunofluorescence staining, Northern blot analysis and SDS gel electrophoresis. Despite high levels of transgene expression, the truncated MTase molecules exhibited neither de novo nor maintenance methylation activity. These findings might indicate that in vivo, an efficient control mechanism prevents the ectopic activity of the DNA MTase that is structurally compromised in its N-terminal regulatory region.

SV40 T-antigen induces breast cancer formation with a high efficiency in lactating and virgin WAP-SV-T transgenic animals but with a low efficiency in ovariectomized animals.

The whey acid protein (WAP) is a major mouse milk protein and its gene expression is induced by various lactotrophic hormones (eg, estrogen, progesterone). Transgenic animals harboring the early SV40 coding region (T/t-antigen) under the transcriptional control of the WAP promoter develop breast cancer after the first lactation period. The tumor cells synthesize the SV40 T-antigen with a high efficiency indicating that WAP-SV-T expression escapes down-regulation after the lactation period. However about 5-10% of the tumors became T-antigen negative during tumor progression and WAP-SV-T expression was only demonstrable by PCR analysis. Both T-antigen positive and negative tumor cells expressed the estrogen and progesterone receptor at a comparable rate, indicating that hormone receptor levels do not determine expression of the WAP-SV-T transgene. Furthermore, WAP and WAP-SV-T gene expression are not restricted to the pregnancy-lactation period. Virgin animals also express both genes with a low efficiency and about 70% of these animals also developed T-antigen positive breast tumors. The tumor rate however was strongly reduced in ovariectomized animals, indicating that the ovary hormones play a critical role in breast cancer formation.

Overexpression of alternative human acetylcholinesterase forms modulates process extensions in cultured glioma cells.

In addition to its well-known synaptic function, acetylcholinesterase was recently shown to stimulate neurite outgrowth from cultured chick neurons in a manner unrelated to its catalytic activity. It remained unclear, however, whether each of the variant acetylcholinesterase enzyme forms can promote such process extension and whether this effect of acetylcholinesterase was limited to neurite outgrowth. Using DNA microinjections and stable transfections of cultured glioma cells, we explored the possibility that specific acetylcholinesterase isoforms affect cellular development and morphology of CNS astrocytes. Cells microinjected with human ACHEDNA constructs that differ in their exon-intron composition displayed rapid yet stable induction of cell body enlargement and process extensions. Cells transfected with ACHEDNA carrying the neuronal-characteristic 3'-E6 domain also displayed stable process extensions. However, stable transfections with ACHEDNAs including the 3'-alternative 14/E5 region induced the appearance of small, round cells in a dominant manner. This was associated with expression of 14/E5-ACHEmRNA transcripts and the production of soluble acetylcholinesterase monomers that were catalytically indistinguishable from the 3'-E6 enzyme but displayed higher electrophoretic mobility than that of the 3'-E6 form. Thus, variable expression levels and alternative splicing modes of the ACHE gene correlated in these experiments with glial development in a manner that was apparently unrelated to catalysis.

Methylation of single sites within the herpes simplex virus tk coding region and the simian virus 40 T-antigen intron causes gene inactivation.

In order to determine whether partial methylation of the herpes simplex virus (HSV) tk gene prevents tk gene expression, the HSV tk gene was cloned as single-stranded DNA. By in vitro second-strand DNA synthesis, specific HSV tk gene segments were methylated, and the hemimethylated DNA molecules were microinjected into thymidine kinase-negative rat2 cells. Conversion of the hemimethylated DNA into symmetrical methylated DNA and integration into the host genome occurred early after gene transfer, before the cells entered into the S phase. HSV tk gene expression was inhibited either by promoter methylation or by methylation of the coding region. Using the HindIII-SphI HSV tk DNA fragment as a primer for in vitro DNA synthesis, all cytosine residues within the coding region, from +499 to +1309, were selectively methylated. This specific methylation pattern caused inactivation of the HSV tk gene, while methylation of the cytosine residues within the nucleotide sequence from +811 to +1309 had no effect on HSV tk gene activity. We also methylated single HpaII sites within the HSV tk gene using a specific methylated primer for in vitro DNA synthesis. We found that of the 16 HSV tk HpaII sites, methylation of 6 single sites caused HSV tk inactivation. All six of these "methylation-sensitive" sites are within the coding region, including the HpaII-6 site, which is 571 bp downstream from the transcription start site. The sites HpaII-7 to HpaII-16 were all methylation insensitive. We further inserted separately the methylation-sensitive HSV tk HpaII-6 site and the methylation-insensitive HpaII-13 site as DNA segments (32-mer) into the intron region of the simian virus 40 T antigen (TaqI site). Methylation of these HpaII sites caused inhibition of simian virus 40 T-antigen synthesis.

Breast cancer formation in transgenic animals induced by the whey acidic protein SV40 T antigen (WAP-SV-T) hybrid gene.

After injection of the whey acidic protein (WAP)-SV-T hybrid gene into fertilized mouse eggs, eight independent transgenic mouse lines were obtained. Females from three lines developed mammary carcinomas with high frequency, coinciding mostly with lactation. In contrast to the endogenous WAP gene, expression of the hybrid gene continued after lactation. The tumor cells had a very invasive growth characteristic. Tumor regression in vivo was not observed. However, after transfer into tissue culture 25% of the cells ceased to express the hybrid gene and acquired the growth characteristic of normal cells. It was possible to retransform these cells by injection of wild-type SV40 DNA, but not after transfer of the hybrid WAP-SV-T gene. Inactivation of the endogenous WAP and of the WAP-SV-T transgene did not correlate with DNA methylation.

After microinjection hemimethylated DNA is converted into symmetrically methylated DNA before DNA replication.

In this investigation we analysed the maintenance methylation activity of the mammalian cell DNA methyltransferase by microinjection of hemimethylated HSV-tk DNA into thymidine kinase-negative rat 2 cells. We found that the hemimethylated DNA was efficiently converted into symmetrical methylated molecules before DNA replication. Furthermore, integration of the trans-DNA into the host genome is an early event after gene transfer.

Cellular mutation mediates T-antigen-positive revertant cells resistant to simian virus 40 transformation but not to retransformation by polyomavirus and adenovirus type 2.

T-antigen-positive transformation revertant cell lines were isolated from fully simian virus 40 (SV40)-transformed Fisher rat embryo fibroblast cells (REF 52 cells) by methionine starvation. Reversion of the transformed cells (SV-52 cells) was caused by a mutation within the cellular genome. To demonstrate this, we isolated SV40 DNA from the host genome, inserted it into plasmid pSPT18 DNA, cloned it in Escherichia coli, and microinjected it into the nuclei of the REF 52 cells. Fully transformed cells were obtained with the same efficiency (20 to 25%) as after microinjection of wild-type SV40 DNA I. Furthermore, the revertant cells were resistant to retransformation by SV40. Following microinjection of wild-type SV40 DNA I, 42 independent cell lines were isolated. Cells of all analyzed lines acquired additional SV40 DNA copies, but changes in the cell morphology or growth characteristic were not demonstrable. However, the revertants were retransformable with a high efficiency after polyomavirus and adenovirus type 2 infections or microinjection. Also, fusion of the revertant cells with the grandparental REF 52 cells led to restoration of the transformed state.

The second large simian virus 40 T-antigen exon contains the information for maximal cell transformation.

Microinjection of early simian virus 40 (SV40) DNA fragments has shown that maximal transformation of rat cells (Ref 52) is a property of the second SV40 T-antigen exon. Expression of this particular T-antigen region was obtained by coinjection of the Taq/Bam DNA fragment with the early promoter/enhancer HpaII/BglI fragment. Microinjection of the DNA fragment mixture induced two categories of transformants; namely, maximally and minimally transformed cells. The maximally transformed cells synthesize two Taq/Bam-specific polypeptides, and the minimally transformed cells only the lower molecular weight form. Both types of transformants contain the cellular p52 protein at high concentrations. Furthermore, maximal transformation of Ref 52 cells requires the carboxy terminus of the T-antigen. Cells transformed by microinjection of the SV40 Pst A-fragment display different parameters of maximally transformed cells but not anchorage-independent growth.

Quantitative correlation between simian virus 40 T-antigen synthesis and late viral gene expression in permissive and nonpermissive cells.

The time-course of intranuclear Simian virus 40 (SV40) tumor (T) antigen synthesis and accumulation in permissive CV1 monkey cells and nonpermissive 3T3 mouse cells has been studied by immunofluorescence and cytofluorometry. CV1 cells accumulate T antigen continuously over a period of 48 h after infection, whereas in 3T3 cells the T-antigen content remains about constant and at a comparatively low level. Only those CV1 cells which have attained a threshold concentration of intranuclear T antigen synthesize viral capsid proteins (V antigen). In nonpermissive 3T3 cells, the T-antigen threshold value for the onset of V-antigen synthesis is higher than in CV1 cells and is never reached by infected cells. However, 3T3 cells microinjected with sufficient amounts of SV40 DNA easily surpass this value and behave permissively.

[Hemodynamic and electrocardiographic prolonged nitrate effect during frequency load in coronary disease]. / Hämodynamische und elektrokardiographische Langzeit-Nitratwirkung unter Frequenzbelastung bei koronarer Herzkrankheit

Hemodynamic and electrocardiographic analysis during rapid right atrial stimulation was performed before and one, two, and four hours after oral application of longacting nitroglycerin (5 mg) and isosorbide dinitrate (20 mg) in 11 and 9 patients, respectively with coronary heart disease. Atrial stimulation without nitrate induced significant ischemic ST segment depression. Cardiac output showed a small decrease and the mean arterial, pulmonary artery, and pulmonary wedge pressure increased. Isosorbide dinitrate reduced the ischemic reaction by 40% from the first to the fourth hour after application. Cardiac output, stroke volume, aterial, pulmonary artery, and pulmonary wedge pressure also decreased continuously. Nitroglycerin caused a similar reduction of ischemic ST segment depression for two hours. Systolic, diastolic, and mean arterial pressure decreased significantly. Cardiac output, stroke volume, and pulmonary artery pressure remained unchanged. It was concluded that the applied dose of isosorbide dinitrate showed a more extensive longacting effect.