Mechanisms of replication-deficient vaccinia virus/T7 RNA polymerase hybrid expression: effect of T7 RNA polymerase levels and alpha-amanitin

Components of the eukaryotic vaccinia virus/T7 RNA polymerase hybrid expression system were assessed using recombinant and nonrecombinant forms of modified vaccinia Ankara (MVA), a replication-deficient vaccinia virus strain. Recombinant MVA virus expressing T7 RNA polymerase (Wyatt, L. S., Moss, B., and Rozenblatt, S. (1995). Virology 210, 202-205) stimulated high levels of expression from a T7 promoter-chloramphenicol acetyltransferase (CAT) reporter. Most, but not all, of the virally induced expression was T7 RNA polymerase and T7 promoter dependent, with no viral enhancement of translation of T7 transcripts. The efficacy of supplying T7 RNA polymerase expression from nonviral sources was evaluated using a self-amplifying T7 RNA polymerase autogene or an inducible T7 RNA polymerase expression vector. The latter modes yielded CAT activity dependent on T7 RNA polymerase expression; however, expression required viral factors independent of T7 RNA polymerase and did not reach that attained using the recombinant virus. In further experiments, MVA-induced T7 RNA polymerase expression was upregulated by alpha-amanitin, an inhibitor of eukaryotic polymerases. This indicates that MVA/T7 RNA polymerase hybrid expression may be rendered still more efficient by ameliorating transcriptional interference due to an alpha-amanitin-sensitive eukaryotic factor(s).

Differential roles of p300 and PCAF acetyltransferases in muscle differentiation

PCAF is a histone acetyltransferase that associates with p300/CBP and competes with E1A for access to them. While exogenous expression of PCAF potentiates both MyoD-directed transcription and myogenic differentiation, PCAF inactivation by anti-PCAF antibody microinjection prevents differentiation. MyoD interacts directly with both p300/CBP and PCAF, forming a multimeric protein complex on the promoter elements. Viral transforming factors that interfere with muscle differentiation disrupt this complex without affecting the MyoD-DNA interaction, indicating functional significance of the complex formation. Exogenous expression of PCAF or p300 promotes p21 expression and terminal cell-cycle arrest. Both of these activities are dependent on the histone acetyltransferase activity of PCAF, but not on that of p300. These results indicate that recruitment of histone acetyltransferase activity of PCAF by MyoD, through p300/CBP, is crucial for activation of the myogenic program.

A histone deacetylase inhibitor potentiates retinoid receptor action in embryonal carcinoma cells

Histone acetylation is thought to have a role in transcription. To gain insight into the role of histone acetylation in retinoid-dependent transcription, we studied the effects of trichostatin A (TSA), a specific inhibitor of histone deacetylase, on P19 embryonal carcinoma cells. We show that coaddition of TSA and retinoic acid (RA) markedly enhances neuronal differentiation in these cells, although TSA alone does not induce differentiation but causes extensive apoptosis. Consistent with the cooperative effect of TSA and RA, coaddition of the two agents synergistically enhanced transcription from stably integrated RA-responsive promoters. The transcriptional synergy by TSA and RA required the RA-responsive element and a functional retinoid X receptor (RXR)/retinoic acid receptor (RAR) heterodimer, both obligatory for RA-dependent transcription. Furthermore, TSA led to promoter activation by an RXR-selective ligand that was otherwise inactive in transcription. In addition, TSA enhanced transcription from a minimum basal promoter, independently of the RA-responsive element. Finally, we show that TSA alone or in combination with RA increases in vivo endonuclease sensitivity within the RA-responsive promoter, suggesting that TSA treatment might alter a local chromatin environment to enhance RXR/RAR heterodimer action. Thus, these results indicate that histone acetylation influences activity of the heterodimer, which is in line with the observed interaction between the RXR/RAR heterodimer and a histone acetylase presented elsewhere.

Alu-mediated detection of DNA damage in the human genome

A new approach to monitoring UV damage and repair in the human genome has been developed. The proposed approach is based on a combination of features unique to interspersed repetitive Alu elements, and the ability of certain DNA lesions to block Taq polymerase-mediated DNA synthesis: namely, the extraordinary abundance of Alu repeats throughout the human genome in conjunction with distinct sequence motifs comprising long runs of T residues which are likely targets for formation of UV lesions. Hence, Taq polymerase-mediated extension synthesis with Alu specific primers was employed to visualize formation of discrete predicted adducts within the element. Several variations of the Alu-primer driven amplification protocol were developed to monitor the following aspects of damage: (i) induction of UV-photoproducts at predicted sites within the Alu sequence, (ii) modification of extension synthesis profiles, (iii) UV dose dependent, quantitative inhibition of Alu-primer driven amplification. The assays reveal sites of predicted Taq polymerase blockage within the Alu sequence, a global decrease in the mean length of extension products, and a measurable reduction in the quantity of extension products that is inversely proportional to UV dose. Thus, the exceptional abundance of Alu repeats and their primary sequence features, in combination with the ability of UV lesions to block elongation by Taq polymerase, provide a novel and sensitive system for detecting UV damage in the human genome. The system detects UV damage at levels that are compatible with cellular DNA repair, and provides a unique amplification-based protocol for probing the overall integrity of human DNA.

Antisense inhibition of CAS, the human homologue of the yeast chromosome segregation gene CSE1, interferes with mitosis in HeLa cells

We have analyzed the effects on HeLa cells of reduction of the CAS protein, the human homologue to yeast chromosome segregation protein CSE1. Expression of CAS antisense cDNA decreases the amount of CAS protein in HeLa cells and perturbs progression from G2 (retards transition from G2) to G1 in the cell cycle. Increased levels of cyclin B in CAS antisense transfected cells correlated with an arrest in G2 phase or mitosis. This arrest upon CAS attenuation is consistent with observations that yeast with CSE1 mutations are defective in mitosis and cyclin B degradation.

WAF1 retards S-phase progression primarily by inhibition of cyclin-dependent kinases

The p21(WAF1/CIP1/sdi1) gene product (WAF1) inhibits DNA replication in vitro (J. Chen, P. Jackson, M. Kirschner, and A. Dutta, Nature 374:386-388, 1995; S. Waga, G. Hannon, D. Beach, and B. Stillman, Nature 369:574-578, 1994), but in vivo studies on the antiproliferative activity of WAF1 have not resolved G1-phase arrest from potential inhibition of S-phase progression. Here, we demonstrate that elevated WAF1 expression can retard replicative DNA synthesis in vivo. The WAF1-mediated inhibitory effect could be antagonized by cyclin A, cyclin E, or the simian virus 40 small-t antigen with no decrease in the levels of WAF1 protein in transfected cells. Proliferating-cell nuclear antigen (PCNA) overexpression was neither necessary nor sufficient to antagonize WAF1 action. Expression of the N-terminal domain of WAF1, responsible for cyclin-dependent kinase (CDK) interaction, had the same effect as full-length WAF1, while the PCNA binding C terminus exhibited modest activity. We conclude that S-phase progression in mammalian cells is dependent on continuing cyclin and CDK activity and that WAF1 affects S phase primarily through cyclin- and CDK-dependent pathways.

A dominant negative mutant of an IFN regulatory factor family protein inhibits both type I and type II IFN-stimulated gene expression and antiproliferative activity of IFNs

Type I (alpha,beta) and type II (gamma) IFNs elicit antiproliferative and antiviral activities through two distinct transcription pathways involving 1) IRF family proteins and ISGF3, and 2) STAT1. We have employed a dominant negative strategy to study the role of IRF family proteins in eliciting the biologic activities of IFN. A truncated IRF protein retaining the DNA-binding domain (DBD) of ICSBP (a member of the IRF family) was stably transfected into U937 monocytic cells. Clones expressing DBD had markedly reduced ISRE-binding activity and were defective in expressing several type I IFN-inducible genes. STAT1 was one such type I IFN-inducible gene whose expression was also inhibited in DBD clones. As a result, the expression of several IFN-gamma-inducible genes was also inhibited in these clones, indicating functional coupling of the type I and type II IFN transcription pathways. Furthermore, DBD clones grew more slowly than control clones and were refractory to antiproliferative effects of both types of IFNs. We found that IFN treatment of U937 cells leads to a G1 arrest and an increase in underphosphorylated retinoblastoma gene product. However, IFN treatment did not change the cell cycle profile, nor retinoblastoma gene product phosphorylation state in DBD clones. These data indicate that expression of DBD disrupts cell cycle regulatory mechanisms. Combined with the previously noted failure of DBD clones to elicit antiviral activity, the present work shows that IRF family proteins play an integral part in growth control activities of IFNs.

A dominant negative mutant of an IFN regulatory factor family protein inhibits both type I and type II IFN-stimulated gene expression and antiproliferative activity of IFNs

Type I (alpha,beta) and type II (gamma) IFNs elicit antiproliferative and antiviral activities through two distinct transcription pathways involving 1) IRF family proteins and ISGF3, and 2) STAT1. We have employed a dominant negative strategy to study the role of IRF family proteins in eliciting the biologic activities of IFN. A truncated IRF protein retaining the DNA-binding domain (DBD) of ICSBP (a member of the IRF family) was stably transfected into U937 monocytic cells. Clones expressing DBD had markedly reduced ISRE-binding activity and were defective in expressing several type I IFN-inducible genes. STAT1 was one such type I IFN-inducible gene whose expression was also inhibited in DBD clones. As a result, the expression of several IFN-gamma-inducible genes was also inhibited in these clones, indicating functional coupling of the type I and type II IFN transcription pathways. Furthermore, DBD clones grew more slowly than control clones and were refractory to antiproliferative effects of both types of IFNs. We found that IFN treatment of U937 cells leads to a G1 arrest and an increase in underphosphorylated retinoblastoma gene product. However, IFN treatment did not change the cell cycle profile, nor retinoblastoma gene product phosphorylation state in DBD clones. These data indicate that expression of DBD disrupts cell cycle regulatory mechanisms. Combined with the previously noted failure of DBD clones to elicit antiviral activity, the present work shows that IRF family proteins play an integral part in growth control activities of IFNs.

The transcriptional coactivators p300 and CBP are histone acetyltransferases

p300/CBP is a transcriptional adaptor that integrates signals from many sequence-specific activators via direct interactions. Various cellular and viral factors target p300/CBP to modulate transcription and/or cell cycle progression. One such factor, the cellular p300/CBP associated factor (PCAF), possesses intrinsic histone acetyltransferase activity. Here, we demonstrate that p300/CBP is not only a transcriptional adaptor but also a histone acetyltransferase. p300/CBP represents a novel class of acetyltransferases in that it does not have the conserved motif found among various other acetyltransferases. p300/CBP acetylates all four core histones in nucleosomes. These observations suggest that p300/CBP acetylates nucleosomes in concert with PCAF.

Human fibroblast commitment to a senescence-like state in response to histone deacetylase inhibitors is cell cycle dependent

Human diploid fibroblasts (HDF) complete a limited number of cell divisions before entering a growth arrest state that is termed replicative senescence. Two histone deacetylase inhibitors, sodium butyrate and trichostatin A, dramatically reduce the HDF proliferative life span in a manner that is dependent on one or more cell doublings in the presence of these agents. Cells arrested and subsequently released from histone deacetylase inhibitors display markers of senescence and exhibit a persistent G1 block but remain competent to initiate a round of DNA synthesis in response to simian virus 40 T antigen. Average telomere length in prematurely arrested cells is greater than in senescent cells, reflecting a lower number of population doublings completed by the former. Taken together, these results support the view that one component of HDF senescence mimics a cell cycle-dependent drift in differentiation state and that propagation of HDF in histone deacetylase inhibitors accentuates this component.

A p300/CBP-associated factor that competes with the adenoviral oncoprotein E1A

The adenoviral oncoprotein E1A induces progression through the cell cycle by binding to the products of the p300/CBP and retinoblastoma gene families. A new cellular p300/CBP-associated factor (P/CAF) having intrinsic histone acetylase activity has been identified that competes with E1A. Exogenous expression of P/CAF in HeLa cells inhibits cell-cycle progression and counteracts the mitogenic activity of E1A. E1A disturbs the normal cellular interaction between p300/CBP and its associated histone acetylase.

RAR and RXR selective ligands cooperatively induce apoptosis and neuronal differentiation in P19 embryonal carcinoma cells

Retinoids cause differentiation in embryonal carcinoma (EC) cells, thus mimicking events in mammalian development. Here, we show that retinoids also cause apoptosis in P19 EC cells. Characteristic DNA fragmentation was observed within 36 h after addition of retinoic acid (RA). Synthetic retinoids that are selective for RA receptors (RAR) were also effective in inducing apoptosis, whereas RXR selective ligands were without effect. The combination of RAR and RXR ligands resulted in a synergistic increase in apoptotic cell death. As with apoptosis, neuronal differentiation of P19 cells was synergistically induced by the combination of RAR and RXR ligands. Data obtained with an RAR antagonist and with P19 cells carrying a dominant negative RXR indicate that the two processes are receptor mediated. Together, our results indicate that retinoid-induced apoptosis and neuronal differentiation are closely coupled, and that both RAR and RXR play a role in these processes as active receptors for their respective ligands.

A naturally occurring T14A11 tract blocks nucleosome formation over the human neurofibromatosis type 1 (NF1)-Alu element

The nature of chromatin organization over Alu repetitive elements is of interest with respect to the maintenance of their transcriptional silencing as well as their potential to influence local chromatin structure. We previously demonstrated that the pattern of nucleosomal organization over Alu elements in native chromatin is specific and similar to the pattern observed with an in vitro reconstituted Alu template. This pattern, distinguished by a nucleosome centered over the 5 -end of the Alu element, is associated with repression of polymerase III-dependent transcription in vitro (Englander, E. W., Wolffe, A. P., and Howard, B. H. (1993) J. Biol. Chem. 268, 19565-19573; Englander, E. W., and Howard, B. H. (1995) J. Biol. Chem. 270, 10091-10096). In the current study, additional templates representing both evolutionarily old and young Alu subfamilies were found to direct a similar pattern of nucleosome assembly, consistent with the view that nucleosome positioning in vitro is shared by a majority of Alus. We discovered however, that the specific nucleosome positioning pattern was disrupted over one member of a young Alu subfamily, which recently transposed immediately downstream to a T14A11 sequence in the neurofibromatosis type 1 locus (Wallace, M. R., Andersen, L. B., Saulino, A. M., Gregory, P. E., Glover, T. W., and Collins, F. S. (1991) Nature 353, 864-866). Upon removal of this sequence motif, the expected pattern of assembly was restored to the neurofibromatosis type 1-Alu template. This finding indicates that, at least in vitro, certain sequences can override the propensity for positioning nucleosomes that is inherent to Alu elements. The finding also raises the possibility that a similar situation may occur in vivo, with potential implications for understanding mechanisms by which certain Alu elements may evade chromatin-mediated transcriptional silencing.

Specific binding sites for a pol III transcriptional repressor and pol II transcription factor YY1 within the internucleosomal spacer region in primate Alu repetitive elements

Alu interspersed repetitive elements possess internal RNA polymerase III promoters that are transcribed in vitro and in transfected mouse cells but are nearly silent in human HeLa cells. Transcriptional repression of these elements is to some extent reversible, as pol III-dependent Alu expression can be induced with herpes simplex or adenovirus. To assess whether sequence-specific DNA binding proteins might contribute to Alu transcriptional silencing, we examined the internucleosomal spacer region surrounding the B box of the Alu pol III promoter in HeLa cell nuclei for evidence of proteins bound at specific sites in vivo. We identified a DNase I-hypersensitive site 5' to the B box and a DNase I-resistant region 3' to the B box in nuclei. An Alu-specific repressor binds to a 5-bp inverted repeat motif overlapping the 5' end of the TFIIIC binding site and may inhibit pol III transcription through competitive displacement. The level of Alu-specific pol III repressor activity is significantly reduced in adenovirus-infected HeLa cells, suggesting that the repressor may contribute to Alu transcriptional silencing in vivo. The 3' DNase I-resistant region coincided with a binding site for the pol II transcription factor YY1 in vitro. YY1 is one of the major proteins in HeLa cells having binding specificity for Alu elements. YY1 bound to tandem arrays of genomic Alu elements may play a role in chromatin organization and silencing.

Replicative senescence: considerations relating to the stability of heterochromatin domains

Replicative senescence of human diploid fibroblasts (HDF) cultured in vitro is characterized by a progressive and irreversible loss of responsiveness to mitogenic stimulation by serum. While some constraints have been placed on the nature of HDF senescence, its underlying molecular mechanism(s) remain obscure. Here, the possibility is considered that defects in cell cycle-coupled reassembly of repressive chromatin domains may contribute to HDF senescence. Features of this model are discussed in relation to established models of HDF senescence based on telomere shortening and loss of DNA methylation.

Adenovirus type 2 preferentially stimulates polymerase III transcription of Alu elements by relieving repression: a potential role for chromatin

The number of Alu transcripts that accumulate in HeLa and other human cells is normally very low; however, infection with adenovirus type 5 increases the expression of Alu elements dramatically, indicating that the potential for polymerase III (pol III)-dependent Alu transcription in vivo is far greater than generally observed (B. Panning and J.R. Smiley, Mol. Cell. Biol. 13:3231-3244, 1993). In this study, we employed nuclear run-on in combination with a novel RNase H-based assay to investigate transcription from uninfected and adenovirus type 2-infected nuclei, as well as genomic DNAs from uninfected and infected cells. When performed in the presence of excess uninfected nuclear extract, such assays revealed that (i) the vast majority of transcriptionally competent Alu elements in nuclei are masked from the pol III transcriptional machinery and (ii) the induction of Alu expression upon adenovirus infection can be largely accounted for by an increased availability of these elements to the pol III transcription machinery. We also investigated the role of H1 histone for silencing of Alu genes and, in comparison, mouse B2 repetitive elements. Depletion of H1 led to an approximately 17-fold activation of B2 repetitive elements but did not change Alu transcription relative to that of constitutively expressed 5S rRNA genes. These results are consistent with the view that Alu repeats are efficiently sequestered by chromatin proteins, that such masking cannot be accounted for by nonspecific H1-dependent repression, and that adenovirus infection at least partially overrides the repressive mechanism(s).

Nucleosome positioning by human Alu elements in chromatin

Alu sequences are interspersed throughout the genomes of primate cells, occurring singly and in clusters around RNA polymerase II-transcribed genes. Because these repeat elements are capable of positioning nucleosomes in in vitro reconstitutes (Englander, E. W., Wolffe, A. P., and Howard, B. H. (1993) J. Biol. Chem. 268, 19565-19573), we investigated whether they also influence in vivo chromatin structure. When assayed collectively using consensus sequence probes and native chromatin as template, Alu family members were found to confer rotational positioning on nucleosomes or nucleosome-like particles. In particular, a 10-base pair pattern of DNase I nicking that spanned the RNA polymerase III box A promoter motif extended upstream to cover diverse 5'-flanking sequences, suggesting that Alu repeats may influence patterns of nucleosome formation over neighboring regions. Computational analysis of a set of naturally occurring Alu sequences indicated that nucleosome positioning information is intrinsic to these elements. Inasmuch as local chromatin organization influences gene expression, the capacity of Alu sequences to affect chromatin structure as demonstrated here may help to clarify some features of these elements.

Methylation- and mutation-dependent stimulation of Alu transcription in vitro

Alu genes are GC-rich, highly repetitive genetic elements whose functions remain unknown. Members of this family are readily transcribed in vitro by RNA polymerase III, but RNA corresponding to only a small sub-set of Alu elements has been found in vivo. Based on the hypothesis that methylation of Alu elements affects their transcription, the transcriptional activity of unmethylated and methylated template DNA was assessed in vitro. It was found that methylation of a single CG site just 5' to Alu functions to stimulate transcription; the base composition in this region also affects transcriptional activity. These results indicate that the methylation state and sequence of DNA flanking Alu elements influence its transcription rate.

Lumbar epidural varix as a cause of radiculopathy

STUDY DESIGN

Venous outflow obstruction or congestion has been implicated in the etiology of some lumbar radicular syndromes. Ten cases of epidural varices or variants manifesting themselves as masses within the lumbar spinal canal or adjacent foramina have been seen.

OBJECTIVES

Diagnosis was made by multiplanar cross-sectional magnetic resonance and computed tomography imaging and confirmed in five patients by operative findings. These venous abnormalities differ from cases of arteriovenous malformations described in the literature.

METHOD

Surgical treatment consisting of coagulative oblation and/or excision of the lesion was consistently successful in the five patients who underwent operations for recalcitrant symptoms. The other five patients experienced spontaneous resolution of symptoms. Three distinctly different types of these abnormalities have been identified.

RESULTS

The described entity may account for some previously unexplained or spontaneously resolving cases of lumbar radiculitis.

CONCLUSIONS

Knowledge of the existence of this condition, its possible etiologies, and its imaging characteristics may assist in its recognition and improved management of patients with it.

Dissociation of retinoblastoma gene protein hyperphosphorylation and commitment to enter S phase

Mitogenic activities of simian virus 40 large T and small t antigens were studied in serum-deprived human diploid fibroblasts. Wild-type large T and small t cooperated in stimulating DNA synthesis and in inducing hyperphosphorylation of the Rb gene product (pRb). In contrast, a T antigen mutant defective for pRb binding (Rb- T) possessed no detectable mitogenic activity alone and failed to complement small t in stimulating DNA synthesis. Surprisingly, Rb- T and small t cooperated as strongly as wild-type T and small t with respect to pRb hyperphosphorylation. As a consequence, in two closely related conditions (i.e., stimulation by small t plus wild-type T versus small t plus Rb- T), the fraction of pRb in hyperphosphorylated forms dissociated from the fraction of cells in the S phase. These results indicate that pRb hyperphosphorylation is not always tightly coupled with a commitment to initiate DNA replication.

Nucleosome interactions with a human Alu element. Transcriptional repression and effects of template methylation

Alu interspersed repetitive elements possess internal RNA polymerase III promoters which are strongly transcribed in vitro, yet these elements are nearly silent in somatic cells. To examine whether repression by chromatin proteins could contribute to the low level of Alu expression, a conserved Alu element from the fourth intron of the human alpha-fetoprotein gene was reconstituted with purified octamer or tetramer particles. Analysis of reconstitutes revealed that this Alu element directed translational and rotational positioning of octamers as well as tetramers. In vitro transcription experiments with reconstituted templates demonstrated that RNA polymerase III-dependent transcription of the Alu element was profoundly repressed by positioned octamer particles. Furthermore, complete CpG methylation of this template enhanced the capacity of tetramers to repress transcription.

Expression of Alu and 7SL RNA in Alzheimer's and control brains

We investigated whether changes in expression of RNA polymerase III (pol III) or heterodisperse RNA polymerase II (pol II) transcripts hybridizing to Alu could be detected in Alzheimer's disease (AD). RNA samples obtained from AD and control brain tissues were examined by Northern analysis for Alu and 7SL RNA expression. All RNA samples contained a prominent band of approximately 300 nucleotides which corresponds to 7SL RNA, the Alu-homologous RNA component of the signal recognition particle. In addition, three small (i.e. less than 300 nucleotide) 7SL/Alu-hybridizing transcripts were detected. The two larger of the low molecular weight transcripts hybridized preferentially to the 7SL RNA probe, while the smallest transcript hybridized to the Alu probe. These transcripts and the heterodisperse RNA were variable in quantity and displayed a lack of correlation with AD.

Expression of GTP-binding proteins and prostaglandin E2 receptors during human T cell activation

GTP-binding proteins (G-proteins) are a family of closely related, yet structurally distinct signal transducing proteins. In this study the presence and relative abundance of several G-proteins and of their corresponding mRNAs were measured in resting and activated human T lymphocytes. We found that T lymphocytes contain RNA coding for Gs, Gi2, and Gi3. No Gi1- and Go-specific RNA could be detected. Membrane fractions of resting and activated lymphocytes were studied in immunoblot experiments. Again, Gs, Gi2, and Gi3, but not Gi1 and Go, were detected. Upon mitogenic activation, a relative increase in mRNA for Gs and Gi3, but not for Gi2 could be demonstrated in Northern blot experiments. Immunoblotting indicated an increase in Gs and Gi3 density in membrane fractions of T cells as well. Paralleling the increase in Gs, we found that activated T cells produce five to seven times more cAMP per cell in response to prostaglandin E2 (PGE2) than resting lymphocytes. Finally, PGE2 binding studies showed that the number of receptors for this hormone increased from 435 +/- 322 to 1035 +/- 357 per cell following in vitro stimulation. We propose that in vitro T cell activation is paralleled by an increase in sensitivity to PGE2-induced cAMP generation. This sensitization is accompanied by both an increase in cell surface PGE2 receptor numbers as well as by increased expression of the signal transducing protein Gs and may physiologically be important for limiting an immune response.