Hexamethylene bisacetamide (HMBA) and DMSO are known to induce differentiation of cultured erythroleukaemic cells and to enhance the reactivation of latent herpes simplex virus (HSV) after explantation of ganglia. We report that the presence of these compounds in cell culture medium overcomes the replication defect of in1814, an HSV-1 mutant with an insertion mutation that inactivates the virion transinducing factor, Vmw65 (VP16). The effect of HMBA was not cell type-specific and was attained even by a short exposure (1-5 to 5 h) to the agent early after infection. The presence of HMBA resulted in an increase in immediate early (IE) RNA accumulation after infection of cells in the presence of cycloheximide, such that RNA levels in inl814-infected cells approached the values observed in wild-type HSV-1-infected cells in the absence of HMBA. Transport of viral DNA to the cell nucleus was not affected by HMBA. The results suggest that HMBA-and DMSOmediated enhancement of reactivation from latency is due to an increase in IE RNA production. In addition, these studies demonstrate a primary effect of HMBA on gene regulation which may bea paradigm for initial events during erythroleukaemic cell differentiation.
The herpes simplex virus type 1 (HSV-1) mutant in1814 encodes an altered form of the virion protein VP16 that is unable to transactivate immediate-early (IE) transcription. As a consequence of the mutation, in1814 initiates productive replication inefficiently after infection of tissue culture cells. Previous studies showed that this defect could be overcome by the inclusion in the culture medium of hexamethylene bisacetamide (HMBA), a compound that promotes the differentiation of murine erythroleukemia cells (MELCs). The effects of additional agents known to induce differentiation of MELCs were investigated. N'-Methylnicotinamide, at concentrations optimal for the induction of MELCs, complemented the replication of in1814 and stimulated IE gene expression. Suberoyl bishydroxamic acid and suberoylanilide hydroxamic acid, which induce differentiation of MELCs at micromolar concentrations, did not complement in1814 but specifically blocked the action of HMBA. The histone deacetylase inhibitor trichostatin A, which also induces differentiation of MELCs, antagonized the effect of HMBA in a manner similar to that of suberoyl bishydroxamic acid and suberoylanilide hydroxamic acid. The results demonstrate that the requirement for VP16 activity is dependent on the metabolic state of the host cell and that the pathways leading to complementation of in1814 and differentiation of MELCs are overlapping but not identical.
A unique transgenic mouse line has undergone transgene integration in a very precise fashion. The phenotype displayed by mice of the line followed the predicted inheritance patterns for X-linked transgene insertion which has been confirmed. In order to investigate the mechanism of integration the DNA sequence of the transgene and cellular junctions have been determined. A comparison between wild type and transgenic mutant sequences at the site of insertion revealed that there was no loss or rearrangement of cellular DNA upon integration of the transgene. The cellular sequences at the transgene 5' and 3' joins are contiguous in the wild type. The integrant exists as a head to tail tandem dimer with minimal loss of sequence compared with the injected monomer. Analysis of the site of insertion has revealed a 5 bp homology between the 5' end of the transgene and the cellular sequences. In addition, adjacent to the site of insertion within the cellular sequences, there are several sequence motifs implicated in recombination events including a clustering of strong consensus sites of DNA topoisomerase type I and a region of homology to the human minisatellite consensus core sequence, the Escherichia coli Chi site and the meiotic recombination hotspot within the E beta gene of the murine major histocompatibility complex. This clustering of features is likely to have been factorial in the integrity of the insertion event. A model depicting the mechanism of this precise integration is proposed.
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