Alterations of polyadenylate nuclease activities in herpes simplex virus-infected cells

Dramatic increase in poly(A) synthesis after infection of Molt-3 cells with HIV

Infection of Molt-3 cells with human immunodeficiency virus-1 (HIV-1) was found to cause a rapid increase in extractable poly(A) polymerase activity, while the activity of poly(A) degrading endoribonuclease IV strongly decreased at the same time. The increase in poly(A) polymerase activity seems not to be due to a change in the actual number of enzyme molecules, but rather to posttranslational enzyme modification, most likely caused by phosphorylation by nuclear protein kinase NI or protein kinase C. Both kinases were found to be able to phosphorylate poly(A) polymerase in vitro [homogeneous enzyme as well as poly(A) polymerase in intact nuclei]. Phosphoamino acid analysis revealed an incorporation of phosphate into serine and, to a lower extent, into threonine residues of the enzyme protein; no phosphotyrosine could be detected. In the nucleus, the poly(A) polymerase and the endoribonuclease IV are bound to the nuclear matrix. The phosphorylation related enhancement of nuclear poly(A) polymerase activity could be abolished by addition of the zinc and copper chelator o-phenanthroline, which inhibited zinc-containing purified poly(A) polymerase and destroyed the poly(A) polymerase containing nuclear matrix structure, resulting in a solubilization of the enzyme.

Poly(A) metabolism and aging: a current view

Polyadenylation of mRNA is a key step in post-transcriptional control of gene expression. Therefore, age-dependent changes in poly(A) synthesis have to play a crucial role in the course of cellular aging. In this review, the importance of the signal sequence, poly(A), in determining mRNA stability and intracellular distribution of mRNA during aging is discussed.

Change of processing and nucleocytoplasmic transport of mRNA in HSV-1-infected cells

A monoclonal antibody (MAb) raised against the pore-complex lamina fraction from CV-1 cells was used to study alterations of gene expression in herpes simplex virus type 1 (HSV-1)-infected cells. This MAb, which recognized only one cellular polypeptide of 60,000 Da, selectively stained the nucleus in immunofluorescence microscopy, showing a punctuated pattern either at the nuclear surface or at the nuclear rim. By immunoelectron microscopy, the p60 antigen could be localized in the nuclear pore complex structure. Infection of CV-1 cells with HSV-1 resulted in a drastic change of the nuclear staining pattern. Four hours p.i., a clustering of the p60 antigen and, 12 h p.i., a formation of finger-like holes, penetrating the nucleus, occurred. Later in infection (22 h p.i.) the antigen was found to be almost absent. By RNA blot hybridization it was demonstrated that, after HSV-1 infection, the level of cellular mRNA (beta-tubulin) gradually decreased, while the level of HSV major DNA binding protein (DBP) mRNA increased, reaching maximal level 3-6 h p.i. Interestingly, the level of beta-tubulin gene transcripts changed differentially in the polysomal and in the nuclear fraction during the initial phase of infection, in contrast to the viral DBP transcripts, indicating that, after HSV infection, host cell transcripts accumulate in the nucleus. Evidence is presented indicating that this change is not due to altered nucleocytoplasmic mRNA transport but is due to an impaired splicing of host cell transcripts in HSV-infected cells. The MAb, directed against the nuclear pore p60 antigen, strongly inhibited the ATP-dependent efflux of both cellular and viral mRNA from isolated nuclei. The ATP-dependence of the efflux did not change during viral infection. However, the inhibitory potency of the MAb was found to be lost at the final stage of HSV infection, paralleling the loss of p60 antigen.

Base-specific ribonucleases potentially involved in heterogeneous nuclear RNA processing and poly(A) metabolism

Polyadenylation and splicing of heterogeneous nuclear RNA, two crucial steps in mRNA processing, are apparently enzymatically mediated processes. This contribution summarizes the properties and the presumed functions of the known poly(A) catabolic enzymes (endoribonuclease IV and V, 2',3'- exoribonuclease ) as well as those of the pyrimidine-specific endoribonucleases associated with snRNP -hnRNP complexes (endoribonuclease VII, acidic pI 4.1 endoribonuclease and poly(U)-specific U1 snRNP -nuclease).

Age-dependent gene induction in quail oviduct X. Alterations on the post-transcriptional level (enzymic aspect)

In quail oviducts the rate of synthesis of avidin, the biological end-point marker for the molecular events caused by progesterone, decreases with age. The cause of the reduced capacity of avidin induction has been studied on the molecular biological level polyadenylation of RNA which is one step in the process of post-transcriptional modification of heterogeneous nuclear RNA resulting in the formation of functional mRNA molecules. This novel approach was biochemically possible after the discovery of the poly(A) anabolic enzyme (poly(A) polymerase) and the two poly(A) catabolic enzymes (endoribonuclease IV and 5'-exoribonuclease). These enzymes are involved in the synthesis and degradation of the poly(A) segment of mRNA in vitro and most likely also in poly(A) metabolism in intact cell systems. Enzymatically controlled poly(A) metabolism of mRNA is regulated by the following interrelations: poly(A)-associated proteins and endoribonuclease IV; labilizing factor and poly(A)-associated proteins; 5'-exoribonuclease in cooperation with endoribonuclease IV and poly(A) polymerase. A close correlation between high levels of poly(A) catabolic enzymes and low rate of protein synthesis which was established in cell culture systems, seems also to be partially the biochemical cause for the reduced avidin synthesis in aging quail oviduct.

Ribonuclease H levels in herpes simplex virus-infected cells

Two forms of ribonuclease H (RNase H) have been identified both in uninfected and Herpes Simplex virus (HSV-)infected BHK cells. Identical RNase H species were detected in control- as well as in infected cells. RNase H I and II have not been found to be associated both with host cell DNA polymerase alpha and beta and HSV-induced DNA polymerase. Infection of BHK cells with HSV type 1 does not lead to a pronounced alteration of RNase H II activity but to an increase (3-fold) of the extractable RNase H I activity. RNase H I activity increases to a maximum between 8-10 hours p.i.; the bulk of HSV-DNA synthesis occurs between 6-8 hours p.i. From these experiments we draw the preliminary conclusion that RNase H I is involved in the degradation of the RNA primer which is covalently linked to newly synthesized HSV-DNA strands.