Mapping early transcripts of herpes simplex virus type 1 by electron microscopy

A human cytomegalovirus early gene has three inducible promoters that are regulated differentially at various times after infection

The long inverted repeat and the adjacent sequences are major early transcription sites of the human cytomegalovirus genome (M. W. Wathen and M. F. Stinski, J. Virol. 41:462-477, 1982). An early transcription unit which flanks the large terminal repeat was analyzed by RNA mapping at various times after infection. Three unspliced, overlapping RNAs were transcribed from different initiation sites and terminated at the same 3' end. Individual promoters were isolated for all three transcripts. These promoters were activated in trans by viral immediate-early (IE) regulatory proteins after either infection with virus or cotransfection with IE2 alone or IE1 plus IE2 genes. DNA sequence analysis detected TATA and CAAT boxes plus multiple-dyad symmetries in the promoter-regulatory region. Deletion analyses showed that the maximum inducible promoter activity lay in a 230-base-pair region. When in the viral genome, the three promoters were regulated differentially during the course of infection. The upstream promoter was used only at late times after infection. Possible reasons for viral RNAs with multiple 5' ends at different times after infection and the recognition of the upstream promoter at only late times after infection are discussed.

Physical location of a herpes simplex virus type-1 gene function(s) specifically associated with a 10 million-fold increase in HSV neurovirulence

In this paper we present a technique developed to physically locate the HSV-1 gene(s) which restore neurovirulence to a non-neurovirulent HSV intertypic recombinant described in the preceding report. In brief, tissue culture cells are co-transfected with unit length RE6 DNA and restriction endonuclease fragmented HSV-1 (strain 17 Syn+) DNA. In this way, random recombinations between RE6 and 17 Syn+ are produced. An in vivo enrichment in mouse brains is then employed to select recombinants which have incorporated the HSV-1 gene(s) associated with neurovirulence. In each of five cases where neurovirulent recombinants were isolated by this procedure, restriction enzyme and Southern DNA transfer analysis revealed that HSV-1 information from 0.71 to 0.83 map units had been incorporated into the RE6 genome. Confirmation of the role of this portion of the genome for HSV neurovirulence was obtained by similar cotransfection and in vivo rescue experiments performed with an electrophoretically purified HSV-1 DNA fragment which encompasses this region. Subsequent genome structure analysis of neurovirulent recombinants generated by this procedure revealed that only type-1 information from 0.71 to 0.83 map units had been incorporated into RE6. Thus an HSV-1 gene function(s) which resides in this region of the viral DNA is associated with a 10 million-fold increase in the neurovirulence of the virus. Potential applications of this in vivo selection technique are discussed.

Temporal patterns of human cytomegalovirus transcription: mapping the viral RNAs synthesized at immediate early, early, and late times after infection

The transcription of the human cytomegalovirus genome was investigated at immediate early, early, and late times after infection. Viral RNAs associated with either the whole cell, the nucleus, the cytoplasm, or the polyribosomes were analyzed. At immediate early times, i.e., in the absence of de novo viral protein synthesis, the viral RNA in high abundance originated from a region of the long unique section of the prototype arrangement of the viral genome (0.660 to 0.770 map units). The viral RNA in low abundance originated from the long repeat sequences (0.010 to 0.035 and 0.795 to 0.825 map units) and a region in the long unique section (0.201 to 0.260 map units). Viral RNAs associated with the polyribosomes as polyadenylated RNA were mapped to these restricted regions of the viral genome and characterized according to size class in kilobases. At 24 h after infection in the presence of an inhibitor of viral DNA replication, i.e., at early times, the stable viral RNAs in highest abundance mapped in the long repeat sequences. Viral RNAs at intermediate abundance under these conditions mapped in two regions of the long unique section of the viral genome (0.325 to 0.460 and 0.685 to 0.770 map units). Stable viral RNAs that were associated with the polyribosomes in high abundance as polyadenylated RNA orginated from the long repeat sequences, but not from the long unique section of the viral genome. An analysis of whole-cell RNA at late times (72 h) indicated that the abundant transcription was in the regions of the long unique sequences (0.325 to 0.460 and 0.660 to 0.685 map units), and transcription of intermediate abundance was from the long repeat sequences. However, stable viral mRNA's derived from the long repeat sequences were associated with the polyribosomes at late times after infection. In addition, mRNA's originating from the long and short unique sequences were found associated with the polyribosomes at higher relative concentration than at early times after infection. It is proposed that expression of the immediate early viral genes is required to transcribe the early viral genes in the long repeat and adjacent sequences. These sequences are also transcribed at late times after infection while viral DNA synthesis continues. The expression of viral genes in most of the long and short unique sequences appears to require viral DNA replication.

Herpes simplex virus type 1 HindIII fragment L encodes spliced and complementary mRNA species

We have used DNA bound to cellulose to isolate and translate in vitro herpes simplex virus type 1 (HSV-1) mRNA's encoded by HindIII fragment L (mapping between 0.592 and 0.647), and 8.450-base-pair (8.45-kb) portion of the long unique region of the viral genome. Readily detectable, late mRNA's 2.7 and 1.9 kb in size encoding 69,000- and 58,000-dalton polypeptides, respectively, were isolated. A very minor late mRNA family composed of two colinear forms, one 2.6 kb and one 2.8 kb, was isolated and found to encode only an 85,000-dalton polypeptide. A major early mRNA, 1.8 kb in size encoding a 64,000-dalton polypeptide, was also isolated. High-resolution mapping of these mRNA's by using S1 nuclease and exonuclease VII digestion of hybrids between them and 5' and 3' end-labeled DNA fragments from the region indicated that the major early mRNA contained no detectable splices, and about half of its 3' end was complementary to the 3' region of the very minor 2.6- to 2.8-kb mRNA's encoded on the opposite strand. These mRNA's also contained no detectable splices. The major late 2.7-kb mRNA was found to be a family made up of members with no detectable splices and members with variable-length (100 to 300 bases) segments spliced out very near (ca. 50 to 100 bases) the 5' end.

Temporal regulation of human cytomegalovirus transcription at immediate early and early times after infection

The immediate early transcripts of human cytomegalovirus originated from restricted regions of the viral genome. In contrast, transcription at early times was complementary to all regions of the viral genome that were fractionated by restriction endonuclease treatment followed by agarose gel electrophoresis. The viral genome was also extensively transcribed when 2 h of protein synthesis or longer was permitted after infection in permissive cells treated with an inhibitor of viral DNA replication or in nonpermissive cells of animal origin that permit little or no viral DNA replication. The size and in vitro translation products of the cytomegalovirus-specified mRNA's at immediate early and early times after infection were determined. Discrete size classes of virus-specified polyadenylated RNA accumulated on the polyribosomes of cells infected in the presence of an inhibitor of protein synthesis. When 2 or 24 h of protein synthesis occurred after infection, there were changes in the relative abundance of the virus-specified RNAs that accumulated on polyribosomes. Treatment of nonpermissive cells had little effect on the size classes of viral RNA found associated with the polyribosomes at early times after infection. These viral mRNA's were assumed to represent early viral gene expression. In vitro translation of the viral mRNA isolated from polyribosomes at immediate early and early times after infection identified many of the virus-specified gene products and demonstrated (i) a switch from immediate early to early viral gene expression and (ii) a prolonged phase of early viral gene expression. The data also indicated that the initiation of viral RNA synthesis does not depend on the formation of viral protein, but that de novo viral protein synthesis may influence the extent of transcription of the viral genome.

Characterization of a major late herpes simplex virus type 1 mRNA

A major, late 6-kilobase (6-kb) mRNa mapping in the large unique region of herpes simplex virus type 1 (HSV-1) was characterized by using two recombinant DNA clones, one containing EcoRI fragment G (0.190 to 0.30 map units) in lambda. WES.B (L. Enquist, M. Madden, P. Schiop-Stansly, and G. Vandl Woude, Science 203:541-544, 1979) and one containing HindIII fragment J (0.181 to 0.259 map units) in pBR322. This 6-kb mRNA had its 3' end to the left of 0.231 on the prototypical arrangement of the HSV-1 genome and was transcribed from right to left. It was bounded on both sides by regions containing a large number of distinct mRNA species, and its 3' end was partially colinear with a 1.5-kb mRNA which encoded a 35,000-dalton polypeptide. The 6-kb mRNA encoded a 155,000-dalton polypeptide which was shown to be the only one of this size detectable by hybrid-arrested translation encoded by late polyadenylated polyribosomal RNA. The S1 nuclease mapping experiments indicated that there were no introns in the coding sequence for this mRNA and that its 3' end mapped approximately 800 nucleotides to the left of the BglII site at 0.231, whereas its 5' end extended very close to the BamHI site at 0.266.

Detailed characterization of the mRNA mapping in the HindIII fragment K region of the herpes simplex virus type 1 genome

We have isolated as recombinant DNA clones, in the plasmid pBR322, regions of the herpesvirus type 1 genome spanning the region between 0.53 and 0.6 on the prototypical arrangement. This 11,000-base-pair region corresponds to 10% of the large unique region and encodes five major and several minor mRNA species abundant at different times after infection, which range in length from 7 to 1 kilobase. In this report, we have used RNA transfer blots and S1 nuclease digestion of hybrids between viral DNA and polyribosomal RNA to precisely localize (+/- 0.1 kilobase) these mRNA's. Comparison of neutral and alkaline gels of S1 nuclease-digested hybrids indicates no internal introns in the coding sequences of these mRNA's, although noncontiguous leader sequences near (ca. 0.1 kilobase) the 5' ends of any or all mRNA's could not be excluded. The 5' ends of several late mRNA's that are encoded opposite DNA strands map very close to one another, and the 3' ends of a major late and a major early mRNA, which are partially colinear, terminate in the same region. In vitro translation of the viral mRNA's isolated by hybridization with DNA bound to cellulose and fractionation of mRNA species on denaturing agarose gels allowed us to assign specific polypeptide products to each of the mRNA's characterized. Among other results, it was demonstrated unequivocally that two major late mRNA's, which partially overlap, encode the same polypeptide.

Herpes simplex virus thymidine kinase transcripts are absent from both nucleus and cytoplasm during infection in the presence of cycloheximide

Nick-translated DNA from a recombinant plasmid containing the herpes simplex virus type 1 thymidine kinase gene was used as a probe for the synthesis of thymidine kinase RNA. The recombinant plasmid was generated by inserting the 3.5-kilobase fragment derived by BamHI digestion of herpes simplex virus type 1 DNA into plasmid pBR322. At 8 h after infection, cytoplasmic and nuclear RNA hybridized to 14% and 19% of the recombinant DNA probe, respectively. However, no significant hybridization was found with either nuclear or cytoplasmic RNA extracted from cells infected and maintained in the presence of cycloheximide. This suggests that no thymidine kinase-related RNA was synthesized in the absence of alpha polypeptides, and supports the hypothesis that the alpha polypeptides effect new thymidine kinase RNA synthesis rather than being involved in processing or transport of thymidine kinase RNA. In cells infected and maintained in the presence of the arginine analog canavanine, about 2 to 3% of the plasmid DNA was found to hybridize with cytoplasmic and nuclear RNA. However, when a recombinant plasmid DNA containing only thymidine kinase coding sequences was used, no significant hybridization was found. The inhibition of thymidine kinase transcription by canavanine suggests that thymidine kinase belongs to the beta 2 kinetic class.

Gene expression of herpes simplex virus. II. UV radiological analysis of viral transcription units

The transcriptional organization of the genome of herpes simplex virus type 1 was analyzed by measuring the sensitivity of viral polypeptide synthesis to UV irradiation of the infecting virus. Herpes simplex virus type 1 was irradiated with various doses of UV light and used to infect xeroderma pigmentosum fibroblasts. Immediate early transcription units were analyzed by having cycloheximide present throughout the period of infection, removing the drug at 8 h postinfection, and pulse-labeling proteins with [35S]methionine. Delayed early transcription units were analyzed in similar studies by having 9-beta-D-arabinofuranosyladenine present during the experiment to block replication of the input irradiated genome. The viral polypeptides were separated by gel electrophoresis and quantitated by densitometry of the gel autoradiograms. The following results were obtained. (i) The UV target sizes for the viral transcription units analyzed ranged from 1.44 to 5.65 kilobase pairs. This implies that the corresponding primary transcripts have minimum molecular weights ranging from 0.46 x 10(6). (ii) The genes for the four viral proteins, 165, 145, 116, and 71 (molecular weight x 10(3), exhibited UV target sizes that agree with their calculated gene size or measured mRNA size or both and thus must reside in promoter-adjacent positions. (iii) The transcription units for the remaining genes analyzed showed target sizes that range from 0.42 to 2.59 kilobase pairs greater than needed to encode the respective proteins. This probably is a reflection of their distances from promoters or the presence of intervening sequences or both. It further suggests that these genes are transcribed as precursor RNA molecules that are larger than their mRNA's. (iv) The results indicate that none of the immediate early genes analyzed can be cotranscribed, whereas some of the delayed early genes might be cotranscribed. No evidence was found for the existance of large, multigene transcription units.

Characterization of herpes simplex virus type 1 RNA present in the absence of de novo protein synthesis

We used herpes simplex virus type 1 (HSV-1) DNA and restriction fragments of HSV-1 DNA covalently coupled to cellulose as a reagent to isolate for further characterization the major and minor HSV-1 immediate-early mRNA species in HeLa cells infected and maintained in the absence of de novo protein synthesis. Five major and several minor immediate-early mRNA species were characterized. One major species was a 4.2-kilobase mRNA mapping in the TR(S)/IR(S) region with its 3' end distal to the U(S) region; this mRNA encoded a 170,000-dalton polypeptide in vitro. A 2.8-kilobase mRNA, encoding a 120,000-dalton polypeptide, was mapped in the TR(L)/IR(L) region with its 3' end directed toward the U(L) region. Three 1.8-kilobase mRNA species were mapped. One, mapping in the IR(S) region with its 3' end in the U(S), encoded a 68,000-dalton polypeptide. One mapped in the TR(S) region and had its 3' end in the U(S) region; the third one encoded a 64,000-dalton polypeptide and mapped in the U(L) region near the IR(L) region. One minor species 5.2 kilobases in size was clearly detectable mapping in the U(L) region. Furthermore, there were indications that one or more immediate-early mRNA species approximately 3 kilobases in size hybridized to regions near the TR(L) and in or near the TR(S)/IR(S) regions. Nuclear immediate-early RNA mapped only in those regions where polyribosomal immediate-early mRNA mapped, although minor differences were seen. Finally, we demonstrated that at least three major immediate-early mRNA's-4.2 kilobases, 2.8 kilobases, and the 1.8-kilobase one mapping in the IR(S)/U(S) region-continued to appear on polyribosomes as functional mRNA late after infection.

Isolation and translation of mRNA encoded by a specific region of the herpes simplex virus type 1 genome

We have examined in detail the major mRNA species encoded by the region of the herpes simplex virus type 1 genome encoded by HindIII fragment K (0.53-0.59 from the left end of the prototype arrangement of the genome) by using this restriction fragment bound to cellulose as a reagent for isolation of this mRNA. Before viral DNA replication in infected cells (early), a major species of viral mRNA 5.2 kilobases (kb) in length is abundant. After the onset of viral DNA replication (late), four mRNA species are abundant: 7, 5.2, 3.8, and 1.8 kb in size. We have used reverse transcriptase from avian myeloblastosis virus to make DNA complementary to these RNA species and their 3' ends. We have shown by hybridization of this complementary DNA to Southern blots of herpes simplex virus type 1 DNA that the 7-, 5.2-, and 1.8-kb mRNA species have their 3' ends to the right of 0.59 and are at least partially colinear. The 3.8-kb mRNA has a 3' end mapping to the left of the 3' ends of these other species. In vitro translation of HindIII fragment K-specific mRNA in a reticulocyte lysate system yielded three major polypeptide products: 140,000, 122,000, and 54,000 daltons (d). Less prominent species of 86,000 and 65,000 d also were produced. Translation of size-fractionated HindIII fragment K-specific mRNA showed that the 7-, 5.2-, and 3.8-kb mRNA's encoded the 54,000-, 140,000-, and 122,000-d polypeptides, respectively. The 140,000-d polypeptide was the major polypeptide translated using early HindIII fragment K-specific mRNA as a template. The 3.8-kb mRNA also encoded the 86,000-d polypeptide, whereas the 1.8-kb mRNA encoded a polypeptide that was indistinguishable from the 54,000-d polypeptide encoded by the 7-kb mRNA, in addition to the 65,000-d polypeptide. The implications of the data are discussed.

Regulation of herpesvirus macromolecular synthesis. VIII. The transcription program consists of three phases during which both extent of transcription and accumulation of RNA in the cytoplasm are regulated

This report concerns the stable viral RNA sequences that accumulate in HEp-2 cells infected with herpes simplex virus type 1. By hybridizing labeled total DNA and restriction endonuclease DNA fragments with excess unlabeled total nuclear and cytoplasmic RNA, we determined the genetic complexity of the RNA and we mapped the regions on the physical map of herpes simplex virus type 1 DNA that are homologous to the RNA. Our results show the following. (i) The viral RNAs accumulating in the nucleus and cytoplasm of cells infected and maintained in the presence of inhibitory concentrations of either cycloheximide or emetine were homologous to 33 and 12% of viral DNA, respectively. All of the fragments tested contained sequences homologous to nuclear RNA. However, only the fragments mapping between 0.00 and 0.18, and 0.53 and 1.00 map units contained sequences homologous to cytoplasmic RNA. (ii) The viral RNAs that accumulate in the nucleus and cytoplasm of cells infected and maintained in the presence of inhibitory concentrations of phoaphonoacetic acid were homologous to 39 and 26% of viral DNA, respectively. In this instance all of the fragments except those mapping between 0.42 and 0.53 map units contained sequences homologous to cytoplasmic RNA. (iii) The viral RNAs that accumulate in the nucleus and cytoplasm 8 h after infection were homologous to greater than 50 and 41%, respectively. All of the fragments tested contained sequences homologous to cytoplasmic RNA. (iv) The viral RNAs that accumulate in the nucleus and cytoplasm of cells infected and maintained in the presence of canavanine are homologous to 33 and 19% of viral DNA, respectively. All of the fragments tested contained sequences homologous to both nuclear and cytoplasmic RNAs. Our results indicate the following. First, there are at least three phases of transcription of viral DNA. Phase 1 does not require the synthesis of host cell or viral proteins. Phase 2 requires the synthesis of viral proteins made before the initiation of viral DNA synthesis. Phase 3 appears to be related to the initiation of viral DNA synthesis. Second, both the extent of transcription and the accumulation of viral RNA in the cytoplasm are tightly regulated. The genetic complexity of total RNA accumulating in infected cells increased in each successive phase. Moreover, the genetic complexity of nuclear RNA was invariably higher than that of cytoplasmic RNA in each phase. Lastly, the results of the studies on viral RNA accumulating in canavanine-treated cells reinforce the hypothesis made previously that more than one polypeptide in each of the alpha and beta polypeptide groups is involved in the transcription preceding the transitions from alpha to beta and beta to gamma polypeptide synthesis, respectively, and that canavanine selectively inactivated subsets of these polypeptides permitting only partial transitions from alpha to beta and beta to gamma to occur.

Isolation and localization of herpes simplex virus type 1 mRNA abundant before viral DNA synthesis

Herpes simplex virus type 1 (HSV-1) DNA covalently bound to cellulose was used as a reagent to isolate viral RNA transcripts for size analysis on denaturing agarose gels. Nuclear and polyribosomal RNA isolated at 2 h postinfection (p.i.) migrated with sizes between 1,500 and 5,500 nucleotides. At 6 h p.i. (when viral DNA synthesis is underway), viral polyribosome-associated polyadenylated RNA showed different discrete sizes of species predominating, with RNA larger than 5,500 nucleotides clearly present. Nearly 50% of the newly made viral RNA found in the nucleus at 6 h p.i. was from 5,000 to 10,000 nucleotides in length. A high-resolution transcription map of the viral mRNA abundant at 2 h p.i. was compiled from the hybridization of Southern blots of HSV-1 DNA restriction fragments to both sizes of fractionated polyribosomal polyadenylated RNA and 3' complementary DNA probe made to this size of fractionated RNA. We have identified and mapped 16 mRNA species abundant at 2 h p.i. These RNAs range in size from 1,500 to 5,300 nucleotides and map throughout the HSV-1 genome. In some instances, a direction of transcription can be suggested. Further, about one-third of this number of mRNA's has been found in cells infected with a DNA-negative temperature-sensitive mutant (tsB2) and grown at the nonpermissive temperature (39 degrees C).

Isolation and localization of herpes simplex virus type 1 mRNA

Herpes simplex virus (HSV) DNA bound to cellulose has been used as a reagent to isolate viral mRNA for size analysis on denaturing agarose gels. Total viral polysomal polyadenylated RNA was isolated from cells late after infection when such RNA has sequences encoded by approximately 45% of the HSV DNA. This RNA has a size range of from 1.5 to greater than or equal to 8 kilobases, with certain sizes, such as 1.7 to 1.9 kilobases, being favored. We have used the restriction endonucleases HindIII and XbaI singly and together to generate various sized fragments covering the entire HSV-1 genome. These fragments have been bound to cellulose to allow isolation of HSV-1 mRNA annealing to different regions of the viral genome. Discrete sizes of viral mRNA are associated with certain regions of the genome, but the mRNA population hybridizing to even the smallest restriction fragments is complex. We used hybridization of size-fractionated RNA to Southern blots of restriction fragments of HSV-1 DNA generated by the BglII as well as HindIII and XbaI endonucleases to confirm the preparative hybridization data and to provide some overlap data for positioning transcripts. The data of blot and preparative hybridization agreed very well and were combined to construct a preliminary transcription map of HSV-1. Such a map revealed at least two areas of the long unique region of the HSV-1 genome which annealed to a large number of HSV-1 transcripts. Furthermore, discrete-sized mRNA species larger than 5 kilobases in length were found only in the middle of the long unique region. The implications of these data are discussed.