Purification and characterization of a DNA-dependent RNA polymerase from vaccinia virions

Anchoring a vaccinia virus promoter in the nucleus prevents its trans-activation by viral infection

The vaccinia virus 7.5 kDa constitutive promoter, when fused to a reporter gene and recombined into the genome of L cells, is not activatable upon subsequent infection with vaccinia virus. However, the same promoter is actively transcribed during transient cytoplasmic transfection procedures or within the context of the viral genome. This suggests that the intact vaccinia transcriptional machinery either does not enter the nucleus or, if it does, is unable to interact with cellular chromatin.

Fine structure mapping and phenotypic analysis of five temperature-sensitive mutations in the second largest subunit of vaccinia virus DNA-dependent RNA polymerase

We have used plasmid clones spanning the region encoding the 132-kDa subunit of the cowpox virus RNA polymerase (CPV rpo 132) to marker rescue each of five vaccinia virus (VV) temperature sensitive (ts) mutants, ts 27, ts 29, ts 32, ts 47, and ts 62, which together constitute a single complementation group. The experiments fine-map the vaccinia mutations to a 1.3-kb region containing the 3' end of the CPV rpo 132 gene. Phenotypic characterization shows that all five mutants are affected to varying extents in their ability to synthesize late viral proteins at the nonpermissive temperature, similar to other ts mutants with lesions in the 22- and the 147-kDa subunits of the VV RNA polymerase. Two mutants, ts 27 and ts 32, exhibit a delay in the synthesis of late viral proteins at both the permissive and the nonpermissive temperatures. We conclude that the five VV mutants affect the 132-kDa subunit of the VV RNA polymerase. Additional genetic experiments demonstrate intragenic complementation between ts 62 and three other members of this complementation group, ts 27, ts 29, and ts 32.

Structure of vaccinia virus early promoters

Functional elements of a vaccinia virus early promoter were characterized by making a complete set of single nucleotide substitutions, as well as more complex mutations, and assaying their effects on gene expression. Synthetic oligonucleotides, based primarily on the sequence of the 7.5-kD early promoter, were inserted into a plasmid vector containing the lacZ gene of Escherichia coli flanked by sequences from the thymidine kinase (TK) gene of vaccinia virus. The lacZ gene, under control of the synthetic promoter, was introduced into the vaccinia virus genome at the TK locus by homologous recombination, and each of the 331 different recombinant viruses thus obtained was assayed for beta-galactosidase expression. The relative amounts and precise 5' ends of lacZ mRNAs specified by a subset of the recombinants were determined by primer extension. Many promoters were tested for their ability to direct specific transcription in vitro. A generally good correlation was noted between measurements of promoter strength estimated by beta-galactosidase expression, primer extension of in vivo mRNA and transcription in vitro. A relatively simple picture emerged from the analysis. The early promoter consists of a 16 base-pair critical region, in which most single nucleotide substitutions have a major effect on expression, separated by 11 base-pairs of a less critical T-rich sequence from a seven base-pair region within which initiation with a purine usually occurs. For the critical region of the 7.5-kD promoter, AAAAgTaGAAAataTA, any substitution of an upper-case nucleotide reduced expression, usually drastically, whereas certain substitutions of lower-case nucleotides maintained or significantly enhanced expression. On the basis of this analysis, the wide range of activities of natural promoters could be attributed to the presence of one or more non-optimal nucleotides in the critical region. Moreover, single nucleotide substitutions in such promoters had the predicted enhancing effects. Most mutations in the critical region of the 7.5-kD promoter behaved independently, but some nucleotide substitutions compensated for potentially detrimental nucleotides at other positions. Promoters substantially stronger than any natural ones examined were constructed by combining several up-mutations within the critical region of the 7.5-kD promoter and by repeating the critical region sequence. Like the TATA box of eukaryotic RNA polymerase II promoters, the critical region specifies the site of transcriptional initiation.

Transcription of a poxvirus early gene is regulated both by a short promoter element and by a transcriptional termination signal controlling transcriptional interference

The promoter region of an early gene (38K gene) of cowpox virus has been characterized by deletion and linker scanning mutational analyses. Modified versions of this promoter region were placed into the genome of vaccinia virus, and their transcriptional efficiencies were assessed by quantifying RNAs transcribed from these sequences. These analyses showed that the sequences in the region between 33 and 4 base pairs upstream of the transcriptional start site affect the efficiency of transcription from this promoter. Linker scanning mutations in the -27 to -10 region inhibited transcription. This region contains the sequence 5'-GAAAATATATT-3', which is present in at least two other early genes in the same positions (-21 to -11) relative to the transcriptional start sites of these genes. Elements of this sequence are similarly positioned in the promoter regions of several other poxvirus genes, suggesting that this sequence represents a transcriptional control element of at least a subset of poxvirus genes. The -8 to -2 sequence (5'-TTTTTAT-3') contains a transcriptional termination signal. Mutation of this sequence had two separate effects: (i) it reduced the efficiency of transcription from the promoter by approximately 30%, and (ii) it prevented this sequence from terminating the transcription from upstream genes. When overlapping transcription from upstream genes was not prevented by a termination signal present either within the 38K promoter or upstream of the promoter, transcription from this promoter was reduced by about 30%. This indicates that transcriptional termination has a role in the regulation of viral gene expression by controlling transcriptional interference.

Vaccinia virus gene D12L encodes the small subunit of the viral mRNA capping enzyme

Vaccinia virus gene D12L, which lies between nucleotides 14,350 and 13,487 in the HindIII D fragment, is transcribed at early times in infection and is capable of encoding a protein 287 amino acids in length with a predicted molecular mass of 33,331. A polyclonal antiserum was raised in rabbits to a fusion protein containing 279 amino acids of the D12L protein, and this serum was used to investigate both the time of synthesis and the function of the D12L protein. A combination of Western blot analysis and immunoprecipitation from pulse-labeled and pulse-chased cell extracts demonstrated that the synthesis of a 31-kDa protein begins early in infection, that it reaches a plateau by about 4 hr, and that it is stable in the infected cell. The D12L protein was localized by Western blot analysis of detergent-solubilized virions to the sodium deoxycholate soluble fraction which suggested that it may be a virion core-associated enzyme. Due to the similarity in apparent molecular weight between the D12L protein and the small subunit of the vaccinia mRNA capping complex the anti-D12L antiserum was employed in Western blot analysis of fractions generated during the purification of the virion mRNA capping enzyme. The 31-kDa D12L protein copurified with the virus capping enzyme through chromatography on heparin-agarose and phosphocellulose and also cosedimented with the capping enzyme through a glycerol density gradient. In addition, the anti-D12L antiserum coprecipitated the large subunit of the capping enzyme, confirming that gene D12L encodes the small subunit of the viral mRNA capping enzyme. An insertion mutation which destroys the gene D12L coding sequence was constructed in a plasmid containing a portion of both genes D11L and D12L and this plasmid was used to rescue a ts mutation, in a single step, in the adjacent gene D11L. Southern blot analysis of the re-plaque-purified virus permitted the identification of the mutant virus only when the mutant was propagated in the presence of wild-type helper virus. We concluded from these data that gene D12L is essential for virus propagation in tissue culture.

Recruitment to the cytoplasm of a cellular lamin-like protein from the nucleus during a poxvirus infection

Monoclonal antibodies (Mabs) directed against core proteins of rabbit poxvirus (RPV) have proven effective in the identification of host cell proteins such as RNA polymerase II (Pol II) that may play a role in the infectious process (D. K. Morrison and R. W. Moyer, 1986, Cell 44, 587-596). In this article we describe a Mab that has allowed the detection and characterization of a lamin-like protein derived from the nucleus of the infected cell, which like Pol II is recruited to the cytoplasm following RPV infection. A portion of the gene encoding this protein has been isolated through the screening of a lambda gt11 expression vector library. Sequence analysis of the gene shows it to be derived from a member of the HindIII 1.9-kb repetitive element, a family of mammalian repetitive sequences that are highly conserved. Immunoblot analysis and sequence analysis of the open reading frame show divergent relatedness to certain nuclear lamins. The protein is not, however, one of the three principal lamins characterized to date, but instead appears to be a perinuclear protein related to the highly conserved nuclear lamins that is recruited to the cytoplasm during the infectious process.

Vaccinia virus gene D8 encodes a virion transmembrane protein

Transcription mapping studies and DNA sequence analysis of the vaccinia virus HindIII D fragment predict that gene D8 encodes a protein 304 amino acids in length, with a molecular mass of 35,426 daltons, that is expressed at late times in infection. In order to determine whether the native D8 protein is required for virus propagation, we constructed a frameshift mutation in the D8 coding sequence. Virus containing this mutation were isolated and shown to replicate in a single-step growth experiment with wild type virus growth kinetics, demonstrating that the normal-length D8 protein is not essential for virus propagation in tissue culture. In order to investigate the synthesis of the wild-type and the mutant D8 proteins in virus-infected cells, we raised polyclonal antisera to a fusion protein consisting of a portion of the D8 coding sequence linked to the Escherichia coli trpE gene. Western blot (immunoblot) analysis of the time course of D8 protein synthesis in cells infected with either wild-type or mutant virus demonstrated that D8 protein was synthesized late in infection in each case and accumulated throughout the experiment. To determine whether the D8 protein was incorporated into the mutant or wild-type virus, purified virions were fractionated into Nonidet P-40-soluble, deoxycholate-soluble, and detergent-insoluble fractions. In both the wild-type and the mutant viruses, the D8 protein was an integral viral protein. The wild-type protein partitioned into the Nonidet P-40-soluble fraction, suggesting that it was a viral membrane protein. The mutant protein fractionated into the detergent-insoluble component, demonstrating that although the altered protein was incorporated into the virus, it was found in a abnormal location. In order to determine whether the D8 protein was present on the virion surface, the susceptibility of the D8 protein to proteolysis was tested by analyzing the products of incubation of the wild-type and mutant viruses with either chymotrypsin or trypsin. These studies demonstrated that the wild-type D8 protein was a transmembrane protein with a major extraviral domain that was released largely intact from the virus by trypsin. The mutant D8 protein was relatively refractory to proteolysis, confirming the hypothesis that although it is associated with the virus, it is in a conformation different from that of the wild-type protein. Tryptic digestion of the wild-type virus increased plaque formation severalfold, concomitant with the removal of the extraviral domain of the D8 protein.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of a binding factor that interacts with the sequences upstream of the vaccinia virus thymidine kinase gene

A small 176 base-pair cloned DNA fragment, representing the nucleotide sequences proximal to the 5'-end of the vaccinia virus thymidine kinase (VV TK) gene, was radiolabeled and used in concert with gel retention assays to detect, partially purify, and characterize a promoter binding factor (PBF) extracted from vaccinia virions. The VV TK PBF was purified from solubilized virus particles by a combination of ion-exchange and DNA-affinity chromatographic procedures. The interaction between VV TK PBF and VV TK promoter sequences was relatively specific in that binding to the radiolabeled probe could be effectively inhibited by unlabeled VV TK promoter or VV TK promoter-specific oligonucleotides, but not by similar-sized fragments of control plasmid DNA. The VV TK PBF did, however, bind to other VV early-promoter elements. Glycerol gradient sedimentation provided an estimate of 130-140 kD for the native molecular weight of VV PBF. This correlated well with data from the purification of VV PBF from radiolabeled VV particles that revealed 2 polypeptides, with molecular weights of 70 and 68 kD that co-purified with VV TK PBF activity. Taken together, these results suggest that a heterodimeric promoter-binding factor, which is present within the cytoplasm of VV-infected cells, is capable of specifically interacting with VV early-promoter elements.

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

The role of the host cell nucleus in vaccinia virus morphogenesis

Despite the fact that cells infected with wild type vaccinia virus synthesize viral DNA and assemble progeny virus particles within the cytoplasm, the host cell nucleus is required for a productive infection. Recent evidence suggests that vaccinia virus selectively recruits components from the host cell nucleus into the cytoplasm for use by the developing virus. One of these components is the largest subunit of the cellular RNA polymerase II (Pol II).

Structure and evolution of prokaryotic and eukaryotic RNA polymerases: a model

A comparative overview of the subunit taxonomy and sequences of eukaryotic and prokaryotic RNA polymerases indicates the presence of a core structure conserved between both sets of enzymes. The differentiation between prokaryotic and eukaryotic polymerases is ascribed to domains and subunits peripheral to the largely conserved central structure. Possible subunit and domain functions are outlined. The core's flexible shape is largely determined by the elongated architecture of the two largest subunits, which can be oriented along the DNA axis with their bulkier amino-terminal head regions looking towards the 3' end of the gene to be transcribed and their more slender carboxyl-terminal domains at the tail end of the enzyme. The two largest prokaryotic subunits appear originally derived from a single gene.

Biosynthesis and phosphorylation of vaccinia virus structural protein VP11

One of the major DNA binding proteins contained in vaccinia virus is an 11-kDA species denoted VP11. The biosynthesis of VP11, a late polypeptide, occurs subsequent to the initiation of viral DNA replication. In particular, VP11 synthesis is blocked by cytosine arabinoside, a specific inhibitor of DNA synthesis. We show here that VP11 is specifically phosphorylated subsequent to translation. Phosphorylated VP11 is present both in viral core particles and in the cytoplasm of virus-infected cells. Kinetic analysis reveals that the total amount of phosphorylated VP11 species increases rapidly and remains approximately constant for as long as 17 hr postinfection. Phosphorylation occurs at two different serine residues, progressing from either site singly to the diphosphorylated product. Under steady-state conditions, the phosphorylated derivative constitutes approximately 85% of total VP11 in extracts of vaccinia virus-infected cells. Even though 15% of the VP11 remains unphosphorylated in cell extracts, only phosphorylated VP11 is found in mature viral cores.

Determination of the promoter region of an early vaccinia virus gene encoding thymidine kinase

Nine recombinant vaccinia viruses that contain overlapping segments of the putative promoter region of the vaccinia virus thymidine kinase (TK) gene linked to DNA coding for the prokaryotic enzyme chloramphenicol acetyltransferase (CAT) were constructed. In each case, the RNA start site and 5 bp of DNA downstream were retained. No significant difference in CAT expression occurred as the deletion was extended from 352 to 32 bp before the RNA start site. Deletion of a further 10 bp, however, led to complete cessation of early promoter activity. Primer extension analysis of the 5' ends of the transcripts verified that the natural TK RNA start site was still used when only 32 bp of upstream DNA remained. Loss of early promoter activity was previously found when deletions were extended from 31 to 24 bp before the RNA start site of another vaccinia gene that is expressed constitutively throughout infection (M.A. Cochran, C. Puckett, and B. Moss, 1985, Proc. Natl. Acad. Sci. USA 82, 19-23). Sequence similarities in the promoter regions of these two genes were noted.

Noncoordinate regulation of a vaccinia virus late gene cluster

Identification of a tightly spaced and tandemly oriented late gene cluster within the central conserved region of the vaccinia virus genome suggested the possibility of coordinate regulation of the genes within this domain (S.L. Weinrich and D.E. Hruby, Nucleic Acids Res. 14:3003-3016, 1986). To test this hypothesis, the steady-state levels of transcripts derived from the individual late genes were examined. Cytoplasmic RNA was isolated from infected cells at hourly intervals throughout infection and was used in concert with 5' S1 nuclease mapping procedures to detect transcripts from specific late genes. Among the set of six closely linked late genes, marked differences were observed in both the levels of transcription and the kinetic patterns of expression, providing direct evidence for the existence of differentially regulated gene subsets within the late gene class. Furthermore, these experiments identified one of the genes (encoding a 33,000-molecular-weight polypeptide) as being expressed both early and late postinfection. Interestingly, although transcripts from the constitutively expressed gene were initiated at the same start sites throughout infection, a discrete terminus for these transcripts was detected only at early times. These data suggest that the lack of cis-acting termination signals is not the reason for the late gene transcript heterogeneity observed in vaccinia virus-infected cells.

Influence of RNA polymerase II upon vaccinia virus-related translation examined by means of alpha-amanitin

Our previous studies employing alpha-amanitin-sensitive H-9 and resistant Ama 102 mutant host cells demonstrated that polymerase II (Pol II), or a drug-sensitive component of the enzyme, is required for replication of vaccinia virus. Evidence was also obtained indicating that transcription from the host genome does not appear to be involved (Silver et al., 1979; Silver and Dales, 1982), suggesting a possible role for Pol II in transcription from the viral genome. This idea is consistent with the present findings, based on immunofluorescence analysis, which revealed that upon infection Pol II antigen is mobilized out of the nucleus into discrete cytoplasmic foci. Effects of treating H-9 rat myoblasts with alpha-amanitin upon vaccinia-specific protein synthesis were also examined. Under the experimental conditions employed, the toxin drastically curtailed in vivo translation into early, late and late-late proteins without altering the spectrum of polypeptides produced. By contrast, treatment with the drug affected, only minimally, the rate of transcription into viral RNA, whether in vivo or from isolated vaccinia factories. The mRNA isolated from infected and treated or untreated cells was translated in a reticulocyte lysate with equal efficiency and general fidelity. This finding suggests that Pol II may be involved in transcription into RNAs related to factors controlling the in vivo translation process. The possible mechanisms for exercising such controls are discussed in relation to factors regulating transcription by host RNA polymerases from a viral DNA genome.

Detection of a subunit of cellular Pol II within highly purified preparations of RNA polymerase isolated from rabbit poxvirus virions

A large (approximately 200 kd) subunit of cellular RNA polymerase II (Pol II) and a virus-encoded subunit of rabbit poxvirus (RPV) RNA polymerase (137 kd) react with common monoclonal antibodies. Hybridization studies with viral and cellular DNA clones confirm that the viral and cellular proteins are related. Following RPV infection, the Pol II subunit is translocated from the nucleus to the cytoplasmic virosomes, then packaged into mature virus, and is found associated with the viral RNA polymerase purified from virions. The results suggest that the cellular Pol II subunit may be directly involved in the transcription of viral genes.

Polyamines stimulate DNA-dependent RNA synthesis catalyzed by vaccinia virus

The RNA synthesis in purified vaccinia virus can occur in the presence of either Mg2+ or Mn2+ if polyamine (spermidine or spermine) is present in the assay system. Under our assay conditions transcription was linear up to 30 min and the RNAs synthesized had a sedimentation coefficient of about 8 to 12 S. We also prepared a virus extract from purified vaccinia virus and tested for in vitro transcription. The soluble transcription system was dependent on the addition of exogenous DNA and single-stranded DNA was a more effective template than double-stranded. In the presence of polyamine and Mg2+ or Mn2+ the viral RNA polymerase was active in the transcription of total native vaccinia DNA and a small fragment cloned in pBR322.

Biochemical and electron microscopic studies of the transcription of vaccinia DNA by RNA polymerase from Escherichia coli: localization and characterization of transcriptional complexes

We used the prokaryotic Escherichia coli RNA polymerase to determine if vaccinia DNA might provide recognition sites for the bacterial binding and initiation. Electron microscopic studies of the interaction of E. coli RNA polymerase with vaccinia DNA and molecular hybridization analysis of the transcription products formed after 3 or 5 min of in vitro incubation showed that: there were 30-40 sites on the template where the polymerase could bind and initiate cRNA synthesis; the entire coding capacity of the genome was utilized for cRNA synthesis; transcription was asymmetric; cRNA molecules were similar in size to the transcripts synthesized by the vaccinia virus RNA polymerase in vitro and in vivo; cRNA contains sequences in common with 'pre-early', 'early', and 'late' in vivo RNA; 'self-annealing' of cRNA in the presence or absence of RNA synthesized in vitro by the virion associated RNA polymerase showed that less than 1% dsRNA product could be detected suggesting that initially the same strand(s) was copied by the viral and bacterial enzymes; no differences in the frequency with which sequences represented in the Hind III fragments of vaccinia DNA were transcripted with time of in vitro incubation could be detected. These findings strongly suggest that the bacterial enzyme might recognize truly viral promotors. With extended in vitro incubations of the E. coli RNA polymerase with vaccinia DNA the control of transcription was found to diminish. This was correlated with an increase in the size of the transcripts and the synthesis of significant amounts of self-complementary RNA, indicating that symmetrical transcription was occurring. The dsRNA species recovered after self-annealing the cRNA from a 30 min in vitro reaction mixture were found to contain sequences which hybridized to some portion of all the Hind III restriction fragments of vaccinia DNA. The methods described here might be useful for the localization and characterization of promotor sequences in the genome of vaccinia virus, as well as for studies on sequence conservation between members of the Poxvirus genus.

Selective transcription of vaccinia virus genes in template dependent soluble extracts of infected cells

A soluble system that specifically and accurately initiates transcription on defined vaccinia virus templates has been obtained from lysates of infected cells. The required regulatory signals are contained within a DNA segment extending about 230 bp upstream and 30 bp downstream of the RNA start site. Transcription is resistant to alpha-amanitin and inhibited by antibodies to the viral RNA polymerase. Whole cell extracts from uninfected cells cannot accurately transcribe vaccinia DNA. Conversely, extracts prepared at 2 hr or later after vaccinia infection no longer transcribe RNA polymerase II templates but retain the ability to transcribe RNA polymerase III templates as well as vaccinia virus DNA. These profound changes in transcriptional specificity may contribute to the selective expression of viral genes following vaccinia infection.

Electron microscopic studies of transcriptional complexes released from vaccinia cores during RNA-synthesis in vitro: methods for fractionation of transcriptional complexes

Electron microscopic (EM) and biochemical methods were employed to study the transcriptional complexes present in detergent lysates of vaccinia virus cores actively synthesizing RNA in vitro. When processed and examined in the EM, 14 'transcriptional sites' could be observed on full-length DNA templates. Fractionation of lysates by equilibrium density centrifugation in CsSO4, chromatography on hydroxyapatite columns or by sedimentation in sucrose gradients, allowed isolation of DNA templates associated with transcripts but these manipulations often resulted in fragmentation of the DNA template or promoted the release of transcripts from the template. It is suggested that RNA transcripts remain associated with the template in regions of supercoiling. These regions, in turn, may be maintained by DNA-protein interactions which are compromised as the transcriptional complexes are fractionated and purified.

Distinctive nucleotide sequences adjacent to multiple initiation and termination sites of an early vaccinia virus gene

Poxviruses, unlike other DNA viruses, replicate in the cytoplasm of infected cells and use their own system of transcription. Examination on one early mRNA synthesized in vivo and in vitro indicated that it has multiple closely spaced 5' and 3' ends. A remarkable 88% AT-rich 60 bp DNA sequence was found immediately upstream of the initiation of transcription sites. Although DNA sequences that bear some homology to Pribnow and Hogness boxes are present, additional recognition sequences located further upstream of procaryotic and eucaryotic initiation sites are absent. A possible initiation of translation codon occurs about 50 nucleotides from the 5' end of the message. The transcript terminates near or within a hexanucleotide CTATTC that is tandemly repeated four times. Sequences similar to those regulating termination of transcription in procaryotes or poly (A) addition in eucaryotes were not found, suggesting that poxviruses have evolved unique recognition signals.

In vitro transcription of the inverted terminal repetition of the vaccinia virus genome: correspondence of initiation and cap sites

Specific RNAs synthesized in vitro by vaccinia virus cores were analyzed with the aid of DNA from the terminal 9,000 base pairs of the genome that was cloned in phage lambda, pBR322, and the single-stranded phage fl. Three mRNA's coding for polypeptides with molecular weights of 7,500 (7.5K), 19K, and 42K were shown to have sizes and map positions similar to those described for mRNA's made early in infection. A previously undescribed transcript made in vivo and in vitro, with a 5' end at about 8.7 kilobase pairs from the end of the genome, was also detected. After chemical removal of the terminal 7-methylguanosine residue, the 5' ends of the RNAs were specifically labeled by enzymatic capping and the mapped by gel electrophoresis of nuclease-resistant RNA.DNA hybrids, as well as by hybridization of the end-labeled RNA to immobilized DNA restriction fragments. Analysis of the purified cap structures demonstrated that three of the mRNA's have both m7G(5')pppAm and, m7G(5')pppGm ends, indicating some degree of terminal heterogeneity. The fourth transcript has exclusively m7G(5')pppAm ends. By synthesizing RNA in the presence of [beta-32P]GTP, it could be shown that cap sites correspond to sites of initiation of RNA synthesis.