Polytranscripts of Sendai virus do not contain intervening polyadenylate sequences

Analysis of the highly diverse gene borders in Ebola virus reveals a distinct mechanism of transcriptional regulation

Ebola virus (EBOV) belongs to the group of nonsegmented negative-sense RNA viruses. The seven EBOV genes are separated by variable gene borders, including short (4- or 5-nucleotide) intergenic regions (IRs), a single long (144-nucleotide) IR, and gene overlaps, where the neighboring gene end and start signals share five conserved nucleotides. The unique structure of the gene overlaps and the presence of a single long IR are conserved among all filoviruses. Here, we sought to determine the impact of the EBOV gene borders during viral transcription. We show that readthrough mRNA synthesis occurs in EBOV-infected cells irrespective of the structure of the gene border, indicating that the gene overlaps do not promote recognition of the gene end signal. However, two consecutive gene end signals at the VP24 gene might improve termination at the VP24-L gene border, ensuring efficient L gene expression. We further demonstrate that the long IR is not essential for but regulates transcription reinitiation in a length-dependent but sequence-independent manner. Mutational analysis of bicistronic minigenomes and recombinant EBOVs showed no direct correlation between IR length and reinitiation rates but demonstrated that specific IR lengths not found naturally in filoviruses profoundly inhibit downstream gene expression. Intriguingly, although truncation of the 144-nucleotide-long IR to 5 nucleotides did not substantially affect EBOV transcription, it led to a significant reduction of viral growth.

IMPORTANCE

Our current understanding of EBOV transcription regulation is limited due to the requirement for high-containment conditions to study this highly pathogenic virus. EBOV is thought to share many mechanistic features with well-analyzed prototype nonsegmented negative-sense RNA viruses. A single polymerase entry site at the 3' end of the genome determines that transcription of the genes is mainly controlled by gene order and cis-acting signals found at the gene borders. Here, we examined the regulatory role of the structurally unique EBOV gene borders during viral transcription. Our data suggest that transcriptional regulation in EBOV is highly complex and differs from that in prototype viruses and further the understanding of this most fundamental process in the filovirus replication cycle. Moreover, our results with recombinant EBOVs suggest a novel role of the long IR found in all filovirus genomes during the viral replication cycle.

Interplay between innate immunity and negative-strand RNA viruses: towards a rational model

The discovery of a new class of cytosolic receptors recognizing viral RNA, called the RIG-like receptors (RLRs), has revolutionized our understanding of the interplay between viruses and host cells. A tremendous amount of work has been accumulating to decipher the RNA moieties required for an RLR agonist, the signal transduction pathway leading to activation of the innate immunity orchestrated by type I interferon (IFN), the cellular and viral regulators of this pathway, and the viral inhibitors of the innate immune response. Previous reviews have focused on the RLR signaling pathway and on the negative regulation of the interferon response by viral proteins. The focus of this review is to put this knowledge in the context of the virus replication cycle within a cell. Likewise, there has been an expansion of knowledge about the role of innate immunity in the pathophysiology of viral infection. As a consequence, some discrepancies have arisen between the current models of cell-intrinsic innate immunity and current knowledge of virus biology. This holds particularly true for the nonsegmented negative-strand viruses (Mononegavirales), which paradoxically have been largely used to build presently available models. The aim of this review is to bridge the gap between the virology and innate immunity to favor the rational building of a relevant model(s) describing the interplay between Mononegavirales and the innate immune system.

The measles virus replication cycle

This review describes the two interrelated and interdependent processes of transcription and replication for measles virus. First, we concentrate on the ribonucleoprotein (RNP) complex, which contains the negative sense genomic template and in encapsidated in every virion. Second, we examine the viral proteins involved in these processes, placing particular emphasis on their structure, conserved sequence motifs, their interaction partners and the domains which mediate these associations. Transcription is discussed in terms of sequence motifs in the template, editing, co-transcriptional modifications of the mRNAs and the phase of the gene start sites within the genome. Likewise, replication is considered in terms of promoter strength, copy numbers and the remarkable plasticity of the system. The review emphasises what is not known or known only by analogy rather than by direct experimental evidence in the MV replication cycle and hence where additional research, using reverse genetic systems, is needed to complete our understanding of the processes involved.

Polymerase read-through at the first transcription termination site contributes to regulation of borna disease virus gene expression

An unusually long noncoding sequence is located between the N gene of Borna disease virus (BDV) and the genes for regulatory factor X and polymerase cofactor P. Most of these nucleotides are transcribed and seem to control translation of the bicistronic X/P mRNA. We report here that Vero cells persistently infected with mutant viruses containing minor alterations in this control region showed almost normal levels of N, X, and P proteins but exhibited greatly reduced levels of mRNAs coding for these viral gene products. Surprisingly, cells infected with these BDV mutants accumulated a viral transcript 1.9 kb in length that represents a capped and polyadenylated mRNA containing the coding regions of the N, X, and P genes. Cells infected with wild-type BDV also contained substantial amounts of this read-through mRNA, which yielded both N and P protein when translated in vitro. Viruses carrying mutations that promoted read-through transcription at the first gene junction failed to replicate in the brain of adult rats. In the brains of newborn rats, these mutant viruses were able to replicate after acquiring second-site mutations in or near the termination signal located downstream of the N gene. Thus, sequence elements adjacent to the core termination signal seem to regulate the frequency by which the polymerase terminates transcription after the N gene. We conclude from these observations that BDV uses read-through transcription for fine-tuning the expression of the N, X, and P genes which, in turn, influence viral polymerase activity.

Expression of novel genes encoded by the paramyxovirus J virus

Characterization of the J virus or, in keeping with recent nomenclature recommendations, J paramyxovirus (JPV) genome revealed a unique genome structure, consisting of eight genes in the order 3'-N-P/V/C-M-F-SH-TM-G-L-5'. The small hydrophobic (SH) protein and the transmembrane (TM) protein genes are predicted to encode proteins 69 and 258 aa in size, respectively. The 4401 nt attachment (G) protein gene, much larger than most other paramyxovirus attachment protein genes sequenced to date, encodes a putative 709 aa attachment protein and contains distally a second open reading frame (ORF-X) 2115 nt long. Experiments undertaken in this study were intended to confirm the sequence-based gene allocation of JPV and to determine if proteins encoded by the SH gene, the novel TM gene and ORF-X are expressed. Northern blot analyses carried out on mRNA purified from JPV-infected cells indicated that the putative transcription initiation and termination sequences flanking the SH and TM genes are functional, consistent with their allocation as discrete genes, although a high level of read-through was observed across almost all transcriptional boundaries. Probes specific to the G protein coding region and ORF-X both identified an mRNA species corresponding to the predicted length of the G gene, confirming sequence-based predictions. While the SH and TM proteins were both detected in infected cells, no evidence was found for the expression of ORF-X. Preliminary studies indicate that the novel TM protein is a type II glycosylated integral membrane protein, orientated with its C terminus exposed at the cell surface.

The long noncoding region of the human parainfluenza virus type 1 f gene contributes to the read-through transcription at the m-f gene junction

Sendai virus (SV) and human parainfluenza virus type 1 (hPIV1) have genomes consisting of nonsegmented negative-sense RNA in which the six genes are separated by well-conserved intergenic (IG) sequences and transcriptional start (S) and end signals. In hPIV1-infected cells, transcriptional termination at the M-F gene junction is ineffective; a large number of M-F read-through transcripts are produced (T. Bousse, T. Takimoto, K. G. Murti, and A. Portner, Virology 232:44-52, 1997). In contrast, few M-F read-through transcripts are detected in SV-infected cells. Sequence analysis indicated that the hPIV1 IG and S sequences in the M-F junction differ from those of SV. Furthermore, the hPIV1 F gene contains an unusually long noncoding sequence. To identify the cis-acting elements that prevent transcriptional termination at the M-F junction, we rescued recombinant SV (rSVhMFjCG) in which its M-F gene junction was replaced by that of hPIV1. Cells infected with rSVhMFjCG produced an abundance of M-F read-through transcripts; this result indicated that the hPIV1 M-F junction is responsible for inefficient termination. When one or both of the IG and S sites in rSVhMFjCG were replaced by those of SV, the efficiency of transcriptional termination increased but not to the level observed in wild-type SV-infected cells. Deletion of most of the long noncoding region of the hPIV1 F gene in rSVhMFjCG in addition to the mutations in IG and S signals resulted in efficient termination that was equivalent to the level observed in wild-type virus-infected cells. Therefore, the long noncoding sequence of the hPIV1 F gene contains cis-acting element(s) that affects transcriptional termination. Our evaluation of the effect of inefficient transcriptional termination on viral replication in culture revealed that cells infected with rSVhMFjCG produced less F protein than cells infected with wild-type SV and that assembly of the recombinant SV in culture was less efficient. These phenotypes seem to be responsible for the extended survival of mice infected with rSVhMFjCG.

Intracellular behavior of rabies virus matrix protein (M) is determined by the viral glycoprotein (G)

To investigate the nature and intracellular behavior of the matrix (M) protein of an avirulent strain (HEP-Flury) of rabies virus, we cloned and sequenced the cDNA of the protein. Using expression vectors pZIP-NeoSV(X)1 and pCDM8, the cDNA was transfected to animal cells (BHK-21 and COS-7) with or without coexpression of viral glycoprotein (G). When M protein alone was expressed in the cells, it displayed homogeneous distribution in the whole cell including the nucleus. In contrast, coexpression with G protein resulted in the abolishment of nuclear distribution of M antigen, and both of the antigens displayed a colocalized distribution in the cell, especially at the cellular membrane as seen in the virus-infected cells, while the distribution of G antigen was not affected by coexpressed M antigen. Immunoprecipitation studies revealed that M protein was coprecipitated with G protein by anti-G antibody, and vice versa, although cross-linking with dithiobis(succinimidyl propionate) was necessary for coprecipitation because of their easier dissociation in the presence of sodium deoxycholate. These results suggest that M protein intimately associates with G protein, which may affect or regulate the behavior (e.g., intracellular localization) of M protein. Studies with deletion mutants of M protein indicate that an internal region around the amino acids from 115 to 151 is essential for the M protein to preserve its binding ability to G protein.

Molecular basis for naturally occurring elevated readthrough transcription across the M-F junction of the paramyxovirus SV5

Transcription of the paramyxovirus RNA genome is thought to involve a sequential stop-start mechanism whereby monocistronic mRNAs are produced by polyadenylation and termination of 3' upstream gene followed by reinitiation at the downstream start site. For a number of paramyxoviruses, transcription across the M-F gene junction results in the synthesis of high levels of a dicistronic M-F readthrough RNA. In cells infected with the paramyxovirus SV5, 15% or less of the transcripts from the viral P, M, SH, HN, and L genes were detected as readthrough products with the 3' proximal gene. By contrast, approximately 40% of the SV5 F mRNA was detected as a dicistronic M-F transcript. A comparison of the individual SV5 gene junctions showed that elevated M-F readthrough transcription correlate with the M gene end having the shortest U tract for directing polyadenylation and a gene end sequence that differs from the consensus sequence. We have tested the hypothesis that elevated M-F readthrough transcription results from an inefficient termination signal at the end of the M gene. A reverse genetics system was established whereby SV5 transcription was reconstituted in transfected cells using cDNA-derived polymerase components and dicistronic minigenomes that encoded either the SV5 M-F or the SH-HN gene junction. Chimeric SV5 minigenomes were constructed to contain exchanges of a 10 base gene end sequence and the U tract from the M-F (approximately 40% readthrough) and SH-HN (approximately 15% readthrough) junctions. Northern blot analysis of RNA synthesized from these altered templates showed that, in the context of the M-F intergenic region, increasing the length of the M gene end U tract from four residues to six or eight U residues did not decrease M-F readthrough transcription. In contrast, chimeric minigenomes that contained the 10 base region from the end of the SH gene directed very efficient gene termination and a corresponding decrease in readthrough transcription. Mutational analysis showed that a single G to A substitution located five bases 3' to the M gene U tract was sufficient to convert the M gene end region to an efficient signal for polyadenylation-termination. These results demonstrate a role for the gene end region located immediately 3' to the U tract as a major determinant of transcription termination in the paramyxovirus genome. The possible role of M-F readthrough transcription in the paramyxovirus growth cycle is discussed.

Polyadenylation of vesicular stomatitis virus mRNA dictates efficient transcription termination at the intercistronic gene junctions

The intercistronic gene junctions of vesicular stomatitis virus (VSV) contain conserved sequence elements that are important for polyadenylation and transcription termination of upstream transcript as well as reinitiation of transcription of downstream transcript. To examine the role of the putative polyadenylation signal 3'AUACU(7)5' at the gene junctions in polyadenylation and transcription termination, we constructed plasmids encoding antigenomic minireplicons containing one or two transcription units. In plasmid-transfected cells, analyses of the bicistronic minireplicon containing the wild-type or mutant intercistronic gene junctions for the ability to direct synthesis of polyadenylated upstream, downstream, and readthrough mRNAs showed that the AUACU(7) sequence element is required for polyadenylation of VSV mRNA. Deletion of AUAC or U(7) resulted in templates that did not support polyadenylation of upstream mRNA. Interestingly, we found that the loss of polyadenylation function led to antitermination of the upstream transcript and resulted in a readthrough transcript that contained the upstream and downstream mRNA sequences. Mutations that blocked polyadenylation also blocked transcription termination and generated mostly readthrough transcript. Reverse transcription-PCR of readthrough transcripts and subsequent nucleotide sequencing of the amplified product revealed no extra adenosine residues at the junction of the readthrough transcript. These results indicate that polyadenylation is required for transcription termination of VSV mRNA. The intergenic dinucleotide GA did not appear to be necessary for transcription termination. Furthermore, we found that insertion of the polyadenylation signal sequence AUACU(7) alone was sufficient to direct polyadenylation and efficient transcription termination at the inserted site. Taken together, the data presented here support the conclusion that polyadenylation is the major determinant of transcription termination at the intercistronic gene junctions of VSV.

Elevated expression of the human parainfluenza virus type 1 F gene downregulates HN expression

Interactions involved in the expression of parainfluenza glycoproteins were examined by expressing cDNA clones of the HN and F genes from human parainfluenza virus type-1 (hPIV1) or Sendai virus (SV) in recombinant Semliki Forest virus (recSFV) or vaccinia-T7 expression vectors. We found that expression of a cloned F protein gene of hPIV1 resulted in downregulation of the HN proteins of hPIV1 or SV. Compared to the amount of HN expressed in the absence of F, coexpression of HN and F led to about 70% reduction in HN. This reduction of HN was observed in both total cell lysates and in protein localized on the cell surface. In contrast to hPIV1 F, SV F did not suppress the expression of HN. Northern blot analysis indicated that similar levels of HN mRNA accumulated in the absence or presence of hPIV1 F. The reduction of HN protein expression by hPIV1 F was detectable after as little as a 10-min labeling period, suggesting that downregulation occurred at the level of translation or at an early stage of protein folding. In hPIV1-infected cells, the amount of F protein synthesized was only about 15% of that of HN, whereas SV F is expressed at high levels. When the level of F in hPIV1-infected cells was artificially increased by recSFV, HN expression was suppressed. The reduction of F protein production in hPIV1-infected cells was regulated at the level of transcription. Characterization of mRNAs produced in hPIV1-infected cells showed that only 20% of the hPIV1 F mRNAs were monocistronic transcripts; 80% were bicistronic M-F readthrough mRNAs. Because proteins are suggested to be synthesized from only the first cistron of bicistronic mRNA in paramyxovirus (T. C. Wong and A. Hirano (1987) J. Virol. 61, 584-589), production of F protein is likely suppressed by transcriptional regulation in hPIV1-infected cells. These results suggest that F is capable of downregulating the synthesis of HN, but that this is normally prevented in hPIV1-infected cells by suppression of F protein synthesis by transcriptional regulation.

Effects of mutations in the gene-start and gene-end sequence motifs on transcription of monocistronic and dicistronic minigenomes of respiratory syncytial virus

Preceding and following each gene of respiratory syncytial virus (RSV) are two conserved sequences, the gene-start (GS) and gene-end (GE) motifs, respectively, which are thought to be transcription signals. The functions and boundaries of these signals and the process of sequential transcription were analyzed with cDNA-encoded RNA analogs (minigenomes) of nonsegmented negative-sense RSV genomic RNA. Two minigenomes were used. The monocistronic RSV-CAT minigenome consists of the chloramphenicol acetyltransferase (CAT) translational open reading frame (ORF) bordered by the GS and GE motifs and flanked by the 3' leader and 5' trailer extragenic regions of genomic RNA. The dicistronic RSV-CAT-LUC minigenome is a derivative of RSV-CAT into which the ORF for luciferase (LUC), bordered by GS and GE motifs, was inserted downstream of the CAT gene with an intergenic region positioned between the two genes. Each minigenome was synthesized in vitro and transfected into RSV-infected cells, where it was replicated and transcribed to yield the predicted polyadenylated subgenomic mRNA(s). The only RSV sequences required for efficient transcription and RNA replication were the 44-nucleotide 3' leader region, the last 40 nucleotides of the 5' trailer region, and the 9- to 10-nucleotide GS and 12- to 13-nucleotide GE motifs. The GS and GE motifs functioned as self-contained, transportable transcription signals which could be attached to foreign sequences to direct their transcription into subgenomic mRNAs. Removal of the GS motif greatly reduced transcription of its gene, and the requirement for this element was particularly strict for the gene in the downstream position. Ablation of the promoter-proximal GS signal was not associated with increased antigenome synthesis. Consistent with its proposed role in termination and polyadenylation, removal of the CAT GE signal in RSV-CAT resulted in the synthesis of a nonpolyadenylated CAT mRNA, and in RSV-CAT-LUC the same mutation resulted in readthrough transcription to yield a dicistronic CAT-LUC mRNA. The latter result showed that a downstream GS signal is not recognized for reinitiation by the polymerase if it is already engaged in mRNA synthesis; instead, it is recognized only if the polymerase first terminates transcription at an upstream termination signal. This result also showed that ongoing transcription did not open the downstream LUC gene for internal polymerase entry. Removal of both the GS and GE signals of the upstream CAT gene in RSV-CAT-LUC silenced expression of both genes, confirming that independent polymerase entry at an internal gene is insignificant. Remarkably, whereas both genes were silent when the CAT GS and GE signals were both absent, restoration of the CAT GE signal alone restored a significant level (approximately 10 to 12% of the wild-type level) of synthesis of both subgenomic mRNAs. This analysis identified a component of sequential transcription that was independent of the promoter-proximal GS signal and appeared to involve readthrough from the leader region.

The structurally diverse intergenic regions of respiratory syncytial virus do not modulate sequential transcription by a dicistronic minigenome

The first nine genes of respiratory syncytial virus (RSV), a nonsegmented negative-strand RNA virus, are separated by intergenic regions which range in size from 1 to 52 nucleotides for strain A2 and lack obvious consensus elements except that each ends in an A (genome sense). Their significance for gene expression was investigated by using RSV-CAT-LUC RNA, a helper-dependent cDNA-encoded dicistronic analog of RSV genomic RNA in which the viral genes were replaced by a negative-sense copy of the translational open reading frame (ORF) encoding chloramphenicol acetyltransferase (CAT) as the upstream, leader-proximal gene and that encoding luciferase (LUC) as the downstream gene. These foreign ORFs were flanked by the RSV gene-start (GS) and gene-end (GE) transcription signals and separated by the naturally occurring G/F intergenic region. The RSV-CAT-LUC minigenome was synthesized in vitro and transfected into RSV-infected cells, and synthesis of the CAT and LUC mRNAs was monitored by enzyme assay and Northern (RNA) blot hybridization. Surprisingly, substitution of each of the other naturally occurring RSV intergenic regions in turn did not significantly alter the absolute or relative amounts of the two mRNAs. Substitution of a nonnatural 10-nucleotide intergenic region, or elimination of the intergenic region altogether, also had little effect on the level of expression of the two genes. Four of the minigenome variants containing naturally occurring intergenic regions were modified further by replacing part of the LUC ORF with a second copy of the CAT ORF, so that each of the two mRNAs would hybridize equally with a CAT-specific probe and their relative molar amounts could be determined. The level of expression of the downstream gene was 0.30 to 0.36 that of the upstream one. This determined the magnitude of RSV transcriptional polarity across a gene pair and confirmed that this value was very similar among the various intergenic regions. Minigenome transcription also yielded a CAT-LUC readthrough mRNA at a level 0.10 to 0.13 that of the LUC mRNA. In summary, the structurally diverse RSV intergenic regions do not appear to play a role in modulating RSV gene expression.

Sequence and genome organization of Borna disease virus

We have previously demonstrated that Borna disease virus (BDV) has a negative nonsegmented single-stranded (NNS) RNA genome that replicates in the nucleus of infected cells. Here we report for the first time the cloning and complete sequence of the BDV genome. Our results revealed that BDV has a genomic organization similar to that of other members of the Mononegavirales order. We have identified five main open reading frames (ORFs). The largest ORF, V, is located closest to the 5' end in the BDV genome and, on the basis of strong homology with other NNS-RNA virus polymerases, is a member of the L-protein family. The intercistronic regions vary in length and nucleotide composition and contain putative transcriptional start and stop signals. BDV untranslated 3' and 5' RNA sequences resemble those of other NNS-RNA viruses. Using a set of overlapping probes across the BDV genome, we identified nine in vivo synthesized species of polyadenylated subgenomic RNAs complementary to the negative-strand RNA genome, including monocistronic transcripts corresponding to ORFs I, II, and IV, as well as six polycistronic polyadenylated BDV RNAs. Interestingly, although ORFs III and V were detected within polycistronic transcripts, their corresponding monocistronic transcripts were not detected. Our data indicate that BDV is a member of the Mononegavirales, specially related to the family Rhabdoviridae. However, in contrast to the rest of the NNS-RNA animal viruses, BDV replication and transcription occur in the nucleus of infected cells. These findings suggest a possible relationship between BDV and the plant rhabdoviruses, which also replicate and transcribe in the nucleus.

Increased synthesis of polycistronic mRNA associated with increased polyadenylation by vesicular stomatitis virus

Electron microscopy suggested that the mRNA produced in vitro by tsG16(I), a temperature-sensitive mutant of vesicular stomatitis virus, contained an increased proportion of polycistronic mRNAs. Using hybrid selection, we found that the poly(A)+ mRNA synthesized in vitro by tsG16(I) contained approximately two to three times more polycistronic mRNA than did poly(A)+ mRNA synthesized in vitro by the parental wild-type (wt) virus. The increase in polycistronic mRNA occurred at all intergenic junctions examined. In vitro, tsG16(I) has an increased polyadenylation phenotype and a temperature-sensitive transcriptase activity that appear to be due to different mutations. Partial revertants of tsG16(I), which have lost the aberrant polyadenylation phenotype but retain the in vitro thermosensitive transcriptase, produced wt amounts of polycistronic mRNA. This suggested that the increased production of polycistronic mRNA by tsG16(I) may be associated with the increased polyadenylation phenotype of this mutant. These data further support the hypothesis that an increase in size of poly(A) tracts is associated with increased production of polycistronic mRNA.

Gene expression of nonsegmented negative strand RNA viruses

Nonsegmented negative strand RNA viruses comprise major human and animal pathogens in nature. This class of viruses is ubiquitous and infects vertebrates, invertebrates, and plants. Our laboratory has been working on the gene expression of two prototype nonsegmented negative strand RNA viruses, vesicular stomatitis virus (a rhabdovirus) and human parainfluenza virus 3 (a paramyxovirus). An RNA-dependent RNA polymerase (L and P protein) is packaged within the virion which faithfully copies the genome RNA in vitro and in vivo; this enzyme complex, in association with the nucleocapsid protein (N), is also involved in the replication process. In this review, we have presented up-to-date information of the structure and function of the RNA polymerases of these two viruses, the mechanisms of transcription and replication, and the role of host proteins in the life-cycle of the viruses. These detailed studies have led us to a better understanding of the roles of viral and cellular proteins in the viral gene expression.

Characterization of human parainfluenza virus type 3 persistent infection in cell culture

Three cell lines persistently infected with human parainfluenza virus type 3 were characterized on a molecular level in this study. All six structural protein genes were transcribed into monocistronic RNAs in the persistently infected cells. In both acutely and persistently infected cells, polycistronic transcripts were abundant, although the ratio of polycistronic to monocistronic transcripts was reduced in the persistently infected cells. Each of the persistently infected cell lines contained a distinct subgenomic RNA species. The subgenomic RNAs were present in purified nucleocapsid cores, indicating that they represent viral genome RNA, were far more abundant than full-length RNA, and were stably maintained through at least 36 cell passages. Nucleotide sequence analysis of the subgenomic RNAs from two of the persistently infected cell lines revealed that the 5' ends are identical to that of the standard genome. Hybridization experiments with oligonucleotide probes showed that both fragments retain sequences from the 5' end of the standard genome and contain approximately 1,200 nucleotides (cell line 1) and 1,500 nucleotides (cell line 2) of the polymerase gene sequence. The demonstration of several alterations in viral gene expression in persistently infected cells offers insight into the factors associated with persistence of parainfluenza virus 3.

Measles virus synthesizes both leaderless and leader-containing polyadenylated RNAs in vivo

The minus-sense RNA genome of measles virus serves as a template for synthesizing plus-sense RNAs of genomic length (antigenomes) and subgenomic length [poly(A)+ RNAs]. To elucidate how these different species are produced in vivo, RNA synthesized from the 3'-proximal N gene was characterized by Northern RNA blot and RNase protection analyses. The results showed that measles virus produced three size classes of plus-sense N-containing RNA species corresponding to monocistronic N RNA, bicistronic NP RNA, and antigenomes. Unlike vesicular stomatitis virus, measles virus does not produce a detectable free plus-sense leader RNA. Instead, although antigenomes invariably contain a leader sequence, monocistronic and bicistronic poly(A)+ N-containing RNAs are synthesized either without or with a leader sequence. We cloned and characterized a full-length cDNA representing a product of the latter type of synthesis. mRNAs and antigenomes appeared sequentially and in parallel with leaderless and leader-containing RNAs. These various RNA species accumulated concurrently throughout infection. However, cycloheximide preferentially inhibited accumulation of antigenomes and leader-containing RNA but not leaderless and subgenomic RNAs late in infection, suggesting that synthesis of the former RNA species requires a late protein function or a continuous supply of structural proteins or both. These results reveal a previously undescribed mechanism for RNA synthesis in measles virus.

Biased hypermutation and other genetic changes in defective measles viruses in human brain infections

We assessed the alterations of viral gene expression occurring during persistent infections by cloning full-length transcripts of measles virus (MV) genes from brain autopsies of two subacute sclerosing panencephalitis patients and one measles inclusion body encephalitis (MIBE) patient. the sequence of these MV genes revealed that, most likely, almost 2% of the nucleotides were mutated during persistence, and 35% of these differences resulted in amino acid changes. One of these nucleotide substitutions and one deletion resulted in alteration of the reading frames of two fusion genes, as confirmed by in vitro translation of synthetic mRNAs. One cluster of mutations was exceptional; in the matrix gene of the MIBE case, 50% of the U residues were changed to C, which might result from a highly biased copying event exclusively affecting this gene. We propose that the cluster of mutations in the MIBE case, and other combinations of mutations in other cases, favored propagation of MV infections in brain cells by conferring a selective advantage to the mutated genomes.

Defective interfering particles of human parainfluenza virus 3

A cyclic pattern of virus production was observed when human parainfluenza virus 3 (HPIV3) was serially passaged nine times in LLC-MK2 cells. Viruses produced from serial passages 8 and 9 interfered with the replication of standard HPIV3. Three subgenomic RNA species (DI-1, DI-2, and DI-3) and virus genomic RNA were detected in the progeny virions produced from cells mixedly infected with standard virus and virus from either serial passages 5 or 8. Northern blot analysis with probes representing all six HPIV3 structural protein genes revealed that DI-1 and DI-2 RNAs contain sequences from the 5' end of the standard virus genome. DI-1 RNA contains L, HN, and F specific sequences, while DI-2 RNA contains only L and HN sequences. DI-3 RNA did not hybridize with any of the probes used. The possibility that DI-3 RNA contains sequences from the 5' end of the standard virus genome is discussed. These results demonstrate that 5' defective interfering particles are generated during serial passage of HPIV3.

Detection of polycistronic transcripts in Newcastle disease virus infected cells and identification of their sequence content

The synthesis of six to seven polycistronic transcripts of Newcastle disease virus (NDV) in BHK cells was detected by Northern hybridization using cDNA clones generated by reverse transcription of five NDV mRNAs. Within the molecular weight range resolved by the gel electrophoresis system employed, four of the transcripts were suggested to be distronic, containing sequences of two genes, NP-P, P-M, M-F0 and F0-HN, respectively. In addition, tricistronic molecules of M-F0-HN and possibly of NP-P-M as well as P-M-F0 appeared to develop, although they were very low in amount. These data suggest a gene order of NP-P-M-F0-HN on the NDV genome. The polycistronic as well as monocistronic transcripts were generated with an almost constant proportion in amount throughout the virus replication. Further, at least several of them were also generated under the conditions where only the primary transcription was allowed by inhibiting de novo protein synthesis. Therefore, it appears likely that there is no distinct temporal control in NDV genome expression.

Molecular cloning and sequence analysis of the human parainfluenza 3 virus gene encoding the matrix protein

The sequence of the matrix (M) protein gene and contiguous intergenic regions of the human parainfluenza 3 virus (PF3) was determined by molecular cloning. The encoded M protein contains 354 amino acids and has a predicted mol wt of 39,506. The M protein amino acid sequence was compared to the homologous proteins from other members of the Paramyxoviridae family. The PF3 protein shared 61% homology with the Sendai virus protein and approximately 35% homology with measles and canine distemper virus proteins. Little homology was observed with respiratory syncytial virus. The M protein appears to be the most highly conserved among the Paramyxoviridae proteins.

Human parainfluenza virus type 3: messenger RNAs, polypeptide coding assignments, intergenic sequences, and genetic map

cDNA clones of mRNAs for the major nucleocapsid protein (NP), the nucleocapsid P protein plus the nonstructural C protein (P+C), and the matrix protein (M) of human parainfluenza virus type 3 (PF3) were identified by hybrid arrest and hybrid selection of in vitro translation. Previously, cDNA clones were identified and sequenced for the hemagglutinin-neuraminidase glycoprotein (HN) and the fusion glycoprotein (F) mRNAs (N. Elango, J. E. Coligan, R. C. Jambou, and S. Venkatesan, J. Virol. 57:481-489, 1986; M. K. Spriggs, R. A. Olmsted, S. Venkatesan, J. E. Coligan, and P. L. Collins, Virology 152:241-251, 1986). Synthetic oligonucleotides, designed from nucleotide sequences of the cDNAs, were used to direct dideoxynucleotide sequencing of gene junctions in PF3 genomic RNA (vRNA). From sequencing of vRNA, a sixth viral gene was detected and identified as the large nucleocapsid protein (L) gene by hybridization of a synthetic oligonucleotide to intracellular PF3 mRNAs separated by gel electrophoresis. The order of the six PF3 genes on vRNA was 3'-NP-P+C-M-F-HN-L-5'. The five intergenic regions consisted of the trinucleotide 3'-GAA. The PF3 genes initiated with semiconserved 10-nucleotide gene-start sequences and terminated with semiconserved 12-nucleotide gene-end sequences. The M gene terminated with an aberrant gene-end sequence; analysis of intracellular mRNA showed that this aberrant sequence correlated with a disproportionately high accumulation of readthrough mRNA. These studies showed that PF3 encodes six unique mRNAs (NP, P+C, M, F, HN, and L) that encode seven proteins (NP, P, C, M, F, HN, and L) and provided evidence of a close relationship between PF3 and Sendai (murine parainfluenza type 1) viruses.

Identification of the sequence content of four polycistronic transcripts synthesized in Newcastle disease virus infected cells

During infection, the Newcastle disease virus (NDV) genome is transcribed to produce 5 to 7 species of polycistronic messenger RNA (Wilde and Morrison, J. Virol. 51, 71-76) in addition to the well characterized monocistronic messenger RNA. To identify the specific sequences present in each of the polycistronic RNA species, cDNA clones generated by reverse transcription of NDV mRNAs were characterized and used as probes on Northern blots of total NDV cytoplasmic RNA. By this method, it was shown that four of these large RNA species are polycistronic transcripts containing sequences from two genes: one species contains nucleocapsid protein (NP) and phosphoprotein (P) gene sequences; another, P and membrane protein (M) gene sequences; another, M and fusion protein (F0) gene sequences; and another, F0 and hemagglutinin-neuraminidase protein (HN) gene sequences. The existence of these transcripts yields a transcription map order of NP, P, M, F0, HN. The remaining RNA bands may be composed of at least three different polycistronic transcripts, each of which represents transcription through three adjacent genes.

Nucleotide sequences for the gene junctions of human respiratory syncytial virus reveal distinctive features of intergenic structure and gene order

Complete sequences for the intergenic regions of the genome of human respiratory syncytial virus were obtained by dideoxynucleotide sequencing using synthetic oligonucleotides. These experiments established that the 10 respiratory syncytial viral genes are arranged, without additional intervening genes, in the order 3' 1C-1B-N-P-M-1A-G-F-22K-L 5'. For the first nine genes, the exact gene boundaries were identified by comparison of the genomic sequences with previously determined mRNA sequences. The intergenic regions varied in length from 1 to 52 nucleotides and lacked any obvious conserved features of primary or secondary structure except that each sequence ended (3' to 5') with an adenosine residue. The exact start site of the 10th gene, the L gene, was not determined. However, RNA blot hybridization using a synthetic oligonucleotide designed from the genomic sequence mapped the L gene to within 54 nucleotides of the end of the penultimate 22K gene. The lack of conservation of chain length and nucleotide sequence for the respiratory syncytial viral intergenic regions, together with the complexity of the genetic map, contrasts with previous observations for other nonsegmented negative-strand viruses.

Nucleotide sequences that affect replicative and transcriptional efficiencies of Sendai virus deletion mutants

Structural features of the genomes of virus deletion mutants (DI virions) influence their replication efficiency. Among nonsegmented negative-strand RNA viruses, substitution of the genomic 3' terminus by a complementary copy of the 5' terminus (so-called "copy-back" sequence) could enhance replication either because the new 3' end is a better promoter of RNA replication or because DI RNAs that possess this sequence are incapable of acting as templates for transcription. Here we provide evidence that both mechanisms operate in mixed infections with Sendai virus DI RNAs. RNAs incapable of transcription always outgrew RNA species that were transcribed. This was true even when the 3'-terminal sequence of the untranscribed RNA was identical to the genomic 3' terminus, as in the case of an internally deleted DI genome (RNA Ra) rendered transcriptionally inert by point mutations of bases 47 and 51 at the 5' end of the positive-strand leader RNA template. Nevertheless, Ra was outgrown by a copy-back DI RNA, indicating that the 3' genomic end of Ra is a less efficient site for replication initiation than the copy-back sequence.

Translational modulation in vitro of a eukaryotic viral mRNA encoding overlapping genes: ribosome scanning and potential roles of conformational changes in the P/C mRNA of Sendai virus

Expression of proteins from three overlapping genes in a single mRNA species of Sendai virus was modulated in a cell-free rabbit reticulocyte translation system. Hybrid-arrested translation by oligodeoxynucleotides complementary to specific regions of the mRNA that specifies the viral P, C, and C' proteins demonstrated that ribosomes scan the RNA from its 5' end to find initiation codons, and suggested that the secondary structure of the mRNA influences the selection of alternative initiation codons. Translational modulation of P, C, and C' proteins by Mg++ and spermidine indicated that RNA folding is involved in this selection process.