Analysis of the Noncoding Regions of Measles Virus Strains in the Edmonston Vaccine Lineage

doi:10.1128/JVI.75.2.921-933.2001

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Journal of Virology, January 2001, p. 921-933, Vol. 75, No. 2
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.2.921-933.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Analysis of the Noncoding Regions of Measles Virus Strains in the Edmonston Vaccine Lineage

Christopher L. Parks, Robert A. Lerch, Pramila Walpita, Hai-Ping Wang, Mohinder S. Sidhu, and Stephen A. Udem^*

Department of Viral Vaccine Research, Wyeth-Lederle Vaccines, Pearl River, New York 10965

Received 10 April 2000/Accepted 16 October 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The noncoding sequence of five Edmonston vaccine viruses (AIK-C, Moraten, Rubeovax, Schwarz, and Zagreb) and those of a low-passageEdmonston wild-type (wt) measles virus have been determined andcompared. Twenty-one nucleotide positions were identified at whichEdmonston wt and one or more vaccine strains differed. The locationof some of these nucleotide substitutions suggests that they mayinfluence the efficiency of mRNA synthesis, processing, and translation,as well as genome replication and encapsidation. Five nucleotidesubstitutions were conserved in all of the vaccine strains. Twoof these were in the genomic 3'-terminal transcriptional controlregion and could affect RNA synthesis or encapsidation. Threewere found within the 5'-untranslated region of the F mRNA, potentiallyaltering translation control sequences. The remaining vaccinevirus base changes were found in one to four vaccine strains.Their genomic localization suggests that some may modify cis-actingregulatory domains, including the Kozak consensus element of theP and M genes, the F gene-end signal, and the F mRNA 5'-untranslatedsequence.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Measles virus (MV) is a highly contagious human pathogen best known as the cause of one of the classical "rash" illnessesof children. Few escaped this acute infection and disease priorto the development of the currently used live attenuated virusvaccines. Severe, even fatal complications, particularly involvingthe respiratory and central nervous systems, were not uncommoneven in industrialized countries. Unfortunately, in many partsof the less-well-developed world, measles continues to be themajor cause of preventable childhood mortality (9, 15, 16).

MV is an enveloped RNA virus of the genus Morbillivirus, family Paramyxoviridae (32). Like other members of this family,its genome is nonsegmented and of negative sense. The 16-kb linearRNA contains six nonoverlapping cistrons (3'-N-P-M-F-H-L-5') thatencode eight known polypeptides (16, 27). In addition to theprotein coding regions, nearly 11% of the 16-kb MV genome is composedof noncoding RNA. Presumably, this relatively small viral genomehas maintained a significant noncoding nucleotide sequence contentfor its functionally important cis-actingelements.

cis-acting regulatory sequences found in all viral genomes are essential for the orderly progression of the viral life cycle.These elements serve to specify, organize, and control gene expressionand genome replication, often exerting these effects through interactionwith virus-encoded proteins or host cell factors. The importantrole of cis-acting sequence elements is well illustrated by thecomplex transcriptional regulatory schemes employed by large DNAviruses such as herpes simplex virus or adenovirus (38, 42).It is equally clear that cis-acting regulatory elements are exploitedby the smaller genomes of negative-strand RNA viruses to controltheir replicative strategy (27). In MV, like other paramyxoviruses,cis-acting sequences have been identified that have roles in genomereplication, genome packaging, translation, and mRNA synthesis,processing, and editing (2, 16, 19, 27, 41).

The known or proposed cis-acting signals in the MV genome are summarized in Fig. 1 (2, 16, 19, 27, 41). The noncoding107 nucleotides at the 3' end of the negative-strand genome (calledthe leader transcriptional control region [TCR]) include promotersequences that initiate two distinct RNA synthesis pathways: (i)production of an end-to-end copy of the genome to generate thepositive-strand replication intermediate and (ii) an elongation-termination-reinitiationtranscription pathway that produces mRNAs corresponding to thesix cistrons. Transcription termination and reinitiation duringmRNA synthesis is mediated by conserved sequence elements locatedin each intergenic region: a gene-end (GE) plus a gene-start (GS)signal separated by the characteristic GAA nucleotide tripletforms the GE/GS signal. The highly conserved GAA triplet is foundbetween all intergenic GE and GS signals except between the Hand L genes, where a GCA triplet is found. In addition to guidingtranscription termination and reinitiation, the GE/GS signal alsodirects mRNA polyadenylation.

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FIG. 1. MV genome map. The location of protein coding regions (white boxes: N, P, V, C, M, F, H, and L) and noncoding regions including the leader and trailer (black terminal boxes) and intergenic regions (shaded blue) are shown, along with specialized sequence motifs (2, 16, 19, 27, 41, 52). The TCRs at the 3' end of the genomic RNA (leader TCR, nucleotides 1 to 107) and the 3' end of the antigenomic RNA (trailer TCR, nucleotides 15785 to 15894) are enlarged below the genome map. Genomic RNA synthesis initiation is shown as open arrowheads in the enlargement of the leader and trailer TCR regions. Sequence motifs shown in the expanded TCR maps include the leader, trailer, GE and GS signals, the 16-base conserved terminal sequence (shown 3' to 5'), the repeated B- and B'-box motif, the G(N)5 motif, the ATG codon for the N gene adjacent to the leader, and the L protein stop codon outside of the 5' end of the trailer. The positions of GE/GS signals are designated with a combination of solid arrowhead (GS) and a black box (GE). The leader TCR GE/GS symbol lacks a GE box, and the trailer TCR GE/GS lacks a GS arrowhead to signify that these sequences may not function identically to GE/GS elements in the intergenic regions. The mRNA editing site is indicated below the V protein coding region (6). Part of the F gene mRNA 5'-untranslated nucleotide sequence is shown to illustrate the three in-frame AUG initiator codons (5). At the bottom of the figure, several symbols found in the TCR maps are defined.

cis-acting sequences similar to those in the leader TCR are also located in the 3'-terminal 109 nucleotides of the positive-strandedantigenome (the trailer TCR; Fig. 1). The trailer TCR exclusivelydirects initiation of negative-strand genome synthesis. Importantsequence motifs found in the leader and trailer TCRs (Fig. 1)include the terminal 16 nucleotides that are thought to be partof the primary site of RNA polymerase recognition (20, 28),the G(N)5 (52) and B-box motifs (2) that have been implicatedas regulators of MV transcription and replication, and a potentialGS signal in the leader TCR prior to the N gene and a GE signalin the trailer TCR that terminates L gene mRNA synthesis (16,19, 27, 41).

Two additional functional cis-acting sequences have been identified in the MV genome. One is the RNA editing site in the Pcistron that permits addition of a G residue in some P mRNAs,resulting in the translational frameshift that directs synthesisof V protein (6). The second cis-acting sequence is found withinthe rather long noncoding intergenic region between the M andF genes. Part of this region specifies the nontranslated leadersequence of the F gene mRNA which has been shown to be an importantdeterminant of translational efficiency and AUG codon selection(5, 13). Deletion of this translational control element fromrecombinant viruses also appears to compromise replication invivo (55). Identification of yet other cis-acting elements islikely to occur as more of the MV noncoding sequences are scrutinizedwith transient assay systems and recombinantviruses.

cis-acting elements can be an important determinant of virus attenuation. For example, mutations in the leader sequence ofhuman parainfluenza virus type 3 (PIV3) vaccine candidates havebeen shown to specify the temperature sensitivity, cold adaptation,and attenuation phenotypes (46). Some attenuated respiratorysyncytial virus A2 (RSV A2) strains contain a nucleotide changein the GS signal of the M2 gene that contributes to their temperature-sensitiveand attenuated phenotypes (56). Also, a GE signal mutation inthe M gene of an attenuated RSV B strain has been found to compromiseexpression of the downstream SH gene (D. A. Buonagurio, personalcommunication). Similarly, a cis-acting sequence mutation hasbeen noted within the GE signal of the mumps vaccine virus F genethat appears to also disrupt normal expression of the downstreamSH gene (51). Taken together, these studies indicate that specificalterations of noncoding cis-acting sequence elements of negative-strandRNA viruses can modulate virus virulence andattenuation.

Genomic modifications that attenuate MV have only recently begun to be defined. For example, several studies have shown thatviruses defective for V or C protein expression display attenuatedgrowth characteristics in some model systems (12, 31, 34,53, 55). Additionally, mutations in genes encoding C, V, P,and L proteins have been associated with reduced viral replicationin the B95 lymphocyte cell line (50). Although these studieshave started to define roles for various proteins in MV attenuation,the potential role of cis-acting sequences has so far receivedless attention. In one case, deletion of most of the F gene mRNA5'-untranslated region from a recombinant MV strain did resultin less-efficient replication in human thymus-liver implants engraftedinto SCID mice (55), demonstrating that modification of thiscis-acting sequence can modulateattenuation.

To learn more about the potential role of noncoding cis-acting sequences in MV attenuation, a comparative sequence analysiswas performed on viruses in the Edmonston vaccine lineage. Thisstudy was based on posing two relatively simple questions. (i)Do the noncoding sequences from several optimally attenuated vaccineviruses differ from the Edmonston wt progenitor strain or an underattenuatedEdmonston vaccine strain? (ii) If differences exist, do they affectnoncoding sequences that may function as cis-acting sequencescontrolling gene expression or replication? The Edmonston viruslineage (39) is attractive for this type of comparative studyfor a variety of reasons. Six viruses from the vaccine lineageare available for comparison, including five independently generatedvaccine strains and a low-passage laboratory isolate of Edmonstonwt (10, 11, 16, 18, 21, 26, 30, 39). This providesa unique opportunity to examine the molecular consequences ofsimilar but independent vaccine derivation schemes (39). Comparisonof Edmonston wt and five different vaccine strains also providesan opportunity to examine the diversity of molecular mechanismsby which the attenuated phenotype is produced by different genotypes.Furthermore, the vaccine strains differ in the level of attenuation.Four of the five vaccines are adequately attenuated, while Rubeovaxproved to be reactogenic (26), and this is an important pointfor comparison that should provide insight into what genome changesinfluence the degree of attenuation. Finally, transient expressionsystems and cDNA rescue technologies provide experimental systemsto further analyze the genetic changes identified by sequenceanalysis (35).

To identify potential attenuation determinants within MV cis-acting regulatory elements we have sequenced the noncoding regionsof a low-passage isolate of Edmonston wt and five vaccine derivatives.Base changes were identified at 21 noncoding positions when thevaccine genomes were compared to Edmonston wt. Five nucleotidesubstitutions were common to all vaccine strains, while the remainingsubstitutions were present in one to four vaccine viruses. Thesequence comparison also revealed that Moraten and Schwarz containedidentical noncoding region sequences and differed at five nucleotidepositions from closely relatedRubeovax.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cells, virus, and genome sequencing. Cell culture and MV propagation was performed as described in an accompanying article (33). The Edmonston wt isolate (11,16) was a gift from Judy Beeler (Center for Biologics Evaluationand Research). Edmonston B (Rubeovax) (10, 26), AIK-C (30),Schwarz (Rimevax; SmithKline Beecham) (26, 40), and Zagreb(21) were generously provided by William Bellini and Paul Rota(Centers for Disease Control) (39). Moraten (Attenuvax; Merck& Co) (18) and a second preparation of Schwarz (Rimevax, SmithKlineBeecham) (26, 40) were obtained from commercially availablevaccine preparations. The two separate sources of Schwarz wereanalyzedindependently.

Viral genome sequence was determined directly from DNA fragments generated by reverse transcription-PCR (RT-PCR) of RNA extractedfrom infected Vero cells (33). Cycle sequencing (17, 25)was performed using dye-labeled terminators and Taq DNA polymerase(Applied Biosystems), followed by analysis on an ABI Prism automatedsequence apparatus. Primers used for PCR amplification and sequencingon both cDNA strands were designed based on published MV sequences(GenBank accession numbers K01711 and S58435). Data analysiswas performed using the MacVector (Oxford Molecular Group) andLasergene (DNAstar, Inc.) software packages. The MV sequenceshave been deposited in GenBank (Edmonston wt, AF266288; AIK-C,AF266286; Moraten AF266287; Rubeovax, AF266289; Schwarz,AF266291; Zagreb, AF266290).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Comparative sequence analysis. Evidence that the base changes within the cis-acting elements of the MV genome may contribute to viral attenuation was soughtthrough comparative analysis of the noncoding region nucleotidesequence of five Edmonston vaccine viruses and a low-passage Edmonstonwt isolate. Potentially attenuating cis-acting nucleotide substitutionswere indeed located, providing the framework for design of futuregenetic studies aimed at dissecting the molecular basis of attenuationusing the MV minireplicon and recombinant MVsystems.

Interpreting such comparative sequence analyses requires caution given the lack of the true Edmonston wt progenitor virus.Fortunately, a low-passage derivative of the Edmonston clinicalisolate was available for these studies. This virus was passaged13 times (39) prior to the analysis presented here, so it ispossible that some degree of tissue culture adaptation may bereflected in the Edmonston wt sequence. Nevertheless, it is thebest approximation of the original clinical isolate available,and the passage number has been kept to a minimum in hopes ofobtaining a meaningful comparison with the vaccineviruses.

The issue of additional nucleotide changes arising during cell culture passage also applies to sequence analysis of vaccinevirus genomes. Propagation of vaccine virus strains in cell cultureto produce RNA for analysis can lead to genome changes that reflectadaptation to culture conditions and host cell type used for infection.This concern has been addressed in two ways. First, the numberof cell culture passages was limited to three or less while generatingviral stocks and RNA. Although this may result in some degreeof cell culture adaptation, the additional minimal passage numberis unlikely to affect greatly the majority of genomes in the infectedcell population. Second, the sequence determination used RT-PCRproducts rather than cloned cDNA fragments. Sequence obtainedfrom RT-PCR products should represent the majority sequence ina population of viral genomes and help alleviate the influencefrom minor viral populations that began to evolve during passagein Verocells.

Leader and trailer transcriptional control regions. The 107 3'-terminal noncoding nucleotides include the MV genomic promoter (43, 44) and are referred to here as the leaderTCR (Fig. 1). Within this TCR lie several discrete sequence elementsthat are thought to act in cis to modulate MV transcription, replication,and gene expression. Two of these are highly conserved, well-acceptedcis-acting regulatory elements of the TCR. One is the terminal16 bases of the leader (Fig. 1). The second is the GS signal thatdirects N gene mRNA synthesis (2, 16, 19, 23, 27, 41).Additional cis-acting elements in the leader TCR [B-box and G(N)5sequences] have been proposed based on genomic sequence comparisons(2, 8) and analyses of defective interfering RNAs (44),and the existence of these proposed elements has been substantiatedby studies with Sendai virus (52). Nucleotide substitution inany of these elements or yet-undefined cis-acting sequences couldhave a significant effect on virus-cell interaction through changesin replication or gene expressionefficiency.

Comparison of leader TCR sequences of Edmonston wt and the five vaccine strains revealed nucleotide differences at three positions(Fig. 2A). Nucleotide transversions were detected in all vaccinesat positions 26 and 42. The wt U residue in the negative-sensegenome strand was changed to an A residue at position 26. Thewt U residue at position 42 was substituted with a G in AIK-C,Moraten, Schwarz, and Rubeovax, and an A residue in Zagreb. Thelocation of these base substitutions is shown in Fig. 2A relativeto previously described sequence motifs (Fig. 1). The position26 and 42 base substitutions were located between the terminalleader TCR domain and the GS sequence (Fig. 2A; see also Fig.7A). The third leader TCR substitution was detected only in Zagrebat position 96. This C-to-U transition occurred within the B boxsequence and at the 5' boundary of the G(N)5 motif.

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FIG. 2. Sequence comparison of Edmonston wt and vaccine leader and trailer TCRs. Terminal 110 bases of genomic sequence (3' to 5') containing the leader TCR (nucleotides 1 to 107; part A) and trailer TCR (nucleotides 15785 to 15894; part B) of Edmonston wt are shown and labeled with genome nucleotide positions. Sequence motifs are illustrated on the sequence according to the key at the bottom of the figure. Relevant protein start or stop codons also are included. The sequence corresponding to the GE region in the leader TCR and the GS region of the trailer TCR are not shaded in gray to indicate that these sequence motifs may not function identically to their intergenic GE/GS counterparts. Illustrated below the wt sequence is the sequence comparison with vaccine strains. Nucleotide identity is given as a dot, and a typed nucleotide indicates disagreement with wt.

Little variability was detected in the trailer TCR and no base substitution was common to all of the vaccine viruses. Transitionswere identified at position 15,789 (C to U) in AIK-C and at position15,843 (U to C) in Zagreb. Neither mutation was located in a previouslydescribed sequence motif, although the Zagreb mutation was adjacentto the 3' boundary of the GE signal that terminates transcriptionfollowing the L gene (Fig. 1 and 2B). Both mutations changed basesin the 3' noncoding region of the LmRNA.

Intergenic regions. Three variable nucleotide positions (Fig. 3A) were found in the intergenic region between the N and P genes (N/P). None ofthese nucleotide substitutions were common to all vaccines. Twowere in the N cistron affecting the region that specifies the3'-untranslated region of the N mRNA. These substitutions includeda U-to-C substitution at position 1702 shared by all vaccine virusesexcept AIK-C. In the same region, Moraten and Schwarz containeda G-to-U transversion at position 1724. Within the P cistron,a C-to-U transition was identified at position 1806. This nucleotidesubstitution was found in Moraten, Schwarz, and Rubeovax, andit changed the base immediately upstream of the P protein translationstart codon.

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FIG. 3. Comparison of N/P and P/M intergenic regions of Edmonston wt and vaccine viruses. Description of this figure is as described for Fig. 2.

Only one nucleotide change was identified in the P/M intergenic region (Fig. 3B). This occurred in the M cistron at nucleotide3431, where a wt A nucleotide was changed to a C residue in Moratenand Schwarz. This nucleotide substitution alters the sequenceof the 5' noncoding region of the M mRNA at nucleotide position $-$ 7 relative to the M gene translation initiationcodon.

Nine different nucleotide positions differed from wt in the long M/F intergenic region (Fig. 4). None of these mutations werefound within the GE/GS signal. Four of the base changes were detectedin the 3'-untranslated region of the M gene mRNA. These were atgenomic positions 4536 (C to A in AIK-C), 4574 (C to U in AIK-C),4608 (A to G in Rubeovax), and 4611 (G to A in AIK-C and Zagreb).The five remaining M/F intergenic region changes occurred withinsequences encoding the 5'-untranslated region of the F gene mRNA.Two of these base substitutions were found only in one vaccinestrain, at genomic positions 5030 in AIK-C (G to A) and 5308 inRubeovax (A to G). The other three were conserved in all vaccinestrains. These changes were two A-to-G transitions at 4978 and5349 and a G-to-C transversion at 5073.

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FIG. 4. Comparison of M/F intergenic regions from Edmonston wt and vaccine viruses. The description of this figure is similar to that for Fig. 2. One line of dots indicating homology to all vaccines is shown under the wt sequence if there were no base changes to report. The sequence shown in this figure extends beyond the noncoding intergenic region to show the position of the three F gene AUG codons. The second AUG codon is the predominately used initiation codon (5). Vaccine virus names are abbreviated as follows: AIK-C (AIK), Moraten and Schwarz (Mor/Sch) Rubeovax (Rubeo) and Zagreb (Zag).

Few nucleotide changes were identified in the F/H and H/L intergenic regions (Fig. 5). One nucleotide substitution was presentin the F/H intergenic region at nucleotide position 7243 (Fig.5A). This A-to-G transition was present within the boundariesof the F gene GE signal of Moraten and Schwarz (Fig. 5A). In theH/L intergenic region, two base substitutions were located inthe 3'-untranslated region of the H gene mRNA (Fig. 5B). At position9139 a G-to-A substitution was present in AIK-C, and a U-to-Atransversion at position 9144 was detected in both Moraten andSchwarz.

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FIG. 5. Comparison of F/H and H/L intergenic regions from Edmonston wt and vaccine viruses. The description of this figure parallels that for Fig. 2.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

These analyses, though limited by the considerations described earlier, revealed distinctive base substitutions within multiplenoncoding region sequences that perform potential cis-acting functions(Fig. 2 to 5). Analyses of human PIV3 and RSV A and B vaccinecandidates also have identified base substitutions in cis-actingregions (7, 14, 18; D. A. Buonagurio, personal communication),indicating that this characteristic is shared by negative-strandvaccine virus strains. None of the five Edmonston vaccine virusesaccumulated base changes resulting in gross alteration of a noncodingregion, suggesting that these sequences do contain important componentsof the viral regulatory apparatus and that alteration is not welltolerated. It may also suggest that only subtle adjustments tocis-acting sequences controlling gene expression and replicationwere required to facilitate growth in the semipermissive cellsused for vaccine virusselection.

Why MV noncoding region mutations accumulate in potential cis-acting sequences is currently speculative, but it seems reasonableto suggest that at least some of these mutations confer a selectiveadvantage for viral replication under conditions used for vaccinederivation. Whether any of these mutations contribute to the attenuatedphenotype remains to be established. Answering this question willrequire further studies using reverse genetics and recombinantviruses in studies like those ongoing with RSV and PIV3 vaccinecandidates (7, 45, 46, 56-58).

Nucleotide substitutions in MV noncoding cis-acting sequences may be a favored response to changes in viral polypeptides inducedby passage in heterologous cell types. In one simple model describingthe biological selection process (33), it has been proposedthat selective pressure is initially driven by a requirement forinteraction between semipermissive host cell factors and viralproteins involved in the earliest stages of viral infection, particularlytranscription and replication. It follows that the early stagesof infection in semipermissive cells would be inefficient becauseviral proteins are not well equipped to deal with the semipermissivehost cell environment. As the passage process progresses, mutationsin viral protein coding regions are favored if they enhance theability of viral proteins to functionally interact with proteinsfound in the semipermissive host cell. Although these proteinmodifications may enhance the level of interaction between viraland cellular proteins, they may be costly to other aspects ofthe virus life cycle. To help compensate for any adverse effectsof amino acid substitutions, the virus evolves second-site compensatorymutations that subtly change gene expression and replication throughbase changes in cis-acting regulatory sequences and additionalamino acid substitutions. As implied by this model, many of thenoncoding region base changes identified in the Edmonston vaccinesseem to have the potential to modify cis-acting regulatory componentsof the virusgenome.

The noncoding region base substitutions can be grouped into three categories based on their potential to modify cis-actingregulatory functions: (i) base substitutions that may affect proteintranslation through changes in mRNA stability or modificationof translational regulatory elements in message, (ii) base substitutionsthat could affect mRNA synthesis by altering promoter activityin the leader TCR or GE/GS signal function, and (iii) base substitutionsthat could affect the activity of replication promoters in theleader or trailer TCRs. Below, the identified MV vaccine noncodingbase substitutions and their attenuation potential are discussedin the context of these categories. Figures 2 to 5 provide thesequence data for each gene region, while Fig. 6 summarizes theseresults schematically.

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FIG. 6. Summary of noncoding region nucleotide substitutions. A genome map similar to Fig. 1 is shown along with the nucleotide positions that varied in vaccine strains. The relative position of the GE/GS signals is shown by an arrow head plus the nucleotide position corresponding to the central A residue in the conserved GAA motif. Boundaries of the noncoding regions are indicated at the ends of the brackets containing the nucleotide substitutions. Nucleotides highlighted in gray depict changes from the Edmonston wt sequence. An asterisk above a column of nucleotides indicates that a base change occurred in all vaccine strains. The dashed box outlining groups of three nucleotides shows positions where Rubeovax differs from Moraten and Schwarz.

Base substitutions and cis-acting regulation of translation. Mutations within the 5'- or 3'-untranslated region of mRNAs can alter protein expression by affecting mRNA stability or translationefficiency (22, 29). The combination of noncoding sequenceand poly(A) tail at the 3' end of mRNAs is known to play an importantrole in determining mRNA stability (22). Destabilizing sequencesare generally AU-rich and commonly contain the pentamer AUUUA.It is plausible that mutations in the 3'-untranslated region ofMV mRNAs could affect a destabilizing sequence by interruptingan AU-rich motif or altering the secondary structure near a destabilizingmotif. Base substitutions in 3' noncoding regions were found inmultiple locations, including the N, M, H, and L genes. None ofthe mutations affecting the 3'-untranslated regions of MV mRNAs,except possibly the base substitution at position 15843 in Zagreb(Fig. 2B), obviously affects an AU-rich element (Fig. 2 to 6),but the potential of any of these base changes to alter mRNA stabilitycan only be determinedexperimentally.

The 5' end of several vaccine virus mRNA sequences included base substitutions located in positions that may affect translationinitiation (Fig. 6 and 7C). In both the P (Fig. 3A and 6) andM (Fig. 3B and 6) genes, base substitutions were identified nearthe AUG translation initiation codon in the Kozak element (Fig.7C). The Kozak consensus sequence influences AUG codon selectionand efficiency of translation initiation (24). In the P geneof Moraten, Schwarz, and Rubeovax, a G-to-A transition (mRNA sense)was found at position $-$ 1 relative to the AUG codon for the P openreading frame (Fig. 7C). In the Moraten and Schwarz M gene, aU-to-G transversion (mRNA sense) occurred at position $-$ 7 relativeto the AUG codon (Fig. 7C).

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FIG. 7. Vaccine nucleotide substitutions in cis-acting sequence motifs. (A) Alignment of MV TCRs containing the GE/GS signal. Similarity between the signals and a consensus sequence is outlined by the box (yellow). The leader TCR GE and trailer TCR GS regions are presented in lower case to indicate that these sequences may not function like the corresponding sequences of the intergenic GE/GS elements and that these sequences were not considered in evaluating the consensus. Below the consensus are the two GE/GS sequences that contained vaccine virus base substitutions. The nucleotide substitution is highlighted by a blue box. (B) Summary of the base changes found in the leader and trailer TCRs. The description of the leader and trailer TCRs can be found in Fig. 1. Nucleotide changes are illustrated below the leader and trailer TCRs. Base changes are highlighted in blue. (C) Comparison of the Kozak element (24) found in wt MV mRNAs. Variation in vaccine virus P and M gene Kozak sequences is shown below the wt sequences.

The initiator codon context of both the M and P mRNAs deviate from the Kozak sequence at positions considered most importantfor AUG strength (24). The M mRNA deviates at the highly conserved+4 position, resulting in a less-favorable context for translationinitiation. This potentially increases the influence of othernucleotides in the vicinity of the AUG such as the U residue atposition $-$ 7 that was changed in the Moraten and Schwarz vaccines.Similarly, the P mRNA lacks a purine at position $-$ 3, which isthe most highly conserved base in the Kozak element (24). Absenceof a purine at $-$ 3 will likely increase the importance of otherbases in the P mRNA Kozak element, such as the base at position $-$ 1 that was changed in Moraten, Schwarz, and Rubeovax. If thesechanges in initiation codon context alter translation efficiency,the effect may be quite subtle since the codon context is changedonly by a single base substitution. This does not mean that thesebase substitutions are not important since it is possible thatattenuation is the result of the cumulative effect of numerousrelatively small adjustments in the virus lifecycle.

The poor agreement between the P gene AUG context and the Kozak element consensus may have evolved to permit a certain percentageof ribosomes to scan through the P AUG codon and engage the Cprotein mRNA AUG codon located downstream. This also suggeststhat base changes in the P Kozak element may influence the ratiosof P, V, and C protein synthesis in the infected cell. The possibilitythat the P AUG codon context may influence translation of C proteinhas been examined previously. Alkhatib et al. (1) placed theP gene into a recombinant adenovirus and analyzed the levels ofP and C protein synthesis in infected cells. Deletion of the PAUG codon had little effect on the synthesis of C protein in thissystem. This implies that C protein mRNA AUG codon strength isindependent of the presence of the upstream P gene AUG codon andfurther implies that altering the P mRNA Kozak element would havelittle if any effect on C protein synthesis. This conclusion,however, may be worth reexamining in an alternative system sincethe P gene cDNA was fused to the adenovirus major late transcriptionunit tripartite leader sequence. These adenovirus sequences functionas a cis-acting translational control element in adenovirus-infectedcells (42) and may negate some of the intrinsic cis-acting elementsfound in the measles virus P mRNA. Clarification of possible interplaybetween the P and C mRNA AUG codons may best emerge from studyof appropriately designed recombinantMVs.

Further evidence linking translation and attenuation may be found by examining the F gene. MV has maintained the 1-kb intergenicregion between the M and F genes that in part specifies a longuntranslated 5' end for the F mRNA (Fig. 1 and 4). This untranslatedsequence is dispensable for recombinant virus growth in a Verocell culture (36). However, it has been found to modulate translationand play a role in the selection of a predominant initiation codonfrom several closely positioned AUG sequences that are in framewith the F coding region (Fig. 1 and 4 and reference 5). Incomparing Edmonston strains, five base changes were detected inthe vaccine virus F gene mRNA untranslated 5' end (Fig. 4). Giventhat the F mRNA 5'-untranslated sequence functions as a cis-actingelement and that three base substitutions in this sequence werecommon to all vaccine strains, it seems likely that modificationof this sequence may have been favored for MV growth in semipermissivecell types. Whether the F mRNA untranslated region plays a rolein attenuation remains uncertain, but studies showing that recombinantvirus lacking most of this sequence replicates less efficientlyin human thymus-liver tissue transplanted in SCID mice (55)suggests that the untranslated region may play a role inpathogenicity.

Base substitutions and the control of mRNA synthesis and processing. The second category encompasses mutations with potential to influence viral mRNA synthesis, specifically mutations in GE/GSsignals and the leader TCR. One such base substitution occurredwithin the F/H intergenic GE/GS signal (Fig. 7A). This mutationwas found in Moraten and Schwarz, where an A-to-G transition occurredin the GE signal (nucleotide position 7243; Fig. 7A). The effectof this base substitution is not known as yet, but it may perturbnormal transcription termination and reinitiation at the F-H geneboundary, leading to altered expression of the downstream H gene.This phenomenon has been observed in some strains of RSV, PIV,and simian virus 5, where less-efficient GE signal variants causereduced transcription termination with overproduction of readthroughbicistronic transcripts at the expense of normal monocistronicmRNA synthesis of the downstream gene (3, 37, 47, 54)(D. A. Buonagurio, personal communication). Reduction in correctlyinitiated mRNA synthesis from the downstream gene, coupled withthe likelihood that the fused bicistronic transcripts are inadequatetemplates for translation of the gene distal to the 5' mRNA cap(24, 60), will restrict protein synthesis encoded by the downstreamgene. This effect could result in diminished H protein expressionif Moraten and Schwarz produce elevated levels of a F/H bicistronicmessage.

It also may be relevant to mention the mutation at position 42 in this context even though it is possible that the GE signallocated in the leader TCR may not function analogously to GE signalsfound in intergenic regions. The position 42 mutation was presentat the 3' boundary of the GE/GS signal consensus drawn in Fig.7A, raising the possibility that it may modify GE/GS signal function.This could be significant if transcription initiating at the genomic3' end must terminate and reinitiate to effectively transcribean N mRNA and the position 42 mutation alters termination or reinitiationfunction. Whether a termination and reinitiation mechanism appliesto mRNA synthesis initiated from the MV leader TCR is uncertaingiven the failure to detect abundant small leader RNA productsin infected cells that would be indicative of termination priorto the N gene GS signal (4, 8). However, it is worth notingthat attempts to detect the small leader RNA in infected cellshave relied on infection with laboratory-adapted Edmonston strainsthat have vaccine leadermutations.

If the base 42 substitution negatively affects termination efficiency, greater accumulation of leader-N mRNA fusions willresult. These readthrough transcripts introduce an AUG sequenceupstream of the authentic N gene initiation codon, potentiallyreducing N protein expression. In addition, leader sequences attachedto N mRNA should serve as substrates for interaction with N protein.Encapsidation of leader-N gene fusion mRNAs should render themunavailable for translation. Given these considerations, the position42 base substitution could reduce the level of N protein synthesisin all vaccine viruses by altering GEfunction.

mRNA levels also may be influenced by promoter strength of the leader TCR. As noted above, three base changes were observedin this region of the vaccine viruses. One was a C-to-U transitionthat was unique to Zagreb at nucleotide position 96 (Fig. 2B).The other two mutations were at positions 26 and 42. The position26 and 42 pyrimidine-to-purine transversions were conserved inall vaccine strains. Alignment of leader TCR mutations to previouslydescribed sequence motifs (Fig. 1, 2, and 7B) showed that theposition 26 mutation was excluded from any currently describedmotifs while, as described earlier, the base change at 42 laywithin the boundaries of the GE/GS consensus sequence (Fig. 7A).The unique Zagreb mutation at position 96 (Fig. 7B) was presentwithin the boundaries of the B box (2, 8) and the overlappingG(N)5 motif (52).

The possibility that these leader TCR mutations affect mRNA synthesis is speculative but intriguing to consider further. Itis noteworthy that the leader TCR changes at 26 and 42 were locatedwithin a region that is not highly homologous to the trailer TCR(Fig. 8). Considering the functional similarity between the leaderand trailer TCRs, it seems reasonable to expect significant sequencehomology in regions that perform largely identical functions.Alignment of both TCRs shows, as described before (2, 8),that they share two regions of strong homology. One includes theterminal 16 bases, and the second encompasses the B and B' boxes.The fact that only the Zagreb mutation (position 96; Fig. 2 and6 to 8) fell within one of these homologous sequences (the B-boxregion) may indicate that these sequence elements are relativelyintolerant of nucleotide substitutions. Alternatively, it mayimply that virus passage in semipermissive cells favored changesin sequences that were unique to leader TCR. This may furtherimply that these leader TCR changes were favored because theymodulated a leader TCR-specific function such as the initiationof mRNA synthesis.

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FIG. 8. Alignment of the Edmonston wt leader (minus strand) and trailer (plus strand). The alignment illustrates the homology between the terminal 16 nucleotides at the 3' end of the leader and trailer, as well as the B-box regions. The motifs identified in the figure are described in the legend to Fig. 1. Vaccine virus leader TCR base changes are shown above the wt sequence, and vaccine trailer TCR changes are shown below.

That the position 26 and 42 base changes may primarily affect mRNA transcription function of the leader TCR is consistentwith the base 42 mutation localization to the leader TCR GE consensussequence boundary (Fig. 1A and 7). Moreover, it is possible thatthe region between nucleotides 17 and 42 performs a function uniqueto mRNA transcription initiation. Perhaps it acts as a polymerasepause site where the decision is made between genome synthesisand mRNA synthesis. It could also serve as a contact site thathas specificity for a modified polymerase complex that is usedfor mRNA synthesis. Both of these possibilities imply that replacingtwo pyrimidine residues at 26 and 42 with purines may affect theefficiency of mRNA transcription initiation by interrupting importantpolymerase contacts in the leader. These contacts could be perturbedif the substitutions replace important contact nucleotides orinduce a subtle change in phasing caused by substitution of pyrimidineswith bulkierpurines.

Leader and trailer TCR base substitutions and the control of genome replication. Base substitutions in the leader or trailer TCR could influence replication by altering the efficiency of genome-length RNAsynthesis. As described above, three base substitutions were foundin the leader TCR. While it was suggested that these mutationsmight act at the level of mRNA transcription, they may additionallyor alternatively have an impact on the initiation of antigenomesynthesis or modulate the pathway that controls the preferentialselection of antigenome or mRNA synthesis. In that context, theunique Zagreb mutation at position 96 present in the B box isinteresting because its location in a motif that is conservedin both the leader and trailer TCRs suggests that this homologoussequence domain regulates the replicationpathway.

Only two base changes were found in the trailer TCR, and these were specific to individual vaccine strains. Neither the AIK-Cmutation (position 15789) nor the Zagreb mutation (position 15843)lie within the 16-base conserved terminal promoter sequences orthe overlapping B box-G(N)5 domains. Although localized to thetrailer TCR, these base substitutions also fall into the categoryof mutations that modify untranslated regions of mRNAs. Both mutationsreside in the 3' noncoding region of the L mRNA. Were they toaffect the phenotype of these vaccine strains, it would likelybe through the changes in the L mRNA stability. Additionally,the Zagreb trailer TCR mutation is positioned at the GE/GS consensusregion (Fig. 8). Although it does not function as a GE/GS signalin the positive genome strand, this relative positioning couldindicate that this region makes contact with the polymerase complexbound at the trailer. It remains to be determined if this Zagrebmutation affects the replicative function of thetrailer.

Beyond their putative capacity to influence transcription and replication, the mutations in leader and trailer TCRs can theoreticallyaffect encapsidation efficiency. During genome synthesis, thefirst sequences that become accessible for encapsidation are theleader and trailer, suggesting that nucleation sites mediate encapsidationwithin these regions. Thus, base substitutions in the leader ortrailer could affect the interaction of N protein with nascentgenomes. This seems a less likely scenario given studies withvesicular stomatitis virus delimiting the encapsidation signalto the terminal 14 bases (41), a region that was unaffectedby base substitutions amongst the Edmonston MVstrains.

Contribution to attenuation. Not all of the vaccine virus noncoding region base changes are expected to have equivalent impact on replication or gene expressionand the levels of attenuation. The base changes found in the Pand M mRNAs, within the Kozak consensus sequence, might affectprotein expression either positively or negatively. The alterationin the M mRNA AUG context could influence virion maturation andpossibly gene expression (16, 49, 59) if the levels of Mprotein synthesis are altered. The case of the P initiation codonis particularly interesting because changes in the AUG codon strengthcould affect the translation of P (and V) as well as the translationof C protein from the downstream AUG. Regulation of P, V, andC mRNA translation as a means of achieving attenuation is particularlyattractive because each of the P gene-encoded proteins, and theirbalance, likely play a central role in controlling genome replicationand mRNA transcription (16, 19, 41). Given these multipleand vital functions, even small changes in the relative concentrationsof P, V, and C proteins in the infected cells could significantlyinfluence viral replication in the infected host (12, 31,34, 53, 55).

Base changes in the untranslated leader of the F gene also may contribute to the attenuated phenotype. Expression of F proteinis essential for cell fusion and effective cell-to-cell spreadof MV (16, 59), and it has been demonstrated that the F gene5'-untranslated region plays a role in determining translationefficiency and AUG codon selection (5). The fact that threemutations were common to all vaccine F gene mRNAs implies thatpassage in semipermissive cells selected for alteration in thiscis-acting element. The most obvious advantage accrued by basesubstitutions in this region is their ability to alter the levelsof F protein expression levels, perhaps through changes in thehigher-order structure of the mRNA 5' end. Perturbation of thisfunction may also be responsible for the reduced viral titersobserved in the human thymus-liver tissue-SCID mouse model system(55) when the thymic implants are infected with a recombinantEdmonston B strains that lacks much of the sequence for the FmRNA 5'-untranslatedregion.

Base changes in the leader TCR also are likely attenuation candidates. It was proposed above that the position 26 and 42 pyrimidine-to-purinetransversions may influence gene expression by changing the interactionbetween the promoter and the viral polymerase. In this scenario,base substitutions disturbing normal levels of mRNA transcriptioncertainly might contribute to an attenuated phenotype. It is alsonoteworthy that amino acid coding changes were identified in vaccinevirus genes for the polymerase complex proteins (P and L) andaccessory proteins (C and V) (33). Possibly, the vaccine virusbase changes in the leader TCR and the amino acid changes in proteincomponents of the gene expression apparatus have evolved togetherto optimize expression in semipermissive cells such as chickenfibroblasts. A by-product of these changes is that upon infectionof the human host this adapted form of the transcriptional apparatusis less efficient and leads to an attenuatedphenotype.

Finally, these comparative analyses included comparison of highly related vaccine viruses that differ in attenuation level.Optimally attenuated Moraten and Schwarz were found to containidentical noncoding region sequences, and these sequences differedfrom the underattenuated Rubeovax strain by only five nucleotides(Fig. 6, nucleotides highlighted with a dashed box). Two of thesedifferences were substitutions unique to Rubeovax, and these wereboth T-to-C transitions (mRNA sense) in the M/F intergenic region.One of these base substitutions was present in the M gene mRNA3'-untranslated sequence, and the other was present in the F genemRNA 5'-untranslated region. These mutations could affect expressionby changing mRNA stability or efficiency of translation. The thirdbase that distinguished Rubeovax from Moraten and Schwarz wasfound in the 3'-untranslated region of the N mRNA. In this case,Rubeovax contained a wt nucleotide compared to the base changecontained in the other two vaccines. Again, if this base contributesto a difference in attenuation levels it would probably be theresult of altered mRNA stability. The final two bases that distinguishRubeovax from Moraten and Schwarz have somewhat more compellinglinks to attenuation. These two substitutions in Moraten and Schwarzremained wt in Rubeovax. They altered a base in the M mRNA Kozakconsensus sequence at position 3431 and a base in the F gene GEsignal at position 7243. As mentioned earlier, the base changein the M gene could influence translation of M protein resultingin altered virion maturation (59) and possibly transcriptionregulation (49). The F GE signal mutation may similarly downregulateexpression of the downstream H gene if it compromises transcriptiontermination or subsequent reinitiation. One or more of these fivefeatures may be responsible for subtle differences between Moratenand Schwarz and the underattenuated Rubeovax strain that helpsaccount for the difference in attenuationlevels.

	ACKNOWLEDGMENTS

C.L.P. and R.A.L. contributed equally to thiswork.

We thank William Bellini and Paul Rota (Centers for Disease Control) for providing MV vaccine strains. We also thank JudyBeeler (Center for Biologics Evaluation and Research, FDA) forproviding a low-passage wt virus. We also appreciate Martin Billeter'scareful review of themanuscript.

The initial stages of these studies were supported by NIH grant AI35286 to S.A.U.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Viral Vaccine Research, Wyeth-Lederle Vaccines, 401 North MiddletownRd., Pearl River, NY 10965-1299. Phone: (845) 732-5450. Fax: (845)732-5727. E-mail: udems{at}war.wyeth.com.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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Tahara, M., Takeda, M., Yanagi, Y. (2005). Contributions of Matrix and Large Protein Genes of the Measles Virus Edmonston Strain to Growth in Cultured Cells as Revealed by Recombinant Viruses. J. Virol. 79: 15218-15225 [Abstract] [Full Text]
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Ayata, M., Komase, K., Shingai, M., Matsunaga, I., Katayama, Y., Ogura, H. (2002). Mutations Affecting Transcriptional Termination in the P Gene End of Subacute Sclerosing Panencephalitis Viruses. J. Virol. 76: 13062-13068 [Abstract] [Full Text]
Bankamp, B., Kearney, S. P., Liu, X., Bellini, W. J., Rota, P. A. (2002). Activity of Polymerase Proteins of Vaccine and Wild-Type Measles Virus Strains in a Minigenome Replication Assay. J. Virol. 76: 7073-7081 [Abstract] [Full Text]
Parks, C. L., Lerch, R. A., Walpita, P., Wang, H.-P., Sidhu, M. S., Udem, S. A. (2001). Comparison of Predicted Amino Acid Sequences of Measles Virus Strains in the Edmonston Vaccine Lineage. J. Virol. 75: 910-920 [Abstract] [Full Text]

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