A chimeric human-bovine parainfluenza virus type 3 expressing measles virus hemagglutinin is attenuated for replication but is still immunogenic in rhesus monkeys.

The chimeric recombinant virus rHPIV3-N(B), a version of human parainfluenza virus type 3 (HPIV3) that is attenuated due to the presence of the bovine PIV3 nucleocapsid (N) protein open reading frame (ORF) in place of the HPIV3 ORF, was modified to encode the measles virus hemagglutinin (HA) inserted as an additional, supernumerary gene between the HPIV3 P and M genes. This recombinant, designated rHPIV3-N(B)HA, replicated like its attenuated rHPIV3-N(B) parent virus in vitro and in the upper and lower respiratory tracts of rhesus monkeys, indicating that the insertion of the measles virus HA did not further attenuate rHPIV3-N(B) in vitro or in vivo. Monkeys immunized with rHPIV3-N(B)HA developed a vigorous immune response to both measles virus and HPIV3, with serum antibody titers to both measles virus (neutralizing antibody) and HPIV3 (hemagglutination inhibiting antibody) of over 1:500. An attenuated HPIV3 expressing a major protective antigen of measles virus provides a method for immunization against measles by the intranasal route, a route that has been shown with HPIV3 and respiratory syncytial virus vaccines to be relatively refractory to the neutralizing and immunosuppressive effects of maternally derived virus-specific serum antibodies. It should now be possible to induce a protective immune response against measles virus in 6-month-old infants, an age group that in developing areas of the world is not responsive to the current measles virus vaccine.

Construction of a live-attenuated bivalent vaccine virus against human parainfluenza virus (PIV) types 1 and 2 using a recombinant PIV3 backbone.

PIV1 and PIV2 are important agents of pediatric respiratory tract disease. We are developing live-attenuated vaccines against these viruses. We earlier constructed a PIV3/PIV1 antigenic chimeric virus, designated rPIV3-1, in which the hemagglutinin-neuraminidase (HN) and fusion (F) proteins of wild type rPIV3 were replaced by their PIV1 counterparts. In the present study, rPIV3-1 was used as a vector to express the HN protein of PIV2 to generate a single virus capable of inducing immunity to both PIV1 and PIV2. The PIV2 HN open reading frame was expressed from an extra gene cassette, under the control of PIV3 cis-acting transcription signals, inserted between the F and HN genes of rPIV3-1. The recombinant derivative, designated rPIV3-1.2HN, was readily recovered and exhibited a level of temperature sensitivity and in vitro growth similar to that of its parental virus. The rPIV3-1.2HN virus was restricted in replication in both the upper and lower respiratory tracts of hamsters compared with rPIV3-1, identifying an attenuating effect of the PIV2 HN insert in hamsters. rPIV3-1.2HN elicited serum antibodies to both PIV1 and PIV2 and induced resistance against challenge with wild type PIV1 or PIV2. Thus, rPIV3-1.2HN, a virus attenuated solely by the insertion of the PIV2 HN gene, functioned as a live attenuated bivalent vaccine candidate against both PIV1 and PIV2.

Comparison of identical temperature-sensitive mutations in the L polymerase proteins of sendai and parainfluenza3 viruses.

The L subunit of the RNA-dependent RNA polymerase of negative strand RNA viruses is believed to possess all the enzymatic activities necessary for viral transcription and replication. Mutations in the L proteins of human parainfluenza virus type 3 (PIV3) and vesicular stomatitis virus (VSV) have been shown to confer temperature sensitivity to the viruses; however, their specific defects have not been determined. Mutant PIV3 L proteins expressed from plasmids were tested for temperature sensitivity in transcription and replication in a minigenome reporter system in cells and for in vitro transcription from purified PIV3 template. The single L mutants, Y942H and L992F, were temperature sensitive (ts) in both assays, although viral RNA synthesis was not completely abolished at the nonpermissive temperature. Surprisingly, the T1558I L mutant was not ts, although its cognate virus was ts. Thus the ts defect in this virus may be due to the abrogation of an essential interaction of the mutant polymerase with a host cell component, which is not measured by the RNA synthesis assays. Most of the combinations of the PIV3 L mutations were not additive and did not show temperature sensitivity in in vitro transcription. Since they were ts in the minigenome assay in vivo, replication appears to be specifically defective. The ts mutations in PIV3 and VSV L proteins were also substituted into the Sendai L protein to compare the defects in related systems. Only Sendai Y942H L was ts in both transcription and replication. One Sendai L mutant, L992F, gave much better replication than transcription. Several other mutants could transcribe but not replicate in vitro, while replication in vivo was normal.

Bovine parainfluenza virus type 3 (BPIV3) fusion and hemagglutinin-neuraminidase glycoproteins make an important contribution to the restricted replication of BPIV3 in primates.

This study examines the contribution of the fusion (F) and hemagglutinin-neuraminidase (HN) glycoprotein genes of bovine parainfluenza virus type 3 (BPIV3) to its restricted replication in the respiratory tract of nonhuman primates. A chimeric recombinant human parainfluenza type 3 virus (HPIV3) containing BPIV3 F and HN glycoprotein genes in place of its own and the reciprocal recombinant consisting of BPIV3 bearing the HPIV3 F and HN genes (rBPIV3-F(H)HN(H)) were generated to assess the effect of glycoprotein substitution on replication of HPIV3 and BPIV3 in the upper and lower respiratory tract of rhesus monkeys. The chimeric viruses were readily recovered and replicated in simian LLC-MK2 cells to a level comparable to that of their parental viruses, suggesting that the heterologous glycoproteins were compatible with the PIV3 internal proteins. HPIV3 bearing the BPIV3 F and HN genes was restricted in replication in rhesus monkeys to a level similar to that of its BPIV3 parent virus, indicating that the glycoprotein genes of BPIV3 are major determinants of its host range restriction of replication in rhesus monkeys. rBPIV3-F(H)HN(H) replicated in rhesus monkeys to a level intermediate between that of HPIV3 and BPIV3. This observation indicates that the F and HN genes make a significant contribution to the overall attenuation of BPIV3 for rhesus monkeys. Furthermore, it shows that BPIV3 sequences outside the F and HN region also contribute to the attenuation phenotype in primates, a finding consistent with the previous demonstration that the nucleoprotein coding sequence of BPIV3 is a determinant of its attenuation for primates. Despite its restricted replication in the respiratory tract of rhesus monkeys, rBPIV3-F(H)HN(H) conferred a level of protection against challenge with HPIV3 that was indistinguishable from that induced by previous infection with wild-type HPIV3. The usefulness of rBPIV3-F(H)HN(H) as a vaccine candidate against HPIV3 and as a vector for other viral antigens is discussed.

Human parainfluenza virus type 3 (PIV3) expressing the hemagglutinin protein of measles virus provides a potential method for immunization against measles virus and PIV3 in early infancy.

Recombinant human parainfluenza virus type 3 (PIV3) was used as a vector to express the major protective antigen of measles virus, the hemagglutinin (HA) glycoprotein, in order to create a bivalent PIV3-measles virus that can be administered intranasally. The measles virus HA open reading frame (ORF) was inserted as an additional transcriptional unit into the N-P, P-M, or HA-neuraminidase (HN)-L gene junction of wild-type PIV3 or into the N-P or P-M gene junction of an attenuated derivative of PIV3, termed rcp45L. The recombinant PIV3 (rPIV3) viruses bearing the HA inserts replicated more slowly in vitro than their parental viruses but reached comparable peak titers of >/=10(7.5) 50% tissue culture infective doses per ml. Each of the wild-type or cold-passaged 45L (cp45L) PIV3(HA) chimeric viruses replicated 5- to 10-fold less well than its respective parent virus in the upper respiratory tract of hamsters. Thus, insertion of the approximately 2-kb ORF itself conferred attenuation, and this attenuation was additive to that conferred by the cp45L mutations. The attenuated cp45L PIV3(HA) recombinants induced a high level of resistance to replication of PIV3 challenge virus in hamsters and induced very high levels of measles virus neutralizing antibodies (>1:8,000) that are well in excess of those known to be protective in humans. rPIV3s expressing the HA gene in the N-P or P-M junction induced about 400-fold more measles virus-neutralizing antibody than did the rPIV3 with the HA gene in the HN-L junction, indicating that the N-P or P-M junction appears to be the preferred insertion site. Previous studies indicated that the PIV3 cp45 virus, a more attenuated version of rcp45L, replicates efficiently in the respiratory tract of monkeys and is immunogenic and protective even when administered in the presence of very high titers of passively transferred PIV3 antibodies (A. P. Durbin, C. J. Cho, W. R. Elkins, L. S. Wyatt, B. Moss, and B. R. Murphy, J. Infect. Dis. 179:1345-1351, 1999). This suggests that this intranasally administered PIV3(HA) chimeric virus can be used to immunize infants with maternally acquired measles virus antibodies in whom the current parenterally administered live measles virus vaccine is ineffective.

Replacement of the ectodomains of the hemagglutinin-neuraminidase and fusion glycoproteins of recombinant parainfluenza virus type 3 (PIV3) with their counterparts from PIV2 yields attenuated PIV2 vaccine candidates.

We sought to develop a live attenuated parainfluenza virus type 2 (PIV2) vaccine strain for use in infants and young children, using reverse genetic techniques that previously were used to rapidly produce a live attenuated PIV1 vaccine candidate. The PIV1 vaccine candidate, designated rPIV3-1cp45, was generated by substituting the full-length HN and F proteins of PIV1 for those of PIV3 in the attenuated cp45 PIV3 vaccine candidate (T. Tao et al., J. Virol. 72:2955-2961, 1998; M. H. Skiadopoulos et al., Vaccine 18:503-510, 1999). However, using the same strategy, we failed to recover recombinant chimeric PIV3-PIV2 isolate carrying the full-length PIV2 glycoproteins in a wild-type PIV3 backbone. Viable PIV3-PIV2 chimeras were recovered when chimeric HN and F open reading frames (ORFs) rather than complete PIV2 F and HN ORFs were used to construct the full-length cDNA. The recovered viruses, designated rPIV3-2CT, in which the PIV2 ectodomain and transmembrane domain were fused to the PIV3 cytoplasmic domain, and rPIV3-2TM, in which the PIV2 ectodomain was fused to the PIV3 transmembrane and cytoplasmic tail domain, possessed similar in vitro and in vivo phenotypes. Thus, it appeared that only the cytoplasmic tail of the HN or F glycoprotein of PIV3 was required for successful recovery of PIV3-PIV2 chimeras. Although rPIV3-2CT and rPIV3-2TM replicated efficiently in vitro, they were moderately to highly attenuated for replication in the respiratory tracts of hamsters, African green monkeys (AGMs), and chimpanzees. This unexpected finding indicated that chimerization of the HN and F proteins of PIV2 and PIV3 itself specified an attenuation phenotype in vivo. Despite this attenuation, these viruses were highly immunogenic and protective against challenge with wild-type PIV2 in hamsters and AGMs, and they represent promising candidates for clinical evaluation as a vaccine against PIV2. These chimeric viruses were further attenuated by the addition of 12 mutations of PIV3cp45 which lie outside of the HN and F genes. The attenuating effects of these mutations were additive with that of the chimerization, and thus inclusion of all or some of the cp45 mutations provides a means to further attenuate the PIV3-PIV2 chimeric vaccine candidates if necessary.

Sequence determination and molecular analysis of two strains of bovine parainfluenza virus type 3 that are attenuated for primates.

The Kansas/15626/84 (Ka) and Shipping Fever (SF) strains of bovine parainfluenza virus type 3 (BPIV3) replicate less efficiently than human PIV3 (HPIV3) in the upper and lower respiratory tract of rhesus monkeys, and BPIV3 Ka is also highly attenuated in humans and is in clinical trials as a candidate vaccine against HPIV3. To initiate an investigation of the genetic basis of the observed attenuation phenotype of BPIV3 in primates, the complete genomic sequences of Ka and SF genomes were determined and compared to those of BPIV3 strain 910N and two HPIV3 strains, JS and Wash/47885/57. There is a high degree of identity between the five PIV3 viruses in their 55 nucleotide (nt) leader (83.6%) and 44 nt trailer (93.2%) sequences. The five viruses display amino acid sequence identity ranging from 58.6% for the phosphoprotein to 89.7% for the matrix protein. Interestingly, the majority of amino acid residues found to be variable at a given position in a five-way protein alignment are nonetheless identical within the viruses of either host species (BPIV3 or HPIV3). These host-specific residues might be products of distinct selective pressures on BPIV3 and HPIV3 during evolution in their respective hosts. These host-specific sequences likely include ones which are responsible for the host range differences, such as the efficient growth of BPIV3 in bovines compared to its restricted growth in primates. It should now be possible using the techniques of reverse genetics to import sequences from BPIV3 into HPIV3 and identify those nt or protein sequences which attenuate HPIV3 for primates. This information should be useful in understanding virus-host interactions and in the development of vaccines to protect against HPIV3-induced disease.

Long nucleotide insertions between the HN and L protein coding regions of human parainfluenza virus type 3 yield viruses with temperature-sensitive and attenuation phenotypes.

Recombinant parainfluenza virus 3 (rPIV3) is being developed as a vector to express foreign genes as a bivalent or multivalent live attenuated virus vaccine. In the present study, we examined the effect of inserted foreign sequence on virus replication in vitro and in vivo, focusing on the parameter of insert length. In one type of construct, foreign sequence of increasing length was flanked by PIV3 transcription signals and inserted as an additional gene unit (GU insert) between the HN and L genes, so that one additional mRNA would be made. In a second type of construct, foreign sequence was inserted into the downstream NCR (NCR insert) of the HN gene, so that the number of encoded mRNAs remained unchanged. In each case, the foreign sequence was designed to lack any significant open reading frame, which permitted an evaluation of the effect of insert length on replication independent of an effect of an expressed protein. The GU or NCR insert sizes ranged from 168 nucleotides (nt) to 3918 nt. rPIV3s containing GU insertions of up to 3918 nt in length, the largest size tested, were viable and replicated efficiently at permissive temperatures in vitro, but a reduction in plaque size was seen at 39 degrees C and 40 degrees C. The rPIV3 with a 3918-nt GU insertion was restricted in replication in the upper (fivefold) and lower (25-fold) respiratory tracts of hamsters. Although a 1908-nt GU insertion did not significantly modify replication of wild-type PIV3 in vitro or in vivo, its introduction significantly augmented the level of temperature sensitivity (ts) and attenuation (att) specified by three mutations in the L protein of a cold-passaged attenuated PIV3 vaccine virus. rPIV3s bearing a 3126- or 3894-nt NCR insertion exhibited in vitro and in vivo phenotypes like those of the rPIV3s bearing similar-sized GU insertions. These findings indicate that rPIV3s whose genome length has been increased by more than 3000 nt by either a GU or an NCR insertion exhibit an unexpected host-range phenotype, that is, efficient replication in vitro but restricted replication in hamsters, especially in the lower respiratory tract. Furthermore, these effects were greatly enhanced when the rPIV3 backbone contained other ts or att mutations. The implications of these findings for the use of single-stranded, negative-sense RNA viruses as vectors for vaccines are discussed.

A live attenuated recombinant chimeric parainfluenza virus (PIV) candidate vaccine containing the hemagglutinin-neuraminidase and fusion glycoproteins of PIV1 and the remaining proteins from PIV3 induces resistance to PIV1 even in animals immune to PIV3.

Using a reverse genetics system for PIV3, we previously recovered recombinant chimeric PIV3-PIV1 virus bearing the major protective antigens of PIV1, the hemaglutinin-neuraminidase and fusion proteins, on a background of PIV3 genes bearing temperature sensitive (ts) and attenuating mutations in the L gene. Immunization of hamsters with this virus, designated rPIV3-1.cp45L, induced a high level of resistance to replication of wild type (wt) PIV1 and, surprisingly, also induced a moderate amount of restriction of the replication of PIV3 challenge virus. This suggested that some immunity is conferred by the internal PIV3 proteins shared by the two viruses. In the present study, we found that the immunity to PIV3 conferred by infection with rPIV3-1.cp45L is short-lived and completely disappeared four months after immunization, whereas resistance to replication of PIV3 induced by prior infection with PIV3 remains high even after an interval of four months. Since a live attenuated PIV1 vaccine such as the chimeric rPIV3-1.cp45L virus will likely be given to infants after a live attenuated PIV3 vaccine in a sequential immunization schedule, we examined the immunogenicity and efficacy of rPIV3-1.cp45L against PIV1 challenge in animals with and without prior immunity to PIV3. rPIV3-1.cp45L efficiently infected hamsters previously infected with wt or attenuated PIV3, but there was approximately a five-fold reduction in replication of rPIV3-1. cp45L virus in the PIV3-immune animals. This reduction in replication of rPIV3-1.cp45L in PIV3-immune animals was accompanied by a significant decrease in efficacy against PIV1 challenge. However, rPIV3-1.cp45L immunization of PIV3-immune animals induced a vigorous serum antibody response to PIV1 and reduced replication of PIV1 challenge virus 1000-fold in the lower respiratory tract and 25 to 200-fold in the upper respiratory tract. This study demonstrated that the recombinant chimeric rPIV3-1.cp45L candidate vaccine can induce immunity to PIV1 even in animals immune to PIV3. This establishes the feasibility of employing a sequential immunization schedule in which a recombinant chimeric rPIV3-1.cp45L vaccine is given following a live attenuated PIV3 vaccine.

Generation of a parainfluenza virus type 1 vaccine candidate by replacing the HN and F glycoproteins of the live-attenuated PIV3 cp45 vaccine virus with their PIV1 counterparts.

Parainfluenza virus type 1 (PIV1) is a major cause of croup in infants and young children, and a vaccine is needed to prevent the serious disease caused by this virus. In the present study, a live attenuated PIV1 vaccine candidate was generated by modification of the extensively-studied PIV3 cold-passaged (cp) cp45 vaccine candidate using the techniques of reverse genetics. The HN and F glycoproteins of the PIV3 cp45 candidate vaccine virus were replaced with those of PIV1. This created a live attenuated PIV1 vaccine candidate, termed rPIV3-1 cp45, which contained the attenuated background of the PIV3 cp45 vaccine virus together with the HN and F protective antigens of PIV1. Three of the 15 mutations of cp45 lie within the HN and F genes, and those in the F gene are attenuating. Thus, some attenuation might be lost by the HN and F glycoprotein replacement. To address this issue we also constructed a derivative of PIV3 cp45, designated rPIV3 cp45 (F(wt)HN(wt)), that possessed wild type PIV3 HN and F glycoproteins but retained the 12 other cp45 mutations. rPIV3 cp45 (F(wt)HN(wt)) replicated in the respiratory tract of hamsters to a level three- to four-fold higher than rPIV3 cp45, indicating that loss of the two attenuating mutations in the cp45 F gene effected a slight reduction in the overall attenuation of cp45 for hamsters. However, the chimeric rPIV3-1 cp45 virus was about 5-fold more restricted in replication in hamsters than rPIV3 cp45 and about 15- to 20-fold more restricted than rPIV3 cp45 (F(wt)HN(wt)). This suggests that two components contribute to the attenuation of the new chimeric rPIV3-1 cp45 PIV1 vaccine candidate: one being the 12 cp45 mutations, which provide most of the observed attenuation, and the other resulting from the introduction of the heterologous PIV1 HN and F proteins into PIV3 (i.e., a chimerization effect). rPIV3-1 cp45 was observed to be immunogenic and protective against challenge with wild type PIV1 in hamsters. This virus shows sufficient promise that it should be evaluated further as a candidate live attenuated vaccine strain for preventing severe lower respiratory tract PIV1 disease in infants and young children.

Attenuation of the recombinant human parainfluenza virus type 3 cp45 candidate vaccine virus is augmented by importation of the respiratory syncytial virus cpts530 L polymerase mutation.

A phenylalanine to leucine mutation at position 521 in the L polymerase of cpts530, a live-attenuated respiratory syncytial virus (RSV) cold-passaged (cp), temperature-sensitive (ts) candidate vaccine, specifies the ts and attenuation (att) phenotypes. Sequence alignment of this region in the L proteins of several distantly related paramyxoviruses revealed that this phenylalanine is conserved. Using reverse genetics, the analogous phenylalanine at position 456 in the L protein of wild-type PIV3 was mutagenized to leucine (F456L). The resulting virus, designated r456(L), was ts (40 degrees C shut-off temperature of plaque formation), and its replication in the upper, but not the lower, respiratory tract of hamsters was 10-fold reduced compared with that of the recombinant wild-type PIV3 (rwt). Thus the phenylalanine to leucine mutation specified a similar level of temperature sensitivity and attenuation in two distantly related paramyxoviruses. We next sought to determine whether the addition of this mutation to the L protein of two rPIV3 candidate vaccine viruses, one bearing the three cp45 ts missense mutations in the L protein (rcp45(L)) and the other bearing all 15 cp45 mutations (rcp45), would further attenuate the viruses in vivo. Each rcp45 derivative to which the F456L mutation was added exhibited an increased level of temperature sensitivity. Furthermore rcp45(L)-456 and rcp45-456 were 100- to 1000-fold more restricted in replication in hamsters than their rcp45(L) and rcp45 parents. Despite the high level of restriction of replication in hamsters, immunization with rcp45-456 induced a moderate level of resistance to replication of PIV3 challenge virus. In contrast to the highly restricted replication observed in hamsters, rcp45-456 was only fivefold more restricted in the respiratory tract of chimpanzees than rcp45 and induced a comparable, moderate to high level of PIV3-specific serum antibodies. rcp45 and rcp45-456 viruses isolated from chimpanzees throughout the 2-week course of replication maintained the level of temperature sensitivity of their respective input viruses, illustrating their phenotypic stability. Thus the acquisition of the F456L mutation by the cp45 virus resulted in a small, incremental increase in its level of attenuation, indicating its possible usefulness in the fine tuning of the level of attenuation of the cp45 vaccine candidate. The ability to transfer mutations identified in heterologous paramyxoviruses, which in this case represent different subfamilies, greatly enhances our ability to rapidly develop novel parainfluenza virus candidate vaccines.

A live attenuated chimeric recombinant parainfluenza virus (PIV) encoding the internal proteins of PIV type 3 and the surface glycoproteins of PIV type 1 induces complete resistance to PIV1 challenge and partial resistance to PIV3 challenge.

The recovery of wild type and attenuated human parainfluenza type 3 (PIV3) recombinant viruses has made possible a new strategy to rapidly generate a live-attenuated vaccine virus fof PIV1. We previously replaced the coding sequences for the hemagglutinin-neuraminidase (HN) and fusion (F) proteins of PIV3 with those of PIV1 in the PIV3 antigenomic cDNA. This was used to recover a fully-viable, recombinant chimeric PIV3-PIV1 virus, termed rPIV3-1, which bears the major protective antigens of PIV1 and is wild type-like with regard to growth in cell culture and in hamsters [Tao T, Durbin AP, Whitehead SS, Davoodi F, Collins PL, Murphy BR. Recovery of a fully viable chimeric human parainfluenza virus (PIV) type 3 in which the hemagglutinin-neuraminidase and fusion glycoprotein have been replaced by those of PIV type 1. J Virol 1998;72:2955-2961]. Here we report the recovery of a derivative of rPIV3-1 carrying the three temperature-sensitive and attenuating amino acid coding changes found in the L gene of the live-attenuated cp45 PIV3 candidate vaccine virus. This virus, termed rPIV3-1.cp45L, is temperature-sensitive with a shut-off temperature of 38 degrees C, which is similar to that of the recombinant rPIV3cp45L, which possesses the same three mutations. rPIV3-1.cp45L is attenuated in the respiratory tract of hamsters to the same extent as rPIV3cp45L. Infection of hamsters with rPIV3-1.cp45L generated a moderate level of hemagglutination-inhibiting antibodies against wild type PIV1 and induced complete resistance to challenge with wild type PIV1. This demonstrates that this novel attenuated chimeric virus is capable of inducing a highly effective immune response against PIV1. It confirms previous observations that the surface glycoproteins of parainfluenza viruses are sufficient to induce a high level of resistance to homologous virus challenge. Unexpectedly, infection with recombinant chimeric virus rPIV3-1.cp45L or rPIV3-1, each bearing the surface glycoprotein genes of PIV1 and the internal genes of PIV3, also induced a moderate level of resistance to replication of wild type PIV3 challenge virus. This indicates that the internal genes of PIV3 can independently induce protective immunity against PIV3 in rodents, albeit a lower level of resistance than that induced by the surface glycoproteins. Thus, a reverse genetics system for PIV3 has been used successfully to produce a live attenuated PIV1 vaccine candidate that is attenuated and protective in experimental infection in hamsters.

Identification of mutations contributing to the temperature-sensitive, cold-adapted, and attenuation phenotypes of the live-attenuated cold-passage 45 (cp45) human parainfluenza virus 3 candidate vaccine.

The live-attenuated human parainfluenza virus 3 (PIV3) cold-passage 45 (cp45) candidate vaccine was shown previously to be safe, immunogenic, and phenotypically stable in seronegative human infants. Previous findings indicated that each of the three amino acid substitutions in the L polymerase protein of cp45 independently confers the temperature-sensitive (ts) and attenuation (att) phenotypes but not the cold-adaptation (ca) phenotype (29). cp45 contains 12 additional potentially important point mutations in other proteins (N, C, M, F, and hemagglutinin-neuraminidase [HN]) or in cis-acting sequences (the leader region and the transcription gene start [GS] signal of the N gene), and their contribution to these phenotypes was undefined. To further characterize the genetic basis for the ts, ca, and att phenotypes of this promising vaccine candidate, we constructed, using a reverse genetics system, a recombinant cp45 virus that contained all 15 cp45-specific mutations mentioned above, and found that it was essentially indistinguishable from the biologically derived cp45 on the basis of plaque size, level of temperature sensitivity, cold adaptation, level of replication in the upper and lower respiratory tract of hamsters, and ability to protect hamsters from subsequent wild-type PIV3 challenge. We then constructed recombinant viruses containing the cp45 mutations in individual proteins as well as several combinations of mutations. Analysis of these recombinant viruses revealed that multiple cp45 mutations distributed throughout the genome contribute to the ts, ca, and att phenotypes. In addition to the mutations in the L gene, at least one other mutation in the 3' N region (i.e., including the leader, N GS, and N coding changes) contributes to the ts phenotype. A recombinant virus containing all the cp45 mutations except those in L was more ts than cp45, illustrating the complex nature of this phenotype. The ca phenotype of cp45 also is a complex composite phenotype, reflecting contributions of at least three separate genetic elements, namely, mutations within the 3' N region, the L protein, and the C-M-F-HN region. The att phenotype is a composite of both ts and non-ts mutations. Attenuating ts mutations are located in the L protein, and non-ts attenuating mutations are located in the C and F proteins. The presence of multiple ts and non-ts attenuating mutations in cp45 likely contributes to the high level of attenuation and phenotypic stability of this promising vaccine candidate.

Three amino acid substitutions in the L protein of the human parainfluenza virus type 3 cp45 live attenuated vaccine candidate contribute to its temperature-sensitive and attenuation phenotypes.

Studies were initiated to define the genetic basis of the temperature-sensitive (ts), cold adaptation (ca), and attenuation (att) phenotypes of the human parainfluenza virus type 3 (PIV3) cp45 live attenuated vaccine candidate. Genetic data had previously suggested that the L polymerase protein of cp45, which contains three amino acid substitutions at positions 942, 992, and 1558, contributed to its temperature sensitivity (R. Ray, M. S. Galinski, B. R. Heminway, K. Meyer, F. K. Newman, and R. B. Belshe, J. Virol. 70:580-584, 1996; A. Stokes, E. L. Tierney, C. M. Sarris, B. R. Murphy, and S. L. Hall, Virus Res. 30:43-52, 1993). To study the individual and aggregate contributions that these amino acid substitutions make to the ts, att, and ca phenotypes of cp45, seven PIV3 recombinant viruses (three single, three double, and one triple mutant) representing all possible combinations of the three amino acid substitutions were recovered from full-length antigenomic cDNA and analyzed for their ts, att, and ca phenotypes. None of the seven mutant recombinant PIVs was cold adapted. The substitutions at L protein amino acid positions 992 and 1558 each specified a 105-fold reduction in plaque formation in cell culture at 40 degrees C, whereas the substitution at position 942 specified a 300-fold reduction. Thus, each of the three mutations contributes individually to the ts phenotype. The triple recombinant which possesses an L protein with all three mutations was almost as temperature sensitive as cp45, indicating that these mutations are the major contributors to the ts phenotype of cp45. The three individual mutations in the L protein each contributed to restricted replication in the upper or lower respiratory tract of hamsters, and this likely contributes to the observed stability of the ts and att phenotypes of cp45 during replication in vivo. Importantly, the recombinant virus possessing L protein with all three mutations was as restricted in replication as was the cp45 mutant in both the upper and lower respiratory tracts of hamsters, indicating that the L gene of the cp45 virus is a major attenuating component of this candidate vaccine.

Bovine papillomavirus type 1 genomes and the E2 transactivator protein are closely associated with mitotic chromatin.

The bovine papillomavirus type 1 E2 transactivator protein is required for viral transcriptional regulation and DNA replication and may be important for long-term episomal maintenance of viral genomes within replicating cells (M. Piirsoo, E. Ustav, T. Mandel, A. Stenlund, and M. Ustav, EMBO J. 15:1-11, 1996). We have evidence that, in contrast to most other transcriptional transactivators, the E2 transactivator protein is associated with mitotic chromosomes in dividing cells. The shorter E2-TR and E8/E2 repressor proteins do not bind to mitotic chromatin, and the N-terminal transactivation domain of the E2 protein is necessary for the association. However, the DNA binding function of E2 is not required. We have found that bovine papillomavirus type 1 genomes are also associated with mitotic chromosomes, and we propose a model in which E2-bound viral genomes are transiently associated with cellular chromosomes during mitosis to ensure that viral genomes are segregated to daughter cells in approximately equal numbers.

The bovine papillomavirus type 1 E2 transactivator and repressor proteins use different nuclear localization signals.

The E2 gene of bovine papillomavirus type 1 encodes at least three nuclear phosphoproteins that regulate viral transcription and DNA replication. All three proteins have a common C-terminal domain that has DNA-binding and dimerization activities. A basic region in this domain forms an alpha helix which makes direct contact with the DNA target. In this study, it is shown that in addition to its role in DNA binding, this basic region functions as a nuclear localization signal both in the E2 DNA-binding domain and in a heterologous protein. Deletion of this signal sequence resulted in increased accumulation of the E2 transactivator and repressor proteins in the cytoplasm, but nuclear localization was not eliminated. In the full-length transactivator protein, another signal, present in the N-terminal transactivation domain, is used for transport to the nucleus, and the C-terminal nuclear localization signal(s) are masked. The use of different nuclear localization signals could potentially allow differential regulation of the subcellular localization of the E2 transactivator and repressor proteins at some stage in the viral life cycle.

Mutational analysis of conserved tyrosines in the NS-1 protein of the parvovirus minute virus of mice.

The NS-1 gene of the parvovirus minute virus of mice encodes a multifunctional protein essential for viral DNA replication and gene expression. In addition to possessing DNA helicase and ATPase activities, NS-1 forms a covalent linkage with the 5' ends of viral DNA and is a strong candidate for the site-specific nicking-closing enzyme postulated to be involved in the resolution of concatemers and terminal hairpin structures that arise during parvoviral DNA replication. Since the covalent linkage between NS-1 and the 5' terminus of MVM DNA resists alkali and mild acid treatment, a tyrosine phosphodiester is likely to be involved. To map domains responsible for this activity, mutations converting tyrosine to phenylalanine were introduced into the NS-1 gene using oligonucleotide-directed mutagenesis and their effect on the DNA replication and transcriptional activation functions of NS-1 was examined in transient in vivo transfection assays. Replacement of Tyr-188, Tyr-197, Tyr-210, Tyr-310, Tyr-422, or Tyr-550 with phenylalanine greatly reduced the ability of NS-1 to complement the replication of the target genome ins 20B in COS-7 cells. However, a Ser-545 to Thr-545 substitution in the Phe-550 mutant restored DNA replication activity. Replacement of 5 other tyrosines in NS-1 with phenylalanine either enhanced (Phe-6), had a moderate inhibitory effect (Phe-209) or had no effect (Phe-47, Phe 227 and Phe-543) on its DNA replication activity. Two of the 11 phenylalanine substitution mutations, Phe-188 and Phe-197, also greatly reduced the ability of NS-1 to transactivate the p38 promoter and displayed a dominant negative phenotype with respect to transactivation. Since the remaining tyrosines in MVM NS-1, Tyr-152, Tyr-252, Tyr-374, and Tyr-595, are not conserved among the NS-1 proteins encoded by porcine and feline parvoviruses, they are presumed to be nonessential for the normal functioning of NS-1. The results point to a role for either Tyr-188, Tyr-197, Tyr-210, Tyr-310, or Tyr-422 in forming a covalent linkage with viral DNA and further suggest a regulatory role for several tyrosines in other DNA replication and transcriptional activation functions of NS-1.

Characterization of linker insertion and point mutations in the NS-1 gene of minute virus of mice: effects on DNA replication and transcriptional activation functions of NS-1.

The NS-1 gene of minute virus of mice encodes a multifunctional protein required for replication of the viral genome and for transcriptional regulation of the two MVM promoters. To study the localization of activities required for DNA replication and transactivation of the capsid gene promoter, insertion and point mutations were introduced into the NS-1 gene. The mutant NS-1 genes were expressed in COS-7 cells by using an SV 40 promoter driven NS-1 expression vector. The ability of the mutant proteins to complement a replication defective NS-1 mutant of the infectious MVM plasmid pMM984 and to activate transcription from the capsid gene promoter in chloramphenicol acetyl transferase expression assays was determined. Two point mutations Ser-249 to Ala and Lys-250 to Gln and a one amino acid insertion between Asp-606 and Leu-607 had no effect on viral DNA replication and transactivation activities. Six independent insertions of between 2 and 12 amino acids inhibited the DNA replication activity of NS-1 between 20- and at least 100-fold. There was no apparent correlation between the extent of inhibition of parvoviral DNA replication and the location of the mutations. The transcriptional activation function of NS-1 was inhibited between 1.5- and at least 20-fold and was therefore overall relatively less sensitive to mutagenesis than was its DNA replication function. An exception to this was a 5 amino acid insertion between Tyr-543 and Gln-544 that abolished transactivation as well as the ability of NS-1 to complement viral DNA replication.

Use of deletion and point mutants spanning the coding region of the adenovirus 5 E1A gene to define a domain that is essential for transcriptional activation.

To help in identifying functional domains within Ad5 E1A proteins, we have constructed a series of mutants that create deletions throughout these products. We have also produced several mis-sense point mutations in the unique 13 S mRNA region. These mutated E1A regions have been tested in plasmid form for their ability to activate transcription of an E3-promoted CAT gene. From the results, a major domain for transactivation has been identified. This begins between residues 138 and 147, ends between residues 188 and 204, and encompasses the unique 13 S region. This domain is sensitive to mis-sense mutations. Transactivation was unaffected by small deletions in the N-terminal half of E1A proteins between residues 4 and 138, but was destroyed when this whole region was deleted. The C-terminal 71 residues may affect transactivation, but the results with the mutant in which this region was deleted were variable. The results obtained with these mutants are discussed in relation to the transactivation obtained by J. W. Lillie et al. [(1987). Cell 50, 1091-1100] with a synthetic peptide similar to the domain described here.