Viral Determinants of Rotavirus Pathogenicity in Pigs: Evidence that the Fourth Gene of a Porcine Rotavirus Confers Diarrhea in the Homologous Host

A porcine rotavirus (prv) monoreassortant, S-F4, which carries RNA segment 4 of the pig-pathogenic variant prv 4F in the genetic background of the pig-apathogenic variant prv 4S (G. I. Tauscher and U. Desselberger, J. Virol. 71:853–857, 1997), was found to be pathogenic in gnotobiotic piglets. This indicates that RNA segment 4 of the pig-pathogenic variant prv 4F is a major determinant of pathogenicity in its homologous host.     

Passive immunity modulates genetic reassortment between rotaviruses in mixedly infected mice.

Genetic reassortment between simian rotavirus SA11 and rhesus rotavirus (RRV) occurs with high frequency following mixed infection of nonimmune suckling mice (J. L. Gombold and R. F. Ramig, J. Virol. 57:110-116, 1986). We examined the effects of passively acquired homotypic or heterotypic immunity on reassortment in vivo. Passively immune suckling mice obtained from dams immune to either serotype 3 simian rotavirus (SA11) or serotype 6 bovine rotavirus (NCDV) were infected orally with either SA11 or RRV or a mixture of SA11 and RRV (both serotype 3 viruses). At various times postinfection, signs of disease were noted and the intestines of individual mice were removed and homogenized for titration of infectious virus and isolation of progeny plaques. Electrophoresis of genomic RNA was used to identify reassortants among the viral progeny isolated from infected animals. No reassortants (less than 0.45%) were detected among 224 clones examined from mixedly infected, homotypically immune mice. Twenty-nine reassortants (10.66%) were identified among 272 progeny clones from mixedly infected, heterotypically immune mice. Thus, reassortment was reduced more than 50-fold by homotypic immunity and approximately threefold by heterotypic immunity compared with prior data obtained from mixed infections of nonimmune mice. In addition, reassortment between SA11 and RRV in nonimmune mice was shown to be dependent on the virus dose. Taken together, these results suggest that immune responses may modulate the frequency of reassortment by reducing the effective multiplicity of infection (by neutralization or other immune mechanisms), thereby preventing efficient mixed infection of enterocytes.     

Identification of virus-coded nonstructural polypeptides in bunyavirus-infected cells.

Analyses of bunyavirus-infected cell extracts identified at least two virus-induced nonstructural polypeptides. With snowshoe hare (SSH), La Crosse (LAC), and six SSH-LAC reassortant viruses, it was shown that one of these nonstructural polypeptides (NSs, approximate molecular weight, 7.4 X 10(3)) is coded by the SSH small (S)-size viral RNA species. This nonstructural polypeptide was not detected (at least in the same relative abundancies) in LAC virus-infected cells or in cells infected with reassortants having LAC S RNA. For SSH virus, tryptic peptide analyses of either [3H]leucine- or [3H]arginine-labeled NSs indicated that it contains unique sequences not present in the SSH nucleocapsid (N) polypeptide (also coded by the S RNA; J. R. Gentsch and D. H. L. Bishop, J. Virol. 28:417-419, 1978). Analyses of SSH virus-infected cell extracts and extracts of cells infected with SSH-LAC reassortants having SSH medium (M)-size RNA species indicated that a nonstructural polypeptide (NSM; approximate molecular weight, 12 X 10(3)) is coded by the SSH M RNA species. In extracts of LAC virus-infected cells (or cells infected with SSH-LAC reassortants having LAC M RNA), a polypeptide with an electrophoretic mobility slightly faster than that of the SSH NSM polypeptide was observed (approximate molecular weight, 11 X 10(3)); it has been designated LAC NSM. The relationships of the NSM polypeptides to the other M RNA-coded polypeptides (G1 and G2; J. R. Gentsch and D. H. L. Bishop, J. Virol. 30;767-770, 1979) have not been determined. Two additional polypeptides present in both LAC- and SSH-infected cell extracts also appear to be virus induced (one with an approximate molecular weight of 10 X 10(3), p10; the other with an approximate molecular weight of 18 X 10(3), p18). Whether these polypeptides are virus coded has not been determined.     

Neuroattenuation of an avirulent bunyavirus variant maps to the L RNA segment.

The derivation and characterization of a neuroattenuated reassortant clone (RFC 25/B.5) of California serogroup bunyavirus was described previously (M. J. Endres, A. Valsamakis, F. Gonzalez-Scarano, and N. Nathanson, J. Virol. 64:1927-1933, 1990). To map the RNA segment responsible for this attenuation, a panel of reassortants was constructed between the attenuated clone B.5 (genotype TLL) and a virulent clone (B1-1a) of reciprocal genotype (LTT). Parent viruses and clones representing all of the six possible reassortants were examined for neurovirulence by intracerebral injection in adult mice. Reassortants bearing the large RNA segment from the virulent parent were almost as virulent as the virulent parent virus, while reassortants bearing the large RNA segment from the avirulent parent virus exhibited low or intermediate virulence. These results indicate that the large RNA segment is the major determinant of neuroattenuation of clone B.5. In addition to its neuroattenuation, clone B.5 was temperature sensitive and exhibited an altered plaque morphology. These phenotypes also segregated with the large RNA segment. The importance of the large RNA segment (which encodes the viral polymerase) in neurovirulence contrasts with prior studies which indicate that the ability to cause lethal encephalitis after peripheral injection of suckling mice (neuroinvasiveness) is primarily determined by the middle-sized RNA segment, which encodes the viral glycoproteins.     

Specific interactions between rotavirus outer capsid proteins VP4 and VP7 determine expression of a cross-reactive, neutralizing VP4-specific epitope.

We previously reported that the expression of rotavirus phenotypes by reassortants was affected by recipient genetic background and proposed specific interactions between the outer capsid proteins VP4 and VP7 as the basis for the phenotypic effects (D. Chen, J. W. Burns, M. K. Estes, and R. F. Ramig, Proc. Natl. Acad. Sci. USA 86:3743-3747, 1989). A neutralizing, cross-reactive VP4-specific monoclonal antibody (MAb), 2G4, was used to probe the protein-protein interactions. The VP4 specificity of 2G4 was confirmed by immunoblot analysis. MAb 2G4 reacted with both standard (SA11-C13) and variant rotavirus SA11 (SA11-4F) but did not react with bovine rotavirus B223 as determined by plaque reduction neutralization (PRN) and enzyme-linked immunosorbent assay (ELISA). When a panel of SA11-4F/B223 and SA11-Cl3/B223 reassortants in purified or crude lysate form that had been grown in the presence or absence of trypsin was analyzed with MAb 2G4 by PRN and ELISA, the results with some reassortants were unexpected. That is, MAb 2G4 reacted with VP4 of SA11 parental origin (4F or C13) when it was assembled into capsids with the homologous SA11 VP7 but failed to react with VP4 of SA11 assembled into capsids with heterologous B223 VP7. Conversely, MAb 2G4 failed to react with VP4 of B223 parental origin when it was assembled into capsids with homologous B223 VP7 but did react with B223 VP4 assembled into capsids with the heterologous SA11 VP7. Similar reactivity was observed when 2G4 was used to immunoprecipitate purified double-shelled virions. When soluble unassembled viral proteins were analyzed by ELISA, the 2G4 reactive pattern was as predicted from the parental origin of VP4. That is, 2G4 reacted with the soluble VP4 of reassortants having VP4 from SA11-Cl3 or SA11-4F and failed to react with VP4 of B223 origin, regardless of the origin of VP7. PRN and ELISA results obtained with nonglycosylated viruses revealed that the unexpected reactivity of 2G4 with virus particles was not the result of differential glycosylation of VP7 and epitope masking. These results indicate that the 2G4 epitope existed in the soluble form of VP4 encoded by SA11-Cl3 or SA11-4F but not in soluble B223 VP4. On the other hand, in assembled virions, the presentation of the 2G4 epitope on VP4 was unexpected in some reassortants and was affected by the specific interactions between VP4 and VP7 of heterologous parental origin.     

Genome complexities of the three mRNA species of snowshoe hare bunyavirus and in vitro translation of S mRNA to viral N polypeptide.

The genome complexities of the principal intracellular viral complementary RNA species of the snowshoe hare bunyavirus have been analyzed by duplex analyses involving hybridization of complementary RNA to individual 32P-labeled viral RNA species (large, L; medium, M; and small, S), recovery of nuclease-resistant duplexes, and determination of the oligonucleotide fingerprints of the protected 32P-labeled viral sequences. The result for the M RNA (which codes for the glycoproteins G1 and G2; J. R. Gentsch and D. H. L. Bishop, J. Virol. 30:767-770, 1979) indicates that there is a single polycistronic M mRNA. Similar results were obtained for the L and S RNA species. In vitro translation studies with the S complementary RNA species of snowshoe hare virus as well as melted purified S duplexes substantiate earlier genetic and molecular studies (J. R. Gentsch and D. H. L. Bishop, J. Virol. 28:417-419, 1978; J. Gentsch, D. H. L. Bishop, and J. F. Obijeski, J. Gen. Virol. 34-257-268, 1977), which indicate that S mRNA codes for the virion nucleocapsid protein N.     

Competitive selection in vivo by a cell for one variant over another: implications for RNA virus quasispecies in vivo.

Infidelity of genome applications of RNA viruses leads to the generation of viral quasispecies both in vitro and in vivo. However, the biological significance of such generated variants in vivo is largely unknown and controversial. To study this issue, we continued our evaluation of the tropism of a lymphocytic choriomeningitis virus (LCMV) variant termed clone 13 with its parental virus clonal pool ARM 53b (wild-type parent) for neuronal cells in vivo. Earlier in vivo and in vitro studies noted that the wild-type virus contained a Phe at glycoprotein (GP) residue 260 which correlated with neuron tropism compared with LCMV variants containing a Leu at residue 260 which showed selected tropism for cells of the immune system (C.F. Evans, P. Borrow, J. C. de la Torre, and M. B. A. Oldstone J. Virol. 68:7367-7373, 1994; L. Villarete, T. Somasundaram, and R. Ahmed, J. Virol 68:7490-7496, 1994). Here we (i) evaluated the ability of the viral variants with either a Phe or Leu at GP residue 260 to replicate in vivo in the spleen, liver, or brain, (ii) analyzed the ability of these viruses to compete against each other for cell (neuron)-specific selection following a single viral inoculation of different ratios of both viruses, and (iii) utilized genetic reassortants of both viruses to test their ability to replicate in neurons in vivo. We found that viral variants containing either a Phe or Leu at GP residue 260 were equally capable of replicating in neurons, but when inoculated together, neurons selected for the viral population containing Phe at GP residue 260 over viruses containing a Leu at this position. This was in contrast to selection in the liver and spleen that favored viruses with Leu and not Phe at GP residue 260. Analysis of inoculations with viral reassortants indicated that genes encoded on the short RNA (the GP and nucleoprotein, not the L [polymerase] and Z proteins that are encoded by the large RNA) were associated with neurotropism. Since the nucleoprotein sequences of wild-type Armstrong and clone 13 are identical, it is likely that specific cytoplasmic factors of the neurons play a fundamental role in the selection of virus with Phe at GP residue 260.     

Epstein-Barr virus DNA XII. A variable region of the Epstein-Barr virus genome is included in the P3HR-1 deletion.

The P3HR-1 subclone of Jijoye differs from Jijoye and from other Epstein-Barr virus (EBV)-infected cell lines in that the virus produced by P3HR-1 cultures lacks the ability to growth-transform normal B lymphocytes (Heston et al., Nature (London) 295:160-163, 1982; Miller et al., J. Virol. 18:1071-1080, 1976; Miller et al., Proc. Natl. Acad. Sci. U.S.A. 71:4006-4010, 1974; Ragona et al., Virology 101:553-557, 1980). The P3HR-1 virus was known to be deleted for a region which encodes RNA in latently infected, growth-transformed cells (Bornkamm et al., J. Virol. 35:603-618, 1980; Heller et al., J. Virol. 38:632-648, 1981; King et al., J. Virol. 36:506-518, 1980; Raab-Traub et al., J. Virol. 27:388-398, 1978; van Santen et al., Proc. Natl. Acad. Sci. U.S.A. 78:1930-1934, 1980). This deletion is now more precisely defined. The P3HR-1 genome contains less than 170 base pairs (and possibly none) of the 3,300-base pair U2 region of EBV DNA and is also lacking IR2 (a 123-base pair repeat which is the right boundary of U2). A surprising finding is that EBV isolates vary in part of the U2 region. Two transforming EB viruses, AG876 and Jijoye, are deleted for part of the U2 region including most or all of a fragment, HinfI-c, which encodes part of one of the three more abundant cytoplasmic polyadenylated RNAs of growth-transformed cells (King et al., J. Virol. 36:506-518, 1980; King et al., J. Virol. 38:649-660, 1981; van Santen et al., Proc. Natl. Acad. Sci. U.S.A. 78:1930-1934).     

RNA-binding properties of a translational activator, the adenovirus L4 100-kilodalton protein.

The adenovirus L4 100-kDa nonstructural protein (100K protein) is required for efficient initiation of translation of viral late mRNA species during the late mRNA species during the late phase of infection (B. W. Hayes, G. C. Telling, M. M. Myat, J. F. Williams, and S. J. Flint, J. Virol. 64:2732-2742, 1990). The RNA-binding properties of this protein were analyzed in an immunoprecipitation assay with the 100K-specific monoclonal antibody 2100K-1 (C. L. Cepko and P. A. Sharp, Virology 129:137-154, 1983). Coprecipitation of the 100K protein and 3H-infected cell RNA was demonstrated. The RNA-binding activity of the 100K protein was inhibited by single-stranded DNA but not by double-stranded DNA, double-stranded RNA, or tRNA. Competition assays were used to investigate the specificity with which the 100K protein binds to RNA in vitro. Although the protein exhibited a strong preference for the ribohomopolymer poly(U) or poly(G), no specific binding to viral mRNA species could be detected; uninfected or adenovirus type 5-infected HeLa cell poly(A)-containing and poly(A)-lacking RNAs were all effective inhibitors of binding of the protein to viral late mRNA. Similar results were obtained when the binding of the 100K protein to a single, in vitro-synthesized L2 mRNA was assessed. The poly(U)-binding activity of the 100K protein was used to compare the RNA-binding properties of the 100K protein prepared from cells infected by adenovirus type 5 and the H5ts1 mutant (B. W. Hayes, G. C. Telling, M. M. Myat, J. F. Williams, and S. J. Flint, J. Virol. 64:2732-2742, 1990). A temperature-dependent decrease in H5ts1 100K protein binding was observed, correlating with the impaired translational function of this protein in vivo. By contrast, wild-type 100K protein RNA binding was unaffected by temperature. These data suggest that the 100K protein acts to increase the translational efficiency of viral late mRNA species by a mechanism that involves binding to RNA.     

The reovirus M1 gene, encoding a viral core protein, is associated with the myocarditic phenotype of a reovirus variant.

Reoviruses contain a genome composed of 10 double-stranded RNA gene segments. A reovirus reassortant, 8B, derived from type 1 Lang (T1L) and type 3 Dearing (T3D), displayed a phenotype unlike that of either of its parents in that it efficiently induced numerous macroscopic external cardiac lesions in neonatal mice (B. Sherry, F. J. Schoen, E. Wenske, and B. N. Fields, J. Virol. 63:4840-4849, 1989). A panel of T1L/T3D reassortants and a panel of reassortants derived from 8B were used to determine whether novel T1L/T3D gene associations in 8B were responsible for its myocarditic phenotype. The results eliminated the possibility that any T1L/T3D gene combination found in 8B, from 2 genes to all 10 genes, was the explanation for its induction of cardiac lesions. This suggested that a mutation(s) in an 8B gene(s) might be responsible for induction of the myocarditis. Statistical analysis of experiments with 31 reassortants derived from 8B revealed a highly significant association (P = 0.002) of the 8B M1 gene with induction of cardiac lesions. The reovirus M1 gene encodes a viral core protein of unknown function, although evidence suggests a potential role in core structure and/or viral RNA synthesis. This represents the first report of the association of a viral gene with induction of myocarditis.     

A lymphatic mechanism of rotavirus extraintestinal spread in the neonatal mouse

We used the neonatal mouse model of rotavirus infection and virus strains SA11-clone 4 (SA11-Cl4) and Rhesus rotavirus (RRV) to examine the mechanism of the extraintestinal spread of viruses following oral inoculation. The spread-competent viruses, RRV and reassortant R7, demonstrated a temporal progression from the intestine, to the terminal ileum, to the mesenteric lymph nodes (MLN), and to the peripheral tissues. SA11-Cl4 was not found outside the intestine. Reassortant virus S7, which was unable to reach the liver in previous studies (E. C. Mossel and R. F. Ramig, J. Virol. 76:6502-6509, 2002), was recovered from 60% of the MLN, suggesting that there are multiple determinants for the spread of virus from the intestine to the MLN. Phenotypic segregation analysis identified RRV genome segment 6 (VP6) as a secondary determinant of the spread of virus to the MLN (P = 0.02) in reassortant viruses containing segment 7 from the spread-incompetent parent. These data suggest that in the orally infected neonatal mouse, the extraintestinal spread of rotavirus occurs via a lymphatic pathway, and the spread phenotype is primarily determined by NSP3 and can be modified by VP6.     

Viremia and nasal and rectal shedding of rotavirus in gnotobiotic pigs inoculated with Wa human rotavirus

Respiratory symptoms with rotavirus shedding in nasopharyngeal secretions have been reported in children with and without gastrointestinal symptoms (Zheng et al., 1991, J. Med. Virol. 34:29-37). To investigate if attenuated and virulent human rotavirus (HRV) strains cause upper respiratory tract infections or viremia in gnotobiotic pigs, we inoculated them with attenuated or virulent HRV intranasally, intravenously, or orally or via feeding tube (gavage) and assayed virus shedding. After oral or intranasal inoculation with attenuated HRV, the pigs remained asymptomatic, but 79 to 95% shed virus nasally and 5 to 17% shed virus rectally. After inoculation by gavage, no pigs shed virus nasally or rectally, but all pigs seroconverted with antibodies to HRV. No viremia was detected through postinoculation day 10. Controls inoculated intranasally with nonreplicating rotavirus-like particles or mock inoculated did not shed virus. In contrast, 100% of pigs inoculated with virulent HRV (oral, intranasal, or gavage) developed diarrhea, shed virus nasally and rectally, and had viremia. The infectivity of sera from the viremic virulent HRV-inoculated pigs was confirmed by inoculating gnotobiotic pigs orally with pooled HRV-positive serum. Serum-inoculated pigs developed diarrhea and fecal and nasal virus shedding and seroconverted with serum and intestinal HRV antibodies. Pigs inoculated intravenously with serum or intestinal contents from the viremic virulent HRV-inoculated pigs developed diarrhea, virus shedding, and viremia, similar to the orally inoculated pigs. This study provides new evidence that virulent HRV causes transient viremia and upper respiratory tract infection in addition to gastrointestinal infection in gnotobiotic pigs, confirming previous reports of rotavirus antigenemia (Blutt et al., Lancet 362:1445-1449, 2003). Our data also suggest that intestinal infection might be initiated from the basolateral side of the epithelial cells via viremia. Additionally, virus shedding patterns indicate a different pathogenesis for attenuated versus virulent HRV.     

Reassortant rotaviruses as potential live rotavirus vaccine candidates.

A series of reassortants was isolated from coinfection of cell cultures with a wild-type animal rotavirus and a "noncultivatable" human rotavirus. Wild-type bovine rotavirus (UK strain) was reassorted with human rotavirus strains D, DS-1, and P; wild-type rhesus rotavirus was reassorted with human rotavirus strains D and DS-1. The D, DS-1, and P strains represent human rotavirus serotypes 1, 2, and 3, respectively. Monospecific antiserum (to bovine rotavirus, NCDV strain) or a set of monoclonal antibodies to the major outer capsid neutralization glycoprotein, VP7 (of the rhesus rotavirus), was used to select for reassortants with human rotavirus neutralization specificity. This selection technique yielded many reassortants which received only the gene segment coding for the major neutralization protein from the human rotavirus parent, whereas the remaining genes were derived from the animal rotavirus parent. Single human rotavirus gene substitution reassortants of this sort represent potential live vaccine strains.     

Virus-like particle-induced fusion from without in tissue culture cells: role of outer-layer proteins VP4 and VP7.

We recently described an assay that measures fusion from without induced in tissue culture cells by rotavirus, a nonenveloped, triple-protein-layered member of the Reoviridae family (M. M. Falconer, J. M. Gilbert, A. M. Roper, H. B. Greenberg, and J. S. Gavora, J. Virol. 69:5582-5591, 1995). The conditions required for syncytium formation are similar to those for viral penetration of the plasma membrane during the course of viral infection of host cells, as the presence of the outer-layer proteins VP4 and VP7 and the cleavage of VP4 are required. Here we present evidence that virus-like particles (VLPs) produced in Spodoptera frugiperda Sf-9 cells from recombinant baculoviruses expressing the four structural proteins of rotavirus can induce cell-cell fusion to the same extent as native rotavirus. This VLP-mediated fusion activity was dependent on trypsinization of VP4, and the strain-specific phenotype of individual VP4 molecules was retained in the syncytium assay similar to what has been seen with reassortant rotaviruses. We show that intact rotavirus and VLPs induce syncytia with cells that are permissive to rotavirus infection whereas nonpermissive cells are refractory to syncytium formation. This finding further supports our hypothesis that the syncytium assay accurately reflects very early events involved in viral infection and specifically the events related to viral entry into the cell. Our results also demonstrate that neither viral replication nor rotavirus proteins other than VP2, VP6, VP4, and VP7 are required for fusion and that both VP4 and VP7 are essential. The combination of a cell-cell fusion assay and the availability of recombinant VLPs will permit us to dissect the mechanisms of rotavirus penetration into host cells.     

Formation and selection of intergenogroup reassortants during cell culture adaptation of rotaviruses from dually infected subjects.

A previous study showed that intergenogroup reassortants of human rotaviruses can persist in nature (R.L. Ward, O. Nakagomi, D.R. Knowlton, M.M. McNeal, T. Nakagomi, J.D. Clemens, D.A. Sack, and G.M. Schiff, J. Virol. 64:3219-3225, 1990), but the mechanisms involved in their formation and selection had not been determined. In this study it was shown that, during cell culture adaptation of rotaviruses belonging to different genogroups from stools of dually infected subjects, intergenogroup reassortants were formed and selected, presumably mimicking the processes that occur in nature.     

Participation of rab5, an early endosome protein, in hepatitis C virus RNA replication machinery

Like most positive-strand RNA viruses, hepatitis C virus (HCV) is believed to replicate its genome on the surface of rearranged membranes. We have shown previously that HCV NS4AB, but not the product NS4B, inhibits endoplasmic reticulum (ER)-to-Golgi protein traffic (K. V. Konan, T. H. Giddings, Jr., M. Ikeda, K. Li, S. M. Lemon, and K. Kirkegaard, J. Virol. 77:7843-7855). However, both NS4AB and NS4B can induce "membranous web" formation, first reported by Egger et al. (D. B Egger, R. Gosert, L. Bianchi, H. E. Blum, D. Moradpour, and K. Bienz, J. Virol. 76:5974-5984), which is also observed in HCV-infected cells (Y. Rouille, F. Helle, D. Delgrange, P. Roingeard, C. Voisset, E. Blanchard, S. Belouzard, J. McKeating, A. H. Patel, G. Maertens, T. Wakita, C. Wychowski, and J. Dubuisson, J. Virol. 80:2832-2841) and cells that bear a subgenomic NS5A-green fluorescent protein (GFP) replicon (D. Moradpour, M. J. Evans, R. Gosert, Z. Yuan, H. E. Blum, S. P. Goff, B. D. Lindenbach, and C. M. Rice, J. Virol. 78:7400-7409). To determine the intracellular origin of the web, we examined NS4B colocalization with endogenous cellular markers in the context of the full-length or subgenomic replicon. We found that, in addition to ER markers, early endosome (EE) proteins, including Rab5, were associated with web-inducing protein NS4B. Furthermore, an immunoisolated fraction containing NS4B was found to contain both ER and EE proteins. Using fluorescence microscopy, we showed that wild-type and constitutively active Rab5 proteins were associated with NS4B. Interestingly, expression of dominant-negative Rab5 resulted in significant loss of GFP fluorescence in NS5A-GFP replicon cells. We also found that a small reduction in Rab5 protein expression decreased HCV RNA synthesis significantly. Furthermore, transfection of labeled Rab5 small interfering RNAs into NS5A-GFP replicon cells resulted in a significant decrease in GFP fluorescence. Finally, Rab5 protein was found to coimmunoprecipitate with HCV NS4B. These studies suggest that EE proteins, including Rab5, may play a role in HCV genome replication or web formation.     

Importance of specific nucleotides in the folding of the natural form of the hairpin ribozyme

The hairpin ribozyme in its natural context consists of two loops in RNA duplexes that are connected as arms of a four-way helical junction. Magnesium ions induce folding into the active conformation in which the two loops are in proximity. In this study, we have investigated nucleotides that are important to this folding process. We have analyzed the folding in terms of the cooperativity and apparent affinity for magnesium ions as a function of changes in base sequence and functional groups, using fluorescence resonance energy transfer. Our results suggest that the interaction between the loops is the sum of a number of component interactions. Some sequence variants such as A10U, G+1A, and C25U exhibit loss of cooperativity and reduced affinity of apparent magnesium ion binding. These variants are also very impaired in ribozyme cleavage activity. Nucleotides A10, G+1, and C25 thus appear to be essential in creating the conformational environment necessary for ion binding. The double variant G+1A/C25U exhibits a marked recovery of both folding and catalytic activity compared to either individual variant, consistent with the proposal of a triple-base interaction among A9, G+1, and C25 [Pinard, R., Lambert, D., Walter, N. G., Heckman, J. E., Major, F., and Burke, J. M. (1999) Biochemistry 38, 16035-16039]. However, substitution of A9 leads to relatively small changes in folding properties and cleavage activity, and the double variant G+1DAP/C25U (DAP is 2,6-diaminopurine), which could form an isosteric triple-base interaction, exhibits folding and cleavage activities that are both very impaired compared to those of the natural sequence. Our results indicate an important role for a Watson--Crick base pair between G+1 and C25; this may be buttressed by an interaction with A9, but the loss of this has less significant consequences for folding. 2'-Deoxyribose substitution leads to folding with reduced magnesium ion affinity in the following order: unmodified RNA > dA9 > dA10 > dC25 approximately dA10 plus dC25. The results are interpreted in terms of an interaction between the ribose ring of C25 and the ribose and base of A10, in agreement with the proposal of Ryder and Strobel [Ryder, S. P., and Strobel, S. A. (1999) J. Mol. Biol. 291, 295-311]. In general, there is a correlation between the ability to undergo ion-induced folding and the rate of ribozyme cleavage. An exception to this is provided by G8, for which substitution with uridine leads to severe impairment of cleavage but folding characteristics that are virtually unaltered from those of the natural species. This is consistent with a direct role for the nucleobase of G8 in the chemistry of cleavage.     

Stereospecificity of flobufen metabolism in guinea pigs in vitro and in vivo: phase I of biotransformation

Flobufen (F) is an original nonsteroidal antiinflammatory drug that exists in two enantiomeric forms. Its biotransformation was investigated in male guinea pigs because of the similarities shown in a preliminary F metabolic study between guinea pig and man. Stereospecificity of the respective enzymes was studied in vitro, using microsomes and cytosol, and in vivo, in urine and feces. Rac-F, R-F, and S-F served as substrates. The amount of 4-dihydroflobufen stereoisomers (DHF) and other metabolites (M-17203 and UM-2) was determined by chiral HPLC using an R,R-ULMO column. It was observed that F reductases were distributed differently in microsomes and cytosol. The microsomal fraction showed higher activity and different stereospecificity in rac-F, R-F, and S-F reduction compared to cytosol. (2R;4S)-DHF was the principle metabolite in microsomes and (2S;4S)-DHF was the principle metabolite in cytosol. In vivo experiments revealed the excretion of a main metabolite UM-2 in addition to other metabolites M-17203 and DHF stereoisomers. UM-2 was predominantly excreted after S-F administration. Stereoselectivity of DHF stereoisomers excretion was different in urine and in feces. The absence of UM-2 and M-17203 in microsomes and cytosol and their presence in urine and feces showed that both could arise in some other extrahepatic tissue or cell compartment or that their formation depends on liver cell integrity.