Murine coronavirus spike protein determines the ability of the virus to replicate in the liver and cause hepatitis

Recombinant mouse hepatitis viruses (MHV) differing only in the spike gene, containing A59, MHV-4, and MHV-2 spike genes in the background of the A59 genome, were compared for their ability to replicate in the liver and induce hepatitis in weanling C57BL/6 mice infected with 500 PFU of each virus by intrahepatic injection. Penn98-1, expressing the MHV-2 spike gene, replicated to high titer in the liver, similar to MHV-2, and induced severe hepatitis with extensive hepatocellular necrosis. S(A59)R13, expressing the A59 spike gene, replicated to a somewhat lower titer and induced moderate to severe hepatitis with zonal necrosis, similar to MHV-A59. S4R21, expressing the MHV-4 spike gene, replicated to a minimal extent and induced few if any pathological changes, similar to MHV-4. Thus, the extent of replication and the degree of hepatitis in the liver induced by these recombinant viruses were determined largely by the spike protein.

Pathogenesis of chimeric MHV4/MHV-A59 recombinant viruses: the murine coronavirus spike protein is a major determinant of neurovirulence

The mouse hepatitis virus (MHV) spike glycoprotein, S, has been implicated as a major determinant of viral pathogenesis. In the absence of a full-length molecular clone, however, it has been difficult to address the role of individual viral genes in pathogenesis. By using targeted RNA recombination to introduce the S gene of MHV4, a highly neurovirulent strain, into the genome of MHV-A59, a mildly neurovirulent strain, we have been able to directly address the role of the S gene in neurovirulence. In cell culture, the recombinants containing the MHV4 S gene, S4R22 and S4R21, exhibited a small-plaque phenotype and replicated to low levels, similar to wild-type MHV4. Intracranial inoculation of C57BL/6 mice with S4R22 and S4R21 revealed a marked alteration in pathogenesis. Relative to wild-type control recombinant viruses (wtR13 and wtR9), containing the MHV-A59 S gene, the MHV4 S gene recombinants exhibited a dramatic increase in virulence and an increase in both viral antigen staining and inflammation in the central nervous system. There was not, however, an increase in the level of viral replication in the brain. These studies demonstrate that the MHV4 S gene alone is sufficient to confer a highly neurovirulent phenotype to a recombinant virus deriving the remainder of its genome from a mildly neurovirulent virus, MHV-A59. This definitively confirms previous findings, suggesting that the spike is a major determinant of pathogenesis.

Targeted recombination within the spike gene of murine coronavirus mouse hepatitis virus-A59: Q159 is a determinant of hepatotropism

Previous studies of a group of mutants of the murine coronavirus mouse hepatitis virus (MHV)-A59, isolated from persistently infected glial cells, have shown a strong correlation between a Q159L amino acid substitution in the S1 subunit of the spike gene and a loss in the ability to induce hepatitis and demyelination. To determine if Q159L alone is sufficient to cause these altered pathogenic properties, targeted RNA recombination was used to introduce a Q159L amino acid substitution into the spike gene of MHV-A59. Recombination was carried out between the genome of a temperature-sensitive mutant of MHV-A59 (Alb4) and RNA transcribed from a plasmid (pFV1) containing the spike gene as well as downstream regions, through the 3' end, of the MHV-A59 genome. We have selected and characterized two recombinant viruses containing Q159L. These recombinant viruses (159R36 and 159R40) replicate in the brains of C57BL/6 mice and induce encephalitis to a similar extent as wild-type MHV-A59. However, they exhibit a markedly reduced ability to replicate in the liver or produce hepatitis compared to wild-type MHV-A59. These viruses also exhibit reduced virulence and reduced demyelination. A recombinant virus containing the wild-type MHV-A59 spike gene, wtR10, behaved essentially like wild-type MHV-A59. This is the first report of the isolation of recombinant viruses containing a site-directed mutation, encoding an amino acid substitution, within the spike gene of any coronavirus. This technology will allow us to begin to map the molecular determinants of pathogenesis within the spike glycoprotein.

The C12 mutant of MHV-A59 is very weakly demyelinating and has five amino acid substitutions restricted to the spike and replicase genes

C12, an attenuated, fusion defective, very weakly hepatotropic mutant of MHV-A59 has been further characterized. Analysis of C12 in vivo in C57BL/6 mice has shown that despite the fact that this virus replicates in the brain to titers at least as high as wild type and causes acute encephalitis similar to wild type, this virus causes minimal demyelination. Thus acute encephalitis is not sufficient for induction of demyelination by wild type MHV-A59. We have previously shown that C12 has two amino acid substitutions relative to wild type virus in the spike gene, Q159L (in the receptor binding domain of S1) and H716D (in the signal sequence for cleavage of S). We have now sequenced the rest of the 31 kb genome of C12 and compared it to wild type virus. Only three additional amino acids substitutions were found, all within the replicase gene, one in the predicted papain like proteinase (PLP)-2 domain and one in the predicted helicase domain. Thus, determinants of virulence, hepatotropism, and demyelination may map to the replicase gene as well as to the spike gene.

Altered pathogenesis of a mutant of the murine coronavirus MHV-A59 is associated with a Q159L amino acid substitution in the spike protein

C12, an attenuated, fusion delayed, very weakly hepatotropic mutant of mouse hepatitis virus strain A59 (MHV-A59( has been further characterized. We have previously shown that C12 has two amino acid substitutions relative to wild type virus in the spike protein, Q159L (within a region of S1 shown to bind to viral receptor in an in vitro assay) and H716D (in the proteolytic cleavage recognition site). We have sequenced the rest of the 31-kb genome of C-12 and compared it to wild type virus. Only three additional amino acids substitutions were found, all encoded within the replicase gene. Analysis of C12 in vivo in C57Bl/6 mice has shown that despite the fact that this virus replicates in the brain to titers at least as high as wild type and causes acute encephalitis similar to wild-type, this virus causes a minimal level of demyelination and only at very high levels of virus inoculation. Thus acute encephalitis is not sufficient for the induction of demyelination by MHV-A59. Analysis of mutants isolated at earlier times from the same persistently infected glial cell culture as C12, as well as mutants isolated from a second independent culture of persistently infected glial cells, suggests that both the weakly demyelinating and the weakly hepatotropic phenotypes of C12 are associated with the Q159L amino acid substitution.

Characterization of two genes encoding the Mycobacterium tuberculosis ribonucleotide reductase small subunit

Two nrdF genes, nrdF1 and nrdF2, encoding the small subunit (R2) of ribonucleotide reductase (RR) from Mycobacterium tuberculosis have 71% identity at the amino acid level and are both highly homologous with Salmonella typhimurium R2F. The calculated molecular masses of R2-1 and R2-2 are 36,588 (322 amino acids [aa]) and 36,957 (324 aa) Da, respectively. Western blot analysis of crude M. tuberculosis extracts indicates that both R2s are expressed in vivo. Recombinant R2-2 is enzymatically active when assayed with pure recombinant M. tuberculosis R1 subunit. Both ATP and dATP are activators for CDP reduction up to 2 and 1 mM, respectively. The gene encoding M. tuberculosis R2-1, nrdF1, is not linked to nrdF2, nor is either gene linked to the gene encoding the large subunit, M. tuberculosis nrdE. The gene encoding MTP64 was found downstream from nrdF1, and the gene encoding alcohol dehydrogenase was found downstream from nrdF2. A nrdA(Ts) strain of E. coli (E101) could be complemented by simultaneous transformation with M. tuberculosis nrdE and nrdF2. An M. tuberculosis nrdF2 variant in which the codon for the catalytically necessary tyrosine was replaced by the phenylalanine codon did not complement E101 when cotransformed with M. tuberculosis nrdE. Similarly, M. tuberculosis nrdF1 and nrdE did not complement E101. Activity of recombinant M. tuberculosis RR was inhibited by incubating the enzyme with a peptide corresponding to the 7 C-terminal amino acid residues of the R2-2 subunit. M. tuberculosis is a species in which a nrdEF system appears to encode the biologically active species of RR and also the only bacterial species identified so far in which class I RR subunits are not arranged on an operon.

CD4+ and CD8+ T cells are not major effectors of mouse hepatitis virus A59-induced demyelinating disease

We examined murine hepatitis virus strain A59 (MHV-A59)-induced demyelinating disease in C57BL/6 mice which had previously been thymectomized at 25 days of age. Demyelination was observed in 51-96% of spinal cord quadrants examined 30 or 60 days post infection (dpi), indicating that neither an intact thymus nor thymic infection is a prerequisite to demyelination. Depletion of CD4+ or CD8+ T cells at 5, 7 or 10 dpi did not influence the extent of demyelination indicating that neither T cell subset is a major effector of demyelination. However, these findings do not exclude the possibility that T cells are involved in initiating demyelinating disease very early in infection.

Primary B-cell response to neuropeptide Y and bovine pancreatic polypeptide

An analysis of the murine primary response to protein epitopes has been made with two small highly structured proteins, neuropeptide Y (NPY) and bovine pancreatic polypeptide (BPP), both of 36-amino acid residue length and containing helical structures. A group of cell lines producing monoclonal IgM antibody have been prepared consisting of six anti-NPY and two anti-BPP. The VH nucleotide sequences have been determined and characterized as germ-line either by identity to established germ-line sequences or by inference from the germ-line character of the D and JH segments. The intrinsic association constants for the homologous ligands have been estimated to range from 10(4) to 10(7) M-1 based on competitive ELISA. No severe restriction in the utilization of VH families, D segments or JH segments appears to be involved in this response. Among the eight cell lines, three VH families were represented as well as all three families of D segments and all of the JH segments, although some preference for JH3 was indicated. The length of the N(D)N sequences was also not subject to restriction, ranging from 9 to 29. Two unusual features of the CRD3s were noted, one involving the utilization of an uncommon DSP2 segment and the other the apparent occurrence of a D-D fusion.

Bacterial expression of immunoglobulin VH proteins

A bacterial expression system in Escherichia coli has been developed that produces as much as 10 mg/l of culture of the VH protein associated with monoclonal antibodies specific for the 5-dimethylaminonaphthalene-2-sulfonyl (Dns) group. This system has been applied to the expression of the VH genes derived from a low-affinity, IgM-producing hybridoma and from a high-affinity, IgG-producing cell line. The plasmid vectors (contributed by Dr William F. Studier) utilize a T7 expression cassette whose activity is initiated by infection with a lambda phage derivative carrying the T7 RNA polymerase gene. The VH proteins were extracted from the bacterial pellet in 8 M urea and purified by chromatography in 8 M urea. Recombinants with the homologous light (L) chains were prepared to yield VHL molecules. These were used to measure intrinsic affinity for Dns-lysine by resonance energy transfer. The association constants were 7 x 10(6) M-1 and 7 x 10(9) M-1 for the low- and high-affinity systems, respectively. These values are not significantly different from those observed with monoclonal antibodies secreted from the corresponding cell lines. This system lends itself to the quantitative evaluation of the binding properties of the VH protein itself as well as the modulation of affinity by site-directed mutagenesis.

Germ-line affinity and germ-line variable-region genes in the B cell response

The predominance of germ-line genes in IgM expression was evaluated from the nucleotide sequences of mRNA, derived from 10 hybridoma cell lines, coding for the VH and VL regions of anti-5-dimethylaminonaphthalene-1-sulfonyl (anti-Dns) IgM antibody. At least six germ-line VH gene segments distributed among four families are used in this response. Seven of the 10 independently rear-ranged VH genes were identified as germ line, with the other three possibly germ line. In all of them the D and JH portions retained the germ-line sequences of the D and JH segments from which they were derived. Maximum diversity was found in the D segments and the use of noncoded nucleotides at the VH-D and D-JH junctions. Of the eight cell lines expressing the lambda light chains, all were germ line and involved the three subtypes. Maximum affinity for the homologous ligand was found among the seven cell lines identified as expressing germ-line gene segments. Thus any somatic mutation among the remaining 3 cell lines did not provide enhanced affinity and the observed affinity of each cell line can be described as germ-line affinity. It is further suggested that the anti-Dns selectivity of the IgM antibodies is associated primarily with the CDR3 regions.

Germ-line affinity and germ-line variable-region genes in the B cell response

The predominance of germ-line genes in IgM expression was evaluated from the nucleotide sequences of mRNA, derived from 10 hybridoma cell lines, coding for the VH and VL regions of anti-5-dimethylaminonaphthalene-1-sulfonyl (anti-Dns) IgM antibody. At least six germ-line VH gene segments distributed among four families are used in this response. Seven of the 10 independently rear-ranged VH genes were identified as germ line, with the other three possibly germ line. In all of them the D and JH portions retained the germ-line sequences of the D and JH segments from which they were derived. Maximum diversity was found in the D segments and the use of noncoded nucleotides at the VH-D and D-JH junctions. Of the eight cell lines expressing the lambda light chains, all were germ line and involved the three subtypes. Maximum affinity for the homologous ligand was found among the seven cell lines identified as expressing germ-line gene segments. Thus any somatic mutation among the remaining 3 cell lines did not provide enhanced affinity and the observed affinity of each cell line can be described as germ-line affinity. It is further suggested that the anti-Dns selectivity of the IgM antibodies is associated primarily with the CDR3 regions.

Attachment of immunoglobulin to liposomal membrane via protein carbohydrate

A general method has been developed for the covalent attachment of immunoglobulin molecules to the outer layer of liposomal membranes. Aldehyde groups are generated by the mild oxidation with periodate or galactose oxidase of the carbohydrate groups on the constant region of the heavy chain. The oxidized protein is then reacted with a hydrazide group linked to a membrane component. Detailed studies were carried out with monomers of a monoclonal human IgM and two monoclonal murine IgM antibodies specific for the 1-dimethylaminonaphthalene-5-sulfonyl (Dns) group. Two hydrazide-containing hydrophobic reagents were used: N alpha-lauroyl, N epsilon-Dns-lysine hydrazide and lauric acid hydrazide. The number of protein aldehyde groups formed was assayed by reaction with N-(2,4-dinitrophenyl)-beta-alanylglycylglycine hydrazide. Measurement of the intrinsic affinity for Dns-lysine of the processed anti-Dns IgMs demonstrated no substantial impairment of the specific reactivity of the antibody either from the oxidation step or the subsequent attachment to small unilamellar vesicles. The extent of attachment of antibody to small unilamellar vesicles was evaluated with respect to the mol% of hydrazide in the membrane, the duration of the incubation period for the aldehyde-hydrazide reaction and the ratio of protein to hydrazide. The yield of attached protein was significantly dependent on each of these experimental parameters over the ranges tested. Under the most favorable conditions the extent of covalent attachment of IgMs to small unilamellar vesicles was 535 micrograms of protein per mumol of phospholipid, corresponding to 0.3 mol% of protein. Under these conditions, 61% of the total protein was associated with the small unilamellar vesicle fraction after fractionation by gel filtration. The attachment of the antibody to small unilamellar vesicles did not destroy the integrity of the vesicles, as demonstrated by the retention of carboxyfluorescein following initial encapsulation during the formation of small unilamellar vesicles.

Equine anti-hapten antibody. IX. IgM anti-lactose antibodies

The immune response to a bacterial vaccine of Streptococcus faecalis (strain N) was characterized in all of the seven horses studied by the sustained production of about 90% IgM anti-lactose antibody over a period of 44 weeks with maximum values of the total antibody ranging from 4 mg/ml of serum to 12 mg/ml of serum. With respect to the binding of a lactose-containing ligand the association constants of the antibodies purified from sera obtained between 5 and 44 weeks fell in the range of 1 times 10-5 M-1 to 2 times 10-5 M-1. Not only was there no significant indication of maturation of a-finity in this period but there was a selective limitation of affinity compared to that of 7S antibodies. It was inferred that the synthesis of IgM antibody involves the selective utilization of V-H and/or V-L genes.