Lymphocytic Choriomeningitis virus. I. Concentration and purification of the infectious virus.

Two procedures for the purification of infectious lymphocytic choriomeningitis virus from cell culture fluid have been developed. If large quantities of very pure virus are to be prepared, infected L cells are maintained with a medium supplemented with calf serum, the proteins of which have been largely removed by pretreatment with polyethylene glycol. Two days after infection of the cultures, the media are collected and the virus is concentrated by treatment with polyethylene glycol 40,000. Purification with a 10,000-fold increase of specific infectivity is achieved with steric chromatography on controlled-pore glass beads with pore sizes of 42 to 44 nm and centrifugation in density gradients prepared with amido trizoate. An alternative method begins with precipitation of the virus from infected cell cuture medium with zinc acetate, followed by controlled-pore glass chromatography and density centrifugation in a discontinuous sucrose gradient. Purification thus obtained is 200-fold in terms of specific infectivity.     

Proteins of Epstein-Barr virus. I. Analysis of the polypeptides of purified enveloped Epstein-Barr virus.

Epstein-Barr virus (EBV) was purified from the extracellular fluid of HR-1 and B95-8 cell lines. The preparations of purified virus consisted of enveloped particles and had EBV-specific antigneic reactivity. Comparison of the amount of labeled protein in preparations of virus purified from cultures incubated in [35S]methionine with the amount of labeled protein in preparations obtained following a mixture of unlabeled virus with [35S]methionine-labeled cellular proteins indicated that less than 2% of the labeled protein in the purified virus preparation could be attributed to contamination with labeled cellular proteins. No extraneous membranous material was seen in thin sections of the purified virus preparations. Analysis of the polypeptides of purified enveloped EBV indicated the following. (i) Eighteen polypeptides could be resolved in Coomassie brilliant blue-stained electropherograms of extracellular virus purified from HR-1 and B95-8 cultures. (ii) Thirty-three polypeptides could be resolved in fluorograms of labeled EBV purified from B95-8 cultures and subjected to electrophoresis in acrylamide gels cross-linked with diallyltartardiamide. The molecular weight of the EBV polypeptides was estimated by co-electrophoresis with the polypeptides of purified herpes simplex virus and purified polypeptides of known molecular weight to range from 28 x 10(3) to approximately 290 x 10(3) (iii) The polypeptides of EBV could be grouped by their relative molar abundancy into three classes: VP6, 7, and 27 present in high abundance; VP1, 12, 20, 23, and 29 present in moderate abundance; and a third class of less abundant polypeptides, VP4, 5, 8, 9, 10, 11, 15, 16, 21, and 22. The remainder of the polypeptides could not be precisely quantitated. (iv) The polypeptides of purified EBV, although similar in number and in range of molecular weight to the polypeptides of purified herpes simplex virus, differ sufficiently from those of herpes simplex virus so as to preclude comparison of individual polypeptide components.     

Proteins of Norwalk virus.

The proteins of the Norwalk virus were studied by polyacrylamide gel electrophoresis. Highly purified specifically immunoprecipitated virions appeared to contain a single primary structural protein with a molecular weight of 59,000. In addition, a soluble Norwalk viral protein with a molecular weight of 30,000 was identified in fecal specimens containing Norwalk virus. The protein structure of the virion is similar to that of the Calciviridae family.     

Polypeptides of mumps virus.

Mumps virus was propagated in the extra-embryonic fluids of embryonated chicken eggs and was labeled by cionjection of radioactively labeled amino acids. The virus was purified by density gradient centrifugation, and its polypeptides were analyzed by polyarylamide gel electrophoresis. The virus was found to be composed of six polypeptides, ranging in size from 40,000 to 64,000 daltons. Viral proteins 1 and 3 were the glycoproteins of the virons. When the virus particle was treated with noniontic detergents, a small fraction of these glycoproteins could be released into the supernatant. After treatment with nonionic detergents in high salt and alkaline conditions, more of the surface glycoproteins were removed. This treatment also released the smallest viral polypeptide from the virion. The glycoproteins were separated using an affinity chromatographic column of agarose-fetuin. The heavier glycoprotein, viral protein 1, was found to contain both the neuraminidase and hemagglutinating activity. The two glycoproteins were tested for their ability to react in complement-fixing tests with mumps antisera. Only the heavier glycoprotein reacted with antisera possessing both anti-S and anti-V activity. Neither glycoprotein reacted with antisera specific for the S antigen. Thus, it was concluded that this glycoprotein corresponds to the classical V antigen of mumps virus.     

Growth of measles virus in nervous tissues. III. Neurovirulence of SSPE virus in ferrets.

The Niigata-1 strain isolated from a patient with subacute sclerosing panencephalitis (SSPE) was inoculated intracerebrally into ferrets. Neurological signs developed in about 1 week in most of the animals. Histopathological examinations of the central nervous tissues revealed degenerative lesions in the parenchyma of the brains and inflammatory reactions predominantly in the meninges and choroid plexus. Virus antigen was demonstrated mainly in the nerve cells by immunofluorescent staining. The results indicated high affinity of the Niigata-1 strain to the nerve cells. In contrast, the Mantooth strain of SSPE virus in cell-free state did not exhibit neurovirulence in ferrets.     

DNA of Epstein-Barr virus. V. Direct repeats of the ends of Epstein-Barr virus DNA.

Previous data indicated that Epstein-Barr virus DNA is terminated at both ends by direct or inverted repeats of from 1 to 12 copies of a 3 X 10(5)-dalton sequence. Thus, restriction endonuclease fragments which include either terminus vary in size by 3 X 10(5)-dalton increments (D. Given and E. Kieff, J. Virol. 28:524--542, 1978; S. D. Hayward and E. Kieff, J. Virol. 23:421--429, 1977). Furthermore, defined fragments containing either terminus hybridize to each other (Given and Kieff, J. Virol. 28:524--542, 1978). The 5' ends of the DNA are susceptible to lambda exonuclease digestion (Hayward and Kieff, J. Virol. 23:421--429, 1977). To determine whether the terminal DNA is a direct or inverted repeat, the structures formed after denaturation and reannealing of the DNA from one terminus and after annealing of lambda exonuclease-treated DNA were examined in the electron microscope. The data were as follows. (i) No inverted repeats were detected within the SalI D or EcoRI D terminal fragments of Epstein-Barr virus DNA. The absence of "hairpin- or pan-handle-like" structures in denatured and partially reannealed preparations of the SalI D or EcoRI D fragment and the absence of repetitive hairpin- or pan-handle-like structures in the free 5' tails of DNA treated with lambda exonuclease indicate that there is no inverted repeat within the 3 X 10(5)-dalton terminal reiteration. (ii) Denatured SalI D or EcoRI D fragments reanneal to form circles ranging in size from 3 X 10(5) to 2.5 X 1O(6) daltons, indicating the presence of multiple direct repeats within this terminus. (iii) Lambda exonuclease treatment of the DNA extracted from virus that had accumulated in the extracellular fluid resulted in asynchronous digestion of ends and extensive internal digestion, probably a consequence of nicks and gaps in the DNA. Most full-length molecules, after 5 min of lambda exonuclease digestion, annealed to form circles, indicating that there exists a direct repeat at both ends of the DNA. (iv) The finding of several circularized molecules with small, largely double-strand circles at the juncture of the ends indicates that the direct repeat at both ends is directly repeated within each end. Hybridization between the direct repeats at the termini is likely to be the mechanism by which Epstein-Barr virus DNA circularizes within infected cells (T. Lindahl, A. Adams, G. Bjursell, G. W. Bornkamm, C. Kaschka-Dierich, and U. Jehn, J. Mol. Biol. 102:511-530, 1976).