FURTHER IMPLICATION OF MURINE LEUKEMIA-LIKE VIRUS IN THE DISORDERS OF NZB MICE

doi:10.1084/jem.129.5.1045

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ARTICLE

FURTHER IMPLICATION OF MURINE LEUKEMIA-LIKE VIRUS IN THE DISORDERS OF NZB MICE

Robert C. Mellors M.D.¹, Tadao Aoki M.D.¹, and Robert J. Huebner M.D.¹

¹ From The Hospital for Special Surgery and The Philip D. Wilson Research Foundation, Affiliated with The New York Hospital-Cornell University Medical College, and the Department of Pathology, Cornell University Medical College, New York 10021; the Division of Immunology, Sloan-Kettering Institute for Cancer Research, New York 10021; and the Viral Carcinogenesis Branch, National Cancer Institute, National Institutes of Health, Bethesda, Maryland 20014

Further evidence implicating murine leukemia-like virus inthe disorders of NZB mice was afforded by a study of antigensassociated with murine leukemia virus (MuLV). MuLV group antigenswere prevalent in extracts of spleen, kidney, and, to a lesserextent, thymus throughout a substantial portion of the lifespan of NZB mice as well as in extracts of lymphomas and sarcomasindigenous to the strain.

G (Gross) soluble antigen, type-specificantigen, was first detected in plasma of untreated NZB miceat 3 months of age. G soluble antigen production increased thereafterin line with age, with 50% of reactions becoming positive at5.3 months and 100% at 7 to 9 months.

From months 3 to 9, thetime-response curve for positive conversion of direct antiglobulin(Coombs) tests in untreated NZB mice corresponded closely tothat for G soluble antigen production.

Beyond the 9th month,G soluble antigen underwent elimination from the plasma of NZBmice, with positive reactions reduced to 50% at 13.3 monthsand to 0% at 18 months. G natural antibody was first detectedin the serum of NZB mice at about 10 months of age and increasedthereafter in line with age. The curves for G antibody productionand G soluble antigen elimination bore a reciprocal relationto each other with crossover at 50% response occurring at 13.3months.

Significant proteinuria, a functional manifestationof membranous glomerulonephritis, became increasingly prevalentin female NZB mice as G soluble antigen was eliminated fromplasma. Cumulative mortality of female NZB mice, mainly attributableto renal glomerular disease, increased in phase with G antibodyproduction. MuLV group antigens were identified in the glomerularlesions by the immunofluorescence method.

Positive conversionof direct antiglobulin tests was significantly delayed by vaccinatingbaby NZB mice with formaldehyde-inactivated cell-free filtratesof older NZB mouse spleens. The plasmas of vaccinated NZB micewith negative direct antiglobulin reactions at 4 to 7 monthswere likewise negative when tested for G soluble antigen. The50% response time for G antibody production in the vaccinatedNZB mice occurred at 7.3 months, that is, 6 months earlier thanin untreated NZB mice.

The collective findings implicate murineleukemia-like virus in the etiology of autoimmune hemolyticdisease and membranous glomerulonephritis, as well as malignantlymphoma, of NZB mice and suggest that virus-specified cell-surfaceand soluble antigen is a factor in the immunopathogenesis ofthe renal disease and possibly also the autoimmune hemolyticdisease.

Submitted on December 17, 1968

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