Relation of GIX antigen of thymocytes to envelope glycoprotein of murine leukemia virus

Expression of Gix surface antigen on thymocytes is an inherited mendelian train of certain strains of mice. We report here the following new findings: (a) Gix antigen was found free in the serum of Gix+ mouse strains. (b) Expression vs. nonexpression of Gix antigen was invariably correlated with presence or absence of the group-specific antigen of Murine leukemia virus (MuLV) gp69/71 in the serum of mice of inbred and segregating populations. (c) Gix antigen could be removed from normal Gix+ mouse serum by precipitation with antiserum to MuLV gp 69/71. (d) Anti-gp69/71 serum was weakly cytotoxic for Gix+ thymocytes, and partially blocked the cytotoxic activity of Gix antibody for Gix+ thymocytes. (e) Purified AKR virus absorbed Gix activity, and disruption of the virions did not increase their absorbing capacity. These serological data indicate that Gix antigen is a constituent of gp69/71, the glycoprotein which is the major component of the MuLV envelope. On present evidence, Gix antigen is represented in intact virions and is probably accessible to Gix antibody.     

Expression of AKR murine leukemia virus gp71-like and BALB(X) gp-71- like antigens in normal mouse tissues in the absence of overt virus expression

By competition radioimmune assays with antisera against AKR murine leukemia virus (MuLV) gp 71 or antisera against xenotropic virus, and iodinated AKR MuLV gp71 or BALB(X) gp71, antigens serologically indistinguishable from the viral antigens can be detected in tissues of normal mice in the absence of overt virus expression. An antigen serologically indistinguishable from AKR MuLV gp71 can be readily detected in normal bone marrow cells of the common strains of mice including NIH Swiss, 129/J, and SWR/J, as well as in Mus cervicolor and Mus musculus casteneus. In contrast, this antigen is not detected in normal spleen, thymus, lymph nodes, or serum. Similarly, an antigen serologically indistinguishable from BALB(X) gp71 was found in all normal mouse sera examined. This antigen was not present in fetal liver, perfused adult liver, thymus, spleen, lymph nodes, or bone marrow of the mice examined. An equivalent antigen was detected in sera from Mus musculus casteneus but not in sera from Mus cervicolor.     

Scanning electron microscopy of tobacco mosaic virus-labeled lymphocyte surface antigens

Thymocytes of several mouse strains were tested for expression of the gp69/71 envelope component of murine leukemia virus by surface iodination, followed by immunoprecipitation and sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Theses strains included two congenic lines differing from their partner stocks with respect to expression of GIX antigen demonstrable in the cytoxicity assay. We conclude that:(a) two structural variants of gp69/71 can be expressed on mouse thymocytes, (b) these are distinguishable by a small difference in mobility in SDS gels, (c) one carries GIX antigen and the other not, (d) they are coded, or their expression is regulated, by different chromosomal loci that are not closely linked, and (e) both can be expressed together on the thymocytes of inbred mice. In the intact thymocyte plasma membrane, the sites of group-specific antigen shared by the two gp69/71 variants, unlike the GIX type specificity carried by only one of them, are probably inaccessible to antibody.     

A cell surface antigen of the mouse related to xenotropic MuLv defined by naturally occurring antibody and monoclonal antibody. Relation to Gix G(rada1), G(aksl2) systems of MuLV-related antigens

A new cell surface antigen of the mouse related to xenotropic murine leukemia virus (MuLV) is described. The antigen, designated G(erld), is defined by cytotoxic tests with the B6-x-ray-induced ERLD and naturally occurring antibody. G(erld) is distinct from all previously defined cell surface antigens. Monoclonal antibody with the same specificity has been developed. Inbred mouse strains are classified as G(erld)+ or G(erld)- according to the presence of absence of the antigen on lymphoid cells. G(erld)+ strains differ with regard to quantitative expression of G(erld) on normal thymocytes. The emergence of G(erld)+ tumors in G(erld)- strains indicates the presence of genes coding for the antigen even in strains not normally expressing the antigen. G(erld) has the characteristic of a differentiation antigen in normal mice. In G(erld)+ strains, high levels of the antigen are found on thymocytes with lower levels being detected on cells of spleen, lymph nodes and bone marrow. No G(erld) was detected in brain or kidney or on erythrocytes. The segregation ratios for G(erld) expression on thymocytes in backcross and F2 mice of crosses between G(erld)+ (B6, 129, and B6-Gix+) and G(erld)- (BALB/c) strains suggest that G(erld) expression is controlled by a single locus in B6, by two unlinked loci in 129, and by three unlinked loci in B6-Gix+ mice. Induction of the antigen by MuLV infection of permissive cells in vitro indicates that G(erld) is closely related to xenotropic and dualtropic MuLV; all xenotropic and dualtropic MuLV tested induced the antigen, whereas the majority of ecotropic and the two amphotropic MuLV failed to do so. As dualtropic MuLV are thought to be recombinants between ecotropic and xenotropic MuLV sequences, G(erld) coding by dualtropic MuLV may signify the contribution of the xenotropic part in the recombinational event. Serological and biochemical characterization indicates that G(erld) is related to the gp 70 component of the MuLV envelope. The relation of G(erld) to the previously defined gp 70-related cell surface antigens (Gix, G(rada), and G(aksl2) is discussed, particularly with regard to their characteristics as differentiation antigens, the genetic origin of dualtropic MuLV, and the leukemogenicity of MuLV.     

Relationship of infectious murine leukemia virus and virus-related antigens in genetic crosses between AKR and the Fv-1 compatible strain C57L

In a further genetic study of murine leukemia virus (MuLV) and its components we examined the backcross C57L X (C57L X AKR). This population was selected because strains AKR and C57L are both Fv-1n, and the restriction which the Fu-1b allele imposes on the output of virus was thereby obviated. The segregants were scored for three characters: (a) infectious Gross-AKR-type MuLV (V), in the tail; (b) group-specific antigen indicative of p30 internal viral protein, in spleen; and (c) GIX antigen, now thought to be indicative of gp69/71 viral envelope glycoprotein, on thymocytes. Our conclusions are: (a) It is confirmed that the AKR mouse has two unlinked chromosomal genes, Akv-1 and Akv-2, each of which can independently give rise to the life-long high output of MuLV that is characteristic of AKR mice. (b) Of the eight phenotypes that could possibly be derived from segregation of the three pairs of independent alternative traits, seven were observed, but on progeny testing only three were shown to reflect stably heritable genotypes; these were V+p30+GIX+ and V-p30-GIX- (the parental types) and V-p30+GIX+. A third, newly identified AKR gene, designated Akvp, segregating independently of Akv-1 and Akv-2, also determines expression of p30 and GIX but in this case independently of XC-detectable MuLV. (c) The four remaining observed phenotypes, which did not breed true on progeny testing, involved mostly antigen-negative parents yielding antigen-positive progeny; it is likely that these discrepancies represented suppression of phenotype by a maternal resistance factor.     

G(RADA1): a new cell surface antigen of mouse leukemia defined by naturally occurring antibody and its relationship to murine leukemia virus

A new cell surface antigenic system of the mouse, designated G(RADA1), is described. The antigen is defined by cytotoxic tests with the A strain X-ray-induced leukemia RADA1 and naturally occurring antibody from random-bred Swiss mice and can be distinguished from all other serologically detected cell surface antigens of the mouse. Absorption tests indicate that G(RADA1) is present in the normal lymphatic tissue and leukemias of mouse strains with high spontaneous leukemia-incidence, e.g., AKR, C58, and C3H/Figge. Low leukemia-incidence strains, e.g., C57BL/6, BALB/c, and A lack G(RADA1) in their normal tissues, but a proportion of leukemias and solid tumors arising in these strains are G(RADA1)+. The relation of G(RADA1) to MuLV is shown by G(RADA1) appearance after MuLV infection of permissive cells in vitro; four of five N-tropic MuLV isolates, one of four B-tropic MuLV, and none of four xenotropic MuLV induce G(RADA1). Two MCF MuLV, thought to represent recombinants between N-ecotropic and xenotropic MuLV, also induce G(RADA1). Serological and biochemical characterization indicates that G(RADA1) is a type-specific determinant of the gp70 component of certain MuLV. The presence of natural antibody to RADA1 in various mouse strains and the emergence of G(RADA1)+ leukemias and solid tumors in mice of G(RADA1)- phenotype suggest widespread occurrence of genetic information coding for this antigen.     

G(AKSL2): a new cell surface antigen of the mouse related to the dualtropic mink cell focus-inducing class of murine leukemia virus detected by naturally occurring antibody.

Normal mouse sera were tested for cytotoxic antibody to surface antigens of cultured monolayer cells infected with AKR-derived ecotropic MuLV, xentropic MuLV, or dualtropic MCF 247 MuLV. Antibody to ecotropic MuLV-infected cells was found in a proportion of C57BL/6, C3Hf/Bi, AKR-Fv-1b, and (C3Hf/Bi X AKR)F1 mice, but not AKR or (AKR X C3Hf/Bi)F1 mice. Antibody to xenotropic MuLV-infected cells was virtually restricted to C57BL/6 mice. Antibody to MCF 247-infected cells was found in all strains tested, including AKR mice. Absorption analysis of (C3Hf/Bi x akr)f1 and AKR-Fv-1b sera with selective reactivity for MCF 247-infected cells showed that these sera recognize distinctive antigens on MCF 247-infected cells that are not present on ecotropic or xenotropic MuLV-infected cells. The transplantable AKR spontaneous leukemia AKSL2 was found to be uniquely sensitive to the cytotoxic action of naturally occurring antibody to MCF 247-related antigens and absorption tests with AKSL2 as the target cell and sera from a single AKR-Fv-1b mouse have permitted the definition of a new MuLV-related cell surface antigen, which has been designated G(AKSL2). Thymocytes from young mice of high leukemia-incidence strains (AKR, C58, and PL) express G(AKSL2), whereas thymocytes from 12 other strains do not. In AKR mice, the antigen is expressed in higher amounts on cells from thymus and bone marrow than on spleen cells. All AKR spontaneous leukemias tested express G(AKSL2), as did three MuLV-induced leukemias arising in G(AKSL2)- strains. Five X-ray-induced leukemias of G(AKSL2)- strains were G(AKSL2)-, as were MuLV+ and MuLV- chemically induced sarcomas. In the limited survey conducted to date, natural antibody to G(AKSL2) has been restricted to strains expressing G(AKSL2) in their normal tissues: AKR, AKR congenic mice AKR-Fv-1b and AKR hybrid mice (C3Hf/Bi x akr)f1 and (C57BL/6 X AKR)F1. In vitro G(AKSL2) induction tests involving MuLV infection of cultured monolayer cells showed that 8 of 12 newly isolated dualtropic MuLV shared the property of G(AKSL2) induction with the prototype MCF MuLV, MCF 247. Of the 12 ecotropic MuLV tested, only the N-tropic MuLV isolated from a leukemia originally induced by Passage A Gross virus induced G(AKSL2). The xenotropic and amphotropic MuLV isolates tested lacked G(AKSL2) inducing activity. Recognition of the g(aksl2) system provides a way to trace the origin and natural history of a class of dualtropic MCF MuLV in the mouse and to determine whether natural antibody to G(AKSL2) plays a role in AKR leukemogenesis.     

Biochemical evidence linking the GIX thymocyte surface antigen to the gp69/71 envelope glycoprotein of murine leukemia virus

It is known that the thymocyte surface antigen GIX is found in some strains of mice and not others, and that its expression in mice of strain 129, in which most extensive genetic studies have been made, is controlled by two unlinked cellular chromosomal loci. We have now isolated a protein with a mol wt of approximately 70,000 daltons from the surface of thymocytes from 129 mice, which have antigenic and biochemical properties characteristic of the gp69/71 envelope component of murine leukemia virus. Our evidence is compatible with the conclusion that it carries the GIX antigen.     

Amplified env and gag products on AKR cells. Origin from different murine leukemia virus genomes

Thymocytes of AKR mice express two species of gp70, the envelope glycoprotein of murine leukemia virus (MuLV), encoded by the env gene. One is denoted Ec+ gp70 in reference to the type-antigen Ec and association with ecotropic virus. The other, Ec- gp70, resembles gp70 found also on thymocytes of mouse strains that are not overt producers of MuLV, and has no evident relation to ecotropic virus. Expression of Ec- gp70 type, but not of Ec+ gp70 type, is amplified with age on AKR thymocytes. In contrast, viral core polyproteins, encoded by the gag gene and simultaneously amplified with age, appear to be related to ecotropic virus. These observations imply selective amplification of products of env and gag genes from two sorts of provirus, a phenomenon which may be connected to the dual genetic origin of recombinant mink- cell-focus inducing viruses in AKR mice.     

Relationships of gp70 of MuLV envelopes to gp70 components of mouse lymphocyte plasma membranes

The family of glycoproteins called gp70 includes molecules that are the main constituent of murine C-type viral envelopes, and some that are expressed as mendelian constituents of thymocyte plasma membranes in the absence of virions. To investigate further the relation of viral gp70s to plasma- membrane gp70s we compared peptide maps of gp70s derived by immunoprecipitation from cells infected with chosen viruses and from various thymocytes and leukemiacells known to express one or more of three immunogenetically defined gp70 types: Glx-gp70, X-gp70, and O-gp70. Maps of gp70 from cultured cells infected with ecotropic and xenotropic viruses were distinguishable from one another, and in general resembled gp70 maps prepared directly from ecotropic and xenotropic virions respectively. Maps of gp70s immunoprecipitated from thymocytes of five mouse strains and from two A strain T-cell leukemias also fell into two distinguishable and generally corresponding patterns. Thus peptide-mapping substantiates earlier conclusions that viral gp70s and plasma-membrane gp70s inherited independently of virus-production are highly related or identical molecules. The gp70 maps of thymocytes from B6, B6-G(+IX), 129, and A mice formed a group resembling the map from cultured cells infected with xenotropic virus. Thymocytes from AKR mice, and the two A strain leukemias, gave gp70 maps conforming more to the second pattern, that of cultured cells infected with ecotropic virus. This second pattern probably comprises at least two gp70 types, one of which is X-gp70. Our data indicate that the G(IX)-gp70 and O-gp70 sub-species of gp70 expressed in the cell populations we have studied are coded by xenotropic viral genomes, and X-gp70 by ecotropic viral genomes.     

RELATION OF CHROMOSOME 4 (LINKAGE GROUP VIII) TO MURINE LEUKEMIA VIRUS-ASSOCIATED ANTIGENS OF AKR MICE

Genes specifying or controlling the expression of G_IX (cell surface), GCSA (cell surface), and gs (internal viral) antigens are located in chromosome 4 (linkage group [LG] VIII) of the AKR mouse. All three antigens may exhibit mendelian inheritance, mice being antigen positive or antigen negative, but each may also appear in leukemic cells of mice whose inherited genotype was antigen negative. The G_IX-determining gene in LG VIII of AKR mice apparently is equivalent to Gv-1, which determines expression of the same antigen in 129 strain mice, but which in the latter strain is located in LG IX. As the estimated distance of Gv-1 from H-2 in 129 mice is considerable (37 units) further tests are now indicated to assess the possibility of pseudolinkage in this case. The Fv-1 locus, also located in LG VIII, influences the mouse's titer of MuLV, and might thereby be thought to regulate the G_IX and gs phenotypes of AKR backcross segregants. But the data indicate a discrete LG VIII locus for G_IX, since expression of this antigen is mendelian and independent of infectious virus titer. Since the G_IX and GCSA phenotypes of AKR backcross segregants were invariably concordant, these two antigens must be specified or controlled by closely linked genes, and the latter also is presumably independent of virus titer. The question as to what extent expression of gs antigen in the segregants is secondary to virus production is undecided.     

THE VIRAL ENVELOPE GLYCOPROTEIN OF MURINE LEUKEMIA VIRUS AND THE PATHOGENESIS OF IMMUNE COMPLEX GLOMERULONEPHRITIS OF NEW ZEALAND MICE

The use of monospecific antisera for the analysis by radioimmunoassay and immunofluorescence study of two major viral proteins, gp69/71 and p30 of murine leukemia virus, that could be of significance in the pathogenesis of immune complex glomerulonephritis of mice, particularly NZB and B/WF₁ hybrid mice, yielded the following conclusions. A remarkably high concentration of viral envelope glycoprotein, gp69/71, was detected in the spleen and serum of New Zealand mice (NZB, NZW, B/WF₁, and W/BF₁); the concentration in the spleen was 10-fold greater than that found in AKR mice and 30-fold greater than that present in C57BL/6 mice. The gp69/71 was deposited along with bound immunoglobulins, apparently as an immune complex, in the diseased kidneys of mice, and the glomerular site and extent of deposition of gp69/71 was related to the severity of the glomerulonephritis. This study suggests that the pathogenesis of immune complex glomerulonephritis (and vasculitis) in mice is related to the expression of this specific viral envelope glycoprotein and to the host immune response to this protein.     

LEUKEMIA-ASSOCIATED TRANSPLANTATION ANTIGENS RELATED TO MURINE LEUKEMIA VIRUS : THE X.1 SYSTEM: IMMUNE RESPONSE CONTROLLED BY A LOCUS LINKED TOH-2

Two BALB radiation leukemias are strongly rejected by hybrids of BALB with certain other mouse strains, although BALB mice themselves exhibit no detectable resistance whatever. Hybrids immunized with progressively increased inocula are resistant to 200 x 10⁶ or more leukemia cells; their serum is cytotoxic for the leukemia cells in vitro and protects BALB mice against challenge with these BALB leukemias. The antigenic system thus identified has been named X.1. In (BALB x B6) hybrids the major determinant of resistance was shown to be a B6 gene in the K region of H-2. This is likely to be the Rgv-1 (Resistance to gross virus) locus of Lilly, which may thus be identified in this case as an Ir (Immune response) allele conferring ability to respond to X.1 antigen on MuLV and leukemia cells, and so responsible for production of X.1 antibody and the rejection of X.1⁺ leukemia cells by hybrid mice. Immunoelectron microscopy with X.1 antiserum (from immunized hybrids) shows labeling both on the cell surface and on virions produced by the leukemia cells. It is not known whether X.1 comprises only one or more than one antigen. Three radiation-induced BALB leukemias, one A strain radiation-induced leukemia, and 15/15 AKR primary spontaneous leukemias were typed X.1⁺ by the cytotoxicity test. Several other leukemias, including one induced by passage A Gross virus and one long-transplanted AKR ascites leukemia carried in (B6 x AKR)F₁ hybrids, were X.1^-. Normal mice of strains with a high incidence of leukemia and one other strain (129) express X.1 antigen, but evidently in amounts too small for certain detection in vitro; by the method of absorption in vivo, however, these strains could be typed X.1⁺ and other strains X.1^-. We ascribe the X.1 antigen system tentatively to a sub-type of MuLV that is not passage A Gross virus and is probably not the dominant sub-type in strains with a high incidence of leukemia. After repeated passage in hybrids, one of the BALB leukemias became relatively resistant to rejection by the hybrid, partially lost its sensitivity to X.1 antiserum in vitro, and in electron micrographs was seen to produce fewer virions. The serum of untreated (BALB x B6) hybrids often contains cytotoxic antibody against leukemia cells, some of it probably anti-X.1. But another commonly occurring antibody, which is cytotoxic for C57BL leukemia EL4, appears to belong to another (undefined) system.     

Source and hormone-dependence of GLx-gp70 in mouse serum

The gp70 family of glycoproteins is distinguished by the role of these molecules as constituents of C-type viral envelopes and also as Mendelian cellular constituents expressed independently of virus production. The source of G(IX)-gp70 in the serum of 129 strain mice, which are not overt producers of virus, could not be traced to any organ or tissue that is known to be G(IX)-positive by serological tests. Hematopoietic tissues were excluded as source of serum G(IX)-gp70 by tests with reciprocal radiation chimeras made from 129 and 129-G(IX)(-) donors and recipients. Thymus and spleen were excluded because excision of these organs did not affect levels of G(IX)-gp70 in the serum. The serum of young adult 129 males contains roughly four times as much G(IX)-gp70 as adult 129 females and the levels rise in both sexes with increasing age. Castration of 129 males reduced the level of serum G(IX)-gp70 to that of females, and the level was fully restored by testosterone. Thus the epididymis and seminal fluid, though rich in G(IX)-gp70, do not contribute significant amounts of G(IX)-gp70 to the serum. The level of G(IX)-gp70 in the serum of testosterone-treated females, though more than double that of untreated females, did not reach the level of normal males, under the conditions tested. This may signify that G(IX)-gp70 production by males is subject to imprinting by testosterone in early life. Evidently the main source of serum G(IX)-gp70 is a tissue or organ that is common to males and females, is directly or indirectly responsive to testosterone, and has not so far been identified serologically as G(IX)- positive.     

Influence of Fv-1 alleles on cellular expression of gp70

Type-variants of gp70 (glycoprotein-70), which is the major envelope protein of C-type mouse virus and is also found in plasma membranes, are identified immunogenetically by the antigens Gix and Ec. Cellular expression of Gix+ gp70 does not depend on production of virus, but expression of Ec+ gp70 (formerly X-gp70) has been observed only in AKR and other strains of mice that produce large amounts of virus throughout life. To test the inference that cellular expression of Ec+ gp70 is secondary to production of virus we examined the effect of Fv-1 alleles, which govern the replicability of N-tropic and B-tropic C-type virus, on the expression of Ec+ gp70 on thymocytes. By typing thymocytes of Fv-1-congenic mice for Ec+ gp70 was found that manifestation of the Ec+ gp70 phenotype requires the Fv-1n allele, which is permissive for replication of N-tropic virus produced by AKR and other virus-producing mouse strains. Substitution of the Fv-1b allele for the Fv-1n allele abolishes demonstrable expression of Ec+ gp70 by AKR thymocytes at ages up to 9 mo, the oldest AKR mice tested.     

THE GIX SYSTEM : A CELL SURFACE ALLO-ANTIGEN ASSOCIATED WITH MURINE LEUKEMIA VIRUS; IMPLICATIONS REGARDING CHROMOSOMAL INTEGRATION OF THE VIRAL GENOME

This report concerns a cell surface antigen (G_IX; G = Gross) which exhibits mendelian inheritance but which also appears de novo in cells that become productively infected with MuLV (Gross), the wild-type leukemia virus of the mouse. In normal mice, G_IX is a cell surface allo-antigen confined to lymphoid cells and found in highest amount on thymocytes. Four categories of inbred mouse strains can be distinguished according to how much G_IX antigen is expressed on their thymocytes. G_IX^- strains have none; in the three G_IX⁺ categories, G_IX³, G_IX², and G_IX¹, the amounts of G_IX antigen present (per thymocyte) are approximately in the ratios 3:2:1. A study of segregating populations derived mainly from strain 129 (the prototype G_IX³ strain) and C57BL/6 (the prototype G_IX^- strain) revealed that two unlinked chromosomal genes are required for expression of G_IX on normal lymphoid cells. The phenotype G_IX⁺ is expressed only when both genes are present, as in 129 mice. C57BL/6 carries neither of them. At one locus, expression of G_IX is fully dominant over nonexpression (G_IX fully expressed in heterozygotes). At the second locus, which is linked with H-2 (at a distance of 36.4 ± 2.7 units) in group IX (locus symbol G_IX), expression is semidominant (50% expression of G_IX in heterozygotes); gene order T:H-2:Tla:G_IX. As a rule, when cells of G_IX^- mice or rats become overtly infected with MuLV (Gross), an event which occurs spontaneously in older mice of certain strains and which also commonly accompanies malignant transformation, their phenotype is converted to G_IX⁺. This invites comparison with the emergence of TL⁺ leukemia cells in TL^- mouse strains which has been observed in previous studies and which implies that TL^- → TL⁺ conversion has accompanied leukemic transformation of such cells. So far the only example of G_IX^- → G_IX⁺ conversion taking place without overt MuLV infection is represented by the occurrence of GCSA^-:G_IX⁺ myelomas in BALB/c (GCSA:G_IX^-) mice. Unlike the other Gross cell surface antigen described earlier, GCSA, which is invariably associated with MuLV (Gross) infection and never occurs in its absence, G_IX antigen sometimes occurs independently of productive MuLV infection; for example, thymocytes and some leukemias of 129 mice are GCSA^-:G_IX⁺, and MuLV-producing sarcomas may be GCSA⁺:G_IX^-. The frequent emergence of cells of G_IX⁺ phenotype in all mouse strains implies that the structural gene coding for G_IX antigen is common to all mice. There is precedent for this in the TL system, in which two of the Tla genes in linkage group IX appear to be ubiquitous among mice, but are normally expressed only in strains of mice carrying a second (expression) gene. It is not yet certain whether either of the two segregating genes belongs to the MuLV genome rather than to the cellular genome. This leaves the question whether MuLV may have a chromosomal integration site still debatable. But there is a good prospect that further genetic analysis will provide the answer and so elucidate the special relationship of leukemia viruses to the cells of their natural hosts.     

Endogenous oncornaviral gene expression in adult and fetal mice: quantitative, histologic, and physiologic studies of the major viral glycorprotein, gp70

Endogenous expression of the murine leukemia virus (MuLV) genome has been studied in a number of strains of mice. Expression of the major envelope glycoprotein, gp70, is restricted to certain anatomical sites and cell types, prominent among which are lymphoid and epithelial cells. On a quantitative basis, the major site of gp70 expression is the male genital tract. During development, gp70 first appears in the hematopoietic liver of 14-day-old embryos and by day 18, it is already expressed at anatomical sites similar to those of the adult. In toto, these results show that control of expression of the MuLV genome in adult and developing mice is linked to differentiation.     

Friend erythroleukemia antigen. A viral antigen specified by spleen focus-forming virus and differentiation antigen controlled by the Fv-2 locus

Serum from C57BL/6 (B6) mice hyperimmunized with NB-tropic Friend virus complex (FV) was cytotoxic for FV-induced erythroleukemic spleen cells and B6 Friend-murine leukemia virus (F-MuLV) lymphoma cells. Cytotoxic activity for erythroleukemia cells remained after repeated absorption of B6 anti-FV antiserum with Friend-Moloney-Rauscher MuLV lymphoma cells but was removed by absorption with erythroleukemia cells induced by FV or Rauscher Vrus. This serologic test system identified a previously unrecognized cell-surface antigen of mouse leukemia, designated Friend Erythroleukemia (FE) antigen to signify its appearance as a determinant of virally induced erythroleukemic differentiation. FE antigen was not detected on 15 transplanted or primary hematopoietic neoplasms, nor was it detected on cells infected with ecotropic, xenotropic, or dualtropic MuLV isolates in tissue culture. Two spleen focus-forming virus (SFFV) nonproducer cells of rats and one of mice express FE antigen in amounts comparable to primary erythroleukemia cells. Absorption tests with FE typing serum indicated that FE antigen was expressed on bone marrow and spleen but not thymus, lymph node, or peripheral blood of uninfected AKR, BALB/c, DBA, and SWR mice; all five tissues from B6 and C57L were negative. Quantitiative absorption tests indicated that the expression of FE antigen, though much lower than on erythroleukemic cells, was greatest on fetal liver, less on bone marrow, and lowest on spleen from BALB and SWR mice. Treatment of BALB/c or SWR fetal liver, bone marrow, spleen, thymus, or lymph node cells with FE typing serum did not result in significant lysis. These observations are consistent with the interpretation that FE antigen is expressed by a minor cell population present in fetal liver, bone marrow, and spleen. Expression of FE antigen, determined by absorption with bone marrow cells, cosegregated with inheritance of the Fv-2s allele in the 17 inbred, 7 recombinant inbred, and 4 congenic mouse strains tested. In summary, the FE antigenic system identifies a cell-surface determinant that has the properties of a SFFV-specified antigen and hematopoietic differentiation alloantigen controlled by the Fv-2 locus. The similarity of FE antigen to Abelson antigen may provide insight into the pathogenic properties of defective transforming MuLV.     

Lymphomagenicity of recombinant mink cell focus-inducing murine leukemia viruses

Recombinant mink cell focus-inducing (MCF) murine leukemic viruses, as well as ecotropic and xenotropic viruses, were tested for ability to accelerate or cause development of lymphoma in AKR and other strains of mice. Of the three classes of virus isolated from AKR, only the MCF viruses were able to accelerate development of AKR lymphoma. This fully supports the idea that the MCF viruses are the proximal cause of spontaneous AKR lymphoma. MCF lymphomagenicity was strain specific, however, in that AKR MCF viruses did not induce lymphomas in many murine strains; they were moderately lymphomagenic in C3H/Bi mice and in National Institutes of Health Swiss partially congenic for Akv-1 or Akv-2. In contrast, MCF viruses from nonthymic hematopoietic neoplasms of C3H/Fg, BALB/c, or mice partially congenic for ecotropic virus loci (Akv-1, Akv-2, Fgv-1, C58v-1, and C58v-2) were not able to accelerate or cause lymphomia in AKR or any other mouse strain tested, including some of the strains of origin. MCF lymphomagenicity correlated with thymic origin in the virus and with ability to replicate in the thymus.