Lymphocyte specificity to protein antigens V. Conformational dependence of activation of cytochrome c-specific T cells

Variations in the immunogenic and antigenic properties of native and denatured forms of cytochrome c were observed depending on the strain of mouse tested. In C57BL/6 and (C57BL/6 X DBA/2)F₁ (BDF₁ mice, priming with either native or denatured cytochrome c (apocytochrome c) gave rise to T cell blasts responding in a similar fashion to the two forms of the antigen and to different peptides derived from CNBr cleavage of the protein when tested for proliferation in the presence of C57BL/6 or BDF₁ accessory cells. A different pattern of proliferation was observed when apocytochrome c-specific DBA/2 or BDF_l T cell blasts were tested with DBA/2 accessory cells. In this case, no response was obtained to heme peptide 1-65. This was not due to an inability of DBA/2 macrophages to process and present heme peptide 1-65, as they were able to present this antigen to native cytochrome c-specific BDF₁ T cell blasts. Thus, it seems that different sets of clones are generated upon priming BDF₁ mice with denatured cytochrome c which are able to recognize different sets of peptides depending on the nature of the accessory cells. The results obtained are consistent with the hypothesis that degradation and presentation of native and denatured cytochrome c by macrophages is dependent on the three-dimensional conformation of the protein.     

Complete nucleotide sequences of the mitochondrial genomes of two avian malaria protozoa, <Emphasis Type="Italic">Plasmodium gallinaceum</Emphasis> and <Emphasis Type="Italic">Plasmodium juxtanucleare</Emphasis>

We analyzed mitochondrial genomes of two avian malaria protozoa, Plasmodium gallinaceum and Plasmodium juxtanucleare. Both mitochondrial genomes were estimated to be 6,002 and 6,014 bp in length, respectively, and to have the identical gene organization and contents to that of other Plasmodium species previously analyzed; three functional genes for cytochrome c oxidase subunit I, III, and cytochrome (cyt b), with following sets of discontinuous and scrambled 15 ribosomal subunit RNA (rRNA) genes. Similarities of the three protein-coding genes showed closer relationship within avian malaria protozoa rather than mammalian Plasmodium species. In addition, we showed the tandem repeated structure of each mitochondrial genome of both P. gallinaceum and P. juxtanucleare as well as previously found in mammalian Plasmodium species. This study revealed the complete sequences and structure of the mitochondrial genomes of avian malaria protozoa for the first time.     

The murine immune response to the male-specific antigen mouse testicular cytochrome c

Male and female A/J mice were examined for their ability to elicit T lymphocyte and antibody (Ab) responses to the male-specific Ag, mouse testicular cytochrome c (Mt cyt).T lymphocytes from both male and female mice primed in vivo responded to the Ag in in vitro proliferation assays, and the dose-response curves were statistically indistinguishable. In addition, similar levels of Ab to Mt cyt were observed in immunized male and female mice. The B cells producing the Ab had switched isotypes to IgG1 and IgG2a, indicating that the self-reactive T helper (Th) cells in male mice were functional. Thus, male mice do not appear to be immunologically tolerant to Mt cyt, at least at the Th and B lymphocyte levels. No evidence for disease was found in male mice primed with Mt cyt. Major histocompatibility complex (MHC) class II-positive antigen-presenting cells are present in the testes and these were shown in vitro to process and present Mt cyt to a Tcell hybridoma specific for the synthetic peptide Mt cyt 93-104. However, the hybridoma was not activated in the absence of exogenous Mt cyt 93-104 or Mt cyt, indicating that endogenous Mt cyt is not normally processed in sufficient quantity to effectively load MHC class II molecules with this particular Mt cyt-derived peptide. Notwithstanding any immunologic privilege of the testes, the lack of tolerance to Mt cyt and its failure to elicit an autoimmune disease could extend from the low levels of processed Mt cyt Ag available for T cell recognition. The T cell response elicited by Mt cyt contrasts the lack of response to mouse somatic cytochrome c which differs from Mt cyt at 13 amino acid residues and is expressed in most tissues and at higher levels.     

Antigen presentation is a function of all B cell subpopulations separated on the basis of size

Purified splenic B cells from nonimmune mice were separated by counterflow centrifugal elutriation into 6 subpopulations containing cells of discrete sizes ranging from 119 to 200 μm³. B cells of each subpopulation were competent to process and present a native globular protein antigen, cytochrome c, to a cytochrome c-specific T cell hybrid. In all cases, the B cells' antigen-presenting function was radiation sensitive and did not require T cells or T cell products, since B cells fixed with paraformaldehyde effectively presented a carboxyl-terminal peptide fragment of cytochrome c containing the T cell determinant. Furthermore, the antigen-presenting function of B cells of each subpopulation was augmented by treatment with submitogenic doses of the F(ab')₂ fragment of rabbit anti-mouse Ig antibodies, in that 10-30-fold fewer B cells were required and higher maximal T cell responses were achieved, indicating that B cells of all sizes are capable of being regulated in their antigen presentation function through their surface Ig. In addition, B cells of each subpopulation responded to soluble factors present in the supernatants of activated T cells as evidenced by an increase in volume and by the uptake of [³H]thymidine. These results indicate that B cells, regardless of size, are able to participate in at least two essential phases of T cell-dependent antibody responses, initiating the interaction by processing and presenting antigen to helper T cells and responding to soluble helper factors secreted by activated T cells.     

Overcoming the Heme Paradox: Heme Toxicity and Tolerance in Bacterial Pathogens

Virtually all bacterial pathogens require iron to infect vertebrates. The most abundant source of iron within vertebrates is in the form of heme as a cofactor of hemoproteins. Many bacterial pathogens have elegant systems dedicated to the acquisition of heme from host hemoproteins. Once internalized, heme is either degraded to release free iron or used intact as a cofactor in catalases, cytochromes, and other bacterial hemoproteins. Paradoxically, the high redox potential of heme makes it a liability, as heme is toxic at high concentrations. Although a variety of mechanisms have been proposed to explain heme toxicity, the mechanisms by which heme kills bacteria are not well understood. Nonetheless, bacteria employ various strategies to protect against and eliminate heme toxicity. Factors involved in heme acquisition and detoxification have been found to contribute to virulence, underscoring the physiological relevance of heme stress during pathogenesis. Herein we describe the current understanding of the mechanisms of heme toxicity and how bacterial pathogens overcome the heme paradox during infection.Iron is an essential cofactor for many enzymes found within all kingdoms of life. Bacterial pathogens are no exception to this rule, and therefore, they must acquire iron from their hosts in order to cause disease. Iron is a transition metal that can cycle between redox states, making it a valuable cofactor for biological processes. Ferric iron is water insoluble, and as such, it requires specialized proteins to facilitate its mobilization and to maintain intracellular reservoirs. In mammalian species, lactoferrin and transferrin transport iron, while ferritin stores iron. The most abundant form of iron in vertebrates, however, is bound within a porphyrin ring as ferriprotoporphyrin IX (heme). Heme solubilizes iron and enhances its catalytic ability by 5 to 10 orders of magnitude (14, 111). This catalytic activity is harnessed by hemoproteins involved in oxygenation reactions, oxidative stress responses, electron transport, oxygen transport, oxygen sensing, and oxygen storage. While heme is a necessary prosthetic group for many proteins, it also has the potential to cause toxicity at high concentrations. This property of heme requires that the intracellular pool of heme be tightly regulated.Intracellular heme concentrations within vertebrates are tightly controlled by balancing the rates of heme biosynthesis and catabolism (87). Free heme released into the plasma by the dissolution of hemoproteins from lysed erythrocytes is quickly scavenged by albumin, hemopexin, and the serum lipocalin α₁-microglobulin (13, 23, 44, 75). Any hemoglobin released into the serum is tightly bound by haptoglobin and subsequently cleared by tissue macrophages (51). It is evident that the vital yet reactive nature of heme requires that its production, degradation, and availability be carefully controlled in metazoans. Meeting these demands reduces heme-mediated toxicity and minimizes surplus free heme. Most bacterial pathogens that infect vertebrate tissues have systems dedicated to the acquisition of heme for use as a nutrient iron source. However, the toxicity of heme presents a paradox for microorganisms that satisfy their nutrient iron requirement through heme acquisition. This heme paradox is resolved through tightly regulated systems dedicated to balancing the acquisition of heme with the prevention of heme-mediated toxicity.     

Presentation of a horse cytochrome c peptide by multiple H-2b class I major histocompatibility complex (MHC) molecules to C57BL/6- and bm1-derived cytotoxic T lymphocytes: Presence of a single MHC anchor residue may confer efficient peptide-specific CTL recognition

In this study the immunogenic tryptic fragment from a horse cytochrome c (cyt c) digest recognized by cytotoxic T lymphocytes (CTL), induced by in vitro peptide stimulation from C57BL/6 (B6) and mutant B6.C-H-2^bm1 (bm1) mice is identified. An identical sequence, p40—53, is recognized by CTL from both B6 and bm1 mice. In addition, both B6 and bm1 cloned CTL lines display unusual major histocompatibility complex (MHC) class I-restricted recognition of this peptide in that they respond to it in the context of H-2K^b, H-2D^b, and H-2K^bm1 class I molecules, although the sequence lacks the usual structural K^b and D^b peptide-binding motifs. Truncated analogues which resemble the lengths of naturally processed MHC class I-presented peptides, confer reactivity for B6 and bm1 CTL against EL4 (H-2^b) targets as well as the L cell transfectants, L + K^b, L + D^b, and L + K^bm1. The antigenic peptide with the greatest potency is p41—49, which appears to be generated by angiotensin converting enzyme cleavage of the full-length p40—53 tryptic peptide. The minimum antigenic peptide recognized by both B6 and bm1 CTL, and which targets lysis on each of the transfectants, is the hexamer p43—48 peptide from horse cyt c. Residues Pro⁴⁴ and Thr⁴⁷, which occupy polymorphic positions with respect to other species-variant cyt c molecules, influence recognition of these peptides differently for the B6 and bm1 CTL. The ability of H-2K^b, H-2D^b, and mutant H-2K^bm1 class I molecules to present the same peptide to a single cloned CTL is discussed in the context of current knowledge of peptide anchor residues and side chain-specific binding pockets in the MHC class I peptide-binding site.     

Polymerase chain reaction-based identification of <Emphasis Type="Italic">Plasmodium</Emphasis> (<Emphasis Type="Italic">Huffia</Emphasis>) <Emphasis Type="Italic">elongatum</Emphasis>, with remarks on species identity of haemosporidian lineages deposited in GenBank

Numerous lineages of avian malaria parasites of the genus Plasmodium have been deposited in GenBank. However, only 11 morphospecies of Plasmodium have been linked to these lineages. Such linking is important because it provides opportunities to combine the existing knowledge of traditional parasitology with novel genetic information of these parasites obtained by molecular techniques. This study linked one mitochondrial cytochrome b (cyt b) gene lineage with morphospecies Plasmodium (Huffia) elongatum, a cosmopolitan avian malaria parasite which causes lethal disease in some birds. One species of Plasmodium (mitochondrial cyt b gene lineage P-GRW6) was isolated from naturally infected adult great reed warblers (Acrocephalus arundinaceus) and inoculated to one naive juvenile individual of the same host species. Heavy parasitaemia developed in the subinoculated bird, which enabled identification of the morphospecies and deposition of its voucher specimens. The parasite of this lineage belongs to P. elongatum. Illustrations of blood stages of this parasite are given. Other lineages closely related to P. elongatum were identified. The validity of the subgenus Huffia is supported by phylogenetic analysis. Mitochondrial cyt b gene lineages, with GenBank accession nos. AF069611 and AY733088, belong to Plasmodium cathemerium and P. elongatum, respectively; these lineages have been formerly attributed to P. elongatum and P. relictum, respectively. Some other incorrect species identifications of avian haematozoa in GenBank have been identified. We propose a strategy to minimise the number of such mistakes in GenBank in the future.     

Langerhans cells transport Leishmania major from the infected skin to the draining lymph node for presentation to antigen-specific T cells

Murine epidermal Langerhans cells (LC) have been shown to internalize Leishmania major, a cause of human cutaneous leishmaniasis, and to stimulate a vigorous parasite-specific T cell response. The present study emphasizes the critical role of LC in leishmaniasis by documenting directly that LC have the ability to transport L. major from the skin to the draining lymph node (LN). This was revealed by irreversible labeling of LC with a fluorescent cell linker and in vivo tracking. In contrast, no migration to the LN was seen with L. major-infected macrophages. These findings were consistent with the results of mixed labeling immunohistology showing that early in infection the expression of parasite antigen in the LN draining the lesion was confined to dendritic cells and could not be detected in macrophages. Furthermore, dendritic cells in LN draining the site of cutaneous infection stimulated L. mayor-primed T cells in vitro and, most notably, were able to activate unprimed T cells capable of mediating parasite-specific delayed-type hypersensitivity reactivity in vivo. Taken together, the results indicate that LC capture L. major in the skin and transport it to the regional LN for initiation of the specific T cell immune response.     

Induction of tolerance in freshly isolated alloreactive CD4+ T cells by activated T cell stimulators

Activated human T cells express major histocompatibility complex class II proteins, and their potential to present antigens to T cell clones has been documented extensively. The effect of such T-T presentation on responder T cell clones has been shown to be the induction of tolerance, sometimes accompanied by activation. To investigate whether freshly isolated responder T cells are also susceptible to such induction of tolerance by activated T cells functioning as antigen-presenting cells (APC), we have used the capability of unprimed ex vivo T cells to respond in a proliferation assay in vitro to alloligands on professional APC. We show that purified human T cells ex vivo, when exposed to alloligand on activated T cells for primary allorecognition In vitro, fail to mount a proliferative response. Priming of responder CD4⁺ T cells with alloligand expressed on activated T cells results in the induction of nonresponsiveness to a subsequent challenge by competent allo-APC. This ability of activated, HLA-DR⁺ T cells to induce nonresponsiveness to subsequent challenge in bulk CD4⁺ T cell populations ex vivo has interesting implications for infections involving T cells such as human immunodeficiency virus.     

High-Level Expression of Chlamydia psittaci Major Outer Membrane Protein in COS Cells and in Skeletal Muscles of Turkeys

The omp1 genes encoding the major outer membrane proteins (MOMPs) of avian Chlamydia psittaci serovar A and D strains were cloned and sequenced. The nucleotide sequences of the avian C. psittaci serovar A and D MOMP genes were found to be 98.9 and 87.8% identical, respectively, to that of the avian C. psittaci serovar A strain 6BC, 84.6 and 99.8% identical to that of the avian C. psittaci serovar D strain NJ1, 79.1 and 81.1% identical to that of the C. psittaci guinea pig inclusion conjunctivitis strain, 60.9 and 62.5% identical to that of the Chlamydia trachomatis L2 strain, and 57.5 and 60.4% identical to that of the Chlamydia pneumoniae IOL-207 strain. The serovar A or D MOMPs were cloned in the mammalian expression plasmid pcDNA1. When pcDNA1/MOMP A or pcDNA1/MOMP D was introduced into COS7 cells, a 40-kDa protein that was identical in size, antigenicity, and electrophoretic mobility to native MOMP was produced. Recombinant MOMP (rMOMP) was located in the cytoplasm of transfected COS7 cells as well as in the plasma membrane and was immunoaccessible. Intramuscular administration of pcDNA1/MOMP in specific-pathogen-free turkeys resulted in local expression of rMOMP in its native conformation, after which anti-MOMP antibodies appeared in the serum.     

A retro-inverso analog mimicks the cognate peptide epitope of a CD4+ T cell clone

Synthetic analogs of peptide epitopes may activate specific T helper cells, antagonize their antigen receptors, or block recognition by competing for major histocompatibility complex (MHC) class II binding sites. Rationally designed peptides may therefore prove useful as vaccines and for treatment of autoimmune diseases and allergies mediated by CD4⁺ T cells. However, their susceptibility to proteolytic degradation limits the applicability of conventional peptides in vivo. By contrast, retro-inverso analogs, in which a native sequence is substituted with D -amino acids linked with a reversed backbone, resist proteolysis and still maintain the side chain topology of the corresponding natural peptide. We report here that an end group-modified retro-inverso analog of the IgG2a^b heavy chain allopeptide determinant γ2a^b 435–447 was recognized by an I-A^d-restricted, γ2a^b 435–447-reactive T cell clone. The pseudopeptide elicited near-maximal interleukin-2 responses, although 300-fold higher concentrations were needed than the native determinant. The weaker antigenicity of the retro-inverso analog could be fully accounted for by an impaired I-A^d binding capacity, which might reflect reduced ability of the distorted main chain to form hydrogen bonds with I-A^d. Glycine substitution at the residue corresponding to the first primary anchor (P1) of the native peptide abrogated I-A^d binding and antigenicity of the retro-inverso analog. Thus, the pseudopeptide resembled the native determinant with respect to orientation in the class II binding site, configuration of the epitopic side chains, and the constraints that governed the interactions between a major anchoring side chain and I-A^d. In conclusion, proteolytically resistant compounds with predefined capacity to interact with MHC class II allelic products and T cell antigen receptors may be designed by retro-inverso modification of native determinants.     

Functional annotation of the T‐cell immunoglobulin mucin family in birds

T‐cell immunoglobulin and mucin (TIM) family molecules are cell membrane proteins, preferentially expressed on various immune cells and implicated in recognition and clearance of apoptotic cells. Little is known of their function outside human and mouse, and nothing outside mammals. We identified only two TIM genes (chTIM) in the chicken genome, putative orthologues of mammalian TIM1 and TIM4, and cloned the respective cDNAs. Like mammalian TIM1, chTIM1 expression was restricted to lymphoid tissues and immune cells. The gene chTIM4 encodes at least five splice variants with distinct expression profiles that also varied between strains of chicken. Expression of chTIM4 was detected in myeloid antigen‐presenting cells, and in γδ T cells, whereas mammalian TIM4 is not expressed in T cells. Like the mammalian proteins, chTIM1 and chTIM4 fusion proteins bind to phosphatidylserine, and are thereby implicated in recognition of apoptotic cells. The chTIM4–immunoglobulin fusion protein also had co‐stimulatory activity on chicken T cells, suggesting a function in antigen presentation.     

Characterization of the murine immune response to the murine TSH receptor ectodomain: induction of hypothyroidism and TSH receptor antibodies

The thyrotropin receptor (TSHR) is the major autoantigen of human Graves' disease. In order to define the antigenicity of the TSHR in a defined model, we examined the immune response of BALB/c mice to immunization with a new bioactive, recombinant preparation of the ectodomain of the murine TSHR (mTSHR-ecd). Mice (n = 10) were immunized with 25–50 μg of insect cell expressed, purified and refolded, mTSHR-ecd in alum adjuvant containing pertussis toxin, on days 0, 21, 36, 50 and 70. Control mice received wild-type baculovirus-infected insect cell protein lysate, in a similar way. After 28 days, murine serum contained high titres of antibodies specific to mTSH-ecd and their titres continued to increase over 90 days. Antibody epitope mapping, using 26 peptides spanning the human TSHR-ecd, showed that a variety of regions of the ectodomain were antigenic. The earliest epitope included aa 22–41, but later two regions of reactivity were noted clustered towards the mid portion and carboxyl terminus of the ectodomain. The murine TSHR autoantibodies (TSHR-Abs) inhibited up to 78% of the binding of labelled TSH to native TSHR, demonstrating the presence of antibodies capable of blocking the native TSHR. We showed that these TSHR antibodies acted, in vitro, as TSH blocking antibodies, inhibiting TSH-induced generation of cyclic AMP in chinese hamster ovary (CHO) cells transfected with the hTSHR. Hence, the antibody response to mTSHR-ecd was potentially antagonistic in its influence on the TSHR. Assessment of thyroid function in the immunized mice showed a fall in serum total T3 by 90 days and markedly elevated murine TSH levels (from 64.0 to 239.6 ng/ml), confirming the onset of thyroid failure. However, thyroid histology remained grossly normal. These data demonstrate that mTSHR-ecd is a potent antigen with three major immunogenic regions. The induced mTSHR-Abs blocked TSH action in vivo and reduced murine thyroid function.     

Taxonomical developments in the family Polyomaviridae

The Polyomaviridae Study Group of the International Committee on Taxonomy of Viruses (ICTV) has recommended several taxonomical revisions, as follows: The family Polyomaviridae, which is currently constituted as a single genus (Polyomavirus), will be comprised of three genera: two containing mammalian viruses and one containing avian viruses. The two mammalian genera will be designated Orthopolyomavirus and Wukipolyomavirus, and the avian genus will be named Avipolyomavirus. These genera will be created by the redistribution of species from the current single genus (Polyomavirus) and by the inclusion of several new species. In addition, the names of several species will be changed to reflect current usage.     

Dendritic cell expansion occurs in mesenteric lymph nodes of B10.BR mice infected with the murine nematode parasite Trichuris muris

Dendritic cells (DCs) are a crucial element in the immune system and bridge innate and adaptive immunity. CD11c⁺ B220^– DCs residing in Peyers patches (PPs) have the ability to produce interleukin 10 (IL-10) and induce T helper (Th2) development. Evidence suggests that CD11c⁺ B220^– DCs maintain the gut environment by suppressing Th1 responses with IL-10, resulting in a Th2-dominat gut environment. Th2 effectors are required for protection against the murine nematode parasite Trichuris muris, and thus CD11c⁺ B220^– DCs may be involved in the induction of Th2 cells in T. muris infection. In the present study, the kinetics of CD11c⁺ B220^– DCs were analyzed in mesenteric lymph nodes of B10.BR mice infected with the E-J isolate of T. muris, and the cellular expansion of CD11c⁺ B220^– DCs was also observed. As well, the DC expansion was consistent with the occurrence of worm expulsion augmented by IL-4 and IL-13. The evidence here suggests the involvement of CD11c⁺ B220^– DCs in protective Th2 responses to T. muris infection.An erratum to this article can be found at     

B lymphocyte recognition of cytochrome c: higher frequency of cells specific for self versus foreign antigen early in the immune response and V gene usage in the response to self antigen

To study immunoglobulin gene usage in the antibody response of mice to the self antigen (Ag) mouse cytochrome c (cyt), B cell hybridomas were prepared from splenic B cells of immunized BALB/c mice prior to the onset of somatic mutation, i.e. 3 days after injecting ovalbumin (OVA)-primed mice with mouse cyt coupled to OVA. Monoclonal antibodies (mAb) from all of the seven primary hybridomas we obtained were sensitive to a single amino acid substitution from aspartic acid to glutamic acid at position 62 in mouse cyt. This is the specificity of the vast majority of B cells responding to mouse cyt as determined from assays of B cells activated in splenic fragment cultures. Six of the mAb derive from the 19.1.2 J558 V_H gene which is also used in the response to α (1 → 6) dextran and three of these mAb derive from the R9 V_x gene, a member of the V_xOx-1 family. The other mAb derive from distinct, although similar, V_x genes. Attempts to obtain hybridomas secreting primary (unmutated) mAb specific for cyt foreign to mice have been hampered by the much lower frequency of B cells responding early to foreign cyt in comparison to the self Ag. This suggests that, contrary to expectation of tolerance mechanisms, in naive BALB/c mice B lymphocytes specific for a single epitope on self cyt are present in higher frequency than B lymphocytes specific for similar epitopes on foreign cyt. Possible explanations for this result include biased expression in the B cell repertoire of the particular combination of V genes encoding mouse cyt-specific mAb or to positive selection of developing B lymphocytes by endogenous Ag.     

Multiple copies of <Emphasis Type="Italic">SRY</Emphasis> on the large Y chromosome of the Okinawa spiny rat, <Emphasis Type="Italic">Tokudaia muenninki</Emphasis>

The Okinawa spiny rat, Tokudaia muenninki, is the only species with a Y chromosome in the genus Tokudaia. Its phylogenic relationship with two XO/XO species, Tokudaia osimensis and Tokudaia tokunoshimensis, lacking a Y chromosome and the mammalian sex-determining gene SRY, is unknown. Furthermore, there has been little cytogenetic analysis of the sex chromosomes in T. muenninki. Therefore, we constructed molecular phylogenetic trees with nucleotide sequences of cyt b, RAG1, and IRBP. All trees strongly supported that T. muenninki was the first to diverge from the Tokudaia ancestor, indicating that loss of the Y chromosome and SRY occurred in the common ancestor of the two XO/XO species after T. muenninki diverged. We found that the X and Y chromosomes of T. muenninki consisted of large euchromatic and heterochromatic regions by conducting G- and C-banding analyses. PCR, Southern blotting, and FISH revealed that T. muenninki males had multiple SRY copies on the long arm of the Y chromosome. At least three of 24 SRY sequences contained a complete open reading frame (ORF). A species-specific substitution from alanine to serine was found in all copies at the DNA-binding surface within the HMG-box, suggesting that it occurred in an original SRY.     

Isolation of a murine retrovirus with a temperature-sensitive src gene

A murine retrovirus containing the src gene of avian sarcoma virus ts LA31A was generated. In contrast to the avian sarcoma virus, our recombinant murine retrovirus can efficiently infect mammalian cells. Transformation of NIH3T3 cells by the recombinant murine retrovirus is temperature sensitive. At the permissive temperature of 34 degrees, cells form foci of rounded cells. At the nonpermissive temperature of 39 degrees, the infected cells remain flat and exhibit contact inhibition. No disease was observed following infection of newborn NFS/n mice with the ts mutant virus. In contrast, infection of newborn NFS/n mice with a recombinant murine retrovirus containing the wild-type src gene causes fibrosarcomas and hepatosplenomegaly.