Nonproducer Clones Research Articles

High-level production of membrane proteins in E. coli BL21(DE3) by omitting the inducer IPTG.

BackgroundFor membrane protein production, the Escherichia coli T7 RNA polymerase (T7 RNAP)-based protein production strain BL21(DE3) in combination with T7-promoter based expression vectors is widely used. Cells are routinely cultured in Lysogeny broth (LB medium) and expression of the chromosomally localized t7rnap gene is governed by the isopropyl-β-d-1-thiogalactopyranoside (IPTG) inducible lacUV5 promoter. The T7 RNAP drives the expression of the plasmid borne gene encoding the recombinant membrane protein. Production of membrane proteins in the cytoplasmic membrane rather than in inclusion bodies in a misfolded state is usually preferred, but often hampered due to saturation of the capacity of the Sec-translocon, resulting in low yields.ResultsContrary to expectation we observed that omission of IPTG from BL21(DE3) cells cultured in LB medium can lead to significantly higher membrane protein production yields than when IPTG is added. In the complete absence of IPTG cultures stably produce membrane proteins in the cytoplasmic membrane, whereas upon the addition of IPTG membrane proteins aggregate in the cytoplasm and non-producing clones are selected for. Furthermore, in the absence of IPTG, membrane proteins are produced at a lower rate than in the presence of IPTG. These observations indicate that in the absence of IPTG the Sec-translocon capacity is not/hardly saturated, leading to enhanced membrane protein production yields in the cytoplasmic membrane. Importantly, for more than half of the targets tested the yields obtained using un-induced BL21(DE3) cells were higher than the yields obtained in the widely used membrane protein production strains C41(DE3) and C43(DE3). Since most secretory proteins reach the periplasm via the Sec-translocon, we also monitored the production of three secretory recombinant proteins in the periplasm of BL21(DE3) cells in the presence and absence of IPTG. For all three targets tested omitting IPTG led to the highest production levels in the periplasm.ConclusionsOmission of IPTG from BL21(DE3) cells cultured in LB medium provides a very cost- and time effective alternative for the production of membrane and secretory proteins. Therefore, we recommend that this condition is incorporated in membrane- and secretory protein production screens.Electronic supplementary materialThe online version of this article (doi:10.1186/s12934-015-0328-z) contains supplementary material, which is available to authorized users.

Deep sequencing reveals different compositions of mRNA transcribed from the F8 gene in a panel of FVIII-producing CHO cell lines.

Coagulation factor VIII (FVIII) is one of the most complex biopharmaceuticals due to the large size, poor protein stability and extensive post-translational modifications. As a consequence, efficient production of FVIII in mammalian cells poses a major challenge, with typical yields two to three orders of magnitude lower than for antibodies. In the present study we investigated CHO DXB11 cells transfected with a plasmid encoding human coagulation factor VIII. Single cell clones were isolated from the pool of transfectants and a panel of 14 clones representing a dynamic range of FVIII productivities was selected for RNA sequencing analysis. The analysis showed distinct differences in F8 RNA composition between the clones. The exogenous F8-dhfr transcript was found to make up the most abundant transcript in the present clones. No correlation was seen between F8 mRNA levels and the measured FVIII productivity. It was found that three MTX resistant, nonproducing clones had different truncations of the F8 transcripts. We find that by using deep sequencing, in contrast to microarray technology, for determining the transcriptome from CHO transfectants, we are able to accurately deduce the mature mRNA composition of the transgene and identify significant truncations that would probably otherwise have remained undetected.

Plasmodium falciparum: mRNA co-expression and protein co-localisation of two gene products upregulated in early gametocytes

Genes encoding Plasmodium falciparum proteins Pfs16 and Pfpeg3/mdv1, specifically appearing in the parasitophorous vacuole of the early gametocytes, are upregulated at the onset of sexual differentiation. Analysis of asexual development in gametocyte producing and non-producing clones of P. falciparum indicated that these genes are also transcribed at a low level in asexual parasites, although their protein products are not detectable in these stages by immunofluorescence. Immunoelectron microscopic analysis of stage II gametocytes indicated that Pfs16 and Pfpeg3/mdv1 proteins co-localise in the parasitophorous vacuole membrane and in all derived membranous structures (such as the multi-laminate membrane whorls of the circular clefts in the infected erythrocyte cytoplasm and the membranes of the gametocyte food vacuoles). In this analysis both proteins were also observed for the first time in the membrane and in the lumen of distinct cleft-like structures in the erythrocyte cytoplasm.

Overexpression of ovine leptin in Pichia pastoris: physiological yeast response to leptin production and characterization of the recombinant hormone.

Ovine leptin was cloned in the methylotrophic yeast Pichia pastoris using a pPIC9K vector. Leptin was produced and secreted into the culture medium using the Saccharomyces cerevisiae alpha-mating factor prepro signal by five clones. Expression levels of leptin varied from clone to clone, depending on the copy number of the ob gene. Highest expression was observed with the single-copy clone S27 (250 mg/l). The modifications of culture conditions in batch and fed-batch culture increase the yield of protein. The use of higher cell concentration (63 g/l) before induction of oLept associate with a regulation of pH at 3.2, which decreases the effects of proteolysis, increases the expression level of the oLept to 402 mg/l. Moreover, compared with the non-producer clone, we observed a drastic decrease in growth rate and biomass yield in the leptin-producing clones. At the end of the fed-batch phase at pH 3.2 with clone S27, mortality rate reached 17.3%. Results showed that recombinant leptin production induced metabolic stress, and a negative impact on biomass yield and growth rate. We characterized the recombinant leptin produced by clone S27. It exhibited a molecular mass of 16 kDa, an N-terminal amino acid sequence identical to that of ovine leptin but with an additional tyrosine introduced by the cloning site. Moreover, it was found to be biologically active in vitro. The available production of a large quantity of oLept will strengthen the functional study for theoretical and practical purposes.

Transcriptional control of the IL-5 gene by human helper T cells: IL-5 synthesis is regulated independently from IL-2 or IL-4 synthesis

Background: IL-5 is fundamentally involved in eosinophilic inflammation. Control of IL-5 production may be effective for the management of allergic diseases. Objective: We aimed to find the transcriptional mechanisms that regulate the IL-5 gene to selectively control IL-5 synthesis. Methods: Allergen-specific T-cell clones and T-cell hybridomas were established from the peripheral blood lymphocytes of patients with asthma, and the transcriptional regulation of the IL-5 gene was investigated with transient transfection and electrophoretic mobility shift analysis. Results: A human IL-5 promoter/enhancer–luciferase gene construct, pIL-5(-511)Luc, was transcribed on activation of IL-5–producing T-cell clones, but not IL-5–nonproducing clones. pIL-5(–511)Luc was transcribed by T-cell hybridomas derived from fusion between IL-5–producing T-cell clones and an IL-5 gene–nonexpressing T-cell line, but not by hybridomas derived from IL-5–nonproducing T-cell clones. IL-5 synthesis was not only induced by T-cell receptor stimulation but also by IL-2 receptor stimulation. Binding of NF-AT, NF-κB, and AP-1 was induced by T-cell receptor (TcR) stimulation, although there was no significant upregulation of binding by IL-2 stimulation. Conclusion: IL-5 synthesis by human helper T cells is regulated at the transcriptional level. A unique transcriptional mechanism distinct from those regulating the IL-2 or IL-4 genes seems to control the IL-5 gene. Selective regulation of IL-5 gene transcription may be useful for treating eosinophlic inflammation. (J Allergy Clin Immunol 1999;103:S429-36.)

Regulatory Mechanisms of Human T Cell IL–5 Synthesis: Differential Roles of the Proximal Promoter–Binding Proteins in IL–5 Gene Transcription

Background: IL–5 is crucially involved in eosinophilic inflammation. We have previously reported that IL–5 synthesis by atopic and nonatopic asthmatics is significantly enhanced compared to control subjects. T cell IL–5 synthesis is regulated at the transcriptional level. The proximal human IL–5 promoter (–62 to –46) homologous to the conserved lymphokine element 0 (CLE0) is essential for activation–induced gene transcription by Th cells. Methods: Luciferase reporter analysis and gel shift analysis were performed. Results: The CLE0 homologous element is the overlapping binding site for a constitutive and an inducible binding factor. Site–directed mutagenesis successfully differentiated the two bindings, and revealed that the transcriptional induction was ascribed to the inducible binding, while the constitutive binding was rather inhibitory. A mutant element which lost the constitutive binding, but retained the inducible binding, exerted 3 times more transcriptional activity compared to the wild–type element. In contrast, another mutant element which lost the inducible binding and retained the constitutive binding exhibited no transcriptional induction. Gel shift analysis was performed to clarify that the inducible binding was more prominent and the constitutive binding was less in IL–5 producing Th clones compared to IL–5–nonproducing clones. Conclusion: The ratio of the inducible/constitutive binding to the CLE0 homologous element may determine the capacity of human Th cells to transcribe the IL–5 gene.

Phenotypic changes and loss of melanoma-specific endogenous C-type retroviruses in BL6 melanoma cells transfected with the H-2Kb gene.

The murine B16 melanoma and its sublines are low or totally deficient in expression of the H-2Kb class I major histocompatibility complex (MHC) gene. In clones derived from the B16F10BL6 subline, expression of the transfected or endogenous H-2Kb gene resulted in alterations of various phenotypic properties of these melanoma cells, among which was the loss of melanoma-associated antigen (MAA) expression. Because our previous immunoelectron microscopy studies showed that MAA was associated with a C-type ecotropic retrovirus specific for melanomas of C57BL/6 origin, we examined the effect of class I H-2Kb as well as class II H-2IAk gene expression on retrovirus production in subclones of BL6 melanoma cells. Here we have shown that expression of the transfected or endogenous H-2Kb gene resulted in the loss of production of budding, MAA-specific, C-type retrovirus particles. Northern blot analysis demonstrated expression of ecotropic retroviral mRNAs in both particle-producing and non-producing BL6 melanoma clones. Southern blot analysis of high-molecular-weight cellular DNAs using an ecotropic env-specific DNA probe indicated that the parental BL6-8 melanoma cells contained the C57BL/6 endogenous ecotropic MuLV (Emv-2) and at least three additional, novel ecotropic retroviral DNAs. Restriction enzyme analysis of the proviral DNA suggests that the loss of retrovirus production in the H-2Kb-expressing melanoma clones is the result of multiple rearrangements in the novel proviral DNAs. Thus, phenotypic changes observed in the H-2Kb gene-transfected BL6 melanoma cells were associated with loss of endogenous melanoma-specific ecotropic retrovirus production.

Multiple sub-sets of CD4+ and CD8+ cytotoxic T-cell clones directed to autologous human melanoma identified by cytokine profiles.

CD4+ and CD8+ cytotoxic T-cell (CTL) clones, selected for T-cell-receptor (TcR)-dependent lysis of the autologous tumor and isolated from peripheral-blood lymphocytes (PBL) or tumor-infiltrating lymphocytes (TIL) of 3 melanoma patients, were characterized for the pattern of 13 different cytokines released by antibody- or tumor-mediated triggering. Induction or enhancement of cytokine release by anti-CD3 monoclonal antibody (MAb) led to the identification of 2 major sub-sets of CD8+ CTL clones on the basis of production of IL-4. Within the 2 groups of IL-4-producing or non-producing clones, further sub-sets could be identified on the basis of differential production of IL-1 beta, IL-2, IL-6, IL-8, IL-10, TNF-alpha, TNF beta and IFN-gamma. A similar analysis performed on a panel of CD4+ CTL clones indicated multiple patterns consistent with at least 4 major sub-sets, but further complexity was evident in each sub-set on the basis of differential production of IL-1, IL2, IL-6, IL-10 and G-CSF. The cytokine profile of CD4+ and CD8+ clones, as determined after anti-CD3 stimulation, was different from the pattern seen after co-culture with autologous tumor, since many clones released cytokines such as IL-4, IL-10, IFN-alpha and -gamma, TNF-alpha and GM-CSF after activation with only 1 of the 2 stimuli. These results indicate that CD4+ and CD8+ CTL clones reacting to human melanoma belong to a highly complex repertoire of functional subsets characterized by distinct cytokine profiles. In addition, the cytokine pattern of each T-cell sub-set can be modulated by changing the activation signals delivered to the T cell.

Cell cycle kinetics of the accumulation of heavy and light chain immunoglobulin proteins in a mouse hybridoma cell line.

Rates of accumulation of immunoglobulin proteins have been determined using flow cytometry and population balance equations for exponentially growing murine hybridoma cells in the individual G1, S and G2+M cell cycle phases. A producer cell line that secretes monoclonal antibodies, and a nonproducer clone that synthesizes only kappa-light chains were analyzed. The pattern for the kinetics of total intracellular antibody accumulation during the cell cycle is very similar to the previously described pattern for total protein accumulation (Kromenaker & Srienc 1991). The relative mean rate of heavy chain accumulation during the S phase was approximately half the relative mean rate of light chain accumulation during this cell cycle phase. This indicates an unbalanced synthesis of heavy and light chains that becomes most pronounced during this cell cycle phase. The nonproducer cells have on average an intracellular light chain content that is 42% lower than that of the producer cells. The nonproducer cells in the G1 phase with low light chain content did not have a significantly higher rate of light chain accumulation relative to other G1 phase nonproducer cells. This is in sharp contrast to what was observed for the G1 phase producer cells. In addition, although the relative mean rate of accumulation of light chain was negative for G2+M phase nonproducer cells, the magnitude of this relative mean rate was less than half that observed for the producer cells in this cell cycle phase. This suggests that the mechanisms that regulate the transport of fully assembled antibody molecules through the secretion pathway differ from those which regulate the secretion of free light chains. The results reported here indicate that there is a distinct pattern for the cell cycle dynamics of antibody synthesis and secretion in hybridomas. These results are consistent with a model for the dynamics of secretion which suggests that the rate of accumulation of secreted proteins will be greatest for newborn cells due to an interruption of the secretion pathway during mitosis.

Isolation of a distally located gene possibly correlated with gametocyte production ability.

Previous studies were focussed on the attempt to correlate observable variations in the size of Plasmodium berghei chromosomes with the loss of ability to produce viable gametocytes. A temporal coincidence between the appearance of a subtelomeric deletion on P. berghei chromosome 5 and the loss of the ability to produce viable gametocytes was observed in a clone (HPE) directly derived from the high gametocyte-producer clone 8417 during mechanical passages. Interestingly enough, three P. berghei sexual-specific genes have already been mapped on internal fragments of this chromosome. A novel gene, clone 150, isolated from a genomic library of clone 8417 using a probe enriched for sexual-specific transcripts, maps on chromosome 5 within 100kb from the telomere. Subtelomeric deletions of chromosome 5 affecting two non-producer clones involve part of the transcribed region of this gene.

Transtrophic interactions in cassava

Cassava plants exude phloem saps at the base of the petioles of the youngest leaves. The effect of these nutrient-rich droplets on the interaction between the predatory miteTyphlodromalus limonicus and the herbivorous miteMononychellus tanajoa was investigated in a semi-field setting. These two organisms were chosen as a model system due to their strong association with cassava. The hypothesis that exudate production can be considered in terms of extrinsic defense was tested experimentally. Because non-producing clones could not be found exudate production was mimicked (or not) by applying honey droplets on the petioles of plants from which exuding plant parts were aborted. The experiments indicated that: (1) The presence of exudate on otherwise clean plants does not prevent extinction of the predator population, but the rate of population decrease is consistently lower than when no exudate is present. (2) When a second food source enables the predators to reproduce, higher population densities are always attained when the sugar source is also present. (3) Higher predator numbers invariably coincide with lower herbivore abundance. (4) Lower prey abundance does not lead to a reduction in egg production when honey is present. (5) Presence of honey leads to enhanced juvenile/adult survival or reduced emigration and thus to a higher number of female predators.

Plasmodium berghei: In vivo generation and selection of karyotype mutants and non-gametocyte producer mutants

We previously reported that karyotype and gametocyte-producer mutants spontaneously arose during in vivo asexual multiplication of Plasmodium berghei. Here we studied the rate of selection of these mutants in vivo. Gametocyte production and karyotype pattern were established at regular intervals during prolonged periods of asexual multiplication of clone 8417 of P. berghei. We found that karyotype mutants and mutants which do not produce gametocytes can replace the original high-producer parasites of clone 8417 within several weeks. The time at which mutants became predominant in the population in different experiments, however, differed greatly. Mutants with intermediate or low gametocyte production were not found. In experimentally mixed infections, containing parasites from two clones from different strains (clone 8417 of the ANKA strain; clone 1 of the K173 strain), high-producer parasites of clone 8417 were overgrown by parasites of the nonproducer clone. Nonproducer mutants from the originally high-producer clone 8417, however, were able to coexist with parasites of the nonproducer clone. These results demonstrate that in our experiments nonproducer parasites had a strong selective advantage during asexual multiplication compared to high producers. All karyotype mutants which became predominant in our experiments were nonproducers. In two experiments a change in karyotype coincided with the loss of gametocyte production which may suggest a causal relationship between these events.

Stabilization of a recombinant plasmid in yeast

Abstract When Saccharomyces cerevisiae AH22R − -2075 harboring pGLD p31-RcT which encodes a modified hepatitis B virus-surface antigen P31 (rHBsAg P31 mutien) coding gene and β-isopropylmalate dehydrogenase gene ( LEU2 ) was cultivated on a large scale in a leucine-lacking medium, rHBsAg non-producing colonies appeared at high frequency. Restriction enzyme analysis and Southern blot analysis with LEU2 probe revealed that the cells from these non-producing colonies had lost the expression plasmid, pGLD p31-RcT, and had unusual 2 μm DNA containing the LEU2 gene. This was caused by homologous recombination between 2 μm DNA and pGLD p31-RcT which contains a 2 μm DNA fragment and the LEU2 gene. Stabilization of the recombinant plasmid was achieved by the following three approaches: (i) reconstruction of the expression plasmid by separating the LEU2 gene from the 2 μm DNA fragment on the plasmid; (ii) selection of plasmid-stabilized clones by taking advantage of the differences in growth rate between producing and non-producing clones; and (iii) addition of a high concentration of l -histidine to the medium.

Cell‐cycle‐dependent protein accumulation by producer and nonproducer murine hybridoma cell lines: A population analysis

Single-cell rates of accumulation of cellular protein have been determined as a function of total protein content using flow cytometry and population balance equations for exponentially growing murine hybridoma cells in the individual G(1), S(1) and G(2) + M cell cycle phases. A novel flow cytometric technique for the identification of hybridoma cells in mitosis was developed and implemented. The data were obtained from a producer cell line which synthesizes and secretes high levels of monoclonal antibodies, and from a nonproducer clone which does not synthesize and secrete substantial amounts of antibody. The results indicate that the kinetics of single-cell protein accumulation in these two cell lines are considerably different. In particular, low protein content G(1) phase producer cells were characterized by a rate of protein accumulation which was approximately five times higher than the mean rate observed for higher protein content producer cells cycle phase. In contrast, the rate of accumulation of protein increased continuously with total protein content for the G(1) phase nonproducer cells. S phase hybridoma cells were characterized by a considerably lower rate of protein accumulation which did not vary much with protein content for either cell line. Finally, G(2) + M phase producer cells demonstrated a negative rate of protein accumulation which indicates that the rates of protein synthesis. It was hypothesized that these differences in total protein accumulation are caused by differences in monoclonal antibody accumulation. The distribution of rates suggests the need for a segregated approach to the modeling of the kinetics of antibody production in hybridomas.

Hepatitis B virus core antigen (HBc Ag) accumulation in an HBV nonproducer clone of HepG2-transfected cells is associated with cytopathic effect

Two clones of the hepatoblastoma HepG2 cell line transfected with complete hepatitis B virus deoxyribonucleic acid (HBV DNA) were studied. The kinetics and cytopathic effect of HBV Ag production in these two clones (one of which was an HBV producer) were compared to those of the parent HepG2 cell line. The presence of hepatitis B surface antigen (HBs Ag) and hepatitis B e antigen (HBe Ag) was determined by commercial enzyme-linked immunosorbent assay (ELISA). A hepatitis B core antigen (HBc Ag)-specific ELISA assay was developed, using monoclonal anti-HBc to detect HBc Ag. Amounts of HBs, HBe, and HBc Ags were partially quantified in both intracellular and extracellular compartments. The HBV producer clone excreted high levels of HBc, HBe, and HBs Ags from the beginning of the growth phase, and no cytopathic effect was observed. The HBV nonproducer clone produced high levels of HBs and HBe Ags, but there was no detectable HBc Ag in the supernatant; instead, HBc Ag accumulated in the intracellular compartment. In this clone, significant cell death was observed 4 days after cell confluency, corresponding with notable HBc Ag release into the supernatant. These results suggest a cytopathic effect associated with HBc Ag accumulation in the HBV nonproducer clone, but no cytopathic effect in the HBV producer clone. This suggests that virological factors as well as the host's immune response may be considered in explaining liver injury occurring in hepatitis B.

5‐bromodeoxyuridine enhancement of Inoue‐Melnick virus synthesis in human colon carcinoma cell lines

Inoue-Melnick virus (IMV) synthesis in naturally infected human colon carcinoma cell lines can be enhanced by 5-bromodeoxyuridine (BUDR). The optimal conditions for BUDR enhancement differed between two cell lines, SW-480 and DLD-1. SW-480 cells produced 100 times more infectious IMV than DLD-1 cells by BUDR treatment. A clonal difference in IMV synthesis in SW-480 cells was also observed. The highest titer of virus was found in the culture fluid of clone H (SW-480/H) cells treated with BUDR, and a herpes-like virus was detected by negative-staining electron microscopy of concentrates of the culture fluid. One nonproducer clone (SW-480/B) was also activated to produce virus when treated with BUDR.

Biologic and molecular characterization of producer and nonproducer clones from HUT-78 cells infected with a patient HIV isolate.

HUT-78 cells were infected with a reverse transcriptase (RT)-positive supernatant of a culture of peripheral blood lymphocytes (PBL) from an AIDS patient and then cloned. Of these clones, two have been isolated and characterized. Clone D10 is persistently and productively infected with an HIV variant. The clone F12, in spite of the presence of an integrated full-length HIV provirus, does not release virus particles in the medium. D10 and F12 clones substantially differ in terms of protein pattern; that is, D10 is super-imposable to infected HUT-78 cells, whereas F12 exhibits a decreased uncleaved p55 gag precursor and the presence of uncleaved gp160 and of a unique p19, although they do not show qualitative or quantitative differences in viral RNA synthesis. Restriction patterns of F12 proviral DNA do not show major genomic deletions. These results indicate that F12 clone cells carry an HIV genome with minor mutations that probably affect the correct production of viral proteins at a posttranscriptional level. In addition, the F12 clone is resistant to high-multiplicity superinfection with HIV-1 or HIV-2.

Properties of Producer and Non-Producer Clones of a Marek's Disease Turkey Lymphoblastoid Cell Line

The MDTC-RP30 lymphoblastoid cell line established from Marek's disease (MD) tumors in turkeys consisted of a heterogeneous population of cells 10 to 25 micron in diameter. Large-cell fractions obtained from a bovine fetal serum gradient had a higher titer of cell-associated MD virus (MDV) than the small-cell fractions. Seven single-cell clones were established from MDTC-RP30 cell line: two consisted of large cells, and the other clones consisted of small cells. Infectious MDV was rescued from large-cell clones in chicken embryo fibroblast cultures but not from small-cell clones. All clones contained MDV DNA sequences when hybridized against cloned MDV DNA. All clones were positive for a Marek's-disease-tumor-associated surface antigen and surface immunoglobulins. All but two small-cell clones caused MD in susceptible chickens. The two large-cell-type clones were uniformly tetraploid, whereas one small-cell clone was diploid and the four others were a mixture of diploid and tetraploid, with an occasional triploid cell. Evidence of translocation involving the male (Z) chromosome and the chromosome #3 was seen in one clone. These results suggest that MDV transforms different subpopulations of lymphocytes.

Host-Clonal Interactions in the Generation of Proviral Gene Deletion Variants

A nonproducer clone (clone A1) (from a retrovirus-infected guinea pig fibrosarcoma) has been described that under conditions of in vivo immunologic selection forms variants that lack the proviral gene. One trivial explanation for the apparent loss of the provirus from clone A1 is that clone A1 did not originate from a single cell. For evaluation of this possibility, subclones were derived from clone A1 and tested for tumor recurrence in nonimmune and virus-immune animals. Each of four subclones contained the A1 provirus and exhibited specific viral interference; tumor recurrences formed from each of these four subclones lacked the clone A1 provirus. Possible, when heterogeneous populations of retrovirus-infected cells are injected into nonimmune animals, some clones will elicit immunologic responses to retroviral antigens and subject other clones in the population to immunologic selective pressures. For testing this concept, clone A1 was injected in admixture with a producer clone (clone A4) into nonimmune Sewall Wright strain 2 guinea pigs. Tumors formed in nonimmune guinea pigs inoculated with clone A1 in admixture with clone A4 were shown to lack a detectable clone A1 provirus. The results supported the concept that a somatic mutational event (deletion of the proviral gene) occurs during growth of clone A1. When heterogeneous populations of retrovirus-infected cells are injected into animals, host-clonal interactions may occur leading to outgrowth of proviral gene deletion variants. These results supported the notion that interactions between tumor clones and the host can change the dominant clonal type of the tumor and provide a genetic basis for this change.

Genetic analysis of myeloproliferative leukemia virus, a novel acute leukemogenic replication-defective retrovirus.

The myeloproliferative leukemia virus (MPLV) is a new acute leukemogenic, nonsarcomatogenic retroviral complex that is generated during the in vivo passage of a molecularly cloned Friend ecotropic helper virus. Examination of viral RNA expression in MPLV-producing cells revealed the presence of two distinct molecular species that hybridized with a long terminal repeat or an ecotropic env-specific probe but not with a xenotropic mink cell focus-forming virus env-specific probe derived from a spleen focus-forming virus: an 8.2-kilobase species corresponding to a full-length Friend murine leukemia virus (F-MuLV) and a deleted species with a genomic size of 7.4 kilobases. This deleted virus was biologically cloned by limiting dilutions and single cell cloning in Mus dunni fibroblasts. Three nonproducer clones with normal morphologies and containing one single integrated copy of the deleted virus were superinfected with F-MuLV, Moloney murine leukemia virus, Gross murine leukemia virus, mink cell focus-forming virus (HIX), or the amphotropic 1504 murine leukemia virus. All pseudotypes caused macroscopic and microscopic abnormalities in mice that were similar to those seen in the parental stock. A comparison of the physical maps of F-MuLV and MPLV, which was deduced from the restriction enzyme digests of unintegrated proviral DNAs, indicated that the MPLV-defective genome (i) is probably derived from F-MuLV, (ii) has conserved the F-MuLV gag and pol regions, and (iii) is deleted and rearranged in the env region in a manner that is clearly distinct from that of Friend or Rauscher spleen focus-forming viruses.