Drosophila rab GDI mutants disrupt development but have normal Rab membrane extraction.

Rab GTPases are essential for vesicular transport. Rab GDP dissociation inhibitor (GDI) binds to GDP-bound rabs, removes rabs from acceptor membranes and delivers rabs to donor membranes. We isolated lethal GDI mutations in Drosophila and analyzed their developmental phenotypes. To learn how these mutations affect GDI structure, the crystal structure of Drosophila GDI was determined by molecular replacement to a resolution of 3.0 A. Two hypomorphic, missense mutations are located in domain II of GDI at highly conserved positions, but not in previously identified sequence conserved regions. The mutant GDIs were tested for ability to extract rabs from membranes and showed wild-type levels of rab membrane extraction. The two missense alleles showed intragenic complementation, indicating that domain II of GDI may have two separable functions. This study indicates that GDI function is essential for development of a complex, multicellular organism and that puparium formation and pole cell formation are especially dependent on GDI function.

Cytopathic feline leukemia viruses cause apoptosis in hemolymphatic cells.

Certain isolates of the oncoretrovirus feline leukemia virus (FeLV) are strongly cytopathic for hemolymphatic cells. A major cytopathicity determinant is encoded by the SU envelope glucoprotein gp70. Isolates with subgroup C SU gp70 genes specifically induce apoptosis in hemolymphatic cells but not fibroblasts. In vitro exposure of feline T-cells to FeLV-C leads first to productive viral replication, next to virus-induced cell agglutination, and lastly to apogenesis. This in vitro phenomenon may explain the severe progressive thymic atrophy and erythroid aplasia which follow viremic FeLV-C infection in vivo. Inappropriate apoptosis induction has also been hypothesized to explain the severe thymico-lymphoid atrophy and progressive immune deterioration associated with isolates of FeLV containing variant envelope genes. The influence of envelope hypervariability (variable regions 1 [Vr1] and 5 [Vr5] on virus tropism, viremia induction, neutralizing antibody development and cytopathicity is discussed. Certain potentially cytopathic elements in FeLV SU gp70 Vr5 may derive from replication-defective, poorly expressed, endogenous FeLVs. Other more highly conserved regions in FeLV TM envelope p15E may also influence apoptosis induction.

GDI1 encodes a GDP dissociation inhibitor that plays an essential role in the yeast secretory pathway.

GTP binding proteins of the Sec4/Ypt/rab family regulate distinct vesicular traffic events in eukaryotic cells. We have cloned GDI1, an essential homolog of bovine rab GDI (GDP dissociation inhibitor) from the yeast Saccharomyces cerevisiae. Analogous to the bovine protein, purified Gdi1p slows the dissociation of GDP from Sec4p and releases the GDP-bound form from yeast membranes. Depletion of Gdi1p in vivo leads to loss of the soluble pool of Sec4p and inhibition of protein transport at multiple stages of the secretory pathway. Complementation analysis indicates that GDI1 is allelic to sec19-1. These results establish that Gdi1p plays an essential function in membrane traffic and are consistent with a role for Gdi1p in the recycling of proteins of the Sec4/Ypt/rab family from their target membranes back to their vesicular pools.

Interaction of Sec4 with GDI proteins from bovine brain, Drosophila melanogaster and Saccharomyces cerevisiae. Conservation of GDI membrane dissociation activity.

Rab GDP dissociation inhibitor (Rab GDI), will induce the dissociation of GDP-bound rab3A from synaptic membranes and will inhibit GDP dissociation from Sec4, a member of the Rab subgroup of the Ras GTPase superfamily which is required for exocytosis in Saccharomyces cerevisiae. We report that Rab GDI releases GDP-bound Sec4 from yeast membranes. dGDI, a Drosophila homologue can similarly inhibit GDP dissociation from Sec4 and release GDP-bound Sec4 from yeast membranes. An activity partially purified from yeast cytosol dissociates GDP-bound Sec4 from yeast membranes, suggesting that yeast also possess a GDI protein that functions to recycle Sec4 from its target membrane.

A new myosin I gene in Drosophila.

We have identified and cloned a new myosin-I cDNA, myosin 61F, from Drosophila melanogaster. The sequence of myosin 61F cDNA shows high similarity to vertebrate myosin-I sequences. Myosin 61F is most similar to bovine myosin Ib, showing 78% similarity and 63% identity. Myosin 61F is a single copy gene which maps to polytene region 61F, a genomic region with several potential myosin mutations. The identification of a myosin-I gene in Drosophila will allow genetic analysis of myosin-I function in a metazoan organism.

A Drosophila homolog of bovine smg p25a GDP dissociation inhibitor undergoes a shift in isoelectric point in the developmental mutant quartet.

The Drosophila developmental mutation quartet causes late larval lethality and small imaginal discs and, when expressed in the adult female, has a lethal effect on early embryogenesis. These developmental defects are associated with mitotic defects, which include a low mitotic index in larval brains and incomplete separation of chromosomes in mitosis in the early embryo. quartet mutations also have a biochemical effect, i.e., a basic shift in isoelectric point in three proteins. We have purified one of these proteins, raised an antibody to it, and isolated and sequenced its cDNA. At the amino acid level, the sequence shows 68% identity and 81% similarity to bovine smg p25a GDP dissociation inhibitor (GDI), a regulator of ras-like small GTPases of the rab/SEC4/YPT1 subfamily. The correlation between a basic shift in isoelectric point in Drosophila GDI in quartet mutant tissue and the quartet developmental phenotype raises the possibility that a posttranslational modification of GDI is necessary for its function and that GDI function is essential for development.

Partial dissociation of subgroup C phenotype and in vivo behaviour in feline leukaemia viruses with chimeric envelope genes.

Feline leukaemia viruses (FeLVs) are classified into subgroups A, B and C by their use of different host cell receptors on feline cells, a phenotype which is determined by the viral envelope. FeLV-A is the ubiquitous, highly infectious form of FeLV, and FeLV-C isolates are rare variants which are invariably isolated along with FeLV-A. The FeLV-C isolates share the capacity to induce acute non-regenerative anaemia and the prototype, FeLV-C/Sarma, has strongly age-restricted infectivity for cats. The FeLV-C/Sarma env sequence is closely related to that of common, weakly pathogenic FeLV-A isolates. We now show by construction of chimeric viruses that the receptor specificity of FeLV-A/Glasgow-1 virus can be converted to that of FeLV-C by exchange of a single env variable domain, Vr1, which differs by a three codon deletion and nine adjacent substitutions. Attempts to dissect this region further by directed mutagenesis resulted in disabled proviruses. Sequence analysis of independent natural FeLV-C isolates showed that they have unique Vr1 sequences which are distinct from the conserved FeLV-A pattern. The chimeric viruses which acquired the host range and subgroup properties of FeLV-C retained certain FeLV-A-like properties in that they were non-cytopathogenic in 3201B feline T cells and readily induced viraemia in weanling animals. They also induced a profound anaemia in neonates which had a more prolonged course than that induced by FeLV-C/Sarma and which was macrocytic rather than non-regenerative in nature. Although receptor specificity and a major determinant of pathogenicity segregate with Vr1, it appears that sequences elsewhere in the genome influence infectivity and pathogenicity independently of the subgroup phenotype.

Lymphocytotoxic strains of feline leukemia virus induce apoptosis in feline T4-thymic lymphoma cells.

Feline leukemia retrovirus (FeLV) strains with subgroup C env genes kill feline T4 lymphoma 3201 cells by 7 to 12 days after in vitro inoculation, whereas FeLV strains with subgroup A env genes do not. Neither FeLV-A nor FeLV-C kill feline fibroblasts. FeLV-C, but not FeLV-A, is replicated to higher titer by 3201 cells and productive infection precedes death by 3 to 7 days. Transcriptional activity of the FeLV-C long terminal repeat, as assessed by chloramphenicol acetyltransferase activity, is high in feline lymphoid cells but low in feline fibroblasts. Activity of the FeLV-A long terminal repeat is moderate in both cell types. FeLV-C-infected cells form aggregates 1 to 4 days before dying; ultrastructurally, virus particles can be seen approximating the clustered cells. Dying cells demonstrate nuclear condensation, surface blebbing, and fragmentation. DNA fragmentation and laddering compatible with apoptosis occur 1 to 2 days before massive cell death. In FeLV-C-infected 3201 cells, a shift from phospholipid to neutral lipid incorporation of [14C]oleic acid, increases in palmitic acid proportions and decreases in linoleic acid proportions occur 1 to 2 days before peak killing. Exposure of 3201 cells to ultraviolet-inactivated FeLV-KT (200-800 micrograms/10(6) cells) causes cytostasis within 2 days and death within 4 days. Blebbing and nuclear condensation occur but clusters do not form. The induction of programmed cell death in feline thymic lymphoma cells by subgroup C feline retroviruses may be relevant to the pathogenesis of FeLV-induced thymic atrophy, paracortical lymphoid depletion and acquired immunodeficiency in vivo.

Prophylactic and therapeutic effects of phosphonoformate against feline leukemia virus in vitro.

Phosphonoformate (PFA), a noncompetitive inhibitor of reverse transcriptase (RT), inhibited feline leukemia virus (FeLV) infection of 2 feline cell lines and inhibited progeny virus RT activity in a chronically FeLV-infected cell line. Feline leukemia virus infection of 3201 cells, an FeLV-negative lymphoma cell line, was inhibited by greater than 70% at a concentration of only 1 microM PFA and by greater than 90% at concentrations of 64 to 256 microM PFA, as evidenced by RT activity. However, FeLV antigen expression by 3201 cells remained relatively constant over noncytotoxic concentrations of PFA. Because the persistence of viral antigen expression with concomitant suppression of RT activity appears to be unique and because 3201 cells express small amounts of an endogenous retrovirus (RD-114) and contain endogenous FeLV proviral sequences, a possible role of endogenous retroviruses acting as helper viruses was suggested. Feline leukemia virus infection of 81C cells, a sarcoma-positive, leukemia-negative fibroblast cell line, was inhibited by greater than 50% at a concentration of 64 microM PFA and by greater than 98% at concentrations of 256 to 512 microM PFA, as indicated by suppression of focus formation. The feline lymphoid cell line FL-74 is a large producer of FeLV. When FL-74 cells were cultured in the presence of 256 microM PFA, virus production (virus budding and viral antigen) was not affected, but progeny virus lost RT activity and infectivity. Direct addition of PFA (256 microM) to FeLV also reduced RT activity and infectivity. These data indicate that PFA can directly and rapidly inactivate retrovirus independent of cellular processing, presumably by inhibiting RT.(ABSTRACT TRUNCATED AT 250 WORDS)

In vitro replication and cytopathogenicity of the feline immunodeficiency virus for feline T4 thymic lymphoma 3201 cells.

Cytotoxic feline immunodeficiency virus (FIV) infection was established in feline T4 thymic lymphoma 3201 cells with the Petaluma isolate of the feline immunodeficiency virus (FIV-Petaluma). Mg2(+)-dependent, reverse transcriptase (Mg2+ RT) activity and FIV p24/28-positive cells were evident beginning at 18 days postinoculation (dpi). Cell death was observed beginning at 22 dpi, with a maximum of 40% dead (trypan blue dye exclusion at 26 dpi). This cytocidal change was not observed in cultured Crandell feline kidney fibroblasts similarly infected with FIV-Petaluma. The surviving cells grew out and a chronic FIV-producer cell line was established. The 3201 cell-derived FIV (FIV-3201) was far more virulent for FIV-naive feline 3201 cells, with FIV p24/28-positive cells and Mg2+ RT activity first detectable by 4-8 dpi and subsequent loss of cell viability detectable by 8-12 dpi. Maximum kill (40% dead) was observed at 16 dpi. Comparison between viral infectivity of FIV-Petaluma and FIV-3201 for FIV-naive 3201 cells showed an increase of 1 log10 tissue culture infectious doses (TCID50) by amplification/passage in 3201 cells. Cytologic and electron microscopic examination of 3201 cells in FIV-infected cultures showed frequent budding lentiviral particles. This lytic infection system opens the way to the routine detection, isolation, and quantitation of FIV from FIV-infected cats, to the large-scale propagation of the virus, and to a system for evaluation of the mechanisms of FIV lymphocytotoxicity and the development of therapies to counteract lentiviral cytopathicity.

In vitro and in vivo evidence that the antiviral activity of 2',3'-dideoxycytidine is target cell dependent in a feline retrovirus animal model.

2',3'-Dideoxycytidine (DDC) was evaluated for prophylactic antiviral activity in vitro and in vivo, using the feline leukemia virus (FeLV)-cat animal model. In vitro antiviral activity of DDC against FeLV was dependent upon the target cell used for infection. DDC (5 to 10 microM) inhibited FeLV infection of feline lymphoid cells by greater than 80%, while 6.07 to 12.13 microM DDC was required to similarly inhibit infection of feline fibroblasts. However, 43 to 384 microM DDC was needed to inhibit FeLV infection of primary bone marrow cells by greater than 80%. These in vitro results suggest that, although relatively low doses of DDC may be adequate to prevent infection of feline lymphoid cells, 8- to 80-times-higher doses may be necessary to block infection of bone marrow cells, a primary target cell type for FeLV infection. In vivo studies with DDC consisted of pharmacokinetic and toxicity determinations and evaluation of the prophylactic antiviral activity against FeLV in cats. Clearance and half-life values for DDC in cats were 6.5 ml/min per kg and 54.7 min, respectively. In the prophylactic studies, DDC was administered by continuous intravenous infusion at doses of 22, 15, 10, and 5 mg/kg per h for 28 days in most animals. Cats were challenged intravenously with FeLV 1 to 3 days after drug treatment began. Doses of 22 and 15 mg/kg per h were extremely toxic, causing death in 8 of 10 cats. The mg/kg per h dose was slightly toxic, causing chronic progressive thrombocytopenia over the 28-day treatment period. Of 10 cats given 10 to 5 mg of DDC per kg per h, only one was completely protected from FeLV antigenemia. However, conversion to positive FeLV antigenemia status was delayed by 2 to 7 weeks in seven of nine remaining animals. Interestingly, FeLV infection of bone marrow cells, as indicated by FELV antigen in peripheral blood neutrophils, was only slightly delayed by 0 to 2 weeks, except in the case of the one protected cat, and usually preceded conversion to antigenemia. This pattern of neutrophils becoming antigen positive before detection of antigenemia was not seen in FeLV challenge control animals and indicates that the antiviral activity of DDC may be incomplete during DDC treatment. Results of our in vitro and in vivo studies suggest that feline bone marrow cells may remain partially susceptible to FeLV infection at tolerated doses, while other somatic target tissues (i.e., lymphoid or epithelial tissues) may be protected from infection. Incomplete inhibition of FeLV infection permitted focal bone marrow infection to develop in cats given DDC. These loci of infection served as virus reservoirs which, subsequent to discontinuation of DDC treatment, permitted spread of infection to tissues previously protected during treatment.

A feline large granular lymphoma and its derived cell line.

A lymphoma cell line (MCC) was derived from an abdominal mass from a 13-yr-old castrated male cat. The cells resemble natural killer precursor cells, have membrane-bound granules, and are positive for chloroacetate esterase, alpha-naphthyl butyrate esterase, and tartrate-resistant acid phosphatase activities. The MCC cells are negative for rearranged feline T-cell receptor genes, negative for feline T-cytotoxic antigen, Ia, and surface mu, tau, and lambda chains and do not form E-rosettes. The MCC cell line is negative for the feline leukemia virus (FeLV); e.g., negative for exogenous FeLV (exU3) sequences, negative for cytoplasmic and surface FeLV major core protein of 27,000 daltons (p27) by indirect immunofluorescence assay, negative for helper FeLV by clone 81 assay, and negative for release of soluble FeLV p27 by enzyme-linked immunosorbent assay. Electron microscopy reveals budding type C retrovirus particles and MCC cells react with anti-RD-114 (anti-endogenous feline retrovirus) reference serum. After in vitro infection, MCC replicate FeLV readily, but replication is noncytopathic.

Quartet: a Drosophila developmental mutation affecting chromosome separation in mitosis.

The Drosophila mutation, quartet, affects development at points in the life cycle that require intense mitotic activity. Examination of embryos affected by the maternal effect of quartet has revealed defects that can be attributed to incomplete chromosome separation at mitosis. These defects include uneven spacing of nuclei, strands of DNA creating bridges between nuclei, and abnormal amounts of DNA per nucleus. Nuclei in quartet-affected embryos also have a greater-than-normal number of centrosomes. Immunofluorescent examination of the spindles in quartet-affected embryos has revealed tripolar spindles and adjacent spindles that share a common spindle pole. Finally, chromosome separation distance was measured in anaphase and telophase spindles in quartet-affected embryos and found to be blocked in anaphase. Examination of mitotic figures in quartet larvae revealed a reduced mitotic index and an elevated frequency of abnormal mitotic figures. quartet could encode a function necessary for the disengagement of chromosomes in mitosis, for kinetochore function or for function of a spindle motor. Mutations in quartet prevent the post-translational modification of three abundant proteins. These proteins may be involved in chromosome separation in mitosis.

Developmental and protein modification defects caused by mutations in the Drosophila gene l(3)c21R.

A temperature-sensitive Drosophila mutation, l(3)c21RRW630 (abbreviated RW630), has been previously shown to have biochemical as well as developmental defects. To analyze further the relationship between the biochemical and developmental defects, recombinational mapping, deletion analysis, and complementation studies with other l(3)c21R alleles were performed. These experiments showed that the biochemical and developmental defects in RW630 can be attributed to a single mutation. Four non-temperature-sensitive l(3)c21R alleles were found to have biochemical defects similar to those seen in RW630 at restrictive temperature. In RW630 and in these four other l(3)c21R alleles, the severity of expression of the biochemical and the developmental defects was closely correlated. Temperature-shift studies of the expression of the RW630 maternal lethal effect on embryogenesis in females transheterozygous for RW630 and other l(3)c21R alleles yielded results which indicated that these defects must accumulate over a period of time before the maternal lethal effect can be detected. These data provide further support for the hypothesis that defects in protein modification produce developmental defects in l(3)c21R mutants.

Defects in protein modification precede developmental defects in l(3)c21RRW630, a temperature-sensitive Drosophila developmental mutant.

The temperature-sensitive Drosophila developmental mutation, l(3)c21RRW630 (abbreviated RW630) disturbs oogenesis and has a maternal effect on embryogenesis. At restrictive temperature, RW630 alters post-translational modification of three abundant proteins. To examine the causal relationship between these biochemical defects and the developmental defects in RW630, a series of temperature-shift experiments was performed. It was found that defects in protein modification could be detected in RW630 ovaries after RW630 females had been exposed to restrictive temperature for 1 day. RW630 females treated in this fashion produce embryos which contain a low level of unmodified proteins. Nevertheless, these embryos hatch at a normal rate. Since these ovaries and these embryos are developmentally normal, but do show defects in protein modification, it is unlikely that the RW630 developmental defects cause the biochemical defects in RW630. It is more likely that accumulation of unmodified proteins after extended exposure to restrictive temperature produces the developmental defects in RW630.

Infectious feline leukaemia virus is erythrosuppressive in vitro.

The direct effect of the feline leukaemia virus (FeLV) on erythroid colony formation in vitro was investigated. Bone marrow mononuclear cells (BMMC) from FeLV-naïve, specific-pathogen-free (SPF), adult cats were inoculated with FeLVs of characterized strains and biologically cloned subgroups and the subsequent development of colony forming units-erythroid (CFUE) and burst forming units-erythroid (BFUE) and colony forming units-granulocyte-macrophage (CFUGM) was monitored. Exposure to the anaemia-causing Kawakami-Theilen strain of FeLV (FeLV-KT), a phenotypic mixture of subgroups A, B, and C, caused constant depression of day 2 CFUE (to 47% of sham-inoculated controls), day 4 CFUE (41% of controls), and day 10 BFUE (38% of controls). CFUGM were unaffected. The lymphoma-causing Rickard strain of FeLV (FeLV-R-TL) caused sporadic depression of CFUE and BFUE. In contrast, neither FeLV-R passaged through feline embryonic kidney fibroblasts (FeLV-R-CRFK) nor biologically cloned, subgroup-specific, FeLVs of fibroblast origin, caused decrements in CFUE or BFUE, suggesting that fibroblast passage attenuated the direct erythrosuppressive effect of FeLV. Suppression of CFUE and BFUE by lymphoma cell-origin FeLV was dependent on infectious virus and was associated with FeLV replication by the cultured myelomonocytic precursor cells. Attenuation of infectivity by heat or u.v. restored CFUE and BFUE development. Examination of the relationship between viral infectivity (VI), viral protein concentration, and CFUE suppression showed that the infectious FeLV was 20-fold more effective than u.v.-inactivated FeLV as an inhibitor of erythrogenesis in vitro.

A deletion of the 3' end of the Drosophila melanogaster hsp70 gene increases stability of mutant mRNA during recovery from heat shock.

hsp40, an X-ray-induced deletion mutant of the major Drosophila melanogaster heat shock protein gene hsp70, was shown to be incorrectly regulated at the translational level. hsp40 protein synthesis persisted at a high level after the release from heat shock, whereas hsp70 protein production was rapidly repressed. This result was observed both in flies heterozygous for the hsp40 gene and in tissue culture cells transfected with the truncated gene. Analysis of the transcription of the hsp40 gene indicated that its mRNA, unlike hsp70 mRNA, was not actively destabilized after a return to control temperatures, permitting prolonged production of the mutant protein.

On the role of fibronectin during the compaction stage of somitogenesis in the chick embryo.

During the early stages of somitogenesis in the chick embryo the presomitic cells in the segmental plate undergo compaction. The aggregation of segmental plate cells is stimulated by fibronectin. The stimulation of segmental plate cells to aggregate and undergo compaction can be effected in isolated segmental plate cells, in isolated segmental plates, and in intact embryos removed from the yolk. The fact that the segmental plate cells react with greater vigor to cellular fibronectin than to plasma fibronectin suggests a specific molecular mechanism in the initiation of somitogenesis.

Specific protein modifications are altered in a temperature-sensitive Drosophila developmental mutant.

The temperature-sensitive Drosophila mutation l(3)c21RRW630 disturbs oogenesis and imaginal disc development and has a maternal effect on embryogenesis. Two-dimensional gel electrophoretic analysis of protein synthesis in mutant tissue at a restrictive temperature shows that the synthesis of three proteins is elevated and the synthesis of three other proteins is reduced, when compared to wild type. Each protein with increased synthesis is similar to a protein whose synthesis is reduced, as judged by comparison of partial proteolytic digests of these proteins. To explain these findings, we propose that the wild-type c21R gene codes for a protein-modifying enzyme. This enzyme catalyzes the acidic modification of three abundant proteins. The correct modification of these proteins is required for cell division, cell motility, and the formation of adult hairs and bristles. In the mutant at restrictive temperature, the enzyme does not function properly and so the unmodified substrate proteins accumulate. This study correlates the morphological defects in a Drosophila developmental mutant with an altered molecular process.