Replication-defective vector based on a chimpanzee adenovirus.

An adenovirus previously isolated from a mesenteric lymph node from a chimpanzee was fully sequenced and found to be similar in overall structure to human adenoviruses. The genome of this virus, called C68, is 36,521 bp in length and is most similar to subgroup E of human adenovirus, with 90% identity in most adenovirus type 4 open reading frames that have been sequenced. Substantial differences in the hexon hypervariable regions were noted between C68 and other known adenoviruses, including adenovirus type 4. Neutralizing antibodies to C68 were highly prevalent in sera from a population of chimpanzees, while sera from humans and rhesus monkeys failed to neutralize C68. Furthermore, infection with C68 was not neutralized from sera of mice immunized with human adenovirus serotypes 2, 4, 5, 7, and 12. A replication-defective version of C68 was created by replacing the E1a and E1b genes with a minigene cassette; this vector was efficiently transcomplemented by the E1 region of human adenovirus type 5. C68 vector transduced a number of human and murine cell lines. This nonhuman adenoviral vector is sufficiently similar to human serotypes to allow growth in 293 cells and transduction of cells expressing the coxsackievirus and adenovirus receptor. As it is dissimilar in regions such as the hexon hypervariable domains, C68 vector avoids significant cross-neutralization by sera directed against human serotypes.

Dysregulated expression of GATA-1 following retrovirus-mediated gene transfer into murine hematopoietic stem cells increases erythropoiesis.

Retrovirus-mediated gene transfer was used to study the effects of dysregulated expression of the zinc-finger transcription factor, GATA-1, which has been shown to be required for erythropoiesis. A retroviral vector (PGK-GATA-1) was constructed with the murine GATA-1 gene linked to the human phosphoglycerate kinase (PGK) promoter. Expression of GATA-1 was demonstrated by super-shift analysis with a monoclonal antibody against murine GATA-1 using extracts of nonerythroid cytotoxic T-lymphocyte line (CTLL) cells transduced with the PGK-GATA-1 virus. Mouse bone marrow cells were transduced in vitro and transplanted into recipient animals. Polymerase chain reaction (PCR) analysis performed on DNA extracted from peripheral blood 12 to 40 weeks posttransplantation demonstrated the presence of the PGK-GATA-1 provirus. Proviral integrity and copy number were demonstrated by Southern blot analysis of DNA from spleen, thymus, and bone marrow tissues from the long-term animals. At 16 weeks posttransplant, animals that received cells transduced by the GATA-1 virus maintained a lower white blood cell (WBC) count and absolute neutrophil count (ANC) and a higher red blood cell (RBC) count than control animals that received cells transduced with a virus containing a neor gene. Erythropoiesis was stimulated in GATA-1 and control animals by phlebotomy. GATA-1 animals required more extensive phlebotomy to reach a hematocrit less than 25 and their hematocrit returned to normal levels sooner than control animals. The effect of twice-daily injections of 10 U recombinant erythropoietin (epo) was also examined. The hematocrit of GATA-1 animals showed a more rapid and elevated response to epo than the hematocrit of control animals. These data suggest that dysregulated expression of GATA-1 in primitive hematopoietic cells enlarges the pool of epo-responsive erythroid progenitor cells.

Microcytic anemia in mk/mk mice is not corrected by retroviral-mediated gene transfer of wild-type p45 NF-E2.

Mice homozygous for the mk mutation have a severe hypochromic, microcytic anemia that is characterized by a decreased mean-corpuscular hemoglobin concentration and balanced alpha- and beta-globin-chain synthesis. Transplantation studies have shown that the defect in homozygous mk/mk mice is intrinsic to both the hematopoietic system and the gut. The gene for the hematopoietic-specific transcription factor, p45 NF-E2, has been found to cosegregate with the mk phenotype and contain a point mutation in mk/mk mice that results in an amino acid substitution (173V-->A). In order to test the hypothesis that this amino acid substitution is responsible for the mk phenotype, we have used recombinant retroviruses to introduce wild-type p45 NF-E2 into the bone marrow of mk/mk mice. Despite gene transfer and expression of p45 NF-E2 in erythroid cells, we found no evidence for correction of the phenotype in mk/mk mice. These results indicate that the mk mutation cannot be corrected by enforced expression of wild-type p45 NF-E2 and suggest that the 173V-->A mutation of the p45 NF-E2 gene is not the cause of anemia in mk/mk mice.

Mutations within the 5' half of the avian retrovirus MC29 v-myc gene alter or abolish transformation of chicken embryo fibroblasts and macrophages.

Avian myelocytomatosis virus MC29 induces a wide variety of neoplastic diseases in infected birds and transforms cells of the macrophage lineage as well as fibroblasts and epithelial cells. A biological and biochemical analysis, carried out on a series of in-frame insertion and deletion mutations within the gag-myc gene of MC29, revealed several mutations within the 5' portion of the v-myc gene that encode proteins either completely defective for transformation or compromised in their ability to transform chicken embryo fibroblasts but not macrophages. Mutations within the 3' end of the v-myc gene which disrupt sequences encoding the basic/helix-loop-helix region were defective for transformation of both fibroblasts and macrophages. Eight variants were cloned into the replication-competent avian expression vector RCAS. Analysis of cells infected with transformation-defective, replication-competent viruses confirmed the expression of functionally defective Myc proteins. Further, expression of the transformation defective variant dl91-137 in chicken fibroblasts inhibited subsequent transformation by wild-type MC29. The results reported herein support the hypothesis that Myc proteins function as regulators of transcription in a variety of cell types and clearly point out the necessity of putative regulatory domains within the amino-terminal half of the Myc protein.