Neuroectodermal specification and regionalization of the Spemann organizer in Xenopus.

During gastrulation in Xenopus convergence and extension movements, mediated by mediolateral intercalations, are the driving force for early neural plate morphogenesis. Here we show that the winged helix transcriptional regulator, Xfd-12' is dynamically expressed in medial neural plate precursors that undergo convergence and extension movements. These medial neuraxial progenitors are specified in and beyond the Spemann organizer prior to specification of the basal anlage of the neural plate. The initiation of Xfd-12' expression coincides with the induction of mesendoderm by Nodal-related growth factors at the late blastula stage. Comparative expression analysis suggests that cellular rearrangements at the pre-gastrulation stage account for regionalization of the Spemann organizer into head and trunk organizer compartments, the latter in which medial neural plate progenitors reside. While the maintenance of Xfd-12' expression in the dorsal non-involuting marginal zone requires FGF signalling, its subsequent positioning along the medial aspect of the neuraxis depends on signalling by Wnt and Nodal-related family members. Based on these findings we propose that XFD-12' is a trunk organizer component that might control convergence and extension movements of medial neural plate precursors during gastrulation.

Retroviral capture of c-erbB proto-oncogene sequences: rapid evolution of distinct viral genomes carrying mutant v-erbB genes with different transforming capacities.

The evolution of oncogene-transducing retroviruses was followed by studying the genomes of five new, erbB carrying retroviruses. These viruses, isolated from cells of one chicken infected with Rous Associated virus 1 (RAV-1), had captured c-erbB sequences as a consequence of RAV-1 integration into the host genome. Their genome structures were distinct; however, their v-erbB genes had sustained identical 5' and 3' deletions and the v-erbB-env junctions were identical at the nucleotide level. The results therefore strongly suggest that all five viruses originate from the same capture event. Sequence analyses of the v-erbB genes from three of these viruses revealed that one of them had undergone no further mutation and lacked detectable capacity to transform cells, therefore probably representing an 'early' form of transducing virus. The two other v-erbB genes contained distinct mutations and differed in their potential to induce fibroblast- and erythroblast transformation; they therefore probably represent later derivatives of the virus that captured the erbB oncogene. The data suggest that the initial retrovirus rapidly underwent many alterations after capture of c-erbB sequences, already in the RAV-1 infected bird as well as during subsequent in vitro isolation procedures. The changes involve both major rearrangements of the genome as well as point mutations that activated the erbB oncogene.

Detection of avian hematopoietic cell surface antigens with monoclonal antibodies to myeloid cells. Their distribution on normal and leukemic cells of various lineages.

The isolation and characterization of monoclonal antibodies reacting with cell surface antigenic determinants of normal and leukemic avian hematopoietic cells is described. The antibodies were produced by immunizing mice with normal macrophages, as well as with myeloid cells transformed with the avian acute leukemia viruses MC29, AMV and E26. Eleven antibodies were characterized for their reactivity with a variety of normal and leukemic cells of the myeloid, B- and T-lymphoid and of the erythroid cell lineage. Using several methods, they could be subdivided into five distinct types: I. Four antibodies were specific for the myeloid lineage, predominantly reacting with immature myeloid cells. II. One antibody reacted with mature and immature myeloid cells as well as with T-lymphoid cells. III. Four antibodies reacted with myeloid, erythroid and T-lymphoid cells. IV. One antibody reacted with myeloid as well as with T- and B-lymphoid cells. V. One antibody reacted with all kinds of chicken hematopoietic cells except erythrocytes. The first type of antibodies detected glycoproteins with MWs of 170 and 130 kD. The pattern of antigens precipitated varied with the different monoclonal antibodies of this group. The antibody of the fourth type precipitated a 30 kD polypeptide from extracts of myeloid and lymphoid cells. None of the other antibodies precipitated any detectable proteins.

Erythroblast cell lines transformed by a temperature-sensitive mutant of avian erythroblastosis virus: a model system to study erythroid differentiation in vitro.

A continuous chicken erythroblast cell line transformed by the temperature-sensitive mutant ts34 of avian erythroblastosis virus was developed. This cell line, designated HD3, could be induced to terminally differentiate by shift to the nonpermissive temperature. The differentiated cells resembled erythrocytes as judged by morphology, expression of hemoglobin as determined by benzidine staining and radioimmunoassay, and by the expression of differentiation-specific cell surface antigens. Terminal differentiation was dependent on an erythropoietin-like activity present in anemic chicken serum. In contrast, induction of differentiation in the same cells by butyric acid was erythropoietin independent and did not lead to the formation of erythrocytes. In addition, we found that the responsiveness to temperature inducibility and to butyric acid could be dissociated in variant sublines of HD3 and that both types of differentiation inducers appear to act via different pathways.

Mutant of avian erythroblastosis virus defective for erythroblast transformation: deletion in the erb portion of p75 suggests function of the protein in leukemogenesis.

Previous studies have shown that td359 AEV, a mutant of avian erythroblastosis virus (AEV), is unable to transform erythroblasts in vitro or in vivo but is capable of transforming fibroblasts in vitro and of causing sarcomas in chicks. In this paper we show that the mutant synthesizes a gag-gene related protein (delta p75) which is about 1000 daltons smaller than the protein, p75, induced by wild-type AEV. The mutant protein lacks 3 of the approximately 53 lysine-arginine tryptic peptides resolved in p75 and also contains an additional peptide. By cleavage of delta p75 with p15 protease and analysis of the fragments for size and peptide composition, the deletion in delta p75 could be located in the non-gag region of the molecule. In contrast, with p40 AEV, a second AEV-specific protein synthesized in in vitro translation experiments, there is no change in size of translation products obtained from td359 AEV RNA. Our data provide direct evidence that p75 is required for erythroblast transformation.