Nm-sized cryogenic hydrogen clusters for a laser-driven proton source.

A cryogenic hydrogen cluster-jet target is described which has been used for laser-plasma interaction studies. Major advantages of the cluster-jet are, on the one hand, the compatibility to pulsed high repetition lasers as the target is operated continuously and, on the other hand, the absence of target debris. The cluster-jet target was characterized using the Mie-scattering technique allowing to determine the cluster size and to compare the measurements with an empirical formula. In addition, an estimation of the cluster beam density was performed. The system was implemented at the high power laser system ARCTURUS, and the measurements show the acceleration of protons after irradiation of the cluster target by high intensity laser pulses with a repetition rate of 5 Hz.

Role of cyclin-dependent kinase 5 and its activator P35 in local axon and growth cone stabilization.

Axons elongate and perform steering reactions with their growth cones constantly undergoing local collapse and stabilization. Our previous studies have shown that a type-1 phosphorylated form of microtubule-associated protein 1B, recognized by monoclonal antibody 1E11 (mab1E11), is present in stable regions and absent from unstable regions of turning growth cones of retinal ganglion cells. In contrast, the total population of microtubule-associated protein 1B is present in the entire growth cone. Here we demonstrate that inhibition of cyclin-dependent kinase 5 (Cdk5) results in loss of mab1E11 binding whereas inhibition of glycogen synthase kinase 3 has no such effect, revealing that mab1E11 recognizes a Cdk5 phosphorylation site on type-1 phosphorylated form of microtubule-associated protein 1B. We moreover show that kinase Cdk5 as well as its activator P35 is present in retinal ganglion cells in the early developing chick embryo retina and enriched in their extending axons. Cdk5 and P35 are concentrated in the youngest, distal axon region and the growth cone as also seen for Cdk5-phosphorylated type-1 phosphorylated form of microtubule-associated protein 1B. Inhibition of Cdk5 by antibodies or inhibitor Roscovitine results in growth cone collapse and axon retraction and prevents substantial axon outgrowth. In contrast, glycogen synthase kinase 3 inhibition causes only a transient axon retraction which is soon recovered and allows for axon formation. In growth cones induced to turn at substrate borders, where stable and instable parts of the growth cone are clearly defined, Cdk5 is present in the entire growth cone. P35, in contrast, is restricted to the stable parts of the growth cone, which do not collapse but instead transform into new distal axon. The local presence of Cdk5-phosphorylated type-1 phosphorylated form of microtubule-associated protein 1B in stabilized growth cone areas can be therefore attributed to the local activation of Cdk5 by P35 in these regions. Together our data demonstrate a crucial role of Cdk5 and its activator P35 in elongation and maintenance of axons as well as for stability and steering of their growth cones.

Cell surface proteins of chicken hematopoietic progenitors, thrombocytes and eosinophils detected by novel monoclonal antibodies.

E26 is an acute avian leukemia virus that contains two nuclear oncogenes, v-myb and v-ets, and that is capable of transforming early cells of the erythroid and myeloid lineages. In another study, we have found that TPA (phorbol 12,13-dibutyrate) treatment of E26-transformants displaying an 'early erythroid' phenotype results in the production of cells with either myeloid or eosinophil characteristics. To analyze this induction in greater detail we have produced a panel of four monoclonal antibodies against E26-transformants before and after TPA-induced differentiation. Two antibodies, MEP21 and MEP26, reacted with proteins of 150 and 47-60 kDa, respectively, which are expressed on the surface of E26 progenitor cells but whose expression is extinguished following TPA-induced differentiation. A third antibody, EOS47, recognizes a 100 kDa molecule that is expressed on the surface of TPA-induced peroxidase positive cells (an enzyme that in avian species is restricted to cells of the eosinophilic lineage). MEP21, MEP26, and EOS47 do not react with lymphoid, myeloid, or more mature erythroid lineage cell lines. The fourth antibody, MEP17, recognizes a heterodimer of 140 and 150 kDa chains which is expressed at high levels by E26-transformed progenitor cells and at lower levels by TPA-induced cells. Further biochemical characterization of the MEP17 antigen revealed a structure similar to that of the leukocyte adhesion molecule VLA-4; a member of the integrin family of adhesion proteins. All four antibodies react with subpopulations of cells in the bone marrow and spleens of 1-day-old chickens. Although the MEP21 and MEP26 antibodies do not appear to react with mature cells of most hematopoietic lineages they are expressed at high levels by mature thrombocytes. In addition, MEP17 is expressed at high levels by the majority of bursal B-cells, thrombocytes, and more weakly by thymocytes. The reagents described should be useful as markers for the study of development, migration, and differentiation of normal avian hematopoietic progenitor cells and eosinophilic precursors, and for the study of retrovirus-induced neoplasia.

v-mil induces autocrine growth and enhanced tumorigenicity in v-myc-transformed avian macrophages.

MH2, an avian retrovirus containing the v-myc and v-mil oncogenes, rapidly transforms chick hematopoietic cells in vitro. The transformed cells belong to the macrophage lineage and proliferate in the absence of exogenous growth factors. Here we analyze a series of MH2 deletion mutants and show that these two oncogenes together establish an autocrine growth system in which v-myc stimulates cell proliferation, while v-mil induces the production of chicken myelomonocytic growth factor (cMGF). We also demonstrate that these two oncogenes cooperate in vivo. MH2 efficiently induces monocytic leukemias and liver tumors, while deletion mutants lacking either a functional v-mil or v-myc do not.

Mutant avian erythroblastosis virus with restricted target cell specificity.

Avian erythroblastosis virus (AEV) induces a fatal erythroblastosis within 2 weeks of intravenous injection in chicks in virtually 100% of cases. In chicks injected intramuscularly, sarcomas frequently develop at the site of injection before the animals die from erythroblastosis. In vitro, AEV transforms both erythroblasts, derived from bone marrow cultures, and fibroblasts. These effects have been shown to be a general property of AEV and not of separate leukaemia- and sarcoma-inducing forms of the virus. AEV is defective for replication and can be propagated only in the prewence of helper virus. Its transformation specificity is independent of the helper virus used. It is not clear whether AEV has two different genes controlling transformation of the two types of target cell or whether it has only one gene coding for both. To investigate this question, we looked for mutants of AEV unable to transform one of the two types of target cell. We now describe such a mutant, which is defective for erythroblast transformation but which can still transform fibroblasts.