Michal Dvořák

The Myb leucine zipper is essential for leukemogenicity of the v-Myb protein.

The AMV v-Myb oncoprotein causes oncogenic transformation of myelomonocytic cells in vivo and in vitro. Its transforming capacity is strictly dependent upon the N-terminal DNA binding domain, the central transactivation region, and on the C-terminal domain containing a putative leucine zipper motif. Here we show that the v-MybL3,4A mutant, in which Leu325 and Leu332 of the leucine zipper have been replaced by alanines, failed to induce leukemia in virus infected chicken. This demonstrates that the leucine zipper domain is indispensable for v-myb induced leukemogenesis in vivo. v-MybL3,4A was, however, still able to transform myelomonocytic cells from chicken bone marrow in vitro. Yet, while v-mybL3,4A transformed cells were impaired in growth at 37°C, they failed to grow at 42°C, the physiological body temperature of avian species. This might explain the loss of v-MybL3,4A leukemogenic potential in vivo. We also demonstrate that the v-Myb leucine zipper domain interacts in vitro with two host cell proteins, p26 and p28. This interaction is compromised in v-MybL3,4A indicating that binding of v-Myb to p26 and p28 might be important for the leukemogenic potential of v-Myb.

The transcription factor EGR1 regulates metastatic potential of v-src transformed sarcoma cells.

Metastatic spreading of cancer cells is a highly complex process directed primarily by the interplay between tumor microenvironment, cell surface receptors, and actin cytoskeleton dynamics. To advance our understanding of metastatic cancer dissemination, we have developed a model system that is based on two v-src transformed chicken sarcoma cell lines—the highly metastatic parental PR9692 and a non-metastasizing but fully tumorigenic clonal derivative PR9692-E9. Oligonucleotide microarray analysis of both cell lines revealed that the gene encoding the transcription factor EGR1 was downregulated in the non-metastatic PR9692-E9 cells. Further investigation demonstrated that the introduction of exogenous EGR1 into PR9692-E9 cells restored their metastatic potential to a level indistinguishable from parental PR9692 cells. Microarray analysis of EGR1 reconstituted cells revealed the activation of genes that are crucial for actin cytoskeleton contractility (MYL9), filopodia formation (MYO10), the production of specific extracellular matrix components (HAS2, COL6A1-3) and other essential pro-metastatic abilities.

bFGF signaling and v-Myb cooperate in sustained growth of primitive erythroid progenitors

The development of red blood cells from hematopoietic progenitors requires the interplay of specific extracellular factors and transcriptional regulators. Here we have identified an erythroid progenitor that is critically dependent on bFGF and requires expression of AMV v-Myb for sustained proliferation in vitro, indicating that bFGF and Myb proteins cooperate in these cells. In the presence of bFGF such v-Myb cells are completely blocked in their ability to differentiate and exhibit an exceptionally high proliferative potential and long lifespan in vitro. Interestingly, in the absence of bFGF cells effectively differentiate into mature erythrocytes, irrespective of constitutive and elevated levels of v-Myb. We also demonstrate that these cells express high levels of FGF receptor type 1 (FGFR1) and that phospholipase Cγ (PLCγ) is one of the important molecules in FGF receptor signaling. Our studies suggest that bFGF, in cooperation with Myb proteins, represents an important factor for determining erythroid lineage choice. These findings unravel a so far unidentified link between extracellular signaling and Myb in hematopoietic cells.

Transmission of (LTR, v-src, LTR) without recombination with a helper virus

We have analyzed transmission of (LTR, v-src, LTR) cryptic structure integrated in the H-19 mammalian tumor cell line. From this cell line different isolates of transforming virus were rescued in heterokaryons produced by fusion with chicken fibroblasts infected by replication-competent avian leukosis virus RAV-1. One of them (F6) was used for the transformation of avian cells in the absence of the helper virus. In four transformed cell lines studied, the (LTR, v-src, LTR) structure was again integrated at a unique position in the cell DNA of each line. This indicated that the (LTR, v-src, LTR) structure is transmitted by the helper virus without recombination. This point has been further supported by the finding that a src-containing species corresponding in size to the nonpolyadenylated src mRNA is present in the RNA isolated from the rescued F6 transforming virus which might serve as template for the synthesis of (LTR, v-src, LTR) structure by the reverse transcriptase provided by RAV-1.

Presence of viral RNA-instructed DNA polymerase in the oncogenic subviral particles (virosomes) isolated from the mitochondria of rous sarcoma cells

Recently we have shown the presence and biosynthesis of virosomes. oncogenic ribonucleoprotein particles in the mitochondria isolated from Rous sarcoma tissue [I, 21 . A high titre of oncogenic viral activity in the ROW sarcoma mitouhondria and presence of viral proteins (Gs antigens) in the mitochondria in avian and mammalian tumors induced by Schmidt-Ruppin strain of Rous sarcoma virus (SR-RSV) have also been demonstrated [3. 41. These data and further experimental evidence that chloramphenicol and ethidium bromide, the inhibitors of mitochondrial functions, evidently inhibit the RSV replication and malignant transformation of the fibroblasts infected with RSV in culture [ 21 strongly suggest that the mitochondria play a significant role in the replication of RSV and in the mechanism of malignant cell transformation by this oncogenic virus. Similar conclusions were published by Richert and Hare [S] In this communication. we are presenting experimental evidence on the presence of Rous sarcoma virus-specific RNA-instructed DNA polymerase, reverse transcriptase 16 1 11 , in the virosomes isolated from the inner membrane and matrix (IM + matrix) fraction of RS mitochondria using the digitonin method of Schnaitman and Greenawalt [ 131 Viral DNA polymerase in the isolated virosomes was characterized by inhibition of this enzymatic activity

Biosynthesis of subviral oncogenic particles (virosomes) in mitochondria of Rous sarcoma and Rauscher murine leukemia cells.

SummaryExperimental evidence for the presence and biosynthesis of subviral, leukemogenic particles in the isolated mitochondria of spleen cells of mice infected with Rauscher murine leukemia (RML) virus is presented. These subviral particles sediment at a density of 1.27–1.29 g/ml and induce splenomegaly and RML three weeks after i.v. or i.p. administration to white mice. Virosomes have been labelled with [32P]phosphate in the isolated mitochondria from RML spleen cells and high molecular weight (70S) [32P]RNA has been isolated from these subviral, leukemogenic particles. Rauscher virus group specific antigens were detected by immunodiffusion in the inner membrane and matrix fraction of the mitochondria of RML spleen cells. These results together with our earlier findings strongly suggest that mitochondria of the transformed cells participate in the biosynthesis of RNA tumor viruses. Possible mechanism of the penetration of viral genetic information of RNA tumor viruses into mitochondria of tumor cellsin vivo is discussed.

The oncoprotein v-Myb activates transcription of Gremlin 2 during in vitro differentiation of the chicken neural crest to melanoblasts

The neural crest (NC) is a transient dynamic structure of ectodermal origin, found in early vertebrate embryos. The multipotential NC cells migrate along well defined routes, differentiate to various cell types including melanocytes and participate in the formation of various permanent tissues. As there is only limited information about the molecular mechanisms controlling early events in melanocyte specification and development, we exploited the AMV v-Myb transcriptional regulator, which directs differentiation of in vitro chicken NC cells to the melanocyte lineage. This activity is strictly dependent on v-Myb specifically binding to the Myb recognition DNA element (MRE). The two tamoxifen-inducible v-Myb alleles were constructed one which recognizes the MRE and one which does not. These were activated in ex ovo NC cells, and the expression profiles of resulting cells were analyzed using Affymetrix microarrays and RT-PCR. These approaches revealed up-regulation of the BMP antagonist Gremlin 2 mRNA, and down-regulation of mRNAs encoding several epithelial genes including KRT19 as very early events following the activation of melanocyte differentiation by v-Myb. The enforced v-Myb expression in neural tubes of chicken embryos resulted in detectable presence of Gremlin 2 mRNA. However, expression of Gremlin 2 in NC cells did not promote formation of melanocytes suggesting that Gremlin 2 is not the master regulator of melanocytic differentiation.