TEL Induces Aggregation in Transformed Cells and Induces Tube Formation in NIH3T3-UCLA Cells.

TEL/ETV6 is the frequent target of translocations associated with lymphoid and myeloid leukemias and solid tumors. We show that TEL induces aggregation of immortalized and transformed fibroblasts, endothelial cells and astrocytes. These aggregates form cellular cords in NIH3T3-UCLA by a cell autonomous process, which occurs when the monolayer is made up of over 75% of cells expressing exogenous TEL. Cords with a diameter of 15-25 microm contain a lumen and occur as tube structures. The possible relevance for vasculogenic mimicry is discussed. By contrast TEL did not induce aggregation of regular NIH3T3 cells, an effect that could only be induced by co-expression of oncogenic RAS/Lys12. Also transduction of TEL and RAS retroviral vectors into the endothelial MS1 cell line and TEL alone in the highly transformed glioblastoma cell lines EH-A and EH-B resulted in extensive aggregation. Thus, the induction of cellular aggregation by TEL correlates with transformation.

The MN1-TEL fusion protein, encoded by the translocation (12;22)(p13;q11) in myeloid leukemia, is a transcription factor with transforming activity.

The Tel gene (or ETV6) is the target of the translocation (12;22)(p13;q11) in myeloid leukemia. TEL is a member of the ETS family of transcription factors and contains the pointed protein interaction (PNT) domain and an ETS DNA binding domain (DBD). By contrast to other chimeric proteins that contain TEL's PNT domain, such as TEL-platelet-derived growth factor beta receptor in t(5;12)(q33;p13), MN1-TEL contains the DBD of TEL. The N-terminal MN1 moiety is rich in proline residues and contains two polyglutamine stretches, suggesting that MN1-TEL may act as a deregulated transcription factor. We now show that MN1-TEL type I, unlike TEL and MN1, transforms NIH 3T3 cells. The transforming potential depends on both N-terminal MN1 sequences and a functional TEL DBD. Furthermore, we demonstrate that MN1 has transcription activity and that MN1-TEL acts as a chimeric transcription factor on the Moloney sarcoma virus long terminal repeat and a synthetic promoter containing TEL binding sites. The transactivating capacity of MN1-TEL depended on both the DBD of TEL and sequences in MN1. MN1-TEL contributes to leukemogenesis by a mechanism distinct from that of other chimeric proteins containing TEL.

Identification and characterization of a new human ETS-family transcription factor, TEL2, that is expressed in hematopoietic tissues and can associate with TEL1/ETV6.

The ETS family of proteins is a large group of transcription factors implicated in many aspects of normal hematopoietic development, as well as oncogenesis. For example, the TEL1/ETV6 (TEL1) gene is required for normal yolk sac angiogenesis, adult bone marrow hematopoiesis, and is rearranged or deleted in numerous leukemias. This report describes the cloning and characterization of a novel ETS gene that is highly related to TEL1 and is therefore called TEL2. The TEL2 gene consists of 8 exons spanning approximately 21 kilobases (kb) in human chromosome 6p21. Unlike the ubiquitously expressed TEL1 gene, however, TEL2 appears to be expressed predominantly in hematopoietic tissues. Antibodies raised against the C-terminus of the TEL2 protein were used to show that TEL2 localizes to the nucleus. All ETS proteins can bind DNA via the highly conserved ETS domain, which recognizes a purine-rich DNA sequence with a GGAA core motif. DNA binding assays show that TEL2 can bind the same consensus DNA binding sequence recognized by TEL1/ETV6. Additionally, the TEL2 protein is capable of associating with itself and with TEL1 in doubly transfected Hela cells, and this interaction is mediated through the pointed (PNT) domain of TEL1. The striking similarities of TEL2 to the oncogenic TEL1, its expression in hematopoietic tissues, and its ability to associate with TEL1 suggest that TEL2 may be an important hematopoietic regulatory protein.

Tel, a frequent target of leukemic translocations, induces cellular aggregation and influences expression of extracellular matrix components.

Tel is an Ets transcription factor that is the target of chromosome translocations in lymphoid and myeloid leukemias and in solid tumors. It contains two functional domains, a pointed oligomerization domain and a DNA-binding domain. Retroviral transduction of a wild-type Tel cDNA into a clonal subline of NIH3T3 fibroblasts resulted in a striking morphologic change: at confluency, the cells reorganized into a specific "bridge-like" pattern over the entire surface of the culture dish, and started migrating, thereby leaving circular holes in the monolayer. Thereafter, formation of cellular cords became apparent. This sequence of events was inhibited by coating the culture dishes with fibronectin and collagen IV. Retroviral transduction of Tel into MS1 endothelial cells reproduced the aggregation phenotype, but not the cellular cord formation. Tel-mutagenesis showed that both the pointed domain and the DNA-binding domain of Tel are required for the morphologic change. Other Ets family genes, Fli-1 and Ets-1 that are both endogenously expressed in endothelial cells, could not induce this morphologic change. Exogenous Tel expression is associated with transcriptional upregulation of entactin/nidogen, Smad5, Col3a1, CD44 and fibronectin, and downregulation of Col1a1 and secretory leukocyte protease inhibitor. Interestingly, Tel, Smad5, fibronectin, Col1a1 and Col3a1 all have essential roles during vascular development.

Transformation of hematopoietic cell lines to growth-factor independence and induction of a fatal myelo- and lymphoproliferative disease in mice by retrovirally transduced TEL/JAK2 fusion genes.

Recent reports have demonstrated fusion of the TEL gene on 12p13 to the JAK2 gene on 9p24 in human leukemias. Three variants have been identified that fuse the TEL pointed (PNT) domain to (i) the JAK2 JH1-kinase domain, (ii) part of and (iii) all of the JH2 pseudokinase domain. We report that all of the human TEL/JAK2 variants, and a human/mouse chimeric hTEL/mJAK2(JH1) fusion gene, transform the interleukin-3 (IL-3)-dependent murine hematopoietic cell line Ba/F3 to IL-3-independent growth. Transformation requires both the TEL PNT domain and JAK2 kinase activity. Furthermore, all TEL/JAK2 variants strongly activated STAT 5 by phosphotyrosine Western blots and by electrophoretic mobility shift assays (EMSA). Mice (n = 40) transplanted with bone marrow infected with the MSCV retrovirus containing either the hTEL/mJAK2(JH1) fusion or its human counterpart developed a fatal mixed myeloproliferative and T-cell lymphoproliferative disorder with a latency of 2-10 weeks. In contrast, mice transplanted with a TEL/JAK2 mutant lacking the TEL PNT domain (n = 10) or a kinase-inactive TEL/JAK2(JH1) mutant (n = 10) did not develop the disease. We conclude that all human TEL/JAK2 fusion variants are oncoproteins in vitro that strongly activate STAT 5, and cause lethal myelo- and lymphoproliferative syndromes in murine bone marrow transplant models of leukemia.

Fusion of TEL, the ETS-variant gene 6 (ETV6), to the receptor-associated kinase JAK2 as a result of t(9;12) in a lymphoid and t(9;15;12) in a myeloid leukemia.

Translocations in hematologic disease of myeloid or lymphoid origin with breakpoints at chromosome band 12p13 frequently result in rearrangements of the Ets variant gene 6 (ETV6). As a consequence either the ETS DNA-binding domain or the Helix-Loop-Helix (HLH) oligomerization domain of ETV6 is fused to different partner genes. We show here that a t(9;12)(p24;p13) in a case of early pre-B acute lymphoid leukemia and a t(9;15;12)(p24;q15;p13) in atypical chronic myelogenous leukemia in transformation involve the ETV6 gene at 12p13 and the JAK2 gene at 9p24. In each case different fusion mRNAs were found, with only one resulting in an open reading frame for a chimeric protein consisting of the HLH oligomerization domain of ETV6 and the protein tyrosine kinase (PTK) domain of JAK2. The cloning of the complete human JAK2 coding and genomic sequences and of the genomic junction fragments of the translocations allowed a characterization of the different splice events leading to the various mRNAs. JAK2 plays a central role in non-protein tyrosine kinase receptor signaling pathways, which could explain its involvement in malignancies of different hematologic lineages. Besides hop in Drosophila no member of the JAK family has yet been implicated in tumorigenesis.

Inhibition of intracellular proteolytic processing of soluble proproteins by an engineered alpha 2-macroglobulin containing a furin recognition sequence in the bait region.

The bait region of the general protease inhibitor alpha 2-macroglobulin (alpha 2M) was mutated by introducing a recognition sequence of furin. This did not interfere with folding, S-ester formation or tetramerization of the mutant recombinant alpha 2M (r alpha 2M). Mutant r alpha 2M inhibited furin in vitro, by a similar mechanism to that used by plasma alpha 2M to inhibit high-molecular-mass proteases. The mutant alpha 2M was intracellularly active in COS-1 cells in inhibiting the endogenous processing of the soluble substrates for furin (von Willebrand factor, transforming growth factor beta1 and a soluble form of the envelope glycoprotein gp160 from HIV-1) but not the membrane-bound form of gp160. The intracellular activity of mutant alpha 2M strongly indicated that alpha 2M attains its native conformation, and thus that the unusual internal S-ester is formed, before alpha 2M passes through the cleavage compartment(s). Our results show for the first time that modulation of the bait region of alpha 2M allows the creation of an inhibitor against membrane-bound proteases. It can be expected that the use of alpha 2M-bait mutants will become important as a technique for the study of various proteolytic processes and for the identification of the proteases involved.

Synthesis of a Cys949Tyr alpha 2-macroglobulin thiol ester mutant: co-transfection with wild-type alpha 2-macroglobulin in an episomal expression system.

A full-length alpha 2-macroglobulin (alpha 2M) cDNA was cloned into the episomal expression vectors pREP7 and pMEP4. Electroporation of the cell lines WI-L2-729HF2, U-937, K-562 and an Epstein-Barr virus-transformed cell line resulted in stable transfectants only with K-562 cells. Stable expression was obtained exclusively with pMEP4-alpha 2M and was driven from the inducible human metallothionein IIA promoter. Expression of the wild-type alpha 2M cDNA resulted in a recombinant protein (r alpha 2M) that could not be distinguished from plasma alpha 2M (p-alpha 2M): the transfected K-562 cells secreted tetrameric alpha 2M with intact internal thiol esters, a functional bait domain and a latent receptor-binding domain. r alpha 2M inhibited trypsin and elastase from cleaving a high-molecular-mass substrate. When the Cys-949 involved in the formation of the internal thiol ester was mutated to tyrosine (C949Y-r alpha 2M), a tetrameric alpha 2M was secreted, with the electrophoretic mobility of methylamine-treated p-alpha 2M (p-alpha 2M/MA) and with a functional receptor-binding domain. The C949Y-r alpha 2M did not possess proteinase-inhibiting capacity. Heterozygosity was mimicked by co-transfecting the K-562 cells with wild-type and mutant expression vectors. In this case, r alpha 2M was secreted with zero, one, two, three or four internal thiol esters. A comparison of the interaction of interleukin 1 beta and basic fibroblast growth factor with native p-alpha 2M, p-alpha 2M/MA and the mutant C949Y-r alpha 2M revealed that when assayed under nondenaturing conditions, no binding occurred to 'slow' p-alpha 2M whereas quantitatively similar binding was observed to 'fast' p-alpha 2M/MA and C949Y-r alpha 2M. Covalent binding, however, was essentially limited to p-alpha 2M/MA, suggesting the involvement of Cys-949 in the process. Covalent binding of insulin, on the contrary, was only observed when it was present during hydrolysis of the internal thiol esters of p-alpha 2M by trypsin treatment, and thus involves the activated Glx residue.

Design of a new protease inhibitor by the manipulation of the bait region of alpha 2-macroglobulin: inhibition of the tobacco etch virus protease by mutant alpha 2-macroglobulin.

Human alpha 2-macroglobulin (alpha 2M) inhibits a broad spectrum of proteases by changing its conformation and physically confining the enzyme. The inhibitory spectrum of alpha 2M is defined by a stretch of 39 amino acids, the bait region, located near the middle of the alpha 2M monomers. To investigate whether a new inhibitory specificity can be introduced by the manipulation of the bait region, recombinant alpha 2M (r alpha 2M) was produced in which the primary cleavage site was replaced by a heptapeptide containing the cleavage specificity of tobacco etch virus (TEV) protease. This protease is not inhibited by wild-type alpha 2M. The r alpha 2M, produced in an episomal expression system, was fully functional and able to inhibit the tobacco etch virus protease according to its normal 'trap' mechanism. The manipulation of the bait region of alpha 2M thus allows the design of new, specific protease inhibitors.