Reciprocal expression of human ETS1 and ETS2 genes during T-cell activation: regulatory role for the protooncogene ETS1

Cytogenetic findings in acute leukaemias of infants

Of 706 children, 528 with acute lymphoblastic leukaemia (ALL) and 178 with acute myelocytic leukaemia (AML), whose leukaemia karyotypes could be successfully analysed, 48 were infants less than 1 year of age, 28 with ALL (5% of ALL patients) and 20 with AML (11% of AML patients). In contrast to older children. ALL-leukaemocytogenetics in infants was characterised by lack of hyperdiploidy with over 50 chromosomes and higher incidence of pseudodiploidy. Thirteen (= 46%) infants had an 11q23 aberration, and 11 of them had t(4;11). In AML, nine (= 45%) infants also had an 11q23 abnormality, e.g. t(9;11). Thus, the 11q23 aberration was present in almost 50% of all leukaemia karyotypes of infants. In ALL of infants, the CALLA negative, pre-pre-B immunophenotype prevailed. In AML of infants, the monocytic subtype dominated. A biphenotypic morphology (lymphoid-monocytic) with the expression of lymphoid and myeloid antigens was seen in several ALL and AML cases. In conclusion, leukaemogenesis in infants is a rare event, arising in stem cells of very early hematopoietic differentiation (probably due to gene rearrangement errors, most frequently at FRA11B), and differs from leukaemogenesis in older age groups by unique clinical and cellular features.

Characterization and uses of monoclonal antibody derived against DNA binding domain of the ets family of genes

A monoclonal antibody recognizing ets proteins from a variety of species has been developed. This antibody recognizes ets1, ets2, erg, and other related proteins. It has a high affinity for the ets1 protein. The epitope for the pan ets mAb consists of about 13 amino acids. This antibody can be used to isolate and characterize new members of ets gene family derived from a c-DNA expression library, as well as to identify other "ets motif" binding proteins.

Evolutionarily conserved Ets family members display distinct DNA binding specificities

Members of the Ets family of proto-oncogenes encode sequence-specific transcription factors that bind to a purine-rich motif centered around a conserved GGA trinucleotide. Ets binding sites have been identified in the transcriptional regulatory regions of multiple T cell genes including the T cell receptor alpha and beta (TCR-alpha and -beta) enhancers and the IL-2 enhancer, as well as in the enhancers of several T cell-trophic viruses including Maloney sarcoma virus, human leukemia virus type 1, and human immunodeficiency virus-2. T cells express multiple members of the Ets gene family including Ets-1, Ets-2, GABP alpha, Elf-1, and Fli-1. The different patterns of expression and protein-protein interactions of these different Ets family members undoubtedly contribute to their ability to specifically regulate distinct sets of T cell genes. However, previous studies have suggested that different Ets family members might also display distinct DNA binding specificities. In this report, we have examined the DNA binding characteristics of two Ets family members, Ets-1 and Elf-1, that are highly expressed in T cells. The results demonstrate that the minimal DNA binding domain of these proteins consists of adjacent basic and putative alpha-helical regions that are conserved in all of the known Ets family members. Both regions are required for DNA binding activity. In vitro binding studies demonstrated that Ets-1 and Elf-1 display distinct DNA binding specificities, and, thereby interact preferentially with different naturally occurring Ets binding sites. A comparison of known Ets binding sites identified three nucleotides at the 3' end of these sequences that control the differential binding of the Ets-1 and Elf-1 proteins. These results are consistent with a model in which different Ets family members regulate the expression of different T cell genes by binding preferentially to purine-rich sequences that share a GGA core motif, but contain distinct flanking sequences.

Identification of nucleotide preferences in DNA sequences recognised specifically by c-Ets-1 protein

The protooncogene Ets-1 is a member of the c-Ets family of genes originally identified through their sequence homology to the v-ets gene of the avian erythroblastosis virus E26. Ets-like factors are characterised by a conserved 85 amino acid domain which appears to be essential for binding to purine rich DNA sequences. Sequences binding to Ets-1 were selected from a random oligonucleotide pool by immunoprecipitation and amplified using the Polymerase Chain Reaction. Oligonucleotides enriched by this procedure were cloned in plasmids and sequenced. Alignment of DNA sequences revealed GGAA and GGAT cores at about a 1.4:1 ratio. Preferred sequences were identified both 5' and 3' of the GGAW core, extending the binding site to ACMGGAWRTT. Analysis of the flanking sequences associated with GGAA and GGAT cores revealed differences which may have compensated for the generally lower affinity of binding sites containing a GGAT core. Lastly mutational analysis of one particular Ets-1 binding site was used to establish the relative importance for binding of some nucleotides within the core and to show that Ets-1 and the closely related Ets-2 proteins bind to similar sequences.

Myb and Ets proteins cooperate in transcriptional activation of the mim-1 promoter

In the generation of the acutely transforming avian retrovirus E26, both myb and ets genes have been transduced, leading to the production of a Gag-Myb-Ets fusion protein. This co-occurrence of v-myb and v-ets oncogenes suggests that the two might have a functional relationship. To look for such a relationship, we tested the transcriptional activation activity of Myb alone or with coexpressed Ets-1 or Ets-2. Using the promoter of the v-Myb-inducible mim-1 gene as a target, we found that full-length c-Myb gene products were poor activators of transcription, while an oncogenic (truncated) form of this protein was a strong trans-activator. However, coexpression of Ets-2 with full-length or truncated forms of Myb greatly increased trans-activation. Coexpression of Ets-1, Fos, Jun, or Myc with Myb did not increase trans-activation of the mim-1 promoter. The ability of Myb and Ets-2 to transactivate was cooperative, since Ets-2 alone gave little or no activation. Bacterially synthesized Ets-2 protein was found to bind specifically to the mim-1 promoter, suggesting that it may be a target for both Myb and Ets proteins. Thus, Myb and Ets proteins can cooperate in transcriptional activation, and their co-occurrence in the E26 virus may reflect a functional relationship between these two oncoproteins. Truncated forms of Myb may have a reduced need for cooperating factors such as Ets-2, and this might constitute an important mechanism associated with oncogenic activation.

Sequence-specific interaction of the Ets1 protein with the long terminal repeat of the human T-lymphotropic virus type I

We recently demonstrated that members of the c-ets proto-oncogene family, Ets1 and Ets2, are sequence-specific transcriptional activators of the human T-lymphotropic virus type I (HTLV-I) long terminal repeat (LTR). We now report that the HTLV-I LTR contains two distinct Ets1-responsive regions, ERR-1 and ERR-2. Expression of Ets1 with reporter plasmids containing ERR-1 or ERR-2 upstream of a basal promoter resulted in an increase in transcriptional activity. By gel mobility shift assay, the interaction of Ets1 with the downstream ERR-1-binding region was found to be more stable than its interaction with the upstream ERR-2 region. By DNase I footprint, gel mobility shift, and methylation interference analyses, ERR-1 was found to contain two Ets1 binding sites, ERE-A and ERE-B. A recombinant Ets1 protein was found to bind with higher affinity to ERE-A than to ERE-B. Binding of Ets1 to these sites appears to result in a specific and sequential protection of a 37-nucleotide sequence of the HTLV-I LTR from -154 to -118. In view of the high-level expression of Ets1 in lymphoid cells, the c-ets proto-oncogenes encode transcription factors which could play an important role in both basal and Tax1-mediated HTLV-I transcription.

v-myb and v-ets cooperate for the mitogenic stimulation of primary fibroblasts by avian E26 retrovirus

By using a series of deletion mutants, we have shown that the stimulation of fibroblast growth by E26 requires the cooperation of the two oncogenes, v-myb and v-ets, fused in the nuclear viral product. Of the two DNA-binding domains, only one must be present to promote anchorage-independent growth, whereas that of v-myb is required to allow growth in low serum medium. Furthermore, the v-ets oncogene comprises multifunctional domains.

Nuclear oncogenes

Ample evidence has accumulated in recent years to establish that most, if not all, nuclear proto-oncogenes are in fact sequence-specific DNA-binding proteins that modulate gene expression. Their synthesis or activity is modulated by extracellular signals or by cross talk between different classes of transcription factors.

The Sfpi-1 proviral integration site of Friend erythroleukemia encodes the ets-related transcription factor Pu.1

Previous studies identified a common site (Sfpi-1) for proviral integration in immortalized Friend erythroleukemias. cDNAs corresponding to a 1.5-kb Sfpi-1 mRNA were isolated and sequenced. These were larger than an independently isolated Sfpi-1 cDNA described by researchers from another laboratory, and they contained common differences from that sequence, including in the coding region four extra nucleotides that altered the reading frame. The properly translated protein is identical to Pu.1, a transcription activation factor that is related to the ets oncogene family. Genetic methods were used to map Sfpi-1 with respect to other loci on mouse chromosome 2. Our results suggest that Pu.1 blocks erythroblast differentiation and thereby causes immortalization.

Monoclonal antibodies specific to human ETS-2 oncoprotein: recognition of epitopes clustered on the B domain

Six monoclonal antibodies were prepared from mice immunized with a bacterially expressed human ets-2 protein. These antibodies specifically recognize the two human ets-2-encoded proteins p56 and p54 but failed to react with chicken, mouse, rat, bovine, or monkey proteins, suggesting that the antibodies recognize epitopes specific to the human ets-2 protein. Differential reactivities of these monoclonal antibodies with the peptide fragments generated by partial proteolytic digestion of the bacterially expressed ets-2 protein indicated that the six antibodies recognize at least three distinct epitopes in the B domain of the ets-2 protein. Immunoprecipitation experiments comparing native and denaturing conditions suggested that the ets-2 domain detected by the monoclonal antibodies is masked in the native condition by either protein folding or interacting proteins. The biochemical analysis of the ets-2 protein will be facilitated by the development of these monoclonal antibodies, which may be useful as both domain-specific probes and tools for specifically detecting the human ets-2 protein in heterologous expression systems.

Sequence-specific binding of human Ets-1 to the T cell receptor alpha gene enhancer

Expression of the human T cell receptor (TCR) alpha gene is regulated by a T cell-specific transcriptional enhancer that is located 4.5 kilobases (kb) 3' to the C alpha gene segment. The core enhancer contains two nuclear protein binding sites, T alpha 1 and T alpha 2, which are essential for full enhancer activity. T alpha 1 contains a consensus cyclic adenosine monophosphate (cAMP) response element (CRE) and binds a set of ubiquitously expressed CRE binding proteins. In contrast, the transcription factors that interact with the T alpha 2 site have not been defined. In this report, a lambda gt11 expression protocol was used to isolate a complementary DNA (cDNA) that programs the expression of a T alpha 2 binding protein. DNA sequence analysis demonstrated that this clone encodes the human ets-1 proto-oncogene. Lysogen extracts produced with this cDNA clone contained a beta-galactosidase-Ets-1 fusion protein that bound specifically to a synthetic T alpha 2 oligonucleotide. The Ets-1 binding site was localized to a 17-base pair (bp) region from the 3' end of T alpha 2. Mutation of five nucleotides within this sequence abolished both Ets-1 binding and the activity of the TCR alpha enhancer in T cells. These results demonstrate that Ets-1 binds in a sequence-specific fashion to the human TCR alpha enhancer and suggest that this developmentally regulated proto-oncogene functions in regulating TCR alpha gene expression.

The ETS-domain: a new DNA-binding motif that recognizes a purine-rich core DNA sequence

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