MDS1 and EVI1 complex locus protein EVI1 (MECOM) also known as ecotropic virus integration site 1 protein homolog (EVI-1) or positive regulatory domain zinc finger protein 3 (PRDM3) is a protein that in humans is encoded by the MECOMgene. EVI1 was first identified as a common retroviral integration site in AKXD murine myeloid tumors. It has since been identified in a plethora of other organisms, and seems to play a relatively conserved developmental role in embryogenesis. EVI1 is a nuclear transcription factor involved in many signaling pathways for both coexpression and coactivation of cell cycle genes.
Gene structure
The EVI1 gene is located in the human genome on chromosome 3 (3q26.2). The gene spans 60 kilobases and encodes 16 exons, 10 of which are protein-coding. The first in-frame ATG start codon is in exon 3.[5]
mRNA
A large number of transcript variations exist, encoding different isoforms or chimeric proteins. Some of the most common ones are:
EVI_1a, EVI_1b, EVI_1c, EVI_1d, and EVI_3L are all variants in the 5' untranslated region, and all except EVI_1a are specific to human cells.[6]
−Rp9 variant is quite common in human and mouse cells, lacks 9 amino acids in the repression domain.[6]
Δ324 found at low levels in human and mouse cells - an alternative splice variant encoding an 88kDa protein lacking zinc fingers 6 and 7 [6][7]
Δ105 variant is unique to mice, and results in a protein truncated by 105 amino acids at the acidic C-terminus.[6]
Fusion transcripts with upstream genes such as MDS1/EVI1 (ME), AML1/MDS1/EVI1 (AME), ETV6/MDS1/EVI1 have all been identified [6]
Protein
The MECOM is primarily found in the nucleus, either soluble or bound to DNA. The 145kDa isoform is the most-studied, encoding 1051 amino acids,[7] although there are many EVI1 fusion products detectable in cells expressing EVI1.
The MECOM protein contains 2 domains characterized by 7 zinc finger motifs followed by a proline-rich transcription repression domain, 3 more zinc finger motifs and an acidic C-terminus.[6]
Biological role
EVI1 is a proto-oncogene conserved across humans, mice, and rats, sharing 91% homology in nucleotide sequence and 94% homology in amino acid sequence between humans and mice.[7] It is a transcription factor localized to the nucleus and binds DNA through specific conserved sequences of GACAAGATA [8] with the potential to interact with both corepressors and coactivators.
Embryogenesis
The role of EVI1 in embryogenesis and development is not completely understood, but it has been shown that EVI1 deficiency in mice is an embryonic lethal mutation, characterized primarily by widespread hypocellularity and poor/disrupted development of the cardiovascular and neural system.[7] EVI1 is highly expressed in the murine embryo, found in the urinary system, lungs, and heart, but is only minutely detectable in most adult tissues,[7] indicating a likely role in tissue development. EVI1 and the fusion transcript MDS1-EVI1 are both expressed in the adult human kidney, lung, pancreas, brain, and ovaries.[7]
Cell cycle and differentiation
In vitro experiments using both human and mouse cell lines have shown that EVI1 prevents the terminal differentiation of bone marrow progenitor cells to granulocytes and erythroid cells, however it favors the differentiation of hematopoietic cell to megakaryocytes.[7] The chimeric gene of AML1-MDS1-EVI1 (AME) formed by the chromosomal translocation (3;21)(q26;q22) has also been shown in vitro to upregulate the cell cycle and block granulocytic differentiation of murine hematopoietic cells, as well as to delay the myeloid differentiation of bone marrow progenitors.[7]
Association with cancer
EVI1 has been described as a proto-oncogene since its first discovery in 1988.[9] Overexpression and aberrant expression of EVI1 has been associated with human acute myelogenous leukemia (AML), myelodysplastic syndrome (MDS) and chronic myelogenous leukemia (CML), and more recently has been shown as a poor prognostic indicator. Its function in these cells may be regulated by phosphorylation of serine196, in its N-terminal DNA binding domain.[10] All of these involve erratic cellular development and differentiation in the bone marrow leading to dramatic alterations in the normal population of blood cells. EVI1 has also been found to play a role in solid ovarian and colon tumors,[11] although it is not yet well characterized in this context. It has been hypothesized that it acts as a survival factor in tumor cell lines, preventing therapeutic-induced apoptosis and rendering the tumor cells more resistant to current treatments.[12]
Role in tumor suppressor signaling and prevention of apoptosis
TGF-β and cell cycle progression
EVI1 has been shown to be involved in the downstream signaling pathway of transforming growth factor beta (TGF-β). TGF-β, along with other TGF-β family ligands such as bone morphogenic protein (BMP) and activin are involved in regulating important cellular functions such as proliferation, differentiation, apoptosis, and matrix production.[13] These biological roles are not only important for cellular development, but also in understanding oncogenesis.
TGF-β signaling induces transcription of the cyclin-dependent kinase (CDK) inhibitors p15Ink4B or p21Cip1, which, as a consequence, act to halt the cell cycle and stop proliferation. This inhibition can lead to cellular differentiation or apoptosis, and therefore any resistance to TGF-β is thought to contribute in some way to human leukemogenesis.[14] The downstream effectors of TGF-β are the Smad receptors (also known as receptor-activated Smads). Smad2 and Smad3 are phosphorylated in response to TGF-β ligand binding, and translocate into the nucleus of the cell, where they can then bind to DNA and other transcription factors.[13] Stable binding to promoters occurs through a conserved MH1 domain, and transcription activation occurs through an MH2 domain, and involves accompanying coactivators such as CBP/p300 and Sp1.[13]
The majority of literature discusses the interaction between EVI1 and Smad3, however there have been some experiments done showing that EVI1 interacts with all of the Smad proteins at varying levels, indicating a potential involvement in all of the pathways that include Smads as downstream effectors.[13] The translocation of phosphorylated Smad3 into the nucleus allows for direct interaction with EVI1, mediated by the first zinc finger domain on EVI1 and the MH2 domain on Smad3.[13][14] As the Smad3 MH2 domain is required for transcription activation, EVI1 binding effectively prevents transcription of the TGF-β induced anti-growth genes through structural blocking, and also leads to recruitment of other transcriptional repressors (see Epigenetics). By inhibiting an important checkpoint pathway for tumor suppression and growth control, overexpression or aberrant expression of EVI1 has characteristic oncogenic activity.
As an additional confirmation of the role of EVI1 expression on cell cycle progression, it has been shown that high EVI1 expression is correlated with the well-known tumor suppressor and cell cycle mediator Retinoblastoma, remaining in a hyperphosphorylated state, even in the presence of TGF-β.[15]
JNK and inhibition of apoptosis
c-Jun N-terminal kinase (JNK) is a MAP kinase activated by extracellular stress signals such as gamma-radiation, ultraviolet light, Fas ligand, tumor necrosis factor α (TNF-α), and interleukin-1.[16] Phosphorylation on two separate residues, Thr183 and Tyr185, cause JNK to become activated and translocate to the nucleus to phosphorylate and activate key transcription factors for the apoptotic response.[16]
Experiments co-expressing EVI1 and JNK have shown that levels of JNK-phosphorylated transcription factors (such as c-Jun) are drastically decreased in the presence of EVI1. Binding of EVI1 and JNK has been shown to occur through the first zinc finger motif on EVI1, and that this interaction does not block JNK phosphorylation and activation, but blocks JNK binding to substrate in the nucleus.[16] Subsequent in vitro assays showed that stress-induced cell death from a variety of stimuli is significantly inhibited by EVI1 and JNK binding.[16]
EVI1 does not bind other MAP kinases such as p38 or ERK.[16]
Oncogenesis and induced proliferation of HSCs
Among the many other observed defects, EVI1−/− mouse embryos have been shown to have defects in both the development and proliferation of hematopoietic stem cells (HSCs). It is presumed that this is due to direct interaction with the transcription factor GATA-2, which is crucial for HSC development.[17] It has subsequently been shown many times in vitro that EVI1 upregulation can induce proliferation and differentiation of HSCs and some other cell types such as rat fibroblasts.[6]
However, existing data is inconclusive regarding the absolute role of EVI1 in cell cycle progression. It appears to depend on the specific cell type, cell line and growth conditions being used as to whether EVI1 expression induces growth arrest or cell differentiation/proliferation, or whether it has any effect at all.[6] The data showing direct interaction of EVI1 with the promoters for a diverse array of genes supports the theory that this is a complex transcription factor associated with many different signalling pathways involved in development and growth.
Angiogenesis
Although the literature is limited on the subject, the well-documented effects on HSCs imply that there is a potential indirect effect of aberrant EVI1 expression on tumoral angiogenesis. HSCs secrete angiopoietin, and its receptor molecule Tie2 has been implicated in angiogenesis of tumors in both humans and mice.[18] Upregulation of Tie2 has been shown to occur under hypoxic conditions, and to increase angiogenesis when coinjected with tumor cells in mice.[18] Observations that EVI1−/− mutants have substantially downregulated Tie2 and Ang-I expression, therefore, hints at an interesting role of high EVI1 expression in tumor progression. This is likely, at least in part, a reason for the widespread hemorrhaging and minimal vascular development in EVI1 deleted embryos,[17] and has potential to indicate yet another reason for poor prognosis of EVI1 positive cancers.
Epigenetics
EVI1 has also been shown to directly interact with C-terminal-binding protein (CtBP, a known transcriptional repressor) through in vitro techniques such as yeast 2-hybrid screens and immunoprecipitation.[14] This interaction has been specifically shown to rely on amino acids 544-607 on the EVI1 protein, a stretch that contains two CtBP-binding consensus motifs.[15] This binding leads to recruitment of histone deacetylases (HDACs) as well as many other corepressor molecules leading to transcription repression via chromatin remodelling.[14]
EVI1 interaction with Smad3 followed by recruitment of corepressors can inhibit transcription and de-sensitize a cell to TGF-β signaling without ever displacing Smad3 from a gene's promoter.[13] The epigenetic modification is clearly enough to make the DNA inaccessible to the transcription machinery.
Although EVI1 has mainly been implicated as a transcription repressor, there is some data that has shown a possible dual role for this protein. Studies show that EVI1 also binds to known coactivators cAMP responsive element binding protein (CBP) and p300/CBP-associated factor (P/CAF).[13] These both have histone acetyltransferase activity, and lead to subsequent transcription activation. In addition, structural changes have been visualized within the nucleus of a cell, depending on the presence of corepressors or coactivators, leading researchers to believe that EVI1 has a unique response to each kind of molecule. In approximately 90% of cells, EVI1 is diffuse within the nucleus; however, when CBP and P/CAF are added, extensive nuclear speckle formation occurs.[19] The complete physiological repercussions of this complex role of EVI1 have yet to be elucidated, however, could provide insight into the wide variety of results that have been reported regarding the effect of EVI1 on in vitro cell proliferation.[6]
Interaction with corepressors and coactivators appears to occur in distinct domains,[19] and there are theories that EVI1 exists in a periodical, reversible acetylated state [7] within the cell. Contrasting theories indicate that the interplay between different EVI1 binding proteins acts to stabilize interactions with different transcription factors and DNA, leading to a response of EVI1 to a diverse set of stimuli.[13]
Chromosome instability
Since it was first identified in murine myeloid leukemia as a common site of retroviral integration into the chromosome, EVI1 and its surrounding DNA have been a site of many identified chromosomal translocations and abnormalities.[20] This can lead to aberrant expression of EVI1, and, as shown in the figure below, commonly involved chromosomal breakpoints have been mapped extensively. One major cause of EVI1 activation and consequent overexpression is a clinical condition called 3q21q26 syndrome from inv(3)(q21q26) or t(3;3)(q21;q26).[7] The result is the placement of a strong enhancing region for the housekeeping gene Ribophorin 1 (RPN1)[21] next to the EVI1 coding sequence, resulting in a dramatic increase of EVI1 levels in the cell.[7]
A summary of common chromosomal abnormalities involving EVI1 and its fusion genes can be found in a review by Nucifora et al..[22]
The most common circumstance involves chromosomal translocations in human AML or MDS, leading to constitutive expression of EVI1 and eventually to cancer.[22] Not only are these abnormalities in the 3q26 region associated with very poor patient prognosis they are also commonly accompanied by additional karyotypic changes such as chromosome 7 monosomy, deletion of the short arm of chromosome 7, or partial deletions of chromosome 5.[23] In addition, it has been shown that development of acute myelogenous leukemia is likely due to several sequential genetic changes, and that expression of EVI1 or its chimeric counterparts ME and AME alone is not enough to completely block myeloid differentiation.[24]BCR-Abl, a fusion gene caused by t(9;22)(q34;q11)is thought to have a cooperative effect with EVI1 during the progression of AML and CML.[24] Together, these two systems disrupt tyrosine kinase signaling and hematopoietic gene transcription.
Despite the extensively studied chromosomal abnormalities at the EVI1 locus, in anywhere from 10-50% of identified cases, EVI1 overexpression is detectable without any chromosomal abnormalities, indicating that there are other not-yet-understood systems, likely epigenetic, leading to EVI1 promoter activation.[6] In many of these cases, it is noted that a variety of 5' transcript variants are detectable at relatively high levels. Clinical studies have shown that these variants (EVI1_1a, EVI1_1b, EVI1_1d, EVI1_3L) as well as the MDS1-EVI1 fusion transcript are all associated with poor prognosis and increased likelihood of rapid remission in cases of de novo AML.[25]
Pharmacogenomics and cancer treatment
Very little research has been done in an attempt to therapeutically target EVI1 or any of its chimeric counterparts. However, since it has become an established fact that overexpression of EVI1 derivatives is a bad prognostic indicator, it is likely that the literature will begin to examine specific targeting within the next few years.
One very promising therapeutic agent for myelogenous leukemia and potentially other forms of cancer is arsenic trioxide (ATO). One study has been done showing that ATO treatment leads to specific degradation of the AML1/MDS1/EVI1 oncoprotein and induces both apoptosis and differentiation.[11] As an atypical use of traditional pharmacogenomics, this knowledge may lead to an increased ability to treat EVI1 positive leukemias that would normally have poor prognoses. If it is established that a clinical cancer case is EVI1 positive, altering the chemotherapeutic cocktail to include a specific EVI1 antagonist may aid to increase lifespan and prevent potential relapse. Arsenic is a fairly ancient human therapeutic agent,[11] however it has only recently returned to the forefront of cancer treatment. It has been observed that it not only induces apoptosis but can also inhibit the cell cycle, and has marked anti-angiogenesis effects.[26] As of 2006, Phase I and II clinical trials were being conducted to test this compound on a wide variety of cancer types, and currently (2008) a number of publications are showing positive outcomes in individual case studies, both pediatric and adult.[citation needed]
Parts of this article (those related to this section) need to be updated. Please help update this article to reflect recent events or newly available information.(February 2016)
Hormones
The important and essential role of EVI1 in embryogenesis clearly indicates a close association with hormonal fluctuations in developing cells. However, to date, the presence of EVI1 in cancer has not been linked to aberrant production of any hormones or hormone receptors. It is likely that EVI1 is far enough downstream of hormonal signaling that once overproduced, it can function independently.
Future and current research
Effect on gene therapy
Areas where retroviral integration into the human genome is favored such as EVI1 have very important implications for the development of gene therapy. It was initially thought that delivery of genetic material through a non-replicating virus vector would pose no significant risk, as the likelihood of a random incorporation near a proto-oncogene was minimal. By 2008 it was realised that sites such as EVI1 are "highly over-represented" when it comes to vector insertions.[5]
Mothers against decapentaplegic homolog 2 also known as SMAD family member 2 or SMAD2 is a protein that in humans is encoded by the SMAD2 gene. MAD homolog 2 belongs to the SMAD, a family of proteins similar to the gene products of the Drosophila gene 'mothers against decapentaplegic' (Mad) and the C. elegans gene Sma. SMAD proteins are signal transducers and transcriptional modulators that mediate multiple signaling pathways.
Mothers against decapentaplegic homolog 3 also known as SMAD family member 3 or SMAD3 is a protein that in humans is encoded by the SMAD3 gene.
Myc is a family of regulator genes and proto-oncogenes that code for transcription factors. The Myc family consists of three related human genes: c-myc (MYC), l-myc (MYCL), and n-myc (MYCN). c-myc was the first gene to be discovered in this family, due to homology with the viral gene v-myc.
The SKI protein is a nuclear proto-oncogene that is associated with tumors at high cellular concentrations. SKI has been shown to interfere with normal cellular functioning by both directly impeding expression of certain genes inside the nucleus of the cell as well as disrupting signaling proteins that activate genes.
Histone deacetylase 1 (HDAC1) is an enzyme that in humans is encoded by the HDAC1 gene.
ETV6 protein is a transcription factor that in humans is encoded by the ETV6 gene. The ETV6 protein regulates the development and growth of diverse cell types, particularly those of hematological tissues. However, its gene, ETV6 frequently suffers various mutations that lead to an array of potentially lethal cancers, i.e., ETV6 is a clinically significant proto-oncogene in that it can fuse with other genes to drive the development and/or progression of certain cancers. However, ETV6 is also an anti-oncogene or tumor suppressor gene in that mutations in it that encode for a truncated and therefore inactive protein are also associated with certain types of cancers.
The nuclear receptor co-repressor 1 also known as thyroid-hormone- and retinoic-acid-receptor-associated co-repressor 1 (TRAC-1) is a protein that in humans is encoded by the NCOR1 gene.
In genetics and molecular biology, a corepressor is a molecule that represses the expression of genes. In prokaryotes, corepressors are small molecules whereas in eukaryotes, corepressors are proteins. A corepressor does not directly bind to DNA, but instead indirectly regulates gene expression by binding to repressors.
Runt-related transcription factor 1 (RUNX1) also known as acute myeloid leukemia 1 protein (AML1) or core-binding factor subunit alpha-2 (CBFA2) is a protein that in humans is encoded by the RUNX1 gene.
Runt-related transcription factor 3 is a protein that in humans is encoded by the RUNX3 gene.
GATA2 or GATA-binding factor 2 is a transcription factor, i.e. a nuclear protein which regulates the expression of genes. It regulates many genes that are critical for the embryonic development, self-renewal, maintenance, and functionality of blood-forming, lympathic system-forming, and other tissue-forming stem cells. GATA2 is encoded by the GATA2 gene, a gene which often suffers germline and somatic mutations which lead to a wide range of familial and sporadic diseases, respectively. The gene and its product are targets for the treatment of these diseases.
E3 SUMO-protein ligase PIAS4 is one of several protein inhibitor of activated STAT (PIAS) proteins. It is also known as protein inhibitor of activated STAT protein gamma, and is an enzyme that in humans is encoded by the PIAS4 gene.
Core-binding factor subunit beta is a protein that in humans is encoded by the CBFB gene.
C-terminal-binding protein 1 also known as CtBP1 is a protein that in humans is encoded by the CTBP1 gene. CtBP1 is one of two CtBP proteins, the other protein being CtBP2.
Protein CBFA2T1 is a protein that in humans is encoded by the RUNX1T1 gene.
ERG is an oncogene. ERG is a member of the ETS family of transcription factors. The ERG gene encodes for a protein, also called ERG, that functions as a transcriptional regulator. Genes in the ETS family regulate embryonic development, cell proliferation, differentiation, angiogenesis, inflammation, and apoptosis.
MAD protein is a protein that in humans is encoded by the MXD1 gene.
Protein CBFA2T2 is a protein that in humans is encoded by the CBFA2T2 gene.
Protein CBFA2T3 is a protein that in humans is encoded by the CBFA2T3 gene.
In molecular biology the MYND-type zinc finger domain is a conserved protein domain. The MYND domain is present in a large group of proteins that includes RP-8 (PDCD2), Nervy, and predicted proteins from Drosophila, mammals, Caenorhabditis elegans, yeast, and plants. The MYND domain consists of a cluster of cysteine and histidine residues, arranged with an invariant spacing to form a potential zinc-binding motif. Mutating conserved cysteine residues in the DEAF-1 MYND domain does not abolish DNA binding, which suggests that the MYND domain might be involved in protein-protein interactions. Indeed, the MYND domain of ETO/MTG8 interacts directly with the N-CoR and SMRT co-repressors. Aberrant recruitment of co-repressor complexes and inappropriate transcriptional repression is believed to be a general mechanism of leukemogenesis caused by the t(8;21) translocations that fuse ETO with the acute myelogenous leukemia 1 (AML1) protein. ETO has been shown to be a co-repressor recruited by the promyelocytic leukemia zinc finger (PLZF) protein. A divergent MYND domain present in the adenovirus E1A binding protein BS69 was also shown to interact with N-CoR and mediate transcriptional repression. The current evidence suggests that the MYND motif in mammalian proteins constitutes a protein-protein interaction domain that functions as a co-repressor-recruiting interface.
↑ Liu Y, Chen L, Ko TC, Fields AP, Thompson EA (Jun 2006). "Evi1 is a survival factor which conveys resistance to both TGFbeta- and taxol-mediated cell death via PI3K/AKT". Oncogene. 25 (25): 3565–75. doi:10.1038/sj.onc.1209403. PMID16462766. S2CID27099061.
1 2 De Palma M, Murdoch C, Venneri MA, Naldini L, Lewis CE (Dec 2007). "Tie2-expressing monocytes: regulation of tumor angiogenesis and therapeutic implications". Trends in Immunology. 28 (12): 519–24. doi:10.1016/j.it.2007.09.004. PMID17981504.
↑ Haas K, Kundi M, Sperr WR, Esterbauer H, Ludwig WD, Ratei R, Koller E, Gruener H, Sauerland C, Fonatsch C, Valent P, Wieser R (Apr 2008). "Expression and prognostic significance of different mRNA 5'-end variants of the oncogene EVI1 in 266 patients with de novo AML: EVI1 and MDS1/EVI1 overexpression both predict short remission duration". Genes, Chromosomes & Cancer. 47 (4): 288–98. doi:10.1002/gcc.20532. PMID18181178. S2CID45500978.
↑ Vinatzer U, Taplick J, Seiser C, Fonatsch C, Wieser R (Sep 2001). "The leukaemia-associated transcription factors EVI-1 and MDS1/EVI1 repress transcription and interact with histone deacetylase". British Journal of Haematology. 114 (3): 566–73. doi:10.1046/j.1365-2141.2001.02987.x. PMID11552981. S2CID7643309.
↑ Kurokawa M, Mitani K, Irie K, Matsuyama T, Takahashi T, Chiba S, Yazaki Y, Matsumoto K, Hirai H (Jul 1998). "The oncoprotein Evi-1 represses TGF-beta signalling by inhibiting Smad3". Nature. 394 (6688): 92–6. Bibcode:1998Natur.394...92K. doi:10.1038/27945. PMID9665135. S2CID4404132.
Further reading
Wieser R (Jul 2007). "The oncogene and developmental regulator EVI1: expression, biochemical properties, and biological functions". Gene. 396 (2): 346–57. doi:10.1016/j.gene.2007.04.012. PMID17507183.
Morishita K, Parganas E, Douglass EC, Ihle JN (Jul 1990). "Unique expression of the human Evi-1 gene in an endometrial carcinoma cell line: sequence of cDNAs and structure of alternatively spliced transcripts". Oncogene. 5 (7): 963–71. PMID2115646.
Ogawa S, Kurokawa M, Tanaka T, Mitani K, Inazawa J, Hangaishi A, Tanaka K, Matsuo Y, Minowada J, Tsubota T, Yazaki Y, Hirai H (Jul 1996). "Structurally altered Evi-1 protein generated in the 3q21q26 syndrome". Oncogene. 13 (1): 183–91. PMID8700545.
Kurokawa M, Mitani K, Irie K, Matsuyama T, Takahashi T, Chiba S, Yazaki Y, Matsumoto K, Hirai H (Jul 1998). "The oncoprotein Evi-1 represses TGF-beta signalling by inhibiting Smad3". Nature. 394 (6688): 92–6. Bibcode:1998Natur.394...92K. doi:10.1038/27945. PMID9665135. S2CID4404132.
Shimizu S, Nagasawa T, Katoh O, Komatsu N, Yokota J, Morishita K (Apr 2002). "EVI1 is expressed in megakaryocyte cell lineage and enforced expression of EVI1 in UT-7/GM cells induces megakaryocyte differentiation". Biochemical and Biophysical Research Communications. 292 (3): 609–16. doi:10.1006/bbrc.2002.6693. PMID11922610.
Vinatzer U, Mannhalter C, Mitterbauer M, Gruener H, Greinix H, Schmidt HH, Fonatsch C, Wieser R (Jan 2003). "Quantitative comparison of the expression of EVI1 and its presumptive antagonist, MDS1/EVI1, in patients with myeloid leukemia". Genes, Chromosomes & Cancer. 36 (1): 80–9. doi:10.1002/gcc.10144. PMID12461752. S2CID28707062.
Nitta E, Izutsu K, Yamaguchi Y, Imai Y, Ogawa S, Chiba S, Kurokawa M, Hirai H (Sep 2005). "Oligomerization of Evi-1 regulated by the PR domain contributes to recruitment of corepressor CtBP". Oncogene. 24 (40): 6165–73. doi:10.1038/sj.onc.1208754. PMID15897867. S2CID22508591.
Overview of all the structural information available in the PDB for UniProt: Q03112 (Histone-lysine N-methyltransferase MECOM) at the PDBe-KB.
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