Nuclear interacting SET domain protein 1 inactivation impairs GATA1-regulated erythroid differentiation and causes erythroleukemia.

The nuclear receptor binding SET domain protein 1 (NSD1) is recurrently mutated in human cancers including acute leukemia. We show that NSD1 knockdown alters erythroid clonogenic growth of human CD34+ hematopoietic cells. Ablation of Nsd1 in the hematopoietic system of mice induces a transplantable erythroleukemia. In vitro differentiation of Nsd1-/- erythroblasts is majorly impaired despite abundant expression of GATA1, the transcriptional master regulator of erythropoiesis, and associated with an impaired activation of GATA1-induced targets. Retroviral expression of wildtype NSD1, but not a catalytically-inactive NSD1N1918Q SET-domain mutant induces terminal maturation of Nsd1-/- erythroblasts. Despite similar GATA1 protein levels, exogenous NSD1 but not NSDN1918Q significantly increases the occupancy of GATA1 at target genes and their expression. Notably, exogenous NSD1 reduces the association of GATA1 with the co-repressor SKI, and knockdown of SKI induces differentiation of Nsd1-/- erythroblasts. Collectively, we identify the NSD1 methyltransferase as a regulator of GATA1-controlled erythroid differentiation and leukemogenesis.

TRIM28 is essential for erythroblast differentiation in the mouse.

In previous mass spectrometry and coimmune precipitation studies, we identified tripartite motif-containing 28 (TRIM28; also known as transcriptional intermediary factor1ß and Krüppel-associated box-associated protein-1) as a cofactor that specifically copurified with an NR2C1/NR2C2 (TR2/TR4) orphan nuclear receptor heterodimer that previous studies had implicated as an embryonic/fetal ß-type globin gene repressor. TRIM28 has been characterized as a transcriptional corepressor that can associate with many different transcription factors and can play functional roles in multiple tissues and cell types. Here, we tested the contribution of TRIM28 to globin gene regulation and erythropoiesis using a conditional loss-of-function in vivo model. We discovered that Trim28 genetic loss in the adult mouse leads to defective immature erythropoiesis in the bone marrow and consequently to anemia. We further found that TRIM28 controls erythropoiesis in a cell-autonomous manner by inducibly deleting Trim28 exclusively in hematopoietic cells. Finally, in the absence of TRIM28, we observed increased apoptosis as well as diminished expression of multiple erythroid transcription factors and heme biosynthetic enzymes in immature erythroid cells. Thus, TRIM28 is essential for the cell-autonomous development of immature erythroblasts in the bone marrow.

Trim24-repressed VL30 retrotransposons regulate gene expression by producing noncoding RNA.

Trim24 (Tif1α) and Trim33 (Tif1γ) interact to form a co-repressor complex that suppresses murine hepatocellular carcinoma. Here we show that Trim24 and Trim33 cooperatively repress retinoic acid receptor-dependent activity of VL30-class endogenous retroviruses (ERVs) in liver. In Trim24-knockout hepatocytes, VL30 derepression leads to accumulation of reverse-transcribed VL30 cDNA in the cytoplasm that correlates with activation of the viral-defense interferon responses mimicking the preneoplastic inflammatory state seen in human liver following exogenous viral infection. Furthermore, upon derepression, VL30 long terminal repeats (LTRs) act as promoter and enhancer elements deregulating expression of neighboring genes and generating enhancer RNAs that are required for LTR enhancer activity in hepatocytes in vivo. These data reinforce the role of the TRIM family of proteins in retroviral restriction and antiviral defense and provide an example of an ERV-derived oncogenic regulatory network.

Tif1γ is essential for the terminal differentiation of mammary alveolar epithelial cells and for lactation through SMAD4 inhibition.

Transforming growth factor ß (TGFß) is widely recognised as an important factor that regulates many steps of normal mammary gland (MG) development, including branching morphogenesis, functional differentiation and involution. Tif1γ has previously been reported to temporally and spatially control TGFß signalling during early vertebrate development by exerting negative effects over SMAD4 availability. To evaluate the contribution of Tif1 γ to MG development, we developed a Cre/LoxP system to specifically invalidate the Tif1g gene in mammary epithelial cells in vivo. Tif1g-null mammary gland development appeared to be normal and no defects were observed during the lifespan of virgin mice. However, a lactation defect was observed in mammary glands of Tif1g-null mice. We demonstrate that Tif1 γ is essential for the terminal differentiation of alveolar epithelial cells at the end of pregnancy and to ensure lactation. Tif1 γ appears to play a crucial role in the crosstalk between TGFß and prolactin pathways by negatively regulating both PRL receptor expression and STAT5 phosphorylation, thereby impairing the subsequent transactivation of PRL target genes. Using HC11 cells as a model, we demonstrate that the effects of Tif1g knockdown on lactation depend on both SMAD4 and TGFß. Interestingly, we found that the Tif1γ expression pattern in mammary epithelial cells is almost symmetrically opposite to that described for TGFß. We propose that Tif1γ contributes to the repression of TGFß activity during late pregnancy and prevents lactation by inhibiting SMAD4.

Tif1γ suppresses murine pancreatic tumoral transformation by a Smad4-independent pathway.

Transcriptional intermediary factor 1γ (TIF1γ; alias, TRIM33/RFG7/PTC7/ectodermin) belongs to an evolutionarily conserved family of nuclear factors that have been implicated in stem cell pluripotency, embryonic development, and tumor suppression. TIF1γ expression is markedly down-regulated in human pancreatic tumors, and Pdx1-driven Tif1γ inactivation cooperates with the Kras(G12D) oncogene in the mouse pancreas to induce intraductal papillary mucinous neoplasms. In this study, we report that aged Pdx1-Cre; LSL-Kras(G12D); Tif1γ(lox/lox) mice develop pancreatic ductal adenocarcinomas (PDACs), an aggressive and always fatal neoplasm, demonstrating a Tif1γ tumor-suppressive function in the development of pancreatic carcinogenesis. Deletion of SMAD4/DPC4 (deleted in pancreatic carcinoma locus 4) occurs in approximately 50% of human cases of PDAC. We, therefore, assessed the genetic relationship between Tif1γ and Smad4 signaling in pancreatic tumors and found that Pdx1-Cre; LSL-Kras(G12D); Smad4(lox/lox); Tif1γ(lox/lox) (alias, KSSTT) mutant mice exhibit accelerated tumor progression. Consequently, Tif1γ tumor-suppressor effects during progression from a premalignant to a malignant state in our mouse model of pancreatic cancer are independent of Smad4. These findings establish, for the first time to our knowledge, that Tif1γ and Smad4 both regulate an intraductal papillary mucinous neoplasm-to-PDAC sequence through distinct tumor-suppressor programs.

TRIM involvement in transcriptional regulation.

Members of the tripartite motif (TRIM) protein family are found in all multicellular eukaryotes and function in a wide range of cellular processes such as cell cycle regulation, differentiation, development, oncogenesis and viral response. Over the past few years, several TRIM proteins have been reported to control gene expression through regulation of the transcriptional activity of numerous sequence-specific transcription factors. These proteins include the transcriptional intermediary factor 1 (TIF1) regulators, the promyelocytic leukemia tumor suppressor PML and the RET finger protein (RFP). In this chapter, we will consider the molecular interactions made by these TRIM proteins and will attempt to clarify some of the molecular mechanisms underlying their regulatory effect on transcription.

Tripartite motif 24 (Trim24/Tif1α) tumor suppressor protein is a novel negative regulator of interferon (IFN)/signal transducers and activators of transcription (STAT) signaling pathway acting through retinoic acid receptor α (Rarα) inhibition.

Recent genetic studies in mice have established that the nuclear receptor coregulator Trim24/Tif1α suppresses hepatocarcinogenesis by inhibiting retinoic acid receptor α (Rara)-dependent transcription and cell proliferation. However, Rara targets regulated by Trim24 remain unknown. We report that the loss of Trim24 resulted in interferon (IFN)/STAT pathway overactivation soon after birth (week 5). Despite a transient attenuation of this pathway by the induction of several IFN/STAT pathway repressors later in the disease, this phenomenon became more pronounced in tumors. Remarkably, Rara haplodeficiency, which suppresses tumorigenesis in Trim24(-/-) mice, prevented IFN/STAT overactivation. Moreover, together with Rara, Trim24 bound to the retinoic acid-responsive element of the Stat1 promoter and repressed its retinoic acid-induced transcription. Altogether, these results identify Trim24 as a novel negative regulator of the IFN/STAT pathway and suggest that this repression through Rara inhibition may prevent liver cancer.

Epigenetic tethering of AID to the donor switch region during immunoglobulin class switch recombination.

Immunoglobulin class switch recombination (CSR) is initiated by double-stranded DNA breaks (DSBs) in switch regions triggered by activation-induced cytidine deaminase (AID). Although CSR correlates with epigenetic modifications at the IgH locus, the relationship between these modifications and AID remains unknown. In this study, we show that during CSR, AID forms a complex with KAP1 (KRAB domain-associated protein 1) and HP1 (heterochromatin protein 1) that is tethered to the donor switch region (Sµ) bearing H3K9me3 (trimethylated histone H3 at lysine 9) in vivo. Furthermore, in vivo disruption of this complex results in impaired AID recruitment to Sµ, inefficient DSB formation, and a concomitant defect in CSR but not in somatic hypermutation. We propose that KAP1 and HP1 tether AID to H3K9me3 residues at the donor switch region, thus providing a mechanism linking AID to epigenetic modifications during CSR.

L3MBTL2 protein acts in concert with PcG protein-mediated monoubiquitination of H2A to establish a repressive chromatin structure.

We have identified human MBT domain-containing protein L3MBTL2 as an integral component of a protein complex that we termed Polycomb repressive complex 1 (PRC1)-like 4 (PRC1L4), given the copresence of PcG proteins RING1, RING2, and PCGF6/MBLR. PRC1L4 also contained E2F6 and CBX3/HP1γ, known to function in transcriptional repression. PRC1L4-mediated repression necessitated L3MBTL2 that compacted chromatin in a histone modification-independent manner. Genome-wide location analyses identified several hundred genes simultaneously bound by L3MBTL2 and E2F6, preferentially around transcriptional start sites that exhibited little overlap with those targeted by other E2Fs or by L3MBTL1, another MBT domain-containing protein that interacts with RB1. L3MBTL2-specific RNAi resulted in increased expression of target genes that exhibited a significant reduction in H2A lysine 119 monoubiquitination. Our findings highlight a PcG/MBT collaboration that attains repressive chromatin without entailing histone lysine methylation marks.

Transcription intermediary factor 1γ is a tumor suppressor in mouse and human chronic myelomonocytic leukemia.

Transcription intermediary factor 1γ (TIF1γ) was suggested to play a role in erythropoiesis. However, how TIF1γ regulates the development of different blood cell lineages and whether TIF1γ is involved in human hematological malignancies remain to be determined. Here we have shown that TIF1γ was a tumor suppressor in mouse and human chronic myelomonocytic leukemia (CMML). Loss of Tif1g in mouse HSCs favored the expansion of the granulo-monocytic progenitor compartment. Furthermore, Tif1g deletion induced the age-dependent appearance of a cell-autonomous myeloproliferative disorder in mice that recapitulated essential characteristics of human CMML. TIF1γ was almost undetectable in leukemic cells of 35% of CMML patients. This downregulation was related to the hypermethylation of CpG sequences and specific histone modifications in the gene promoter. A demethylating agent restored the normal epigenetic status of the TIF1G promoter in human cells, which correlated with a reestablishment of TIF1γ expression. Together, these results demonstrate that TIF1G is an epigenetically regulated tumor suppressor gene in hematopoietic cells and suggest that changes in TIF1γ expression may be a biomarker of response to demethylating agents in CMML.

Transcription cofactors TRIM24, TRIM28, and TRIM33 associate to form regulatory complexes that suppress murine hepatocellular carcinoma.

TRIM24 (TIF1α), TRIM28 (TIF1ß), and TRIM33 (TIF1γ) are three related cofactors belonging to the tripartite motif superfamily that interact with distinct transcription factors. TRIM24 interacts with the liganded retinoic acid (RA) receptor to repress its transcriptional activity. Germ line inactivation of TRIM24 in mice deregulates RA-signaling in hepatocytes leading to the development of hepatocellular carcinoma (HCC). Here we show that TRIM24 can be purified as at least two macromolecular complexes comprising either TRIM33 or TRIM33 and TRIM28. Somatic hepatocyte-specific inactivation of TRIM24, TRIM28, or TRIM33 all promote HCC in a cell-autonomous manner in mice. Moreover, HCC formation upon TRIM24 inactivation is strongly potentiated by further loss of TRIM33. These results demonstrate that the TIF1-related subfamily of TRIM proteins interact both physically and functionally to modulate HCC formation in mice.

Adult hematopoiesis is regulated by TIF1γ, a repressor of TAL1 and PU.1 transcriptional activity.

Crosstalk between transcription factors and cytokines precisely regulates tissue homeostasis. Transcriptional intermediary factor 1γ (TIF1γ) regulates vertebrate hematopoietic development, can control transcription elongation, and is a component of the TGF-ß signaling pathway. Here we show that deletion of TIF1γ in adult hematopoiesis is compatible with life and long-term maintenance of essential blood cell lineages. However, loss of TIF1γ results in deficient long-term hematopoietic stem cell (LT-HSC) transplantation activity, deficient short-term HSC (ST-HSC) bone marrow retention, and priming ST-HSCs to myelomonocytic lineage. These defects are hematopoietic cell-autonomous, and priming of TIF1γ-deficient ST-HSCs can be partially rescued by wild-type hematopoietic cells. TIF1γ can form complexes with TAL1 or PU.1-two essential DNA-binding proteins in hematopoiesis-occupy specific subsets of their DNA binding sites in vivo, and repress their transcriptional activity. These results suggest a regulation of adult hematopoiesis through TIF1γ-mediated transcriptional repression of TAL1 and PU.1 target genes.

TIF1ß association with HP1 is essential for post-gastrulation development, but not for Sertoli cell functions during spermatogenesis.

TIF1ß is an essential mammalian transcriptional corepressor. It interacts with the heterochromatin proteins HP1 through a highly conserved motif, the HP1box, and we have previously shown that this interaction is essential for the differentiation of F9 cells to occur. Here we address the in vivo functions of the TIF1ß-HP1 interaction, by generating mice in which the TIF1ß HP1box is mutated, leading to the loss of TIF1ß interaction with HP1. The effects of the mutation were monitored in two instances, where TIF1ß is known to play key roles: early embryonic development and spermatogenesis. We find that mutating the HP1box of TIF1ß disrupts embryonic development soon after gastrulation. This effect is likely caused by the misexpression of TIF1ß targets that regulate mitotic progression and pluripotency. In contrast, in Sertoli cells, we found that the absence of TIF1ß but not its mutation in the HP1box leads to a clear defect of spermatogenesis characterized by a failure of spermatid release and a testicular degeneration. These data show that the interaction between TIF1ß and HP1 is essential for some but not all TIF1ß functions in vivo. Furthermore, we observed that TIF1ß is dispersed through the nucleoplasm of E7.0 embryos, whereas it is mainly associated with pericentromeric heterochromatin of E8.5 embryos and of Sertoli cells, an association that is lost upon TIF1ß HP1box mutation. Altogether, these data provide strong evidence that nuclear organization plays key roles during early embryonic development.

Negative control of Smad activity by ectodermin/Tif1gamma patterns the mammalian embryo.

The definition of embryonic potency and induction of specific cell fates are intimately linked to the tight control over TGFbeta signaling. Although extracellular regulation of ligand availability has received considerable attention in recent years, surprisingly little is known about the intracellular factors that negatively control Smad activity in mammalian tissues. By means of genetic ablation, we show that the Smad4 inhibitor ectodermin (Ecto, also known as Trim33 or Tif1gamma) is required to limit Nodal responsiveness in vivo. New phenotypes, which are linked to excessive Nodal activity, emerge from such a modified landscape of Smad responsiveness in both embryonic and extra-embryonic territories. In extra-embryonic endoderm, Ecto is required to confine expression of Nodal antagonists to the anterior visceral endoderm. In trophoblast cells, Ecto precisely doses Nodal activity, balancing stem cell self-renewal and differentiation. Epiblast-specific Ecto deficiency shifts mesoderm fates towards node/organizer fates, revealing the requirement of Smad inhibition for the precise allocation of cells along the primitive streak. This study unveils that intracellular negative control of Smad function by ectodermin/Tif1gamma is a crucial element in the cellular response to TGFbeta signals in mammalian tissues.

Nizp1 zinc finger protein localization is determined by SCAN-domain inclusion regulated through alternative splicing.

The NSD1 histone methyl transferase is involved in childhood acute myeloid leukemia and the outgrowth disorders Sotos and Weaver syndromes. NSD1 is a transcriptional co-repressor for the zinc finger protein Nizp1 (also abbreviated Zfp496 and Zkscan17). Nizp1 includes a SCAN-domain, a KRAB-domain, four C2H2 Krüppel related zinc fingers, and a C2HR transcriptional repression and protein interaction domain required for NSD1 interaction. In this study we have identified alternative splicing of the Nizp1 gene resulting in transcripts encoding Nizp1 protein isoforms with a short N-terminal deletion or a SCAN-domain deletion. The alternative Nizp1 transcripts are expressed in lower levels relative to the canonical Nizp1 transcript. The Nizp1 SCAN-domain mediates Nizp1 self-association but lacks intrinsic transcriptional activating or repressing capacity and has no influence on the transcriptional repression activity of Nizp1 in reporter assays. Sub-cellular localization analysis showed that a fraction of Nizp1 localizes to CBP nuclear bodies and that the SCAN-domain is required for the localization to nuclear bodies. The presented results show that alternative splicing is a functional mechanism to generate Nizp1 protein isoforms with different SCAN-domain compositions and accordingly different sub-cellular localizations.

The NIZP1 KRAB and C2HR domains cross-talk for transcriptional regulation.

The NSD1 histone methyltransferase is involved in the outgrowth disorders Sotos and Weaver syndromes and childhood acute myeloid leukemia. NSD1 is a bona fida transcriptional co-repressor for Nizp1 which is a protein including SCAN, KRAB, C2HR and zinc-finger domains. In this study the Nizp1 KRAB-domain was identified to possess an intrinsic transcriptional activation capacity suppressed in cis by the presence of the C2HR domain. Oppositely, the KRAB-domain supported C2HR domain mediated transcriptional repression. The presence of the KRAB-domain resulted in increased NSD1 co-repressor association with the C2HR domain. This study shows a new function of the KRAB-domain, C2HR-domain, and the associated factors to confer Nizp1 mediated transcriptional regulation.

Epigenetic inactivation of the Sotos overgrowth syndrome gene histone methyltransferase NSD1 in human neuroblastoma and glioma.

Sotos syndrome is an autosomal dominant condition characterized by overgrowth resulting in tall stature and macrocephaly, together with an increased risk of tumorigenesis. The disease is caused by loss-of-function mutations and deletions of the nuclear receptor SET domain containing protein-1 (NSD1) gene, which encodes a histone methyltransferase involved in chromatin regulation. However, despite its causal role in Sotos syndrome and the typical accelerated growth of these patients, little is known about the putative contribution of NSD1 to human sporadic malignancies. Here, we report that NSD1 function is abrogated in human neuroblastoma and glioma cells by transcriptional silencing associated with CpG island-promoter hypermethylation. We also demonstrate that the epigenetic inactivation of NSD1 in transformed cells leads to the specifically diminished methylation of the histone lysine residues H4-K20 and H3-K36. The described phenotype is also observed in Sotos syndrome patients with NSD1 genetic disruption. Expression microarray data from NSD1-depleted cells, followed by ChIP analysis, revealed that the oncogene MEIS1 is one of the main NSD1 targets in neuroblastoma. Furthermore, we show that the restoration of NSD1 expression induces tumor suppressor-like features, such as reduced colony formation density and inhibition of cellular growth. Screening a large collection of different tumor types revealed that NSD1 CpG island hypermethylation was a common event in neuroblastomas and gliomas. Most importantly, NSD1 hypermethylation was a predictor of poor outcome in high-risk neuroblastoma. These findings highlight the importance of NSD1 epigenetic inactivation in neuroblastoma and glioma that leads to a disrupted histone methylation landscape and might have a translational value as a prognostic marker.

Inactivation of TIF1gamma cooperates with Kras to induce cystic tumors of the pancreas.

Inactivation of the Transforming Growth Factor Beta (TGFbeta) tumor suppressor pathway contributes to the progression of Pancreatic Ductal AdenoCarcinoma (PDAC) since it is inactivated in virtually all cases of this malignancy. Genetic lesions inactivating this pathway contribute to pancreatic tumor progression in mouse models. Transcriptional Intermediary Factor 1 gamma (TIF1gamma) has recently been proposed to be involved in TGFbeta signaling, functioning as either a positive or negative regulator of the pathway. Here, we addressed the role of TIF1gamma in pancreatic carcinogenesis. Using conditional Tif1gamma knockout mice (Tif1gamma(lox/lox)), we selectively abrogated Tif1gamma expression in the pancreas of Pdx1-Cre;Tif1gamma(lox/lox) mice. We also generated Pdx1-Cre;LSL-Kras(G12D);Tif1gamma(lox/lox) mice to address the effect of Tif1gamma loss-of-function in precancerous lesions induced by oncogenic Kras(G12D). Finally, we analyzed TIF1gamma expression in human pancreatic tumors. In our mouse model, we showed that Tif1gamma was dispensable for normal pancreatic development but cooperated with Kras activation to induce pancreatic tumors reminiscent of human Intraductal Papillary Mucinous Neoplasms (IPMNs). Interestingly, these cystic lesions resemble those observed in Pdx1-Cre;LSL-Kras(G12D);Smad4(lox/lox) mice described by others. However, distinctive characteristics, such as the systematic presence of endocrine pseudo-islets within the papillary projections, suggest that SMAD4 and TIF1gamma don't have strictly redundant functions. Finally, we report that TIF1gamma expression is markedly down-regulated in human pancreatic tumors by quantitative RT-PCR and immunohistochemistry supporting the relevance of these findings to human malignancy. This study suggests that TIF1gamma is critical for tumor suppression in the pancreas, brings new insight into the genetics of pancreatic cancer, and constitutes a promising model to decipher the respective roles of SMAD4 and TIF1gamma in the multifaceted functions of TGFbeta in carcinogenesis and development.

iNKT cell development is orchestrated by different branches of TGF-beta signaling.

Invariant natural killer T (iNKT) cells constitute a distinct subset of T lymphocytes exhibiting important immune-regulatory functions. Although various steps of their differentiation have been well characterized, the factors controlling their development remain poorly documented. Here, we show that TGF-beta controls the differentiation program of iNKT cells. We demonstrate that TGF-beta signaling carefully and specifically orchestrates several steps of iNKT cell development. In vivo, this multifaceted role of TGF-beta involves the concerted action of different pathways of TGF-beta signaling. Whereas the Tif-1gamma branch controls lineage expansion, the Smad4 branch maintains the maturation stage that is initially repressed by a Tif-1gamma/Smad4-independent branch. Thus, these three different branches of TGF-beta signaling function in concert as complementary effectors, allowing TGF-beta to fine tune the iNKT cell differentiation program.

Disruption of the interaction between transcriptional intermediary factor 1{beta} and heterochromatin protein 1 leads to a switch from DNA hyper- to hypomethylation and H3K9 to H3K27 trimethylation on the MEST promoter correlating with gene reactivation.

Here, we identified the imprinted mesoderm-specific transcript (MEST) gene as an endogenous TIF1beta primary target gene and demonstrated that transcriptional intermediary factor (TIF) 1beta, through its interaction with heterochromatin protein (HP) 1, is essential in establishing and maintaining a local heterochromatin-like structure on MEST promoter region characterized by H3K9 trimethylation and hypoacetylation, H4K20 trimethylation, DNA hypermethylation, and enrichment in HP1 that correlates with preferential association to foci of pericentromeric heterochromatin and transcriptional repression. On disruption of the interaction between TIF1beta and HP1, TIF1beta is released from the promoter region, and there is a switch from DNA hypermethylation and histone H3K9 trimethylation to DNA hypomethylation and histone H3K27 trimethylation correlating with rapid reactivation of MEST expression. Interestingly, we provide evidence that the imprinted MEST allele DNA methylation is insensitive to TIF1beta loss of function, whereas the nonimprinted allele is regulated through a distinct TIF1beta-DNA methylation mechanism.