Protein-arginine methyltransferase 1 (PRMT1) methylates Ash2L, a shared component of mammalian histone H3K4 methyltransferase complexes

Multiple enzymes and enzymatic complexes coordinately regulate the addition and removal of post-translational modifications on histone proteins. The oncoprotein Ash2L is a component of the mixed lineage leukemia (MLL) family members 1-4, Setd1A, and Setd1B mammalian histone H3K4 methyltransferase complexes and is essential to maintain global trimethylation of histone H3K4. However, regulation of these complexes at the level of expression and activity remains poorly understood. In this report, we demonstrate that Ash2L is methylated on arginine residues both in vitro and in cells. We found that both protein-arginine methyltransferases 1 and 5 methylate Arg-296 within Ash2L. These findings are the first to demonstrate that post-translational modifications occur on the Ash2L protein and provide a novel example of cross-talk between chromatin-modifying enzyme complexes.     

Functional Specificity of CpG DNA-binding CXXC Domains in Mixed Lineage Leukemia

The MLL CXXC domain binds nonmethylated CpG-containing DNA and is essential for the oncogenic properties of MLL fusion proteins. To determine potential functional promiscuity of similar DNA binding domains, we replaced the MLL CXXC domain in the context of the leukemogenic MLL-AF9 fusion with CXXC domains from DNMT1, CGBP (CFP1), and MBD1, or with a methyl-CpG-binding domain (MBD) from MBD1. MLL(DNMT1 CXXC)-AF9 shows robust in vitro colony forming activity and in vivo leukemogenesis, similar to MLL-AF9. However, colony forming ability and leukemogenicity are abrogated in MLL-AF9 containing either the CGBP or MBD1 CXXC domains or the MBD1 MBD domain. Direct comparison of in vitro DNA binding affinity of the isolated CXXC or MBD domains demonstrated that MLL, DNMT1, and CGBP CXXC domains could each bind to unmethylated DNA but with differing affinity. In contrast, the isolated MBD1 CXXC and MBD1 MBD domains were unable to bind to the same DNA. However, all substituted domains still allowed targeting of the MLL fusions to the functionally important Hoxa9 locus in primary bone marrow progenitor cells. In addition to DNA binding activity, it was critical that specific CpG residues in the Hoxa9 locus were protected from methylation for leukemia development. This ultimately prevented histone 3 lysine 9 trimethylation (H3K9me3) of the locus and enabled Hoxa9 expression. These were properties shared by MLL and DNMT1 CXXC domains but not by CGBP CXXC or the other swapped fusions tested. We demonstrate that similar CXXC domains can be mechanistically distinguished by specificity of CpG nucleotides preferentially protected from DNA methylation.     

The Cks1/Cks2 axis fine-tunes Mll1 expression and is crucial for MLL-rearranged leukaemia cell viability

The Cdc28 protein kinase subunits, Cks1 and Cks2, play dual roles in Cdk-substrate specificity and Cdk-independent protein degradation, in concert with the E3 ubiquitin ligase complexes SCF^Skp2 and APC^Cdc20. Notable targets controlled by Cks include p27 and Cyclin A. Here, we demonstrate that Cks1 and Cks2 proteins interact with both the Mll^N and Mll^C subunits of Mll1 (Mixed-lineage leukaemia 1), and together, the Cks proteins define Mll1 levels throughout the cell cycle. Overexpression of CKS1B and CKS2 is observed in multiple human cancers, including various MLL-rearranged (MLLr) AML subtypes. To explore the importance of MLL-Fusion Protein regulation by CKS1/2, we used small molecule inhibitors (MLN4924 and C1) to modulate their protein degradation functions. These inhibitors specifically reduced the proliferation of MLLr cell lines compared to primary controls. Altogether, this study uncovers a novel regulatory pathway for MLL1, which may open a new therapeutic approach to MLLr leukaemia.     

SETD1A Methyltransferase Is Physically and Functionally Linked to the DNA Damage Repair Protein RAD18

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Highlights

• •Protein interaction screen of SETD1A/COMPASS complex subunits.
• •Unexpected interaction with DNA damage protein RAD18 was confirmed for SETD1A, but not for other subunits.
• •SETD1A and/or RAD18 influence each other's mRNA and protein expression levels, and disruption of either gene elicits a similar DNA damage sensitivity phenotype.