Your search keyword '"Michael S. Cosgrove"' showing total 29 results

1. Convergent Alterations of a Protein Hub Produce Divergent Effects within a Binding Site

Author

Ali Imran, Brandon S. Moyer, Dan Kalina, Thomas M. Duncan, Kelsey J. Moody, Aaron J. Wolfe, Michael S. Cosgrove, and Liviu Movileanu

Subjects

Binding Sites, Multienzyme Complexes, Intracellular Signaling Peptides and Proteins, Humans, Molecular Medicine, Histone-Lysine N-Methyltransferase, General Medicine, Ligands, Peptides, Biochemistry, Protein Binding

Abstract

Progress in tumor sequencing and cancer databases has created an enormous amount of information that scientists struggle to sift through. While several research groups have created computational methods to analyze these databases, much work still remains in distinguishing key implications of pathogenic mutations. Here, we describe an approach to identify and evaluate somatic cancer mutations of WD40 repeat protein 5 (WDR5), a chromatin-associated protein hub. This multitasking protein maintains the functional integrity of large multi-subunit enzymatic complexes of the six human SET1 methyltransferases. Remarkably, the somatic cancer mutations of WDR5 preferentially distribute within and around an essential cavity, which hosts the WDR5 interaction (Win) binding site. Hence, we assessed the real-time binding kinetics of the interactions of key clustered WDR5 mutants with the Win motif peptide ligands of the SET1 family members (SET1

Published

2022

2. Mechanistic insights into enhancement or inhibition of phase separation by different polyubiquitin chains

Author

Thuy P Dao, Yiran Yang, Maria F Presti, Michael S Cosgrove, Jesse B Hopkins, Weikang Ma, Stewart N Loh, and Carlos A Castañeda

Subjects

Models, Molecular, Ubiquitin, Genetics, Ubiquitination, Polyubiquitin, Molecular Biology, Biochemistry, Protein Binding

Abstract

Ubiquitin-binding shuttle UBQLN2 mediates crosstalk between proteasomal degradation and autophagy, likely via interactions with K48- and K63-linked polyubiquitin chains, respectively. UBQLN2 comprises self-associating regions that drive its homotypic liquid-liquid phase separation (LLPS). Specific interactions between one of these regions and ubiquitin inhibit UBQLN2 LLPS. Here, we show that, unlike ubiquitin, the effects of multivalent polyubiquitin chains on UBQLN2 LLPS are highly dependent on chain types. Specifically, K11-Ub4 and K48-Ub4 chains generally inhibit UBQLN2 LLPS, whereas K63-Ub4, M1-Ub4 chains, and a designed tetrameric ubiquitin construct significantly enhance LLPS. We demonstrate that these opposing effects stem from differences in chain conformations but not in affinities between chains and UBQLN2. Chains with extended conformations and increased accessibility to the ubiquitin-binding surface promote UBQLN2 LLPS by enabling a switch between homotypic to partially heterotypic LLPS that is driven by both UBQLN2 self-interactions and interactions between multiple UBQLN2 units with each polyubiquitin chain. Our study provides mechanistic insights into how the structural and conformational properties of polyubiquitin chains contribute to heterotypic LLPS with ubiquitin-binding shuttles and adaptors.

Published

2022

3. Hierarchical assembly of the MLL1 core complex regulates H3K4 methylation and is dependent on temperature and component concentration

Author

Kevin E.W. Namitz, Song Tan, and Michael S. Cosgrove

Subjects

Cell Biology, Molecular Biology, Biochemistry

Published

2023

4. Probing multiple enzymatic methylation events in real time with NMR spectroscopy

Author

Emery T. Usher, Scott A. Showalter, Kevin E. W. Namitz, and Michael S. Cosgrove

Subjects

Methyltransferase, Magnetic Resonance Spectroscopy, Chemistry, Lysine, Biophysics, MLL1 complex, Methylation, Histone-Lysine N-Methyltransferase, Histones, Histone H3, Biochemistry, Transcriptional regulation, Protein Processing, Post-Translational, Heteronuclear single quantum coherence spectroscopy, PRDM9

Abstract

Post-translational modification (PTM) of proteins is of critical importance to the regulation of many cellular processes in eukaryotic organisms. One of the most well-studied protein PTMs is methylation, wherein an enzyme catalyzes the transfer of a methyl group from a cofactor to a lysine or arginine side chain. Lysine methylation is especially abundant in the histone tails and is an important marker for denoting active or repressed genes. Given their relevance to transcriptional regulation, the study of methyltransferase function through in vitro experiments is an important stepping stone toward understanding the complex mechanisms of regulated gene expression. To date, most methyltransferase characterization strategies rely on the use of radioactive cofactors, detection of a methyl transfer byproduct, or discontinuous-type assays. Although such methods are suitable for some applications, information about multiple methylation events and kinetic intermediates is often lost. Herein, we describe the use of two-dimensional NMR to monitor mono-, di-, and trimethylation in a single reaction tube. To do so, we incorporated 13C into the donor methyl group of the enzyme cofactor S-adenosyl methionine. In this way, we may study enzymatic methylation by monitoring the appearance of distinct resonances corresponding to mono-, di-, or trimethyl lysine without the need to isotopically enrich the substrate. To demonstrate the capabilities of this method, we evaluated the activity of three lysine methyltransferases, Set7, MWRAD2 (MLL1 complex), and PRDM9, toward the histone H3 tail. We monitored mono- or multimethylation of histone H3 tail at lysine 4 through sequential short two-dimensional heteronuclear single quantum coherence experiments and fit the resulting progress curves to first-order kinetic models. In summary, NMR detection of PTMs in one-pot, real-time reaction using facile cofactor isotopic enrichment shows promise as a method toward understanding the intricate mechanisms of methyltransferases and other enzymes.

Published

2021

5. Kinetics of the multitasking high-affinity Win binding site of WDR5 in restricted and unrestricted conditions

Author

Aaron J. Wolfe, Liviu Movileanu, Michael S. Cosgrove, Ashley J. Canning, Ali Imran, Kelsey Moody, Thomas M. Duncan, Brandon S. Moyer, and Dan Kalina

Subjects

Methyltransferase, Protein Conformation, Quantitative proteomics, Amino Acid Motifs, Computational biology, Biochemistry, Article, WD40 repeat, Histone methylation, WDR5, Humans, Protein Interaction Domains and Motifs, Binding site, Molecular Biology, Binding Sites, biology, Chemistry, Intracellular Signaling Peptides and Proteins, Cell Biology, Methylation, Histone-Lysine N-Methyltransferase, Peptide Fragments, Kinetics, Histone, biology.protein, Protein Binding

Abstract

Recent advances in quantitative proteomics show that WD40 proteins play a pivotal role in numerous cellular networks. Yet, they have been fairly unexplored and their physical associations with other proteins are ambiguous. A quantitative understanding of these interactions has wide-ranging significance. WD40 repeat protein 5 (WDR5) interacts with all members of human SET1/MLL methyltransferases, which regulate methylation of the histone 3 lysine 4 (H3K4). Here, using real-time binding measurements in a high-throughput setting, we identified the kinetic fingerprint of transient associations between WDR5 and 14-residue WDR5 interaction (Win) motif peptides of each SET1 protein (SET1Win). Our results reveal that the high-affinity WDR5-SET1Win interactions feature slow association kinetics. This finding is likely due to the requirement of SET1Win to insert into the narrow WDR5 cavity, also named the Win binding site. Furthermore, our explorations indicate fairly slow dissociation kinetics. This conclusion is in accordance with the primary role of WDR5 in maintaining the functional integrity of a large multisubunit complex, which regulates the histone methylation. Because the Win binding site is considered a key therapeutic target, the immediate outcomes of this study could form the basis for accelerated developments in medical biotechnology.

Published

2021

6. Unique Role of the WD-40 Repeat Protein 5 (WDR5) Subunit within the Mixed Lineage Leukemia 3 (MLL3) Histone Methyltransferase Complex

Author

Stephen A. Shinsky and Michael S. Cosgrove

Subjects

Models, Molecular, Histone H3 Lysine 4, Protein Conformation, Protein subunit, histone, Biology, Biochemistry, Protein structure, Histone methylation, Humans, Gene Regulation, histone methylation, Histone methyltransferase complex, Molecular Biology, Genetics, Intracellular Signaling Peptides and Proteins, leukemia, Histone-Lysine N-Methyltransferase, Cell Biology, Chromatin, DNA-Binding Proteins, enzyme, Histone, Histone methyltransferase, Histone Methyltransferases, biology.protein, chromatin, Protein Binding

Abstract

Background: The mixed lineage leukemia 3 (MLL3) core complex catalyzes monomethylation of histone H3 lysine 4 (H3K4). Results: The WDR5 subunit is not required for MLL3 core complex assembly and partially inhibits methyltransferase activity. Conclusion: WDR5 plays a unique role within the MLL3 core complex. Significance: SET1 family complexes retain WDR5 for distinct purposes., The MLL3 (mixed lineage leukemia 3) protein is a member of the human SET1 family of histone H3 lysine 4 methyltransferases and contains the conserved WDR5 interaction (Win) motif and the catalytic suppressor of variegation, enhancer of zeste, trithorax (SET) domain. The human SET1 family includes MLL1–4 and SETd1A/B, which all interact with a conserved subcomplex containing WDR5, RbBP5, Ash2L, and DPY-30 (WRAD) to form the minimal core complex required for full methyltransferase activity. However, recent evidence suggests that the WDR5 subunit may not be utilized in an identical manner within all SET1 family core complexes. Although the roles of WDR5 within the MLL1 core complex have been extensively studied, not much is known about the roles of WDR5 in other SET1 family core complexes. In this investigation, we set out to characterize the roles of the WDR5 subunit in the MLL3 core complex. We found that unlike MLL1, the MLL3 SET domain assembles with the RbBP5/Ash2L heterodimer independently of the Win motif-WDR5 interaction. Furthermore, we observed that WDR5 inhibits the monomethylation activity of the MLL3 core complex, which is dependent on the Win motif. We also found evidence suggesting that the WRAD subcomplex catalyzes weak H3K4 monomethylation within the context of the MLL3 core complex. Furthermore, solution structures of the MLL3 core complex assembled with and without WDR5 by small angle x-ray scattering show similar overall topologies. Together, this work demonstrates a unique role for WDR5 in modulating the enzymatic activity of the MLL3 core complex.

Published

2015

7. Biochemical Reconstitution and Phylogenetic Comparison of Human SET1 Family Core Complexes Involved in Histone Methylation

Author

Kelsey E. Monteith, Stephen A. Shinsky, Michael S. Cosgrove, and Susan Viggiano

Subjects

Histone H3 Lysine 4, Methyltransferase, Protein subunit, Plasma protein binding, Crystallography, X-Ray, complex mixtures, environment and public health, Methylation, Biochemistry, Histones, Phylogenetics, Histone methylation, Humans, Gene Regulation, Molecular Biology, Phylogeny, Genetics, biology, Lysine, Nuclear Proteins, Histone-Lysine N-Methyltransferase, Cell Biology, Histone, Amino Acid Substitution, Multiprotein Complexes, biology.protein, bacteria, Myeloid-Lymphoid Leukemia Protein, Protein Binding, Transcription Factors

Abstract

Mixed lineage leukemia protein-1 (MLL1) is a member of the SET1 family of histone H3 lysine 4 (H3K4) methyltransferases that are required for metazoan development. MLL1 is the best characterized human SET1 family member, which includes MLL1-4 and SETd1A/B. MLL1 assembles with WDR5, RBBP5, ASH2L, DPY-30 (WRAD) to form the MLL1 core complex, which is required for H3K4 dimethylation and transcriptional activation. Because all SET1 family proteins interact with WRAD in vivo, it is hypothesized they are regulated by similar mechanisms. However, recent evidence suggests differences among family members that may reflect unique regulatory inputs in the cell. Missing is an understanding of the intrinsic enzymatic activities of different SET1 family complexes under standard conditions. In this investigation, we reconstituted each human SET1 family core complex and compared subunit assembly and enzymatic activities. We found that in the absence of WRAD, all but one SET domain catalyzes at least weak H3K4 monomethylation. In the presence of WRAD, all SET1 family members showed stimulated monomethyltransferase activity but differed in their di- and trimethylation activities. We found that these differences are correlated with evolutionary lineage, suggesting these enzyme complexes have evolved to accomplish unique tasks within metazoan genomes. To understand the structural basis for these differences, we employed a "phylogenetic scanning mutagenesis" assay and identified a cluster of amino acid substitutions that confer a WRAD-dependent gain-of-function dimethylation activity on complexes assembled with the MLL3 or Drosophila trithorax proteins. These results form the basis for understanding how WRAD differentially regulates SET1 family complexes in vivo.

Published

2015

8. Automethylation Activities within the Mixed Lineage Leukemia-1 (MLL1) Core Complex Reveal Evidence Supporting a 'Two-active Site' Model for Multiple Histone H3 Lysine 4 Methylation

Author

Venkatasubramanian Dharmarajan, Benny Howard, Gillian V. Kupakuwana, Stephen A. Shinsky, Michael S. Cosgrove, Stephen Swatkoski, Anamika Patel, Valarie E. Vought, Susan Viggiano, Robert J. Cotter, Kelsey E. Monteith, and Kevin E. Namitz

Subjects

Models, Molecular, Histone H3 Lysine 4, Enzyme Mechanisms, DNA and Chromosomes, Biology, environment and public health, Methylation, Biochemistry, Mass Spectrometry, Histones, Histone H3, Histone methylation, Animals, Humans, Cysteine, Molecular Biology, Histone binding, Leukemia, Binding Sites, Lysine, Intracellular Signaling Peptides and Proteins, Nuclear Proteins, Active site, Histone-Lysine N-Methyltransferase, Cell Biology, Self-methylation, Protein Structure, Tertiary, Cell biology, DNA-Binding Proteins, Kinetics, Histone, Amino Acid Substitution, Histone methyltransferase, Mutation, Automethylation, biology.protein, Chromatin Histone Modification, Epigenetics, Histone Methylation, Electrophoresis, Polyacrylamide Gel, Myeloid-Lymphoid Leukemia Protein, Transcription Factors

Abstract

Background: The MLL1 core complex mono- and dimethylates histone H3 lysine 4 (H3K4). Results: MLL1 automethylates a conserved cysteine residue in its active site cleft. Conclusion: MLL1 automethylation is inhibited by unmodified histone H3 but not by histones previously mono-, di-, or trimethylated at H3K4. Significance: The pattern of automethylation inhibition is consistent with distinct active sites for mono- and dimethylation of H3K4., The mixed lineage leukemia-1 (MLL1) core complex predominantly catalyzes mono- and dimethylation of histone H3 at lysine 4 (H3K4) and is frequently altered in aggressive acute leukemias. The molecular mechanisms that account for conversion of mono- to dimethyl H3K4 (H3K4me1,2) are not well understood. In this investigation, we report that the suppressor of variegation, enhancer of zeste, trithorax (SET) domains from human MLL1 and Drosophila Trithorax undergo robust intramolecular automethylation reactions at an evolutionarily conserved cysteine residue in the active site, which is inhibited by unmodified histone H3. The location of the automethylation in the SET-I subdomain indicates that the MLL1 SET domain possesses significantly more conformational plasticity in solution than suggested by its crystal structure. We also report that MLL1 methylates Ash2L in the absence of histone H3, but only when assembled within a complex with WDR5 and RbBP5, suggesting a restraint for the architectural arrangement of subunits within the complex. Using MLL1 and Ash2L automethylation reactions as probes for histone binding, we observed that both automethylation reactions are significantly inhibited by stoichiometric amounts of unmethylated histone H3, but not by histones previously mono-, di-, or trimethylated at H3K4. These results suggest that the H3K4me1 intermediate does not significantly bind to the MLL1 SET domain during the dimethylation reaction. Consistent with this hypothesis, we demonstrate that the MLL1 core complex assembled with a catalytically inactive SET domain variant preferentially catalyzes H3K4 dimethylation using the H3K4me1 substrate. Taken together, these results are consistent with a “two-active site” model for multiple H3K4 methylation by the MLL1 core complex.

Published

2014

9. Targeted Disruption of the Interaction between WD-40 Repeat Protein 5 (WDR5) and Mixed Lineage Leukemia (MLL)/SET1 Family Proteins Specifically Inhibits MLL1 and SETd1A Methyltransferase Complexes*

Author

Jeong Heon Lee, David G. Skalnik, Nilda L. Alicea-Velázquez, Stephen A. Shinsky, Michael S. Cosgrove, and Daniel M. Loh

Subjects

0301 basic medicine, Genetics, Histone H3 Lysine 4, Methyltransferase, Peptidomimetic, HEK 293 cells, Amino Acid Motifs, Intracellular Signaling Peptides and Proteins, Cell Biology, Histone-Lysine N-Methyltransferase, Biology, Biochemistry, Protein–protein interaction, 03 medical and health sciences, 030104 developmental biology, Protein structure, HEK293 Cells, Multienzyme Complexes, Histone methylation, Mutation, WDR5, Humans, Gene Regulation, Molecular Biology, Myeloid-Lymphoid Leukemia Protein

Abstract

MLL1 belongs to the SET1 family of histone H3 lysine 4 (H3K4) methyltransferases, composed of MLL1–4 and SETd1A/B. MLL1 translocations are present in acute leukemias, and mutations in several family members are associated with cancer and developmental disorders. MLL1 associates with a subcomplex containing WDR5, RbBP5, ASH2L, and DPY-30 (WRAD), forming the MLL1 core complex required for H3K4 mono- and dimethylation and transcriptional activation. Core complex assembly requires interaction of WDR5 with the MLL1 Win (WDR5 interaction) motif, which is conserved across the SET1 family. Agents that mimic the SET1 family Win motif inhibit the MLL1 core complex and have become an attractive approach for targeting MLL1 in cancers. Like MLL1, other SET1 family members interact with WRAD, but the roles of the Win motif in complex assembly and enzymatic activity remain unexplored. Here, we show that the Win motif is necessary for interaction of WDR5 with all members of the human SET1 family. Mutation of the Win motif-WDR5 interface severely disrupts assembly and activity of MLL1 and SETd1A complexes but only modestly disrupts MLL2/4 and SETd1B complexes without significantly altering enzymatic activity in vitro. Notably, in the absence of WDR5, MLL3 interacts with RAD and shows enhanced activity. To further probe the role of the Win motif-WDR5 interaction, we designed a peptidomimetic that binds WDR5 (Kd ∼3 nm) and selectively inhibits activity of MLL1 and SETd1A core complexes within the SET1 family. Our results reveal that SET1 family complexes with the weakest Win motif-WDR5 interaction are more susceptible to Win motif-based inhibitors.

Published

2016

10. The Bin3 RNA methyltransferase targets 7SK RNA to control transcription and translation

Author

Steven D. Hanes, Ye Ding, William A. Rennie, Michael J. Lane, and Michael S. Cosgrove

Subjects

Five-prime cap, animal structures, biology, General transcription factor, RNA-dependent RNA polymerase, RNA, RNA polymerase II, Non-coding RNA, Biochemistry, Molecular biology, Cell biology, RNA silencing, Transcription (biology), biology.protein, Molecular Biology

Abstract

Bicoid-interacting protein 3 (Bin3) is a conserved RNA methyltransferase found in eukaryotes ranging from fission yeast to humans. It was originally discovered as a Bicoid (Bcd)-interacting protein in Drosophila, where it is required for anterior-posterior and dorso-ventral axis determination in the early embryo. The mammalian ortholog of Bin3 (BCDIN3), also known as methyl phosphate capping enzyme (MePCE), plays a key role in repressing transcription. In transcription, MePCE binds the non-coding 7SK RNA, which forms a scaffold for an RNA-protein complex that inhibits positive-acting transcription elongation factor b, an RNA polymerase II elongation factor. MePCE uses S-adenosyl methionine to transfer a methyl group onto the γ-phosphate of the 5' guanosine of 7SK RNA generating an unusual cap structure that protects 7SK RNA from degradation. Bin3/MePCE also has a role in translation regulation. Initial studies in Drosophila indicate that Bin3 targets 7SK RNA and stabilizes a distinct RNA-protein complex that assembles on the 3'-untranslated region of caudal mRNAs to prevent translation initiation. Much remains to be learned about Bin3/MeCPE function, including how it recognizes 7SK RNA, what other RNA substrates it might target, and how widespread a role it plays in gene regulation and embryonic development.

Published

2012

11. Myosin5a Tail Associates Directly with Rab3A-containing Compartments in Neurons

Author

George M. Langford, D. William Provance, Michael S. Cosgrove, Valarie E. Vought, Torsten Wöllert, Ying Lung Lee, Anamika Patel, and John A. Mercer

Subjects

Myosin Type V, Biology, Biochemistry, Synaptic vesicle, Rats, Sprague-Dawley, Motor protein, Mice, Animals, Humans, Molecular Biology, Neurons, Myosin Heavy Chains, Vesicle, Decapodiformes, Brain, Cell Biology, Rab3A GTP-Binding Protein, Recombinant Proteins, rab3A GTP-Binding Protein, Frontal Lobe, Rats, Cell biology, Mice, Inbred C57BL, Vesicular transport protein, Squid giant axon, Axoplasm, Guanosine Triphosphate, Rab, Dimerization, Protein Binding

Abstract

Myosin-Va (Myo5a) is a motor protein associated with synaptic vesicles (SVs) but the mechanism by which it interacts has not yet been identified. A potential class of binding partners are Rab GTPases and Rab3A is known to associate with SVs and is involved in SV trafficking. We performed experiments to determine whether Rab3A interacts with Myo5a and whether it is required for transport of neuronal vesicles. In vitro motility assays performed with axoplasm from the squid giant axon showed a requirement for a Rab GTPase in Myo5a-dependent vesicle transport. Furthermore, mouse recombinant Myo5a tail revealed that it associated with Rab3A in rat brain synaptosomal preparations in vitro and the association was confirmed by immunofluorescence imaging of primary neurons isolated from the frontal cortex of mouse brains. Synaptosomal Rab3A was retained on recombinant GST-tagged Myo5a tail affinity columns in a GTP-dependent manner. Finally, the direct interaction of Myo5a and Rab3A was determined by sedimentation velocity analytical ultracentrifugation using recombinant mouse Myo5a tail and human Rab3A. When both proteins were incubated in the presence of 1 mm GTPγS, Myo5a tail and Rab3A formed a complex and a direct interaction was observed. Further analysis revealed that GTP-bound Rab3A interacts with both the monomeric and dimeric species of the Myo5a tail. However, the interaction between Myo5a tail and nucleotide-free Rab3A did not occur. Thus, our results show that Myo5a and Rab3A are direct binding partners and interact on SVs and that the Myo5a/Rab3A complex is involved in transport of neuronal vesicles.

Published

2011

12. Mixed lineage leukemia: a structure-function perspective of the MLL1 protein

Author

Anamika Patel and Michael S. Cosgrove

Subjects

Genetics, Histone H3 Lysine 4, Methyltransferase, biology, Cell Biology, Methylation, medicine.disease, Biochemistry, Leukemia, Histone, medicine, biology.protein, WDR5, Myeloid-Lymphoid Leukemia Protein, Molecular Biology, Gene

Abstract

Several acute lymphoblastic and myelogenous leukemias are correlated with alterations in the human mixed lineage leukemia protein-1 (MLL1) gene. MLL1 is a member of the evolutionarily conserved SET1 family of histone H3 lysine 4 (H3K4) methyltransferases, which are required for the regulation of distinct groups of developmentally regulated genes in metazoans. Despite the important biological role of SET1 family enzymes and their involvement in human leukemias, relatively little is understood about how these enzymes work. Here we review several recent structural and biochemical studies that are beginning to shed light on the molecular mechanisms for the regulation of H3K4 methylation by the human MLL1 enzyme.

Published

2010

13. On the Mechanism of Multiple Lysine Methylation by the Human Mixed Lineage Leukemia Protein-1 (MLL1) Core Complex

Author

Valarie E. Vought, Michael S. Cosgrove, Anamika Patel, and Venkatasubramanian Dharmarajan

Subjects

Histone H3 Lysine 4, Methyltransferase, Lysine, Biology, Methylation, environment and public health, Biochemistry, Histones, Transcription (biology), Humans, Transcription, Chromatin, and Epigenetics, Molecular Biology, Gene Rearrangement, Leukemia, Intracellular Signaling Peptides and Proteins, Nuclear Proteins, Retinol-Binding Proteins, Cellular, Histone-Lysine N-Methyltransferase, Cell Biology, MLL1 complex, DNA-Binding Proteins, Multiprotein Complexes, Histone methyltransferase, Myeloid-Lymphoid Leukemia Protein, Transcription Factors

Abstract

Transcription in eukaryotic genomes depends on enzymes that regulate the degree of histone H3 lysine 4 (H3K4) methylation. The mixed lineage leukemia protein-1 (MLL1) is a member of the SET1 family of H3K4 methyltransferases and is frequently rearranged in acute leukemias. Despite sequence comparisons that predict that SET1 family enzymes should only monomethylate their substrates, mono-, di-, and trimethylation of H3K4 has been attributed to SET1 family complexes in vivo and in vitro. To better understand this paradox, we have biochemically reconstituted and characterized a five-component 200-kDa MLL1 core complex containing human MLL1, WDR5, RbBP5, Ash2L, and DPY-30. We demonstrate that the isolated MLL1 SET domain is a slow monomethyltransferase and that tyrosine 3942 of MLL1 prevents di- and trimethylation of H3K4. In contrast, a complex containing the MLL1 SET domain, WDR5, RbBP5, Ash2L, and DPY-30, displays a marked approximately 600-fold increase in enzymatic activity but only to the dimethyl form of H3K4. Single turnover kinetic experiments reveal that the reaction leading to H3K4 dimethylation involves the transient accumulation of a monomethylated species, suggesting that the MLL1 core complex uses a non-processive mechanism to catalyze multiple lysine methylation. We have also discovered that the non-SET domain components of the MLL1 core complex possess a previously unrecognized methyltransferase activity that catalyzes H3K4 dimethylation within the MLL1 core complex. Our results suggest that the mechanism of multiple lysine methylation by the MLL1 core complex involves the sequential addition of two methyl groups at two distinct active sites within the complex.

Published

2009

14. The Structural Basis of Sirtuin Substrate Affinity

Author

Cynthia Wolberger, Katherine M. Bever, José L. Avalos, Michael S. Cosgrove, Xiangbin Zhang, and Shabazz Muhammad

Subjects

Models, Molecular, Stereochemistry, Molecular Sequence Data, Crystallography, X-Ray, Biochemistry, Substrate Specificity, Structure-Activity Relationship, chemistry.chemical_compound, Hydrolase, Escherichia coli, Side chain, Sirtuins, Thermotoga maritima, Amino Acid Sequence, chemistry.chemical_classification, Binding Sites, Sequence Homology, Amino Acid, biology, Substrate (chemistry), Enzyme, chemistry, Acetylation, Acetyllysine, Sirtuin, biology.protein, Thermodynamics, NAD+ kinase, Peptides, Protein Binding

Abstract

Sirtuins comprise a family of enzymes that catalyze the deacetylation of acetyllysine side chains in a reaction that consumes NAD+. Although several crystal structures of sirtuins bound to non-native acetyl peptides have been determined, relatively little about how sirtuins discriminate among different substrates is understood. We have carried out a systematic structural and thermodynamic analysis of several peptides bound to a single sirtuin, the Sir2 homologue from Thermatoga maritima (Sir2Tm). We report structures of five different forms of Sir2Tm: two forms bound to the p53 C-terminal tail in the acetylated and unacetylated states, two forms bound to putative acetyl peptide substrates derived from the structured domains of histones H3 and H4, and one form bound to polypropylene glycol (PPG), which resembles the apoenzyme. The structures reveal previously unobserved complementary side chain interactions between Sir2Tm and the first residue N-terminal to the acetyllysine (position -1) and the second residue C-terminal to the acetyllysine (position +2). Isothermal titration calorimetry was used to compare binding constants between wild-type and mutant forms of Sir2Tm and between additional acetyl peptide substrates with substitutions at positions -1 and +2. The results are consistent with a model in which peptide positions -1 and +2 play a significant role in sirtuin substrate binding. This model provides a framework for identifying sirtuin substrates.

Published

2006

15. How does the histone code work?

Author

Michael S. Cosgrove and Cynthia Wolberger

Subjects

Models, Molecular, Genetics, Acetylation, Cell Biology, Biology, Methylation, Biochemistry, Linker DNA, Chromatin, Nucleosomes, Cell biology, Histones, Histone H1, Histone methylation, Chromatosome, Histone H2A, Animals, Humans, Histone code, Nucleosome, Histone octamer, Phosphorylation, Protein Processing, Post-Translational, Molecular Biology

Abstract

Patterns of histone post-translational modifications correlate with distinct chromosomal states that regulate access to DNA, leading to the histone-code hypothesis. However, it is not clear how modification of flexible histone tails leads to changes in nucleosome dynamics and, thus, chromatin structure. The recent discovery that, like the flexible histone tails, the structured globular domain of the nucleosome core particle is also extensively modified adds a new and exciting dimension to the histone-code hypothesis, and calls for the re-examination of current models for the epigenetic regulation of chromatin structure. Here, we review these findings and other recent studies that suggest the structured globular domain of the nucleosome core particle plays a key role regulating chromatin dynamics.Key words: histones, histone code, modifications, epigenetic, chromatin, nucleosome, dynamics, regulated nucleosome mobility, core, archaeal, combinatorial switch, histone octamer.

Published

2005

16. The Catalytic Mechanism of Glucose 6-Phosphate Dehydrogenases: Assignment and 1H NMR Spectroscopy pH Titration of the Catalytic Histidine Residue in the 109 kDa Leuconostoc mesenteroides Enzyme

Author

Jeung-Hoi Ha, Michael S. Cosgrove, Stewart N. Loh, and H. Richard Levy

Subjects

biology, Stereochemistry, Chemistry, Titrimetry, Glucosephosphate Dehydrogenase, Hydrogen-Ion Concentration, biology.organism_classification, Biochemistry, NMR spectra database, Kinetics, chemistry.chemical_compound, Heteronuclear molecule, Glucose 6-phosphate, Leuconostoc mesenteroides, Catalytic Domain, Mutagenesis, Site-Directed, Histidine, Titration, Enzyme kinetics, Nuclear Magnetic Resonance, Biomolecular, Two-dimensional nuclear magnetic resonance spectroscopy, Leuconostoc

Abstract

The chemical shifts of the C(epsilon1) and C(delta2) protons of His-240 from the 109 kDa Leuconostoc mesenteroides glucose 6-phosphate dehydrogenase (G6PD) were assigned by comparing 1H and 13C spectra of the wild-type and mutant G6PDs containing the His-240 to asparagine mutation (H240N). Unambiguous assignment of the His-240 1H(epsilon1) resonance was obtained from comparing 13C-1H heteronuclear multiple quantum coherence NMR spectra of wild-type and H240N G6PDs that were selectively labeled with 13C(epsilon1) histidine. The results from NOESY experiments with wild-type and H240N variants were consistent with these assignments and the three-dimensional structure of G6PD. pH titrations show that His-240 has a pK(a) of 6.4. This value is, within experimental error, identical to the value of 6.3 derived from the pH dependence of kcat [Viola, R. E. (1984) Arch. Biochem. Biophys. 228, 415-424], suggesting that the pK(a) of His-240 is unperturbed in the apoenzyme despite being part of a His-Asp catalytic dyad. The results obtained for this 109 kDa enzyme indicate that 1H NMR spectroscopy in combination with heteronuclear methods can be a useful tool for functional analysis of large proteins.

Published

2002

17. Characterization of the Grp94/OS-9 chaperone-lectin complex

Author

Daniel T. Gewirth, Stephen A. Shinsky, Michael S. Cosgrove, Zihai Li, Paul M. Seidler, and Feng Hong

Subjects

Glycosylation, Plasma protein binding, Endoplasmic-reticulum-associated protein degradation, Article, chemistry.chemical_compound, Dogs, Structural Biology, Lectins, Yeasts, Escherichia coli, Animals, Humans, Molecular Biology, Membrane Glycoproteins, biology, Endoplasmic reticulum, Hsp90, Neoplasm Proteins, Protein Structure, Tertiary, Rats, HEK293 Cells, Biochemistry, chemistry, Chaperone (protein), biology.protein, Thermodynamics, Protein folding, Cattle, Protein Processing, Post-Translational, Ultracentrifugation, Allosteric Site, Binding domain, Molecular Chaperones, Protein Binding

Abstract

Grp94 is a macromolecular chaperone belonging to the hsp90 family and is the most abundant glycoprotein in the endoplasmic reticulum (ER) of mammals. In addition to its essential role in protein folding, Grp94 was proposed to participate in the ER-associated degradation quality control pathway by interacting with the lectin OS-9, a sensor for terminally misfolded proteins. To understand how OS-9 interacts with ER chaperone proteins, we mapped its interaction with Grp94. Glycosylation of the full-length Grp94 protein was essential for OS-9 binding, although deletion of the Grp94 N-terminal domain relieved this requirement suggesting that the effect was allosteric rather than direct. Although yeast OS-9 is composed of a well-established N-terminal mannose recognition homology lectin domain and a C-terminal dimerization domain, we find that the C-terminal domain of OS-9 in higher eukaryotes contains "mammalian-specific insets" that are specifically recognized by the middle and C-terminal domains of Grp94. Additionally, the Grp94 binding domain in OS-9 was found to be intrinsically disordered. The biochemical analysis of the interacting regions provides insight into the manner by which the two associate and it additionally hints at a plausible biological role for the Grp94/OS-9 complex.

Published

2014

18. Delineation of the Roles of Amino Acids Involved in the Catalytic Functions of Leuconostoc mesenteroides Glucose 6-Phosphate Dehydrogenase

Author

Valarie Vought, Teriggi Ciccone, Lane Fairbairn, H. Richard Levy, Mark H. Davino, Yuan Lin, Michael S. Cosgrove, and and Margaret J. Adams

Subjects

Models, Molecular, Proline, Glutamine, Glucose-6-Phosphate, Dehydrogenase, Glucosephosphate Dehydrogenase, Arginine, Biochemistry, Catalysis, Cofactor, Coenzyme binding, Enzyme kinetics, Conserved Sequence, chemistry.chemical_classification, Binding Sites, biology, Lysine, NAD, biology.organism_classification, Amino acid, Kinetics, Enzyme, chemistry, Leuconostoc mesenteroides, Mutation, Mutagenesis, Site-Directed, biology.protein, Thermodynamics, NAD+ kinase, Dimerization, Leuconostoc, NADP

Abstract

The roles of particular amino acids in substrate and coenzyme binding and catalysis of glucose-6-phosphate dehydrogenase of Leuconostoc mesenteroides have been investigated by site-directed mutagenesis, kinetic analysis, and determination of binding constants. The enzyme from this species has functional dual NADP(+)/NAD(+) specificity. Previous investigations in our laboratories determined the three-dimensional structure. Kinetic studies showed an ordered mechanism for the NADP-linked reaction while the NAD-linked reaction is random. His-240 was identified as the catalytic base, and Arg-46 was identified as important for NADP(+) but not NAD(+) binding. Mutations have been selected on the basis of the three-dimensional structure. Kinetic studies of 14 mutant enzymes are reported and kinetic mechanisms are reported for 5 mutant enzymes. Fourteen substrate or coenzyme dissociation constants have been measured for 11 mutant enzymes. Roles of particular residues are inferred from k(cat), K(m), k(cat)/K(m), K(d), and changes in kinetic mechanism. Results for enzymes K182R, K182Q, K343R, and K343Q establish Lys-182 and Lys-343 as important in binding substrate both to free enzyme and during catalysis. Studies of mutant enzymes Y415F and Y179F showed no significant contribution for Tyr-415 to substrate binding and only a small contribution for Tyr-179. Changes in kinetics for T14A, Q47E, and R46A enzymes implicate these residues, to differing extents, in coenzyme binding and discrimination between NADP(+) and NAD(+). By the same measure, Lys-343 is also involved in defining coenzyme specificity. Decrease in k(cat) and k(cat)/K(m) for the D374Q mutant enzyme defines the way Asp-374, unique to L. mesenteroides G6PD, modulates stabilization of the enzyme during catalysis by its interaction with Lys-182. The greatly reduced k(cat) values of enzymes P149V and P149G indicate the importance of the cis conformation of Pro-149 in accessing the correct transition state.

Published

2000

19. An Examination of the Role of Asp-177 in the His-Asp Catalytic Dyad of Leuconostoc mesenteroides Glucose 6-Phosphate Dehydrogenase: X-ray Structure and pH Dependence of Kinetic Parameters of the D177N Mutant Enzyme

Author

Michael S. Cosgrove, M.J. Adams, L. Vandeputte-Rutten, S. Gover, H.R. Levy, and C.E. Naylor

Subjects

Models, Molecular, Movement, Glucose-6-Phosphate, Glutamic Acid, Dehydrogenase, Glucosephosphate Dehydrogenase, Crystallography, X-Ray, Biochemistry, chemistry.chemical_compound, Oxidoreductase, Catalytic Domain, Glucose-6-phosphate dehydrogenase, Histidine, Ternary complex, chemistry.chemical_classification, Aspartic Acid, biology, Substrate (chemistry), Hydrogen-Ion Concentration, biology.organism_classification, Enzyme assay, Kinetics, Models, Chemical, Glucose 6-phosphate, chemistry, Leuconostoc mesenteroides, Mutation, Mutagenesis, Site-Directed, biology.protein, Leuconostoc

Abstract

The role of Asp-177 in the His-Asp catalytic dyad of glucose 6-phosphate dehydrogenase from Leuconostoc mesenteroides has been investigated by a structural and functional characterization of the D177N mutant enzyme. Its three-dimensional structure has been determined by X-ray cryocrystallography in the presence of NAD(+) and in the presence of glucose 6-phosphate plus NADPH. The structure of a glucose 6-phosphate complex of a mutant (Q365C) with normal enzyme activity has also been determined and substrate binding compared. To understand the effect of Asp-177 on the ionization properties of the catalytic base His-240, the pH dependence of kinetic parameters has been determined for the D177N mutant and compared to that of the wild-type enzyme. The structures give details of glucose 6-phosphate binding and show that replacement of the Asp-177 of the catalytic dyad with asparagine does not affect the overall structure of glucose 6-phosphate dehydrogenase. Additionally, the evidence suggests that the productive tautomer of His-240 in the D177N mutant enzyme is stabilized by a hydrogen bond with Asn-177; hence, the mutation does not affect tautomer stabilization. We conclude, therefore, that the absence of a negatively charged aspartate at 177 accounts for the decrease in catalytic activity at pH 7.8. Structural analysis suggests that the pH dependence of the kinetic parameters of D177N glucose 6-phosphate dehydrogenase results from an ionized water molecule replacing the missing negative charge of the mutated Asp-177 at high pH. Glucose 6-phosphate binding orders and orients His-178 in the D177N-glucose 6-phosphate-NADPH ternary complex and appears to be necessary to form this water-binding site.

Published

2000

20. On the Mechanism of the Reaction Catalyzed by Glucose 6-Phosphate Dehydrogenase

Author

Michael S. Cosgrove, H.R. Levy, M.J. Adams, S Paludan, and C.E. Naylor

Subjects

Models, Molecular, chemistry.chemical_classification, Aspartic Acid, biology, Protein Conformation, Molecular Sequence Data, Dehydrogenase, Glucosephosphate Dehydrogenase, biology.organism_classification, Biochemistry, Catalysis, Amino acid, chemistry.chemical_compound, Enzyme, chemistry, Leuconostoc mesenteroides, Oxidoreductase, Mutagenesis, Site-Directed, Glucose-6-phosphate dehydrogenase, Histidine, Asparagine, Branched-chain alpha-keto acid dehydrogenase complex, Leuconostoc

Abstract

The catalytic mechanism of glucose 6-phosphate dehydrogenase from Leuconostoc mesenteroides was investigated by replacing three amino acids, His-240, Asp-177, and His 178, with asparagine, using site-directed mutagenesis. Each of the mutant enzymes was purified to homogeneity and characterized by substrate binding studies and steady-state kinetic analyses. The three-dimensional structure of the H240N glucose 6-phosphate dehydrogenase was determined at 2.5 A resolution. The results support a mechanism in which His-240 acts as the general base that abstracts the proton from the C1-hydroxyl group of glucose 6-phosphate, and the carboxylate group of Asp-177 stabilizes the positive charge that forms on His-240 in the transition state. The results also confirm the postulated role of His-178 in binding the phosphate moiety of glucose 6-phosphate.

Published

1998

21. Kabuki syndrome missense mutations disrupt the formation and histone methyltransferase activity of the MLL2 core complex

Author

Jay Shendure, Valarie E. Vought, Michael Hu, Sarah B. Ng, Michael J. Bamshad, Stephen A. Shinsky, and Michael S. Cosgrove

Subjects

Genetics, Histone methyltransferase activity, Chemistry, Core (graph theory), medicine, Missense mutation, medicine.disease, Molecular Biology, Biochemistry, Kabuki syndrome, Biotechnology

Published

2013

22. Allosteric activation of the phosphoinositide phosphatase Sac1 by anionic phospholipids

Author

FoSheng Hsu, Christopher J. Stefan, Xiaochun Wu, Shurong Zhong, Anamika Patel, Michael S. Cosgrove, and Yuxin Mao

Subjects

Saccharomyces cerevisiae Proteins, Protein Conformation, Phosphatase, Allosteric regulation, Biochemistry, Article, Phosphoinositide Phosphatases, 03 medical and health sciences, chemistry.chemical_compound, Protein structure, Allosteric Regulation, Catalytic Domain, Phosphatidylinositol, Phospholipids, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, 030302 biochemistry & molecular biology, Phosphatidylserine, Phosphoric Monoester Hydrolases, Kinetics, Enzyme, chemistry, Allosteric enzyme, biology.protein

Abstract

Sac family phosphoinositide phosphatases comprise an evolutionarily conserved family of enzymes in eukaryotes. Our recently determined crystal structure of the Sac phosphatase domain of yeast Sac1, the founding member of the Sac family proteins, revealed a unique conformation of the catalytic P-loop and a large positively charged groove at the catalytic site. We now report a unique mechanism for the regulation of its phosphatase activity. Sac1 is an allosteric enzyme that can be activated by its product phosphatidylinositol or anionic phospholipid phosphatidylserine. The activation of Sac1 may involve conformational changes of the catalytic P-loop induced by direct binding with the regulatory anionic phospholipids in the large cationic catalytic groove. These findings highlight the fact that lipid composition of the substrate membrane plays an important role in the control of Sac1 function.

Published

2012

23. Mgm101 Is a Rad52-related Protein Required for Mitochondrial DNA Recombination*

Author

Stephan Wilkens, Elizabeth Hoffman, Jonathan D. Nardozzi, MacMillan Mbantenkhu, Xin Jie Chen, Xiaowen Wang, Michael S. Cosgrove, and Anamika Patel

Subjects

Mitochondrial DNA, Saccharomyces cerevisiae Proteins, RAD52, DNA, Single-Stranded, Saccharomyces cerevisiae, Mitochondrion, Biology, DNA and Chromosomes, Biochemistry, DNA, Mitochondrial, Mitochondrial Proteins, chemistry.chemical_compound, Gene Expression Regulation, Fungal, Escherichia coli, Molecular Biology, Replication protein A, Alleles, Mitochondrial nucleoid, Recombination, Genetic, Models, Genetic, Cell Biology, Molecular biology, Mitochondria, Rad52 DNA Repair and Recombination Protein, DNA-Binding Proteins, Cross-Linking Reagents, chemistry, Mutation, Biophysics, Homologous recombination, Recombination, DNA, Gene Deletion, Plasmids

Abstract

Homologous recombination is a conserved molecular process that has primarily evolved for the repair of double-stranded DNA breaks and stalled replication forks. However, the recombination machinery in mitochondria is poorly understood. Here, we show that the yeast mitochondrial nucleoid protein, Mgm101, is related to the Rad52-type recombination proteins that are widespread in organisms from bacteriophage to humans. Mgm101 is required for repeat-mediated recombination and suppression of mtDNA fragmentation in vivo. It preferentially binds to single-stranded DNA and catalyzes the annealing of ssDNA precomplexed with the mitochondrial ssDNA-binding protein, Rim1. Transmission electron microscopy showed that Mgm101 forms large oligomeric rings of ∼14-fold symmetry and highly compressed helical filaments. Specific mutations affecting ring formation reduce protein stability in vitro. The data suggest that the ring structure may provide a scaffold for stabilization of Mgm101 by preventing the aggregation of the otherwise unstable monomeric conformation. Upon binding to ssDNA, Mgm101 is remobilized from the rings to form distinct nucleoprotein filaments. These studies reveal a recombination protein of likely bacteriophage origin in mitochondria and support the notion that recombination is indispensable for mtDNA integrity.

Published

2011

24. Structural basis for the recognition of Set1 family Win motifs by WDR5

Author

Michael S. Cosgrove, Anamika Patel, Valarie E. Vought, and Venkatasubramanian Dharmarajan

Subjects

Basis (linear algebra), Computer science, Genetics, Computational biology, Molecular Biology, Biochemistry, Biotechnology

Published

2010

25. A conserved arginine-containing motif crucial for the assembly and enzymatic activity of the mixed lineage leukemia protein-1 core complex

Author

Anamika Patel, Valarie E. Vought, Venkatasubramanian Dharmarajan, and Michael S. Cosgrove

Subjects

Histone H3 Lysine 4, Methyltransferase, DNA, Complementary, Arginine, Amino Acid Motifs, Molecular Sequence Data, Biology, Biochemistry, Histone H3, WDR5, Humans, Amino Acid Sequence, Molecular Biology, Sequence Homology, Amino Acid, Lysine, Intracellular Signaling Peptides and Proteins, Nuclear Proteins, Cell Biology, Histone-Lysine N-Methyltransferase, In vitro, Protein Structure, Tertiary, DNA-Binding Proteins, Myeloid-Lymphoid Leukemia Protein, Arginine binding, Spleen, Protein Binding, Transcription Factors

Abstract

The mixed lineage leukemia protein-1 (MLL1) belongs to the SET1 family of histone H3 lysine 4 methyltransferases. Recent studies indicate that the catalytic subunits of SET1 family members are regulated by interaction with a conserved core group of proteins that include the WD repeat protein-5 (WDR5), retinoblastoma-binding protein-5 (RbBP5), and the absent small homeotic-2-like protein (Ash2L). It has been suggested that WDR5 functions to bridge the interactions between the catalytic and regulatory subunits of SET1 family complexes. However, the molecular details of these interactions are unknown. To gain insight into the interactions among these proteins, we have determined the biophysical basis for the interaction between the human WDR5 and MLL1. Our studies reveal that WDR5 preferentially recognizes a previously unidentified and conserved arginine-containing motif, called the "Win" or WDR5 interaction motif, which is located in the N-SET region of MLL1 and other SET1 family members. Surprisingly, our structural and functional studies show that WDR5 recognizes arginine 3765 of the MLL1 Win motif using the same arginine binding pocket on WDR5 that was previously shown to bind histone H3. We demonstrate that WDR5's recognition of arginine 3765 of MLL1 is essential for the assembly and enzymatic activity of the MLL1 core complex in vitro.

Published

2008

26. The MLL SET domain is a histone H3 lysine 4 mono‐methyltransferase that interacts with WDR5 in the pre‐SET ATA2 domain

Author

Venkat Dharmarajan, Michael S. Cosgrove, and Anamika Patel

Subjects

Physics, Set (abstract data type), Histone H3 Lysine 4, Methyltransferase, SET domain, Genetics, WDR5, Computational biology, Molecular Biology, Biochemistry, Biotechnology, Domain (software engineering)

Published

2008

27. Histone proteomics and the epigenetic regulation of nucleosome mobility

Author

Michael S. Cosgrove

Subjects

Genetics, Proteomics, Histone-modifying enzymes, biology, Computational biology, Biochemistry, Chromatin remodeling, SWI/SNF, Chromatin, Epigenesis, Genetic, Nucleosomes, Histones, Histone, biology.protein, Nucleosome, Histone code, Molecular Biology, Protein Processing, Post-Translational, Epigenomics

Abstract

Chromatin structure plays a vital role in the transmission of heritable gene expression patterns. The recent application of mass spectrometry to histone biology provides several striking insights into chromatin regulation. The continuing identification of new histone post-translational modifications is revolutionizing the ways in which we think about how access to genomic DNA is controlled. While post-translational modifications of the flexible histone tails continue to be an active area of investigation, the recent discovery of multiple modifications in the structured globular domains of histones provides new insights into how the nucleosome works. Recent experiments underscore the importance of a subgroup of these modifications: those that regulate histone-DNA interactions on the lateral surface of the nucleosome. This information highlights an emerging new paradigm in chromatin control, that of the epigenetic regulation of nucleosome mobility.

Published

2007

28. Insights into the Role of Histone H3 and Histone H4 Core Modifiable Residues in Saccharomyces cerevisiae

Author

Edel M. Hyland, Henrik Molina, Robert J. Cottee, Jef D. Boeke, Akhilesh Pandey, Michael S. Cosgrove, and Dongxia Wang

Subjects

Models, Molecular, DNA Repair, Transcription, Genetic, Saccharomyces cerevisiae, Molecular Sequence Data, Chromosome Structure and Dynamics, Biology, Mass Spectrometry, Evolution, Molecular, Histones, Histone H4, Histone H3, Histone H1, Heterochromatin, Histone H2A, Histone methylation, Histone code, Amino Acid Sequence, Gene Silencing, Histone octamer, Molecular Biology, Alleles, Genetics, Sequence Homology, Amino Acid, Errata, Reverse Transcriptase Polymerase Chain Reaction, DNA, Cell Biology, biology.organism_classification, Cell biology, Nucleosomes, Blotting, Southern, Phenotype, Biochemistry, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Histone methyltransferase, Mutation, Mutagenesis, Site-Directed, Protein Processing, Post-Translational, DNA Damage, Plasmids

Abstract

The biological significance of recently described modifiable residues in the globular core of the bovine nucleosome remains elusive. We have mapped these modification sites onto the Saccharomyces cerevisiae histones and used a genetic approach to probe their potential roles both in heterochromatic regions of the genome and in the DNA repair response. By mutating these residues to mimic their modified and unmodified states, we have generated a total of 39 alleles affecting 14 residues in histones H3 and H4. Remarkably, despite the apparent evolutionary pressure to conserve these near-invariant histone amino acid sequences, the vast majority of mutant alleles are viable. However, a subset of these variant proteins elicit an effect on transcriptional silencing both at the ribosomal DNA locus and at telomeres, suggesting that posttranslational modification(s) at these sites regulates formation and/or maintenance of heterochromatin. Furthermore, we provide direct mass spectrometry evidence for the existence of histone H3 K56 acetylation in yeast. We also show that substitutions at histone H4 K91, K59, S47, and R92 and histone H3 K56 and K115 lead to hypersensitivity to DNA-damaging agents, linking the significance of the chemical identity of these modifiable residues to DNA metabolism. Finally, we allude to the possible molecular mechanisms underlying the effects of these modifications.

Published

2005

29. A novel non-SET domain multi-subunit methyltransferase required for sequential nucleosomal histone H3 methylation by the mixed lineage leukemia protein-1 (MLL1) core complex

Author

Venkatasubramanian Dharmarajan, Michael S. Cosgrove, Valarie E. Vought, and Anamika Patel

Subjects

Histone H3 Lysine 4, Histone lysine methylation, DNA and Chromosomes, Biology, Methylation, Biochemistry, Catalysis, Substrate Specificity, Histones, Histone H3, Histone H1, Histone methylation, Histone H2A, Humans, Histone code, Molecular Biology, Genetics, Histone-Lysine N-Methyltransferase, Cell Biology, Cell biology, Kinetics, Zinc, Multiprotein Complexes, Histone methyltransferase, Additions and Corrections, Myeloid-Lymphoid Leukemia Protein

Abstract

Gene expression within the context of eukaryotic chromatin is regulated by enzymes that catalyze histone lysine methylation. Histone lysine methyltransferases that have been identified to date possess the evolutionarily conserved SET or Dot1-like domains. We previously reported the identification of a new multi-subunit histone H3 lysine 4 methyltransferase lacking homology to the SET or Dot1 family of histone lysine methyltransferases. This enzymatic activity requires a complex that includes WRAD (WDR5, RbBP5, Ash2L, and DPY-30), a complex that is part of the MLL1 (mixed lineage leukemia protein-1) core complex but that also exists independently of MLL1 in the cell. Here, we report that the minimal complex required for WRAD enzymatic activity includes WDR5, RbBP5, and Ash2L and that DPY-30, although not required for enzymatic activity, increases the histone substrate specificity of the WRAD complex. We also show that WRAD requires zinc for catalytic activity, displays Michaelis-Menten kinetics, and is inhibited by S-adenosyl-homocysteine. In addition, we demonstrate that WRAD preferentially methylates lysine 4 of histone H3 within the context of the H3/H4 tetramer but does not methylate nucleosomal histone H3 on its own. In contrast, we find that MLL1 and WRAD are required for nucleosomal histone H3 methylation, and we provide evidence suggesting that each plays distinct structural and catalytic roles in the recognition and methylation of a nucleosome substrate. Our results indicate that WRAD is a new H3K4 methyltransferase with functions that include regulating the substrate and product specificities of the MLL1 core complex.

Published

2011