Your search keyword '"Rachel Senturia"' showing total 11 results

1. The DGCR8 RNA-Binding Heme Domain Recognizes Primary MicroRNAs by Clamping the Hairpin

Author

Jen Quick-Cleveland, Jose P. Jacob, Sara H. Weitz, Grant Shoffner, Rachel Senturia, and Feng Guo

Subjects

Biology (General), QH301-705.5

Abstract

Canonical primary microRNA transcripts (pri-miRNAs) are characterized by a ∼30 bp hairpin flanked by single-stranded regions. These pri-miRNAs are recognized and cleaved by the Microprocessor complex consisting of the Drosha nuclease and its obligate RNA-binding partner DGCR8. It is not well understood how the Microprocessor specifically recognizes pri-miRNA substrates. Here, we show that in addition to the well-known double-stranded RNA-binding domains, DGCR8 uses a dimeric heme-binding domain to directly contact pri-miRNAs. This RNA-binding heme domain (Rhed) directs two DGCR8 dimers to bind each pri-miRNA hairpin. The two Rhed-binding sites are located at both ends of the hairpin. The Rhed and its RNA-binding surface are important for pri-miRNA processing activity. Additionally, the heme cofactor is required for formation of processing-competent DGCR8-pri-miRNA complexes. Our study reveals a unique protein-RNA interaction central to pri-miRNA recognition. We propose a unifying model in which two DGCR8 dimers clamp a pri-miRNA hairpin using their Rheds.

Published

2014

2. Dimerization and heme binding are conserved in amphibian and starfish homologues of the microRNA processing protein DGCR8.

Author

Rachel Senturia, Arthur Laganowsky, Ian Barr, Brooke D Scheidemantle, and Feng Guo

Subjects

Medicine, Science

Abstract

Human DiGeorge Critical Region 8 (DGCR8) is an essential microRNA (miRNA) processing factor that is activated via direct interaction with Fe(III) heme. In order for DGCR8 to bind heme, it must dimerize using a dimerization domain embedded within its heme-binding domain (HBD). We previously reported a crystal structure of the dimerization domain from human DGCR8, which demonstrated how dimerization results in the formation of a surface important for association with heme. Here, in an attempt to crystallize the HBD, we search for DGCR8 homologues and show that DGCR8 from Patiria miniata (bat star) also binds heme. The extinction coefficients (ε) of DGCR8-heme complexes are determined; these values are useful for biochemical analyses and allow us to estimate the heme occupancy of DGCR8 proteins. Additionally, we present the crystal structure of the Xenopus laevis dimerization domain. The structure is very similar to that of human DGCR8. Our results indicate that dimerization and heme binding are evolutionarily conserved properties of DGCR8 homologues not only in vertebrates, but also in at least some invertebrates.

Published

2012

3. Fe(III) heme sets an activation threshold for processing distinct groups of pri-miRNAs in mammalian cells

Author

Jen Quick-Cleveland, Sara H. Weitz, Shimon Weiss, Jose Jacob, Kikuye Koyano, Xinshu Xiao, Feng Guo, Ian G. Barr, and Rachel Senturia

Subjects

0303 health sciences, biology, Chemistry, DGCR8, 030302 biochemistry & molecular biology, Mutant, In vitro, Cofactor, Microprocessor complex, 03 medical and health sciences, chemistry.chemical_compound, Biochemistry, Cell culture, microRNA, biology.protein, Heme, 030304 developmental biology

Abstract

The essential biological cofactor heme is synthesized in cells in the Fe(II) form. Oxidized Fe(III) heme is specifically required for processing primary transcripts of microRNAs (pri-miRNAs) by the RNA-binding protein DGCR8, a core component of the Microprocessor complex. It is unknown how readily available Fe(III) heme is in the largely reducing environment in human cells and how changes in cellular Fe(III) heme availability alter microRNA (miRNA) expression. Here we address the first question by characterizing DGCR8 mutants with various degrees of deficiency in heme-binding. We observed a strikingly simple correlation between Fe(III) heme affinityin vitroand the Microprocessor activity in HeLa cells, with the heme affinity threshold for activation estimated to be between 0.6-5 pM under typical cell culture conditions. The threshold is strongly influenced by cellular heme synthesis and uptake. We suggest that the threshold reflects a labile Fe(III) heme pool in cells. Based on our understanding of DGCR8 mutants, we reanalyzed recently reported miRNA sequencing data and conclude that heme is generally required for processing canonical pri-miRNAs, that heme modulates the specificity of Microprocessor, and that cellular heme level and differential DGCR8 heme occupancy alter the expression of distinct groups of miRNAs in a hierarchical fashion. Overall, our study provides the first glimpse of a labile Fe(III) heme pool important for a fundamental physiological function and reveal principles governing how Fe(III) heme modulates miRNA maturation at a genomic scale. We also discuss potential states and biological significance of the labile Fe(III) heme pool.

Published

2020

4. Caspases cleave and inhibit the microRNA processing protein DiGeorge Critical Region 8

Author

Michael Faller, Feng Guo, Rachel Senturia, Matthew Ulgherait, Ming Gong, and Yanqiu Chen

Subjects

Cleavage factor, biology, DGCR8, Cleavage (embryo), Biochemistry, chemistry.chemical_compound, chemistry, Apoptosis, biology.protein, Molecular Biology, Heme, Drosha, Caspase, Dicer

Abstract

DGCR8 (DiGeorge Critical Region 8) is an essential microRNA (miRNA) processing protein that recognizes primary transcripts of miRNAs (pri-miRNAs) and triggers their cleavage by the Drosha nuclease. We previously found that Fe(III) heme binds and activates DGCR8. Here we report that in HeLa cells, DGCR8 undergoes two proteolytic events that produce two C-terminal fragments called DGCR8C1 and DGCR8C2, respectively. DGCR8C2 accumulates during apoptosis and is generated through cleavage by a caspase. The caspase cleavage site is located in the central loop of the heme-binding domain. Cleavage of DGCR8 by caspase-3 in vitro results in loss of the otherwise tightly bound Fe(III) heme cofactor, dissociation of the N- and C-terminal proteolytic fragments, and inhibition of the pri-miRNA processing activity. These results reveal an intrinsic mechanism in the DGCR8 protein that seems to have evolved for regulating miRNA processing via association with Fe(III) heme and proteolytic cleavage by caspases. Decreased expression of miRNAs has been observed in apoptotic cells, and this change was attributed to caspase-mediated cleavage of a down-stream miRNA processing nuclease Dicer. We suggest that both the Drosha and Dicer cleavage steps of the miRNA maturation pathway may be inhibited in apoptosis and other biological processes where caspases are activated.

Published

2012

5. Ferric, not ferrous, heme activates RNA-binding protein DGCR8 for primary microRNA processing

Author

Yanqiu Chen, Rachel Senturia, Ian G. Barr, Aaron T. Smith, Judith N. Burstyn, and Feng Guo

Subjects

inorganic chemicals, Heme, Plasma protein binding, Ligands, Ferric Compounds, Ferrous, chemistry.chemical_compound, Protein structure, medicine, Animals, Humans, Ferrous Compounds, RNA Processing, Post-Transcriptional, Binding selectivity, Multidisciplinary, Protein Stability, Ligand, Chemistry, Proteins, RNA-Binding Proteins, Biological Sciences, Protein Structure, Tertiary, MicroRNAs, Biochemistry, Ferric, Mutant Proteins, Apoproteins, Oxidation-Reduction, Protein Binding, medicine.drug

Abstract

The RNA-binding protein DiGeorge Critical Region 8 (DGCR8) and its partner nuclease Drosha are essential for processing of microRNA (miRNA) primary transcripts (pri-miRNAs) in animals. Previous work showed that DGCR8 forms a highly stable and active complex with ferric [Fe(III)] heme using two endogenous cysteines as axial ligands. Here we report that reduction of the heme iron to the ferrous [Fe(II)] state in DGCR8 abolishes the pri-miRNA processing activity. The reduction causes a dramatic increase in the rate of heme dissociation from DGCR8, rendering the complex labile. Electronic absorption, magnetic circular dichroism, and resonance Raman spectroscopies indicate that reduction of the heme iron is accompanied by loss of the cysteines as axial ligands. ApoDGCR8 dimers, generated through reduction and removal of the heme, show low levels of activity in pri-miRNA processing in vitro. Importantly, ferric, but not ferrous, heme restores the activity of apoDGCR8 to the level of the native ferric complex. This study demonstrates binding specificity of DGCR8 for ferric heme, provides direct biochemical evidence for ferric heme serving as an activator for miRNA maturation, and suggests that an intracellular environment increasing the availability of ferric heme may enhance the efficiency of pri-miRNA processing.

Published

2012

6. DiGeorge Critical Region 8 (DGCR8) Is a Double-cysteine-ligated Heme Protein

Author

Rachel Senturia, Brooke D. Scheidemantle, Yanqiu Chen, Ian G. Barr, Aaron T. Smith, Feng Guo, and Judith N. Burstyn

Subjects

Circular dichroism, Porphyrins, Hemeprotein, Proline, Stereochemistry, Heme, Ligand Binding Protein, Biochemistry, Xenopus laevis, chemistry.chemical_compound, Metalloprotein, Animals, Humans, Cysteine, Horses, Muscle, Skeletal, Selenomethionine, Molecular Biology, chemistry.chemical_classification, biology, Ligand, Circular Dichroism, Electron Spin Resonance Spectroscopy, Proteins, RNA-Binding Proteins, Cytochrome P450, Cell Biology, MicroRNAs, chemistry, Spectrophotometry, Mutation, Protein Structure and Folding, Mutagenesis, Site-Directed, biology.protein, Oxidation-Reduction

Abstract

All known heme-thiolate proteins ligate the heme iron using one cysteine side chain. We previously found that DiGeorge Critical Region 8 (DGCR8), an essential microRNA processing factor, associates with heme of unknown redox state when overexpressed in Escherichia coli. On the basis of the similarity of the 450-nm Soret absorption peak of the DGCR8-heme complex to that of cytochrome P450 containing ferrous heme with CO bound, we identified cysteine 352 as a probable axial ligand in DGCR8. Here we further characterize the DGCR8-heme interaction using biochemical and spectroscopic methods. The DGCR8-heme complex is highly stable, with a half-life exceeding 4 days. Mutation of the conserved proline 351 to an alanine increases the rate of heme dissociation and allows the DGCR8-heme complex to be reconstituted biochemically. Surprisingly, DGCR8 binds ferric heme without CO to generate a hyperporphyrin spectrum. The electronic absorption, magnetic circular dichroism, and electron paramagnetic resonance spectra of the DGCR8-heme complex suggest a ferric heme bearing two cysteine ligands. This model was further confirmed using selenomethionine-substituted DGCR8 and mercury titration. DGCR8 is the first example of a heme-binding protein with two endogenous cysteine side chains serving as axial ligands. We further show that native DGCR8 binds heme when expressed in eukaryotic cells. This study provides a chemical basis for understanding the function of the DGCR8-heme interaction in microRNA maturation.

Published

2011

7. Structure of the dimerization domain of DiGeorge Critical Region 8

Author

Michael R. Sawaya, Feng Guo, Duilio Cascio, Michael Faller, Joseph A. Loo, Rachel Senturia, Sheng Yin, Daniel Hwang, and Robert T. Clubb

Subjects

biology, Heme binding, DGCR8, RNA-binding protein, Biochemistry, Molecular biology, Cell biology, Microprocessor complex, chemistry.chemical_compound, Protein structure, chemistry, biology.protein, Molecular Biology, Heme, Peptide sequence, Drosha

Abstract

Maturation of microRNAs (miRNAs, approximately 22nt) from long primary transcripts [primary miRNAs (pri-miRNAs)] is regulated during development and is altered in diseases such as cancer. The first processing step is a cleavage mediated by the Microprocessor complex containing the Drosha nuclease and the RNA-binding protein DiGeorge critical region 8 (DGCR8). We previously reported that dimeric DGCR8 binds heme and that the heme-bound DGCR8 is more active than the heme-free form. Here, we identified a conserved dimerization domain in DGCR8. Our crystal structure of this domain (residues 298-352) at 1.7 A resolution demonstrates a previously unknown use of a WW motif as a platform for extensive dimerization interactions. The dimerization domain of DGCR8 is embedded in an independently folded heme-binding domain and directly contributes to association with heme. Heme-binding-deficient DGCR8 mutants have reduced pri-miRNA processing activity in vitro. Our study provides structural and biochemical bases for understanding how dimerization and heme binding of DGCR8 may contribute to regulation of miRNA biogenesis.

Published

2010

8. A crystal structure of a dimer of the antibiotic ramoplanin illustrates membrane positioning and a potential Lipid II docking interface

Author

James B. Hamburger, Dewey G. McCafferty, Rachel Senturia, Amanda J. Hoertz, Patrick J. Loll, and Amy S. Lee

Subjects

Molecular Conformation, Microbial Sensitivity Tests, Plasma protein binding, Biology, Crystallography, X-Ray, Gram-Positive Bacteria, Ligands, Bacterial cell structure, Cell membrane, Depsipeptides, Drug Resistance, Bacterial, Amphiphile, medicine, Multidisciplinary, Lipid II, Cell Membrane, Ramoplanin, Biological Sciences, Lipids, Anti-Bacterial Agents, Membrane, medicine.anatomical_structure, Models, Chemical, Biochemistry, Docking (molecular), Peptides, Dimerization, Protein Binding, medicine.drug

Abstract

The glycodepsipeptide antibiotic ramoplanin A2 is in late stage clinical development for the treatment of infections from Gram-positive pathogens, especially those that are resistant to first line antibiotics such as vancomycin. Ramoplanin A2 achieves its antibacterial effects by interfering with production of the bacterial cell wall; it indirectly inhibits the transglycosylases responsible for peptidoglycan biosynthesis by sequestering their Lipid II substrate. Lipid II recognition and sequestration occur at the interface between the extracellular environment and the bacterial membrane. Therefore, we determined the structure of ramoplanin A2 in an amphipathic environment, using detergents as membrane mimetics, to provide the most physiologically relevant structural context for mechanistic and pharmacological studies. We report here the X-ray crystal structure of ramoplanin A2 at a resolution of 1.4 Å. This structure reveals that ramoplanin A2 forms an intimate and highly amphipathic dimer and illustrates the potential means by which it interacts with bacterial target membranes. The structure also suggests a mechanism by which ramoplanin A2 recognizes its Lipid II ligand.

Published

2009

9. The DGCR8 RNA-binding heme domain recognizes primary microRNAs by clamping the hairpin

Author

Feng Guo, Grant M. Shoffner, Rachel Senturia, Jose Jacob, Jen Quick-Cleveland, and Sara H. Weitz

Subjects

Protein Structure, DGCR8, Protein Conformation, 1.1 Normal biological development and functioning, Medical Physiology, RNA-binding protein, Heme, Biology, General Biochemistry, Genetics and Molecular Biology, Article, Microprocessor complex, chemistry.chemical_compound, Protein structure, Underpinning research, Genetics, Humans, lcsh:QH301-705.5, Drosha, Nuclease, Binding Sites, RNA, RNA-Binding Proteins, Protein Structure, Tertiary, MicroRNAs, lcsh:Biology (General), chemistry, Biochemistry, Biophysics, biology.protein, Nucleic Acid Conformation, Biochemistry and Cell Biology, Tertiary, Protein Binding, Biotechnology

Abstract

Canonical primary microRNA transcripts (pri-miRNAs) are characterized by a ~30bp hairpin flanked by single-stranded regions. These pri-miRNAs are recognized and cleaved by the Microprocessor complex consisting of the Drosha nuclease and its obligate RNA-binding partner DGCR8. It is not well understood how the Microprocessor specifically recognizes pri-miRNA substrates. Here, we show that in addition to the well-known double-stranded RNA-binding domains, DGCR8 uses a dimeric heme-binding domain to directly contact pri-miRNAs. This RNA-binding heme domain (Rhed) directs two DGCR8 dimers to bind each pri-miRNA hairpin. The two Rhed-binding sites are located at both ends of the hairpin. The Rhed and its RNA-binding surface are important for pri-miRNA processing activity. Additionally, the heme cofactor is required for formation of processing-competent DGCR8-pri-miRNA complexes. Our study reveals a unique protein-RNA interaction central to pri-miRNA recognition. We propose a unifying model in which two DGCR8 dimers clamp a pri-miRNA hairpin using their Rheds. © 2014 The Authors.

Published

2014

10. DGCR8 recognizes primary transcripts of microRNAs through highly cooperative binding and formation of higher-order structures

Author

Rachel Senturia, Z. Hong Zhou, Feng Guo, Daniel B. Toso, Yanqiu Chen, Ivo Atanasov, Michael Faller, and Michio Matsunaga

Subjects

Ribonuclease III, biology, DGCR8, RNA, Cooperative binding, Cooperativity, Trimer, Cleavage (embryo), Molecular biology, Article, Protein Structure, Tertiary, DEAD-box RNA Helicases, MicroRNAs, Protein structure, Biophysics, biology.protein, DiGeorge Syndrome, Animals, Molecular Biology, Drosha, RNA, Double-Stranded

Abstract

DiGeorge critical region 8 (DGCR8) is essential for maturation of microRNAs (miRNAs) in animals. In the cleavage of primary transcripts of miRNAs (pri-miRNAs) by the Drosha nuclease, the DGCR8 protein directly binds and recognizes pri-miRNAs through a mechanism currently controversial. Our previous data suggest that DGCR8 trimerizes upon cooperative binding to pri-mir-30a. However, a separate study proposed a model in which a DGCR8 molecule contacts one or two pri-miRNA molecules using its two double-stranded RNA binding domains. Here, we extensively characterized the interaction between DGCR8 and pri-miRNAs using biochemical and structural methods. First, a strong correlation was observed between the association of DGCR8 with pri-mir-30a and the rate of pri-miRNA processing in vitro. Second, we show that the high binding cooperativity allows DGCR8 to distinguish pri-miRNAs from a nonspecific competitor with subtle differences in dissociation constants. The highly cooperative binding of DGCR8 to a pri-miRNA is mediated by the formation of higher-order structures, most likely a trimer of DGCR8 dimers, on the pri-miRNA. These properties are not limited to its interaction with pri-mir-30a. Furthermore, the amphipathic C-terminal helix of DGCR8 is important both for trimerization of DGCR8 on pri-miRNAs and for the cleavage of pri-miRNAs by Drosha. Finally, our three-dimensional model from electron tomography analysis of the negatively stained DGCR8–pri-mir-30a complex directly supports the trimerization model. Our study provides a molecular basis for recognition of pri-miRNAs by DGCR8. We further propose that the higher-order structures of the DGCR8–pri-miRNA complexes trigger the cleavage of pri-miRNAs by Drosha.

Published

2010

11. Structure of the dimerization domain of DiGeorge critical region 8

Author

Rachel, Senturia, Michael, Faller, Sheng, Yin, Joseph A, Loo, Duilio, Cascio, Michael R, Sawaya, Daniel, Hwang, Robert T, Clubb, and Feng, Guo

Subjects

Models, Molecular, Spectrometry, Mass, Electrospray Ionization, Molecular Sequence Data, Humans, Proteins, RNA-Binding Proteins, Amino Acid Sequence, Protein Multimerization, Crystallography, X-Ray, Protein Structure, Secondary, Article, Protein Structure, Tertiary

Abstract

Maturation of microRNAs (miRNAs, approximately 22nt) from long primary transcripts [primary miRNAs (pri-miRNAs)] is regulated during development and is altered in diseases such as cancer. The first processing step is a cleavage mediated by the Microprocessor complex containing the Drosha nuclease and the RNA-binding protein DiGeorge critical region 8 (DGCR8). We previously reported that dimeric DGCR8 binds heme and that the heme-bound DGCR8 is more active than the heme-free form. Here, we identified a conserved dimerization domain in DGCR8. Our crystal structure of this domain (residues 298-352) at 1.7 A resolution demonstrates a previously unknown use of a WW motif as a platform for extensive dimerization interactions. The dimerization domain of DGCR8 is embedded in an independently folded heme-binding domain and directly contributes to association with heme. Heme-binding-deficient DGCR8 mutants have reduced pri-miRNA processing activity in vitro. Our study provides structural and biochemical bases for understanding how dimerization and heme binding of DGCR8 may contribute to regulation of miRNA biogenesis.

Published

2010