Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:Q02556 (DNA-binding domain)
6,431 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Protein kinase C (PKC) delta is cleaved by caspase-3 to a kinase-active catalytic fragment (PKCdeltaCF) in the apoptotic response of cells to DNA damage. Expression of PKCdeltaCF contributes to the induction of apoptosis by mechanisms that are presently unknown. Here we demonstrate that PKCdeltaCF associates with p73beta, a structural and functional homologue of the p53 tumor suppressor. The results show that PKCdeltaCF phosphorylates the p73beta transactivation and DNA-binding domains. One PKCdeltaCF-phosphorylation site has been mapped to Ser-289 in the p73beta DNA-binding domain. PKCdeltaCF-mediated phosphorylation of p73beta is associated with accumulation of p73beta and induction of p73beta-mediated transactivation. By contrast, PKCdeltaCF-induced activation of p73beta is attenuated by mutating Ser-289 to Ala (S289A). The results also demonstrate that PKCdeltaCF stimulates p73beta-mediated apoptosis and that this response is attenuated with the p73beta(S289A) mutant. These findings demonstrate that cleavage of PKCdelta to PKCdeltaCF induces apoptosis by a mechanism in part dependent on PKCdeltaCF-mediated phosphorylation of the p73beta Ser-289 site.
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PMID:p73beta is regulated by protein kinase Cdelta catalytic fragment generated in the apoptotic response to DNA damage. 1209 19

Sex-specific gene expression in Drosophila melanogaster is regulated in part by the Doublesex (DSX) transcription factor. Male- and female-specific splicing isoforms share a novel DNA-binding domain, designated the DM motif. This domain is conserved among a newly recognized family of vertebrate transcription factors involved in developmental patterning and sex determination. The DM motif consists of an N-terminal zinc module and a disordered C-terminal tail, hypothesized to fold on specific DNA binding as a recognition alpha-helix. Truncation of the tail does not perturb the structure of the zinc module but impairs DNA binding and DNA-dependent dimerization. Chemical protein synthesis and alanine scanning mutagenesis are employed to test the contributions of 13 side chains to specific DNA binding. Selected arginine or lysine residues in the zinc module were substituted by norleucine, an isostere that maintains the aliphatic portion of the side chain but lacks a positive charge. Arginine or glutamine residues in the tail were substituted by alanine. Evidence is obtained that both the zinc module and C-terminal tail contribute to a bipartite DNA-binding surface. Conserved arginine and glutamine residues in the tail are required for high affinity DNA recognition, consistent with its proposed role as a nascent recognition alpha-helix.
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PMID:Sex-specific gene regulation. The Doublesex DM motif is a bipartite DNA-binding domain. 1219 17

Nuclear receptors are ligand-dependent transcription factors responsible for controlling differentiation, growth and development of higher eukaryotes. Three amino acids within the recognition alpha-helix of the DNA-binding domain of the nuclear receptors constitute the so-called "P-box" which determines response element specificity. In the ultraspiracle (Usp) protein, which together with EcR forms the heterodimeric ecdysone receptor, the P-box residues are E19, G20 and G23. Substitution of E19, the most characteristic amino acid for estrogen receptor-like P-boxes, with alanine showed that the mutation did not appreciably alter the affinity of the wild-type Usp DNA-binding domain (UspDBD(WT)) for a probe containing natural ecdysone response element (hsp27(wt)). Since in many cases E19 contacts a G/C base pair in position -4, which is absent in hsp27(wt), we analysed the interaction of UspDBD(WT), E19A and other P-box region mutants with the hsp27(wt) derivative which contains a G/C instead of an T/A base pair in position -4. UspDBD(WT) exhibited higher affinity for this element than for hsp27(wt). Moreover, a different interaction pattern of P-box region mutants was also observed. Thus we conclude that the E19 residue of UspDBD is not involved in any hsp27(wt) sequence-discerning contacts. However, substitution of the hsp27(wt) T/A base pair in position -4 with G/C generates target sequence with distinct functional characteristics and possibly with a new specificity. These results could serve as a basis for understanding the role of the presence of a T/A or G/C base-pair in the position -4 in the two types of ecdysone response elements found in nature.
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PMID:Functionality versus strength -- has functional selection taken place in the case of the ecdysteroid receptor response element?. 1242 44

Resistance to hormones is commonly due to mutations in genes encoding receptors. Resistance to thyroid hormone is due mostly to mutations of the beta-form of the human (h) thyroid hormone receptor (hTRbeta). We determined x-ray crystal structures of two hTRbeta ligand-binding domains (LBDs), Ala 317 Thr and Arg 316 His. Amino acids 316 and 317 form part of the hormone-binding pocket. The methyl of Ala 317, contacting iodine, sculpts the T3 hormone-binding pocket. Arg 316 is not in direct contact with T3 and has an unknown role in function. Remarkably, the Arg forms part of an unusual buried polar cluster in hTRbeta. Although the identity of the amino acids changes, the polar cluster appears in all nuclear receptors. In spite of the differing roles of 316 and 317, both resistance to thyroid hormone mutants display decreased T3 affinity and weakened transcriptional activation. The two mutants differ in that the Arg 316 His receptor does not form TR-TR homodimers on DNA. 3,5,3'-Triiodothyroacetic acid is bound to both receptors. Thr 317 repositions 3,5,3'-triiodothyroacetic acid distending the face of the receptor that binds coregulators. Arg 316 forms two hydrogen bonds with helix 1. Both are lost with mutation to His displacing helix 1 of the LBD and disordering the loop after helix 1. The stability of the helix 1, deriving in part from the buried polar cluster, is important for hormone binding and formation of TR dimers. The observation that the Arg 316 His mutation affects these functions implies a role for helix 1 in linking hormone binding to the DNA-binding domain-LBD configuration.
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PMID:Two resistance to thyroid hormone mutants with impaired hormone binding. 1255 82

Genes of the early growth response (EGR) family encode transcription factors with a highly conserved DNA binding zinc finger domain, which regulate a variety of genes, e.g. late myelin genes. Here, the cloning, genomic structure and expression of the bovine orthologue of the EGR4 gene are reported. The gene consists of two exons and encodes a 482 amino acid protein with a Cys2His2 zinc finger structure. The predicted protein shares between 80 and 87% identity to mouse, rat and human EGR4 proteins and all four species share almost complete identity in the DNA-binding domain. The bovine transcript is alternatively spliced by retaining intronic sequence, giving rise to two different mRNAs differing in three nucleotides and resulting in an extra alanine residue in the longer variant of the predicted protein. The gene was mapped by radiation hybrid (RH) mapping to markers on bovine chromosome 11. EGR4 transcripts were detected by reverse transcriptase polymerase chain reaction (RT-PCR) in the frontal cortex and cerebellum, and a low expression level was also detected in the liver. The EGR4 gene was evaluated as a candidate gene for bovine spinal dysmyelination (BSD). Sequencing of the gene from a homozygous affected animal and a heterozygous carrier revealed a single base mutation that leads to an amino acid substitution at residue 322 in EGR4. Genotype analysis of this polymorphism in a pedigree segregating for BSD, as well as in a panel of different cattle breeds, and sequence analysis of the entire coding region suggested that the EGR4 is not the gene responsible for BSD. Furthermore, 87 animals of different cattle breeds were screened for single-nucleotide polymorphisms (SNPs) resulting in the identification of two SNPs in EGR4.
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PMID:Cloning and characterization of the bovine EGR4 gene and evaluation as candidate gene for bovine spinal dysmyelination. 1264 95

The essential Saccharomyces cerevisiae protein Cdc13 binds the conserved single-stranded overhang at the end of telomeres and mediates access of protein complexes involved in both end-capping and telomerase activity. The single-stranded DNA-binding domain (ssDBD) of Cdc13 exhibits both high affinity (K(d) of 3 pM) and sequence specificity for the GT-rich sequences present at yeast telomeres. We have used the ssDBD of Cdc13 to understand the sequence-specific recognition of extended single-stranded DNA (ssDNA). The recent structure of the Cdc13 DNA-binding domain revealed that ssDNA is recognized by a large protein surface containing an oligonucleotide/oligosaccharide-binding fold (OB-fold) augmented by an extended 30-amino acid loop. Contacts to ssDNA occur via a contiguous surface of aromatic, hydrophobic, and basic residues. A complete alanine scan of the binding interface has been used to determine the contribution of each contacting side chain to binding affinity. Substitution of any aromatic or hydrophobic residue at the interface was deleterious to binding (20 to >700-fold decrease in binding affinity), while tolerance for replacement of basic residues was observed. The important aromatic and hydrophobic contacts are spread throughout the extended interface, indicating that the entire surface is both structurally and thermodynamically required for binding. While all of these contacts are important, several of the individual alanine substitutions that abolish binding cluster to one region of the protein surface. This region is vital for recognition of four bases at the 5' end of the DNA and constitutes a "hotspot" of binding affinity.
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PMID:Site-directed mutagenesis reveals the thermodynamic requirements for single-stranded DNA recognition by the telomere-binding protein Cdc13. 1266 66

The glucocorticoid receptor (GR) is a hormone dependent nuclear receptor that regulates gene transcription when bound to the glucocorticoid response element (GRE). The GRE acts as an allosteric effector, inducing a structural change in the GR DNA-binding domain (GR DBD) upon binding, thereby switching the GR to an active conformation. A similar conformational change can be induced by two single point mutations: Ser459Ala and Pro493Arg. Structural and dynamical aspects of the conformational switch have been investigated by molecular dynamics simulations. Our results indicate that these two mutants, which share a similar phenotype, exert their action at a structural level through different mechanisms. In the Arg(493) mutant, the D-loop and the second helix are stabilized in a conformation that preforms the protein-protein dimer interface. In the Ala(459) mutant, the structurally important hydrogen bond between Arg(496) and Ser(459) is missing, which leads to a core reorganization and a reorientation of the second helical region. Although remote, both in sequence and three dimensional structure, these two mutations induce structural changes that are ultimately reflected in similar regions of the GR DBD structure, namely the D-loop and the short second helical region. These correspond to hot area of the GR DBD that are important both for DNA-binding and for the proper formation of the protein-protein interface. The conformational rearrangements in these area are proposed to decrease unfavorable protein-DNA and protein-protein contacts and allow unspecific DNA-binding leading to the squelching phenotype of the mutants. The GR DBD can thus exist in two states, a transcriptionally active and an inactive state. Switching between these states can be accomplished either by GRE binding or by the described mutations.
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PMID:Molecular dynamics studies of a molecular switch in the glucocorticoid receptor. 1269 44

The chromokinesin Kid is important in chromosome alignment at the metaphase plate. Here, we report that Kid function is regulated by phosphorylation. We identify Ser427 and Thr463 as M phase-specific phosphorylation sites and Cdc2-cyclin B as a Thr463 kinase. Kid with a Thr463 to alanine mutation fails to be localized on chromosomes and is only detected along spindles, although it retains the ability to bind DNA or chromosomes. Localization of rigor-type mutant Kid, which shows nucleotide-independent microtubule association, is also confined to the spindle, implying that strong association of Kid with the spindle can sequester it from chromosomes. T463A substitution in DNA-binding domain-truncated Kid consistently enhances its spindle localization. At physiological ionic strength, unphosphorylated Kid shows ATP-independent microtubule association, whereas Thr463-phosphorylated Kid shows ATP dependency. Moreover, the stalk region of unphosphorylated Kid interacts with microtubules and the interaction is weakened when Thr463 is phosphorylated. Our data suggest that phosphorylation on Thr463 of Kid downregulates its affinity for microtubules to ensure reversible association with spindles, allowing Kid to bind chromosomes and exhibit its function.
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PMID:Cdc2-mediated phosphorylation of Kid controls its distribution to spindle and chromosomes. 1272 76

Serum stimulation leads to activation of the serum response factor (SRF)-mediated transcription of immediate-early genes such as c-fos via various signal transduction pathways. We have previously reported that promyelocytic leukemia protein (PML) is involved in the transcriptional regulation by SRF. PML is one of the well-known substrates for modification by small ubiquitin-related modifier-1 (SUMO-1) and several SUMO-1-modified proteins associate with PML. Here, we report that SRF is modified by SUMO-1 chiefly at lysine(147) within the DNA-binding domain. Substitution of this target lysine for alanine did not affect the translocation of SRF to PML-nuclear bodies. The SRF mutant augmented the transcriptional activity under Rho A-stimulated condition but not under serum-starved condition, suggesting that activated SRF is suppressed by its sumoylation. These data support the transcriptional role of SUMO-1 conjugating system in cellular serum response.
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PMID:Serum response factor is modulated by the SUMO-1 conjugation system. 1278 62

Serum response factor (SRF) is a phosphoprotein that regulates skeletal and cardiac alpha-actin gene transcription. Myotonic dystrophy protein kinase (DMPK), a muscle- and neuron-restricted kinase, enhanced SRF-mediated promoter activity of the skeletal and cardiac alpha-actin genes in C2C12 myoblasts as well as in nonmyogenic cells. DMPK phosphorylated SRF in vitro in the alphaI coil of the DNA-binding domain in the MADS box, a highly conserved region required for DNA binding, dimerization, and co-activator interaction in COS and CV1 cells. Threonine 159 in the MADS box alphaI coil was a specific phosphorylation target in vitro as well as in vivo of both DMPK and protein kinase C-alpha. Substitution of threonine 159 with the nonphosphorylatable residue alanine markedly diminished activation of the cardiac alpha-actin promoter in the presence of kinase, while its substitution with aspartic acid, to introduce a negative charge and mimic phosphorylation, restored activation completely. Phosphorylation of the MADS box may constitute a novel mechanism for regulation of SRF-dependent actin gene transcription.
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PMID:Novel phosphorylation target in the serum response factor MADS box regulates alpha-actin transcription. 1280 4


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