Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Structure-based sequence alignment of 728 sequences of different globin subfamilies shows that in each subfamily there are two clusters of consensually conserved residues. The first is the well-known "functional" cluster which includes six heme-binding conserved residues (Phe CD1, His F8; aliphatic E11, FG5; hydrophobic F4, G5) and seven other conserved residues (Pro C2; aliphatic H19; hydrophobic B10, B13, B14, CD4, E4) that do not bind the heme but belong to its immediate neighborhood. The second cluster revealed here (aliphatic A8, G16, G12; aromatic A12; hydrophobic H8 and possibly H12) is distant from the heme. It is entirely non-polar and includes one turn (i, i+4 positions) from each of helices A, G, and H. It is known that A, G, and H helices formed at the earliest stage of apomyoglobin folding remain relatively stable in the equilibrium molten globule state, and are likely to be tightly packed with each other in this state. We have shown the existence of two similar conserved clusters in c -type cytochromes, heme-binding and distal from the heme. The second cluster in c -cytochromes includes one turn from each of the N and C-terminal alpha-helices. These N and C-terminal helices in cytochrome c are formed at the earliest stage of protein folding, remain relatively stable in the molten globule state, and are tightly packed with each other in this state, similar to the observed behavior of the globins. At least these two large protein families (c -type cytochromes and globins) have a close similarity in the existence and mutual positions of non-functional conserved residues. We assume that non-functional conserved residues are requisite for the fast and correct folding of both of these protein families into their stable 3D structures.
J Mol Biol 1999 Aug 20
PMID:Non-functional conserved residues in globins and their possible role as a folding nucleus. 1044 45

Human topoisomerase I is composed of four major domains: the highly charged NH(2)-terminal region, the conserved core domain, the positively charged linker domain, and the highly conserved COOH-terminal domain. Near complete enzyme activity can be reconstituted by combining recombinant polypeptides that approximate the core and COOH-terminal domains, although DNA binding is reduced somewhat for the reconstituted enzyme (Stewart, L., Ireton, G. C., and Champoux, J. J. (1997) J. Mol. Biol. 269, 355-372). A reconstituted enzyme comprising the core domain plus a COOH-terminal fragment containing the complete linker region exhibits the same biochemical properties as a reconstituted enzyme lacking the linker altogether, and thus detachment of the linker from the core domain renders the linker non-functional. The rate of religation by the reconstituted enzyme is increased relative to the forms of the enzyme containing the linker indicating that in the intact enzyme the linker slows religation. Relaxation of plasmid DNA by full-length human topoisomerase I or a 70-kDa form of the enzyme that is missing only the non-essential NH(2)-terminal domain (topo70) is inhibited approximately 16-fold by the anticancer compound, camptothecin, whereas the reconstituted enzyme is nearly resistant to the inhibitory effects of the drug despite similar affinities for the drug by the two forms of the enzyme. Based on these results and in light of the crystal structure of human topoisomerase I, we propose that the linker plays a role in hindering supercoil relaxation during the normal relaxation reaction and that camptothecin inhibition of DNA relaxation depends on a direct effect of the drug on DNA rotation that is also dependent on the linker.
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PMID:A functional linker in human topoisomerase I is required for maximum sensitivity to camptothecin in a DNA relaxation assay. 1055 62

We have determined that Borrelia burgdorferi strain B31 MI carries 21 extrachromosomal DNA elements, the largest number known for any bacterium. Among these are 12 linear and nine circular plasmids, whose sequences total 610 694 bp. We report here the nucleotide sequence of three linear and seven circular plasmids (comprising 290 546 bp) in this infectious isolate. This completes the genome sequencing project for this organism; its genome size is 1 521 419 bp (plus about 2000 bp of undetermined telomeric sequences). Analysis of the sequence implies that there has been extensive and sometimes rather recent DNA rearrangement among a number of the linear plasmids. Many of these events appear to have been mediated by recombinational processes that formed duplications. These many regions of similarity are reflected in the fact that most plasmid genes are members of one of the genome's 161 paralogous gene families; 107 of these gene families, which vary in size from two to 41 members, contain at least one plasmid gene. These rearrangements appear to have contributed to a surprisingly large number of apparently non-functional pseudogenes, a very unusual feature for a prokaryotic genome. The presence of these damaged genes suggests that some of the plasmids may be in a period of rapid evolution. The sequence predicts 535 plasmid genes >/=300 bp in length that may be intact and 167 apparently mutationally damaged and/or unexpressed genes (pseudogenes). The large majority, over 90%, of genes on these plasmids have no convincing similarity to genes outside Borrelia, suggesting that they perform specialized functions.
Mol Microbiol 2000 Feb
PMID:A bacterial genome in flux: the twelve linear and nine circular extrachromosomal DNAs in an infectious isolate of the Lyme disease spirochete Borrelia burgdorferi. 1067 74

The 308 residue MotB protein anchors the stator complex of the Escherichia coli flagellar motor to the peptidoglycan of the cell wall. Together with MotA, it comprises the transmembrane channel that delivers protons to the motor. At the outset of the mutational analysis of MotB described here, we found that the non-motile phenotype of a DeltamotAB strain was rescued better by a pmotA(+)B(+) plasmid than the non-motile phenotype of a DeltamotB strain was rescued by a pmotB(+) plasmid. Transcription in each case was from the inducible tac promoter but relied on the native ribosome-binding site (RBS). This result confirms that translational coupling to motA is important for normal translation of the motB mRNA, since overproduction of MotA in trans did not improve complementation by pmotB. However, introduction of an optimized RBS into pmotB (to generate pmotB(o)) did. To dissect the function of the periplasmic domain of MotB, site-directed mutagenesis was used to replace Gln, Ser, and Tyr codons scattered throughout motB with amber (UAG) codons. Plasmid-borne motB(am) genes were introduced into sup(o), supE, and supF strains to see what motility defects were imposed by particular amber mutations and whether the defects could be suppressed by amber-suppressor tRNAs inserting the native or heterologous amino acids. Amber mutations at codon 268 or earlier in pmotB, and at codon 261 or earlier in pmotB(o) or pmotAB, eliminated motility. Thus, in agreement with the deletion analysis of motB by another laboratory, we conclude that the portion of MotB carboxyl-terminal to its peptidoglycan-binding motif (residues 161 to 264) is not essential. In strains containing supE or supF alleles, motility defects associated with motB(am) mutations were suppressed weakly, if at all, in pmotB. In contrast, motility defects conferred by most motB(am) mutations in pmotB(o) or pmotAB could be suppressed to a significant extent. However, the S18(am), Q100(am), Q112(am), Q124(am), Y201(am), and Y208(am) mutations were still suppressed extremely poorly. Full-length MotB was present at very low levels in suppressor strains containing the first four mutations, but Y201(am) and Y208(am) were suppressed efficiently at the translational level. We suggest that a translational pause by suppressor tRNAs reading UAG at these two positions may divert the nascent polypeptide into an alternative folding pathway that traps MotB in a non-functional conformation. We further propose that MotA and MotB form a stable pre-assembly complex in the membrane. In this complex, MotB exists in a form that cannot associate with peptidoglycan and blocks the proton-conducting channel. Opening of the channel and attachment to the cell wall may occur when the complex collides with a flagellar basal body and MotA makes specific contacts with the C ring and/or the MS ring.
J Mol Biol 2000 Mar 17
PMID:Mot protein assembly into the bacterial flagellum: a model based on mutational analysis of the motB gene. 1070 3

Zinc plays an important role in the maintenance of the immune system. While the mechanisms of zinc ions interaction with immune cells are still poorly understood, a striking concurrent effect of zinc is the induction of the biosynthesis of metallothioneins (MT), a group of low molecular weight, cysteine-rich metal-binding proteins, believed to play a role in zinc homeostasis. In humans, they are encoded by a family of genes, located at 16q13 containing 10 functional and 7 non-functional MT isoforms. In this work we analyzed the spectrum of different isoforms in human peripheral blood lymphocytes. It was demonstrated by RT-PCR that the MT-2a, MT-1a, MT-1e, MT-1f, MT-1g, MT-1h and MT-1x genes are expressed in these cells and that these isoforms are further upregulated by zinc, as examined by quantitative RT-PCR. Surprisingly, RT-PCR also showed the presence, even in unstimulated cells, of MT-3 transcripts, which are considered as brain-specific isoforms. In an effort to determine whether MTmRNA abundance is translated into MT protein, MT isolated from zinc-treated lymphocytes by gel chromatography was resolved into 7 metal-binding fractions by using RP-HPLC. Automatic Edman-degradation of the different fractions revealed the presence of MT-2a, MT-1a, MT-1e, MT-1f, MT-1g, MT-1h, MT-1x and MT-1k, an isoform which until now was only identified at the level of protein in human liver and kidney tissue.
Cell Mol Biol (Noisy-le-grand) 2000 Mar
PMID:Metallothionein isoform gene expression in zinc-treated human peripheral blood lymphocytes. 1077 30

The Saccharomyces cerevisiae genes PHO80 and PHO85 encode, respectively, a cyclin and cyclin-dependent kinase, which negatively regulate PHO5 gene transcription by phosphorylating the transcription activator Pho4p. Cyclin-dependent kinases (CDKs) are highly conserved proteins, both within and between species. It was previously demonstrated, using reporter genes activated in yeast by Pho4p, that hybrid proteins in which over two-thirds of Pho85p were replaced with the homologous region from human Cdk2 retained the function of native Pho85p with respect to promoter repression. In the present study, various truncated forms of the hybrid human-yeast CDKs were tested for function. Surprisingly, truncations in which significant portions of the C-terminal region of the 291-residue hybrid CDK were deleted retained activity. Genes encoding human Cdk2 proteins which terminated after amino acids 151, 140, 130, 120 and 90 each complement a chromosomal pho85 gene disruption in which the HIS3 gene is inserted at codon 49. Truncated Cdk2 proteins containing less than 60 amino acids failed to complement the pho85::HIS3 gene disruption. Although the functional C-terminal truncations disrupt the ATP-binding and active sites of Cdk2, reporter gene repression mediated by these truncated proteins is apparently due to phosphorylation of Pho4p, since a gene in which the essential lysine codon at position 33 was converted to an arginine codon does not complement the chromosomal gene disruption. The human Cdk2 truncations were demonstrated to function through intergenic complementation. The intact Cdk2-Pho85 hybrid CDK complemented the pho85 mutation in yeast strains in which the entire PHO85 coding region was deleted from chromosome XVI. The C-terminal Cdk2 truncations, however, were non-functional in these strains and thus dependent for activity on the pho85 coding region which remained in the mutant pho85::HIS3 chromosomal locus. These genetic results are consistent with a model involving protein fragment complementation in which the active site of the CDK is bisected.
Mol Gen Genet 2000 Mar
PMID:Intergenic complementation truncation mutants of cyclin-dependent kinase. 1077 40

Using simple design and selective pressure, we have evolved an artificial M13 bacteriophage coat protein. M13 coat proteins first reside in the bacterial inner membrane and subsequently surround the DNA core of the assembled virus. The artificial coat protein (ACP) was designed and evolved to mimic both functions of the natural M13 coat proteins, but with an inverted orientation. ACP is a non-functional coat protein because it is not required for the production of phage particles. Instead, it incorporates into a phage coat which still requires all the natural coat proteins for structural integrity. In contrast with other M13 coat proteins, which can display polypeptides as amino-terminal fusions, ACP permits the carboxy-terminal display of large polypeptides. The results suggest that viruses can co-opt host membrane proteins to acquire new coat proteins and thus new functions. In particular, M13 bacteriophage can be engineered for new functions, such as carboxy-terminal phage display.
J Mol Biol 2000 Jun 30
PMID:Design and evolution of artificial M13 coat proteins. 1086 10

Ectomycorrhizal fungi contribute to the nitrogen nutrition of their host plants, but no information is available on the molecular control of their nitrogen metabolism. The cloning and pattern of transcriptional regulation of two nitrite reductase genes of the symbiotic basidiomycete Hebeloma cylindrosporum are presented. The genomic copy of one of these genes (nar1) was entirely sequenced; the coding region is interrupted by 12 introns. The nar1 gene, which is transcribed and codes for a putative 908-amino acid polypeptide complemented nitrate reductase-deficient mutants of H. cylindrosporum upon transformation, thus demonstrating that the gene is functional. The second gene (nar2), for which no mRNA transcripts were detected, is considered to be an ancestral, non-functional duplication of nar1. In a 462-nt partial sequence of nar2 two introns were identified at positions identical to those of introns 8 and 9 of nar1, although their respective nucleotide sequences were highly divergent; the exon sequences were much more conserved. In wild-type strains, transcription of nar1 is repressed in the presence of a high concentration of ammonium. High levels of transcription are observed in the presence of either very low nitrogen concentrations or high concentrations of nitrate or organic N sources such as urea, glycine or serine. This indicates that in H. cylindrosporum, in contrast to all nitrophilous organisms studied so far, an exogenous supply of nitrate is not required to induce transcription of a nitrate reductase gene. In contrast, repression by ammonium suggests the existence of a wide-domain regulatory gene, as already characterized in ascomycete species.
Mol Gen Genet 2000 Jul
PMID:Transcription of a nitrate reductase gene isolated from the symbiotic basidiomycete fungus Hebeloma cylindrosporum does not require induction by nitrate. 1095 80

The autosomal dominant disorders iris hypolasia (IH), iridogoniodysgenesis syndrome (IGDS) and Axenfeld-Rieger syndrome (ARS) are characterized by maldevelopment of the anterior segment of the eye associated with an increased risk of early-onset glaucoma. IH, IGDS and ARS are allelic disorders, as all three can result from mutations of the transcription factor PITX2. IH is the mildest of the three, whereas ARS exhibits the most severe ocular malformations. We hypothesize that varying amounts of residual PITX2 activity could underlie the severity of these phenotypes. Missense mutations of the PITX2 homeodomain identified in IH (Arg46Trp), IGDS (Arg31His) and ARS patients (Leu16Gln; Thr30Pro; Arg53Pro) were introduced into recombinant PITX2 cDNA by site-directed mutagenesis. PITX2 mutant proteins expressed in COS-7 cells were determined to be stable and localized to the nucleus; however, the Arg53Pro ARS mutant also displayed cytoplasmic staining. Our findings are consistent with the possibility of a novel nuclear localization signal (NLS) within helix 3 of the PITX2 homeodomain, homologous to the NLS of the related transcription factor PDX-1. Analysis of the five mutant PITX2 proteins by DNA-binding shifts and transactivation studies demonstrated reduced activity of the IH and IGDS mutant PITX2 proteins, with the IH mutant retaining the most activity in both studies, whereas the ARS mutant PITX2 proteins proved to be non-functional. In addition to providing insight into the etiological mechanism of IH, IGDS and ARS, these results are consistent with the hypothesis that mutant PITX2 proteins that retain partial function result in milder anterior segment aberrations.
Hum Mol Genet 2000 Sep 01
PMID:Variation in residual PITX2 activity underlies the phenotypic spectrum of anterior segment developmental disorders. 1095 52

Crystal structures of carbon monoxide dehydrogenase (CODH), a seleno-molybdo-iron-sulfur flavoprotein from the aerobic carbon monoxide utilizing carboxidotrophic eubacterium Hydrogenophaga pseudoflava, have been determined from the enzyme synthesized at high (Mo(plus) CODH) and low intracellular molybdenum content (Mo(minus) CODH) at 2.25 A and 2.35 A resolution, respectively. The structures were solved by Patterson search methods utilizing the enzyme from Oligotropha carboxidovorans as the initial model. The CODHs from both sources are structurally very much conserved and show the same overall fold, architecture and arrangements of the molybdopterin-cytosine dinucleotide-type of molybdenum cofactor, the type I and type II [2Fe-2S] clusters and the flavin-adenine dinucleotide. Unlike the CODH from O. carboxidovorans, the enzyme from H. pseudoflava reveals a unique post-translationally modified C(gamma)-hydroxy-Arg384 residue which precedes the catalytically essential S-selanyl-Cys385 in the active-site loop. In addition, the Trp193 which shields the isoalloxazine ring of the flavin-adenine dinucleotide in the M subunit of the H. pseudoflava CODH is a Tyr193 in the O. carboxidovorans CODH. The hydrogen bonding interaction pattern of the molybdenum cofactor involves 27 hydrogen bonds with the surrounding protein. Of these, eight are with the cytosine moiety, eight with the pyrophosphate, six with the pyranopterin, and five with the ligands of the Mo ion. The structure of the catalytically inactive Mo(minus) CODH indicates that an intracellular Mo-deficiency affects exclusively the active site of the enzyme as an incomplete non-functional molybdenum cofactor was synthesized. The 5'-CDP residue was present in Mo(minus) CODH, whereas the Mo-pyranopterin moiety was absent. In Mo(plus) CODH the selenium faces the Mo ion and flips away from the Mo site in Mo(minus) CODH. The different side-chain conformations of the active-site residues S-selanyl-Cys385 and Glu757 in Mo(plus) and Mo(minus) CODH indicate a side-chain flexibility and a function of the Mo ion in the proper orientation of both residues.
J Mol Biol 2000 Sep 01
PMID:The effect of intracellular molybdenum in Hydrogenophaga pseudoflava on the crystallographic structure of the seleno-molybdo-iron-sulfur flavoenzyme carbon monoxide dehydrogenase. 1096 17


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