Spelling suggestions: "subject:"stoppedflow"" "subject:"stopped.power""
31 |
Structural and functional analysis of catalase-peroxidasesWiseman, Benjamin 08 April 2010 (has links)
Catalase-peroxidases (KatGs), responsible for the activation of the anti-tubercular prodrug isoniazid (INH), are unusual members of the class I plant peroxidase family that possess strong catalase activity as well as peroxidase activity. Due to their strong catalase activity and their ability to activate INH, KatGs have been the subject of intense study for many years, and thus the goal of this work is to further characterize this enzyme in the hope of gaining a better understanding into these unusual reactions. Recent successful crystallization of a few representative KatGs revealed a unique covalent Met-Tyr-Trp cross-link joined to the conserved tryptophan in the heme active site, along with a nearby arginine that is in ionic association with the cross-linked tyrosine. Using the KatG from Burkholderia pseudomallei (BpKatG) as a model, site-directed mutagenesis to these residues revealed that they were essential for catalase, but not peroxidase activity. Structural and kinetic analysis revealed that Arg426 acts as a molecular switch, moving between 2 conformations, favoring heme oxidation when not in association with Tyr238 and favoring heme reduction when in association with Tyr238 by imparting its influence on the heme through the cross-link. Analysis of the reaction with peroxyacetic acid using stopped-flow spectrophotometry revealed an initial, rapidly formed enzyme-substrate complex before the formation of the oxoferryl compound I. Kinetic characterization revealed that formation of both the enzyme-substrate complex and the oxoferryl species were dependent on peroxyacetic acid concentration implying that 2 molecules of peroxyacetic acid are required to form the oxoferryl compound I intermediate. Successful co-crystallization with INH and its co-substrate, NAD+ has revealed their binding sites for the first time in a KatG. The NAD+ binding site is 20 Å from the entrance to the heme cavity, involving interactions primarily with the ADP portion of the molecule. The best defined INH binding site is located in a funnel shaped channel on the opposite side of the protein from the entrance channel that requires the movement of a glutamate residue for binding. The structures suggest that once INH is cleaved to the isonicotinoyl radical it diffuses to the NAD+ binding site to form the final active antimicrobial compound, IN-NAD, in a non-enzymatic reaction enhanced by the enzyme’s ability to bind NAD+.
|
32 |
Correlação estrutura-função de variantes da hemoglobina humana = Structure-function relations of human hemoglobin variants / Structure-function relations of human hemoglobin variantsJorge, Susan Elisabeth Domingues Costa, 1983- 31 July 2013 (has links)
Orientadores: Maria de Fatima Sonati, Munir Salomão Skaf / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-23T23:13:39Z (GMT). No. of bitstreams: 1
Jorge_SusanElisabethDominguesCosta_D.pdf: 8714965 bytes, checksum: 3191d67be1e9be2f9782ce3483bcfd3a (MD5)
Previous issue date: 2013 / Resumo: O resumo poderá ser visualizado no texto completo da tese digital / Abstract: The complete abstract is available with the full electronic document / Doutorado / Ciencias Biomedicas / Doutora em Ciências Médicas
|
33 |
Kinetic Analysis of Mammalian Translation InitiationYi, Sung-Hui 13 December 2021 (has links)
No description available.
|
34 |
Investigating the Role of Subunit III in the Structure and Function of Rhodobacter Sphaeroides Cytochrome C OxidaseGeyer, R. Ryan 31 July 2007 (has links)
No description available.
|
35 |
Thermodynamic, Kinetic, and Dynamics Studies of the Allosteric Ligand-Responsive Regulatory Protein TRAPKleckner, Ian Robert 19 October 2011 (has links)
No description available.
|
36 |
Spectroscopic Investigation of Conformational Transitions in the Copper-transporting P1B-ATPase CopA from Legionella pneumophilaSayed, Ahmed 22 May 2015 (has links) (PDF)
All cells maintain essential metal nutrients at optimal levels by metal homeostasis. P-type ATPases, a crucial superfamily of integral membrane proteins, are involved in the active transport of metal ions across biological membranes driven by the motive force of ATP- hydrolysis. The PIB-type ATPase subfamily, also called CPx-ATPases, fulfills a key role in heavy metal homoeostasis among the most widespread species from bacteria to human. In humans, the defect in copper transporters is the direct cause of severe neurological and hepatic disorders such as Wilson and Menkes diseases, therefore, understanding the molecular function of these pumps is of paramount importance in human health. Cu+-ATPases have two transmembrane metal binding sites (TM-MBS) and three cytosolic domains, namely the actuator (A-domain) and phosphorylation and nucleotide-binding domain (PN), and regulatory N-terminal heavy metal binding domain (HMBD).
Here, we have studied the Legionella pneumophila CopA (LpCopA) and its isolated cytosolic domains to improve our understanding of the functional interaction of the protein domains during metal transport relate this to the known structure of this ATPase. To elucidate how cytosolic ligands (Cu+ and nucleotide) stimulate the interactions among the cytosolic domains and may transmit conformational changes to the TM-MBS, the interactions among recombinant isolated cytosolic domains were first examined biochemically by co-purification and spectroscopically by circular dichroism, time-resolved fluorescence and site-directed fluorescent labeling assays. The Cu+-dependent interaction between the A-domain and HMBD has been postulated as a mechanism for activating the ATPase cycle. This question was addressed here by studying copper-dependent interactions between the isolated expressed domains.
Spectroscopic evidence is provided that an HMBD-A complex is formed in the presence of Cu+ which binds with 100-200 nM affinity to the recombinant HMBD. In contrast, the A-domain interacts with the PN domain in a nucleotide-dependent fashion. This molecular recognition is required for the dephosphorylation step in the catalytic cycle. The interaction was investigated in more detail by the use of a decameric peptide derived from the PN-binding interface of the A-domain and carrying the conserved TGE-motif involved in dephosphorylation. Its binding to the isolated PN domain in a weakly nucleotide-dependent manner, is demonstrated here by stopped-flow fluorescence spectroscopy.
Several ATPase assays were modified to assess the functionality of the PN-domain and full length LpCopA. The peptide was found to reduce the catalytic turnover of full length LpCopA. This agrees with the expected slowing down of the reformation of the PN-A-domain interaction since the peptide occupies their binding interface. Thus, the synthetic peptide provides a means to study specifically the influence of PN-A-domain interactions on the structure and function of LpCopA. This was done by time-correlated single photon counting (TCSPC) method. The time-dependent Stokes shift of the environmentally sensitive fluorophore BADAN which was covalently attached to the conserved CPC-motif in the TM-MBS was measured. The data indicate that the interior of the ATPase is hydrated and the mobility of the intra-protein water varies from high to low at C382 at the “luminal side” and C384 at the “cytosolic side” of the TM-MBS, respectively. This finding is consistent with the recent MD simulation of LpCopA, bringing the first experimental evidence on a luminal-open conformation of E2~P state. The A-domain-derived decapeptide, although binding to the cytosolic head piece, induces structural changes also at the TM-MBS. The peptide-stabilized state (with a disrupted PN-A interface) renders the C384 environment more hydrophobic as evidenced by TCSPC.
Taken together, the data from cytosolic domain interactions, ATPase assays and of time-dependent Stoke shift analyses of BADAN-labeled LpCopA reveal the presence of hydrated intramembraneous sites whose degree of hydration is regulated by the rearrangement of cytosolic domains, particularly during the association and dissociation of the PN-A domains. Copper affects this arrangement by inducing the linkage of the A-domain to the HMBD. The latter appears to play not only an autoinhibitory but also a chaperone-like role in transferring Cu+ to the TM-MBS during catalytic turnover.
|
37 |
Investigation of Interactions between Homeodomain Proteins and DNA / Untersuchung der Wechselwirkungen zwischen Homeodomän-Proteinen und DNSVainius, Darius 18 May 2004 (has links)
No description available.
|
38 |
Spectroscopic Investigation of Conformational Transitions in the Copper-transporting P1B-ATPase CopA from Legionella pneumophilaSayed, Ahmed 23 March 2015 (has links)
All cells maintain essential metal nutrients at optimal levels by metal homeostasis. P-type ATPases, a crucial superfamily of integral membrane proteins, are involved in the active transport of metal ions across biological membranes driven by the motive force of ATP- hydrolysis. The PIB-type ATPase subfamily, also called CPx-ATPases, fulfills a key role in heavy metal homoeostasis among the most widespread species from bacteria to human. In humans, the defect in copper transporters is the direct cause of severe neurological and hepatic disorders such as Wilson and Menkes diseases, therefore, understanding the molecular function of these pumps is of paramount importance in human health. Cu+-ATPases have two transmembrane metal binding sites (TM-MBS) and three cytosolic domains, namely the actuator (A-domain) and phosphorylation and nucleotide-binding domain (PN), and regulatory N-terminal heavy metal binding domain (HMBD).
Here, we have studied the Legionella pneumophila CopA (LpCopA) and its isolated cytosolic domains to improve our understanding of the functional interaction of the protein domains during metal transport relate this to the known structure of this ATPase. To elucidate how cytosolic ligands (Cu+ and nucleotide) stimulate the interactions among the cytosolic domains and may transmit conformational changes to the TM-MBS, the interactions among recombinant isolated cytosolic domains were first examined biochemically by co-purification and spectroscopically by circular dichroism, time-resolved fluorescence and site-directed fluorescent labeling assays. The Cu+-dependent interaction between the A-domain and HMBD has been postulated as a mechanism for activating the ATPase cycle. This question was addressed here by studying copper-dependent interactions between the isolated expressed domains.
Spectroscopic evidence is provided that an HMBD-A complex is formed in the presence of Cu+ which binds with 100-200 nM affinity to the recombinant HMBD. In contrast, the A-domain interacts with the PN domain in a nucleotide-dependent fashion. This molecular recognition is required for the dephosphorylation step in the catalytic cycle. The interaction was investigated in more detail by the use of a decameric peptide derived from the PN-binding interface of the A-domain and carrying the conserved TGE-motif involved in dephosphorylation. Its binding to the isolated PN domain in a weakly nucleotide-dependent manner, is demonstrated here by stopped-flow fluorescence spectroscopy.
Several ATPase assays were modified to assess the functionality of the PN-domain and full length LpCopA. The peptide was found to reduce the catalytic turnover of full length LpCopA. This agrees with the expected slowing down of the reformation of the PN-A-domain interaction since the peptide occupies their binding interface. Thus, the synthetic peptide provides a means to study specifically the influence of PN-A-domain interactions on the structure and function of LpCopA. This was done by time-correlated single photon counting (TCSPC) method. The time-dependent Stokes shift of the environmentally sensitive fluorophore BADAN which was covalently attached to the conserved CPC-motif in the TM-MBS was measured. The data indicate that the interior of the ATPase is hydrated and the mobility of the intra-protein water varies from high to low at C382 at the “luminal side” and C384 at the “cytosolic side” of the TM-MBS, respectively. This finding is consistent with the recent MD simulation of LpCopA, bringing the first experimental evidence on a luminal-open conformation of E2~P state. The A-domain-derived decapeptide, although binding to the cytosolic head piece, induces structural changes also at the TM-MBS. The peptide-stabilized state (with a disrupted PN-A interface) renders the C384 environment more hydrophobic as evidenced by TCSPC.
Taken together, the data from cytosolic domain interactions, ATPase assays and of time-dependent Stoke shift analyses of BADAN-labeled LpCopA reveal the presence of hydrated intramembraneous sites whose degree of hydration is regulated by the rearrangement of cytosolic domains, particularly during the association and dissociation of the PN-A domains. Copper affects this arrangement by inducing the linkage of the A-domain to the HMBD. The latter appears to play not only an autoinhibitory but also a chaperone-like role in transferring Cu+ to the TM-MBS during catalytic turnover.
|
39 |
Formation and Decomposition of Platinum–Thallium Bond, Kinetics and Mechanism. Structural Characterization of Some Metal Cyanides in the Solid StateNagy, Péter January 2004 (has links)
The kinetic and mechanistic features of a new series ofplatinum-thallium cyano compounds containing a direct andunsupported by ligands metal-metal bond have been studied insolution, using standard mixandmeasurespectrophotometric technique and stoppedflow method.These reactions are interpreted as oxidative addition of the cspecies to the square planar Pt(CN)42-complex. Each of these processes was found to befirst-order in Pt(CN)42-, the corresponding TIIIIcomplex and a cyanide ion donating species whichacts as a catalyst. Both di- and trinuclear complexes werestudied, and the kinetically significant thallium complexes intheir formation and the catalytically active cyanide sourcesare as follows: [(CN)5PtTl(CN)3]3-: Tl(CN)4(alkaline region), Tl(CN)3(slightly acidic region) and CN; [(CN)5PtTl(CN)]: Tl(CN)2+and Tl(CN)2+; [(CN)5PtTlPt(CN)5]3-: [(CN)5PtTl(CN)]and HCN. Appropriatemechanisms were postulated for the overall reactions in allcases, which include i) metalmetal bond formation stepand ii) coordination of an axial cyanide ion to the platinumcenter. Two experimentally indistinguishable kinetic modelswere proposed for the formation of the dinuclear complexeswhich are different in the sequence of the two steps. In thecase of the trinuclear complex, experimental evidence isavailable to exclude one of the alternative reaction paths, andit was proven that the metalmetal bond formation precedesthe axial cyanide coordination. The cyanide ligands coordinated to TIIIIin the PtTl complexes could be replacedsuccessfully with aminopolycarboxylates e.g.: mimda2-, nta3-, edta4-. The [(CN)5PtTl(edta)]4-complex, with a direct metalmetal bond hasbeen prepared in solution by two different reactions: a)dissolution of [(CN)5PtTl](s) in an aqueous solution of edta, b)directly from Pt(CN)42-and Tl(edta)(CN)2-. The decomposition reaction is greatlyaccelerated by cyanide and significantly inhibited by edta. Itproceeds through the [(CN)5PtTl(CN)3]3-intermediate. The formation of [(CN)5PtTl(edta)]4-can proceed via two different pathways dependingon the ratio of the cyanide to the edta ligand concentrations.Thedirect pathat excess of edta means theformation of intermediate[(CN)4Pt···Tl(CN)(edta)]4-, followed by a release of the cyanide from theTlcentre followed by coordination of a cyanide from thebulk to the Ptcentre of the intermediate. Theindirect pathdominates in the absence of extraedta and the formation of the PtTl bond occours betweenPt(CN)42-and Tl(CN)4. Homoligand MTl(CN)4(M = TlI, K, Na) and, for the first time, Tl(CN)3species have been synthesized in the solid stateand their structures solved by single crystal Xraydiffraction method. Interesting redox processes have been foundbetween TIIIIand CNin nonaqueous solution and in Tl2O3-CNaqueous suspension. In the crystal structureof Tl(CN)3·H2O, the thallium(III) ion has a trigonal bypiramidalcoordination geometry with three cyanides in the trigonalplane, while an oxygen atom of the water molecule and anitrogen atom from a cyanide ligand attached to a neighboringthallium complex, form a linear OTlN fragment.Cyanide ligand bridges thallium units forming an infinitezigzag chain structure. Among the thallium(III) tetracyanocompounds, the isostructural M[Tl(CN)4](M = Tl and K) and Na[Tl(CN)4]·3H2O crystallize in different crystal systems, but thethallium(III) ion has in all cases the same tetrahedralgeometry in the [Tl(CN)4]unit. Three adducts of mercury(II) (isoelectronic with TIIII) (K2PtHg(CN)6·2H2O, Na2PdHg(CN)6·2H2O and K2NiHg(CN)6·2H2O) have been prepared from Hg(CN)2and square planar transition metal cyanides MII(CN)42-and their structure have been studied by singlecrystal Xray diffraction, XPS and Raman spectroscopy inthe solid state. The structure of (K2PtHg(CN)6·2H2O consists of strictly linear one dimensional wireswith PtIIand HgIIcenters located alternately, dHgPt= 3.460 Å. The structure of Na2PdHg(CN)6·2H2O and K2NiHg(CN)6·2H2O can be considered as double salts, the lack ofheterometallophilic interaction between both the HgIIand PdIIatoms, dHgPd= 4.92 Å, and HgIIand NiIIatoms, dNiPd= 4.60 Å, seems obvious. Electronbinding energy values of the metallic centers measured by XPSshow that there is no electron transfer between the metal ionsin all three adducts. In solution, experimental findingsclearly indicate the lack of metalmetal bond formation inall studied HgIICN-MII(CN)42-systems (M = Pt, Pd and Ni). It is in contrary tothe platinumthallium bonded cyanides. KEYWORDS:metalmetal bond, platinum, thallium,kinetics, mechanism, stopped flow, oxidative addition, cyanocomplexes, edta, redox reaction, metal cyanides, Xraydiffraction, Raman, NMR, mercury, palladium, nickel, onedimensional wire
|
40 |
Spectroscopic and Kinetic Investigation of the Catalytic Mechanism of Tyrosine HydroxylaseEser, Bekir Engin 2009 December 1900 (has links)
Tyrosine Hydroxylase (TyrH) is a pterin-dependent mononuclear non-heme iron
oxygenase. TyrH catalyzes the hydroxylation reaction of tyrosine to
dihydroxyphenylalanine (DOPA). This reaction is the first and the rate-limiting step in
the biosynthesis of the catecholamine neurotransmitters. The active site iron in TyrH is
coordinated by the common facial triad motif, 2-His-1-Glu. A combination of kinetic
and spectroscopic techniques was applied in order to obtain insight into the catalytic
mechanism of this physiologically important enzyme.
Analysis of the TyrH reaction by rapid freeze-quench Mossbauer spectroscopy
allowed the first direct characterization of an Fe(IV) intermediate in a mononuclear nonheme
enzyme catalyzing aromatic hydroxylation. Further rapid kinetic studies
established the kinetic competency of this intermediate to be the long-postulated
hydroxylating species, Fe(IV)O.
Spectroscopic investigations of wild-type (WT) and mutant TyrH complexes
using magnetic circular dichroism (MCD) and X-ray absorption spectroscopy (XAS)
showed that the active site iron is 6-coordinate in the resting form of the enzyme and that binding of either tyrosine or 6MPH4 alone does not change the coordination. However,
when both tyrosine and 6MPH4 are bound, the active site becomes 5-coordinate, creating
an open site for reaction with O2. Investigation of the kinetics of oxygen reactivity of
TyrH complexes in the absence and presence of tyrosine and/or 6MPH4 indicated that
there is a significant enhancement in reactivity in the 5-coordinate complex in
comparison to the 6-coordinate form. Similar investigations with E332A TyrH showed
that Glu332 residue plays a role in directing the protonation of the bridged complex that
forms prior to the formation of Fe(IV)O.
Rapid chemical quench analyses of DOPA formation showed a burst of product
formation, suggesting a slow product release step. Steady-state viscosity experiments
established a diffusional step as being significantly rate-limiting. Further studies with
stopped-flow spectroscopy indicated that the rate of TyrH reaction is determined by a
combination of a number of physical and chemical steps.
Investigation of the NO complexes of TyrH by means of optical absorption,
electron paramagnetic resonance (EPR) and electron spin echo envelope modulation
(ESEEM) techniques revealed the relative positions of the substrate and cofactor with
respect to NO, an O2 mimic, and provided further insight into how the active site is
tuned for catalytic reactivity upon substrate and cofactor binding.
|
Page generated in 0.0273 seconds