Joey Studts scite author profile

Pim-1 kinase is a member of a distinct class of serine/ threonine kinases consisting of Pim-1, Pim-2, and Pim-3. Pim kinases are highly homologous to one another and share a unique consensus hinge region sequence, ER-PXPX, with its two proline residues separated by a nonconserved residue, but they (Pim kinases) have <30% sequence identity with other kinases. Pim-1 has been implicated in both cytokine-induced signal transduction and the development of lymphoid malignancies. We have determined the crystal structures of apo Pim-1 kinase and its AMP-PNP (5-adenylyl-␤,␥-imidodiphosphate) complex to 2.1-Å resolutions. The structures reveal the following. 1) The kinase adopts a constitutively active conformation, and extensive hydrophobic and hydrogen bond interactions between the activation loop and the catalytic loop might be the structural basis for maintaining such a conformation. 2) The hinge region has a novel architecture and hydrogen-bonding pattern, which not only expand the ATP pocket but also serve to establish unambiguously the alignment of the Pim-1 hinge region with that of other kinases. 3) The binding mode of AMP-PNP to Pim-1 kinase is unique and does not involve a critical hinge region hydrogen bond interaction. Analysis of the reported Pim-1 kinase-domain structures leads to a hypothesis as to how Pim kinase activity might be regulated in vivo.

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Recombinant Toluene-4-monooxygenase: Catalytic and Mössbauer Studies of the Purified Diiron and Rieske Components of a Four-Protein Complex

Pikus

et al. 1996

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Expression of the tmoA-F gene cluster from Pseudomonas mendocina KRI in Escherichia coli BL21(DE3) produces a catalytically active form of the toluene-4-monooxygenase (T4MO) complex. Here we report the purification and characterization of four soluble proteins required for the in vitro reconstitution of T4MO catalytic activity. These proteins are a diiron hydroxylase (T4MOH), a Riesketype ferredoxin (T4MOC), an effector protein (T4MOD), and an NADH oxidoreductase (T4MOF). The T4MOH component is composed of the tmoA, tmoB, and tmoE gene products [quaternary structure (alpha beta epsilon)2, Mr approximately 220 kDa]. The T4MOA polypeptide contains two copies of the amino acid sequence motif (D/E)X(28-37)DEXRH; the same motif provides all of the protein-derived ligands to the diiron centers of ribonucleotide reductase, the soluble methane monooxygenase, and the stearoyl-ACP delta 9 desaturase. Mössbauer, optical, and EPR measurements show that the T4MOH contains diiron centers and suggest that the diiron center contains hydroxo bridge(s) in the diferric state, as observed for methane monooxygenase. Mössbauer and EPR measurements also show that the T4MOC contains a Rieske-type iron-sulfur center. This assignment is in accord with the presence of the amino acid sequence motif CPHX(15-17)CX2H, which has also been found in the bacterial, chloroplastic, and mitochondrial Rieske proteins as well as the bacterial NADH-dependent cis-dihydrodiol-forming aromatic dioxygenases. While single-turnover catalytic studies confirm the function of the T4MOH as the hydroxylase, the NADH-dependent multiple-turnover hydroxylation activity is increased by more than 100-fold in the presence of the T4MOC, which mediates highly specific electron transfer between the T4MOF and the T4MOH. The T4MOD can be purified as an 11.6 kDa monomeric protein devoid of cofactors or redox-active metal ions; this component is also detected as a substoichiometric consitutent of the purified T4MOH. The rate of the hydroxylation reaction can be mildly stimulated by the further addition of separately purified T4MOD to the T4MOH, implying the formation of a high affinity, catalytically competent complex between these two components. These characterizations define a novel, four-component oxygenase combining elements from the soluble methane oxidation complex of the methanotrophic bacteria and the aromatic hydroxylation complexes of the soil pseudomonads.

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Structural Basis of Chemokine Sequestration by a Herpesvirus Decoy Receptor

Alexander

Nelson

Berkel

et al. 2002

Cell

107

133

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The M3 protein encoded by murine gamma herpesvirus68 (gamma HV68) functions as an immune system saboteur by the engagement of chemoattractant cytokines, thereby altering host antiviral inflammatory responses. Here we report the crystal structures of M3 both alone and in complex with the CC chemokine MCP-1. M3 is a two-domain beta sandwich protein with a unique sequence and topology, forming a tightly packed anti-parallel dimer. The stoichiometry of the MCP-1:M3 complex is 2:2, with two monomeric chemokines embedded at distal ends of the preassociated M3 dimer. Conformational flexibility and electrostatic complementation are both used by M3 to achieve high-affinity and broad-spectrum chemokine engagement. M3 also employs structural mimicry to promiscuously sequester chemokines, engaging conservative structural elements associated with both chemokine homodimerization and binding to G protein-coupled receptors.

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Combined Participation of Hydroxylase Active Site Residues and Effector Protein Binding in aParatoOrthoModulation of Toluene 4-Monooxygenase Regiospecificity

Mitchell

Studts²,

Fox³

2002

Biochemistry

120

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Toluene 4-monooxygenase (T4MO) is a diiron hydroxylase that exhibits high regiospecificity for para hydroxylation. This fidelity provides the basis for an assessment of the interplay between active site residues and protein complex formation in producing an essential biological outcome. The function of the T4MO catalytic complex (hydroxylase, T4moH, and effector protein T4moD) is evaluated with respect to effector protein concentration, the presence of T4MO electron-transfer components (Rieske ferredoxin, T4moC, and NADH oxidoreductase), and use of mutated T4moH isoforms with different hydroxylation regiospecificities. Steady-state kinetic analyses indicate that T4moC and T4moD form complexes of similar affinity with T4moH. At low T4moD concentrations, the steady-state hydroxylation rate is linearly dependent on T4moD-T4moH complex formation, whereas regiospecificity and the coupling efficiency between NADH consumption and hydroxylation are associated with intrinsic properties of the T4moD-T4moH complex. The optimized complex gives both efficient coupling and high regiospecificity with p-cresol representing >96% of total products from toluene. Similar coupling and regiospecificity for para hydroxylation are obtained with T3buV (an effector protein from a toluene 3-monooxygenase), demonstrating that effector protein binding does not uniquely determine or alter the regiospecificity of toluene hydroxylation. The omission of T4moD causes an approximately 20-fold decrease in hydroxylation rate, nearly complete uncoupling, and a decrease in regiospecificity so that p-cresol represents approximately 60% of total products. Similar shifts in regiospecificity are observed in oxidations of alternative substrates in the absence or upon the partial removal of either T4moD or T3buV from toluene oxidations. The mutated T4moH isoforms studied have apparent V(max)/K(M) specificities differing by approximately 2-4-fold and coupling efficiencies ranging from 88% to 95%, indicating comparable catalytic function, but also exhibit unique regiospecificity patterns for all substrates tested, suggesting unique substrate binding preferences within the active site. The G103L isoform has enhanced selectivity for ortho hydroxylation with all substrates tested except nitrobenzene, which gives only m-nitrophenol. The regiospecificity of the G103L isoform is comparable to that observed from naturally occurring variants of the toluene/benzene/o-xylene monooxygenase subfamily. Evolutionary and mechanistic implications of these findings are considered.

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Joey Studts

Structural Basis of Constitutive Activity and a Unique Nucleotide Binding Mode of Human Pim-1 Kinase

Recombinant Toluene-4-monooxygenase: Catalytic and Mössbauer Studies of the Purified Diiron and Rieske Components of a Four-Protein Complex

Structural Basis of Chemokine Sequestration by a Herpesvirus Decoy Receptor

Combined Participation of Hydroxylase Active Site Residues and Effector Protein Binding in aParatoOrthoModulation of Toluene 4-Monooxygenase Regiospecificity

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