Multi-state recognition pathway of the intrinsically disordered protein kinase inhibitor by protein kinase A.

In the nucleus, the spatiotemporal regulation of the catalytic subunit of cAMP-dependent protein kinase A (PKA-C) is orchestrated by an intrinsically disordered protein kinase inhibitor, PKI, which recruits the CRM1/RanGTP nuclear exporting complex. How the PKA-C/PKI complex assembles and recognizes CRM1/RanGTP is not well understood. Using NMR, SAXS, fluorescence, metadynamics, and Markov model analysis, we determined the multi-state recognition pathway for PKI. After a fast binding step in which PKA-C selects PKI's most competent conformations, PKI folds upon binding through a slow conformational rearrangement within the enzyme's binding pocket. The high-affinity and pseudo-substrate regions of PKI become more structured and the transient interactions with the kinase augment the helical content of the nuclear export sequence, which is then poised to recruit the CRM1/RanGTP complex for nuclear translocation. The multistate binding mechanism featured by PKA-C/PKI complex represents a paradigm on how disordered, ancillary proteins (or protein domains) are able to operate multiple functions such as inhibiting the kinase while recruiting other regulatory proteins for nuclear export.

Rate-Determining Attack on Substrate Precedes Rieske Cluster Oxidation during Cis-Dihydroxylation by Benzoate Dioxygenase.

Rieske dearomatizing dioxygenases utilize a Rieske iron-sulfur cluster and a mononuclear Fe(II) located 15 Šacross a subunit boundary to catalyze O2-dependent formation of cis-dihydrodiol products from aromatic substrates. During catalysis, O2 binds to the Fe(II) while the substrate binds nearby. Single-turnover reactions have shown that one electron from each metal center is required for catalysis. This finding suggested that the reactive intermediate is Fe(III)-(H)peroxo or HO-Fe(V)═O formed by O-O bond scission. Surprisingly, several kinetic phases were observed during the single-turnover Rieske cluster oxidation. Here, the Rieske cluster oxidation and product formation steps of a single turnover of benzoate 1,2-dioxygenase are investigated using benzoate and three fluorinated analogues. It is shown that the rate constant for product formation correlates with the reciprocal relaxation time of only the fastest kinetic phase (RRT-1) for each substrate, suggesting that the slower phases are not mechanistically relevant. RRT-1 is strongly dependent on substrate type, suggesting a role for substrate in electron transfer from the Rieske cluster to the mononuclear iron site. This insight, together with the substrate and O2 concentration dependencies of RRT-1, indicates that a reactive species is formed after substrate and O2 binding but before electron transfer from the Rieske cluster. Computational studies show that RRT-1 is correlated with the electron density at the substrate carbon closest to the Fe(II), consistent with initial electrophilic attack by an Fe(III)-superoxo intermediate. The resulting Fe(III)-peroxo-aryl radical species would then readily accept an electron from the Rieske cluster to complete the cis-dihydroxylation reaction.

Hydrogen peroxide dependent cis-dihydroxylation of benzoate by fully oxidized benzoate 1,2-dioxygenase.

Rieske dioxygenases catalyze the reductive activation of O2 for the formation of cis-dihydrodiols from unactivated aromatic compounds. It is known that O2 is activated at a mononuclear non-heme iron site utilizing electrons supplied by a nearby Rieske iron sulfur cluster. However, it is controversial whether the reactive species is an Fe(III)-(hydro)peroxo or an Fe(II)-(hydro)peroxo (or electronically equivalent species formed by breaking the O-O bond). Here it is shown that benzoate 1,2 dioxygenase oxygenase component (BZDO) prepared in a form with the Rieske cluster oxidized and the mononuclear iron in the Fe(III) state can utilize H2O2 as a source of reduced oxygen to form the correct cis-dihydrodiol product from benzoate. The reaction approaches stoichiometric yield relative to the mononuclear Fe(III) concentration, being limited to a single turnover by inefficient product release from the Fe(III)-product complex. EPR and Mössbauer studies show that the iron remains ferric throughout this single turnover "peroxide shunt" reaction. These results strongly support Fe(III)-(hydro)peroxo (or Fe(V)-oxo-hydroxo) as the reactive species because there is no source of additional reducing equivalents to form the Fe(II)-(hydro)peroxo state. This conclusion could be further tested in the case of BZDO because the peroxide shunt occurs very slowly compared with normal turnover, allowing the reactive intermediate to be trapped for spectroscopic analysis. We attribute the slow reaction rate to a forced change in the normally strict order of the substrate binding and enzyme reduction steps that regulate the catalytic cycle. The reactive intermediate is a high-spin ferric species exhibiting an unusual negative zero field splitting and other EPR and Mössbauer spectroscopic properties reminiscent of previously characterized side-on-bound peroxide adducts of Fe(III) model complexes. If the species in BZDO is a similar adduct, its isomer shift is most consistent with an Fe(III)-hydroperoxo reactive state.

VTVH-MCD and DFT studies of thiolate bonding to [FeNO]7/[FeO2]8 complexes of isopenicillin N synthase: substrate determination of oxidase versus oxygenase activity in nonheme Fe enzymes.

Isopenicillin N synthase (IPNS) is a unique mononuclear nonheme Fe enzyme that catalyzes the four-electron oxidative double ring closure of its substrate ACV. A combination of spectroscopic techniques including EPR, absorbance, circular dichroism (CD), magnetic CD, and variable-temperature, variable-field MCD (VTVH-MCD) were used to evaluate the geometric and electronic structure of the [FeNO]7 complex of IPNS coordinated with the ACV thiolate ligand. Density Function Theory (DFT) calculations correlated to the spectroscopic data were used to generate an experimentally calibrated bonding description of the Fe-IPNS-ACV-NO complex. New spectroscopic features introduced by the binding of the ACV thiolate at 13 100 and 19 800 cm-1 are assigned as the NO pi*(ip) --> Fe dx2-y2 and S pi--> Fe dx2-y2 charge transfer (CT) transitions, respectively. Configuration interaction mixes S CT character into the NO pi*(ip) --> Fe dx2-y2 CT transition, which is observed experimentally from the VTVH-MCD data from this transition. Calculations on the hypothetical {FeO2}8 complex of Fe-IPNS-ACV reveal that the configuration interaction present in the [FeNO]7 complex results in an unoccupied frontier molecular orbital (FMO) with correct orientation and distal O character for H-atom abstraction from the ACV substrate. The energetics of NO/O2 binding to Fe-IPNS-ACV were evaluated and demonstrate that charge donation from the ACV thiolate ligand renders the formation of the FeIII-superoxide complex energetically favorable, driving the reaction at the Fe center. This single center reaction allows IPNS to avoid the O2 bridged binding generally invoked in other nonheme Fe enzymes that leads to oxygen insertion (i.e., oxygenase function) and determines the oxidase activity of IPNS.

Substrate binding to NO-ferro-naphthalene 1,2-dioxygenase studied by high-resolution Q-band pulsed 2H-ENDOR spectroscopy.

The active site of naphthalene 1,2-dioxygenase (NDO) contains a Rieske Fe-S cluster and a mononuclear non-heme iron, which are contributed by different alpha-subunits in the (alphabeta)(3) structure. The enzyme catalyzes cis-dihydroxylation of aromatic substrates, in addition to numerous other adventitious oxidation reactions. High-resolution Mims (2)H-ENDOR (electron nuclear double resonance) spectra have been recorded for the NO-ferrous center of NDO bound with the substrates d(8)-naphthalene, d(2)-naphthalene, d(8)-toluene, d(3)-toluene, and d(6)-benzene; samples were prepared in a D(2)O buffer to test for solvent-derived ligands; spectra were collected for enzymes with the Rieske diiron center in both its oxidized and reduced states. A sharp quartet ENDOR pattern from a nearby deuteron of the substrate in a major binding geometry (denoted as A) was detected for all perdeuterated substrates. Examination of the sample prepared with 1,4-di-deutero-naphthalene shows that the signal arises from D1. Analysis of two-dimensional (2-D) orientation-selective ENDOR patterns collected for this sample defined the location of the D1 deuteron, with respect to the g-frame of the iron center and the orientation of the C-D1 bond. Consideration of the orientations of naphthalene that are permitted within the constraints of these results, as supported by a novel approach to simulations of orientation-selective, 2-D ENDOR patterns for the perdeuterated naphthalene sample, which summed contributions from D1/D2/D8, disclose the geometry of the naphthalene and the Fe-NO fragment. The two deuterons of the reactive carbons, D1 and D2, are closest to the Fe atom (r(Fe)(-)(D1) approximately 4.3 A, r(Fe)(-)(D2) approximately 5.0 A), whereas D8 is farther away (r(Fe)(-)(D8) approximately 5.3 A). Perhaps more instructive, D1-N and D2-N distances to the O(2) surrogate, NO, are approximately 2.4 and approximately 3.3 A, respectively, whereas the D8-N distance is approximately 3.7 A. The data show that benzene and the aromatic ring of toluene also sit within the substrate-binding pocket adjacent to the mononuclear Fe atom. These rings occupy a position similar to that of the "proximal" ring of naphthalene, with the closest ring deuteron being located at a distance of approximately 4.3-4.4 A from the Fe atom and with the Fe-D vector being slightly off the Fe-N(O) direction. In particular, comparison of the data for d(8)-toluene and methyl-d(3)-toluene shows that the methyl group of toluene points away from the Fe atom, despite observations that the oxidation of toluene occurs at the methyl group during catalysis. The Rieske cluster is reduced during both steady-state and single-turnover catalysis; therefore, the effect of its oxidation state on the geometry of substrate binding was examined. The spectra from the NDO-naphthalene complex also revealed a second binding conformation (denoted as B), in which the substrate is located approximately 0.5 A farther from the Fe atom. The relative populations of A- and B-sites are allosterically changed when the Rieske cluster is reduced. ENDOR of exchangeable protons shows that the water/hydroxide of Fe-NDO is retained upon binding NO.

Modulation of substrate binding to naphthalene 1,2-dioxygenase by rieske cluster reduction/oxidation.

The active site of the oxygenase component of naphthalene 1,2-dioxygenase (NDO) contains a Rieske Fe-S cluster and a mononuclear non-heme iron, which are contributed by different alpha-subunits in the (alphabeta)(3) structure. The enzyme catalyzes cis-dihydroxylation of aromatic substrates in addition to numerous other adventitious oxidation reactions. High-resolution Mims (2)H-ENDOR spectra have been recorded for the NO-ferrous center of NDO bound with d(8)-naphthalene and d(2)-naphthalene; spectra were collected for the enzyme with the Rieske diiron center both in its oxidized and in its reduced states. A sharp quartet ENDOR pattern from a nearby deuteron of substrate was detected for each substrate. Examination of the sample prepared with 1,4-dideutero-naphthalene shows that the signal arises from D1. The ENDOR data place D1 at a distance of ca. 4.4 A from the mononuclear Fe and with the Fe-D vector being roughly along the Fe-N(O) direction. Because reduction of the Rieske cluster is required for O(2) binding and subsequent catalysis, the effect of its oxidation state on substrate binding was examined. The spectra from the NDO-naphthalene complex reveal two different binding conformations, which change in relative population when the oxidation state of the Rieske cluster is changed. This shift, and the conformational coupling it implies, may hold the key to both oxygen gating and oxygen reactivity for Rieske aromatic dioxygenases.