Structure of Dicer and mechanistic implications for RNAi.

Dicer is a specialized ribonuclease that processes double-stranded RNA (dsRNA) into small RNA fragments about 25 nucleotides in length during the initiation phase of RNA interference (RNAi). We previously determined the crystal structure of a Dicer enzyme from the diplomonad Giardia intestinalis and proposed a structural model for dsRNA processing. Here, we provide evidence that Dicer is composed of three structurally rigid regions connected by flexible hinges and propose that conformational flexibility facilitates dsRNA binding and processing. We also examine the role of the accessory domains found in Dicers of higher eukaryotes but absent in Giardia Dicer. Finally, we combine the structure of Dicer with published biochemical data to propose a model for the architecture of the RNA-induced silencing complex (RISC)-loading complex.

Crystal structure of ATP sulfurylase from the bacterial symbiont of the hydrothermal vent tubeworm Riftia pachyptila.

In sulfur chemolithotrophic bacteria, the enzyme ATP sulfurylase functions to produce ATP and inorganic sulfate from APS and inorganic pyrophosphate, which is the final step in the biological oxidation of hydrogen sulfide to sulfate. The giant tubeworm, Riftia pachyptila, which lives near hydrothermal vents on the ocean floor, harbors a sulfur chemolithotroph as an endosymbiont in its trophosome tissue. This yet-to-be-named bacterium was found to contain high levels of ATP sulfurylase that may provide a substantial fraction of the organisms ATP. We present here, the crystal structure of ATP sulfurylase from this bacterium at 1.7 A resolution. As predicted from sequence homology, the enzyme folds into distinct N-terminal and catalytic domains, but lacks the APS kinase-like C-terminal domain that is present in fungal ATP sulfurylase. The enzyme crystallizes as a dimer with one subunit in the crystallographic asymmetric unit. Many buried solvent molecules mediate subunit contacts at the interface. Despite the high concentration of sulfate needed for crystallization, no ordered sulfate was observed in the sulfate-binding pocket. The structure reveals a mobile loop positioned over the active site. This loop is in a "closed" or "down" position in the reported crystal structures of fungal ATP sulfurylases, which contained bound substrates, but it is in an "open" or "up" position in the ligand-free Riftia symbiont enzyme. Thus, closure of the loop correlates with occupancy of the active site, although the loop itself does not interact directly with bound ligands. Rather, it appears to assist in the orientation of residues that do interact with active-site ligands. Amino acid differences between the mobile loops of the enzymes from sulfate assimilators and sulfur chemolithotrophs may account for the significant kinetic differences between the two classes of ATP sulfurylase.

Temperature effects on the allosteric transition of ATP sulfurylase from Penicillium chrysogenum.

The effects of temperature on the initial velocity kinetics of allosteric ATP sulfurylase from Penicillium chrysogenum were measured. The experiments were prompted by the structural similarity between the C-terminal regulatory domain of fungal ATP sulfurylase and fungal APS kinase, a homodimer that undergoes a temperature-dependent, reversible dissociation of subunits over a narrow temperature range. Wild-type ATP sulfurylase yielded hyperbolic velocity curves between 18 and 30 degrees C. Increasing the assay temperature above 30 degrees C at a constant pH of 8.0 increased the cooperativity of the velocity curves. Hill coefficients (n(H)) up to 1.8 were observed at 42 degrees C. The bireactant kinetics at 42 degrees C were the same as those observed at 30 degrees C in the presence of PAPS, the allosteric inhibitor. In contrast, yeast ATP sulfurylase yielded hyperbolic plots at 42 degrees C. The P. chrysogenum mutant enzyme, C509S, which is intrinsically cooperative (n(H) = 1.8) at 30 degrees C, became more cooperative as the temperature was increased yielding n(H) values up to 2.9 at 42 degrees C. As the temperature was decreased, the cooperativity of C509S decreased; n(H) was 1.0 at 18 degrees C. The cumulative results indicate that increasing the temperature increases the allosteric constant, L, i.e., promotes a shift in the base-level distribution of enzyme molecules from the high MgATP affinity R state toward the low MgATP affinity T state. As a result, the enzyme displays a true "temperature optimum" at subsaturating MgATP. The reversible temperature-dependent transitions of fungal ATP sulfurylase and APS kinase may play a role in energy conservation at high temperatures where the organism can survive but not grow optimally.

Crystal structure of ATP sulfurylase from Penicillium chrysogenum: insights into the allosteric regulation of sulfate assimilation.

ATP sulfurylase from Penicillium chrysogenum is an allosterically regulated enzyme composed of six identical 63.7 kDa subunits (573 residues). The C-terminal allosteric domain of each subunit is homologous to APS kinase. In the presence of APS, the enzyme crystallized in the orthorhombic space group (I222) with unit cell parameters of a = 135.7 A, b = 162.1 A, and c = 273.0 A. The X-ray structure at 2.8 A resolution established that the hexameric enzyme is a dimer of triads in the shape of an oblate ellipsoid 140 A diameter x 70 A. Each subunit is divided into a discreet N-terminal domain, a central catalytic domain, and a C-terminal allosteric domain. Two molecules of APS bound per subunit clearly identify the catalytic and allosteric domains. The sequence 197QXRN200 is largely responsible for anchoring the phosphosulfate group of APS at the active site of the catalytic domain. The specificity of the catalytic site for adenine nucleotides is established by specific hydrogen bonds to the protein main chain. APS was bound to the allosteric site through sequence-specific interactions with amino acid side chains that are conserved in true APS kinase. Within a given triad, the allosteric domain of one subunit interacts with the catalytic domain of another. There are also allosteric-allosteric, allosteric-N-terminal, and catalytic-catalytic domain interactions across the triad interface. The overall interactions-each subunit with four others-provide stability to the hexamer as well as a way to propagate a concerted allosteric transition. The structure presented here is believed to be the R state. A solvent channel, 15-70 A wide exists along the 3-fold axis, but substrates have access to the catalytic site only from the external medium. On the other hand, a surface "trench" links each catalytic site in one triad with an allosteric site in the other triad. This trench may be a vestigial feature of a bifunctional ("PAPS synthetase") ancestor of fungal ATP sulfurylase.

Induction of positive cooperativity by amino acid replacements within the C-terminal domain of Penicillium chrysogenum ATP sulfurylase.

ATP sulfurylase from Penicillium chrysogenum is an allosteric enzyme in which Cys-509 is critical for maintaining the R state. Cys-509 is located in a C-terminal domain that is 42% identical to the conserved core of adenosine 5'-phosphosulfate (adenylylsulfate) (APS) kinase. This domain is believed to provide the binding site for the allosteric effector, 3'-phosphoadenosine 5'-phosphosulfate (PAPS). Replacement of Cys-509 with either Tyr or Ser destabilizes the R state, resulting in an enzyme that is intrinsically cooperative at pH 8 in the absence of PAPS. The kinetics of C509Y resemble those of the wild type enzyme in which Cys-509 has been covalently modified. The kinetics of C509S resemble those of the wild type enzyme in the presence of PAPS. It is likely that the negative charge on the Cys-509 side chain helps to stabilize the R state. Treatment of the enzyme with a low level of trypsin results in cleavage at Lys-527, a residue that lies in a region analogous to a PAPS motif-containing mobile loop of true APS kinase. Both mutant enzymes were cleaved more rapidly than the wild type enzyme, suggesting that movement of the mobile loop occurs during the R to T transition.

Crystal structure of adenosine 5'-phosphosulfate kinase from Penicillium chrysogenum.

Adenosine 5'-phosphosulfate (APS) kinase catalyzes the second reaction in the two-step conversion of inorganic sulfate to 3'-phosphoadenosine 5'-phosphosulfate (PAPS). This report presents the 2.0 A resolution crystal structure of ligand-free APS kinase from the filamentous fungus, Penicillium chrysogenum. The enzyme crystallized as a homodimer with each subunit folded into a classic kinase motif consisting of a twisted, parallel beta-sheet sandwiched between two alpha-helical bundles. The Walker A motif, (32)GLSASGKS(39), formed the predicted P-loop structure. Superposition of the APS kinase active site region onto several other P-loop-containing proteins revealed that the conserved aspartate residue that usually interacts with the Mg(2+) coordination sphere of MgATP is absent in APS kinase. However, upon MgATP binding, a different aspartate, Asp 61, could shift and bind to the Mg(2+). The sequence (156)KAREGVIKEFT(166), which has been suggested to be a (P)APS motif, is located in a highly protease-susceptible loop that is disordered in both subunits of the free enzyme. MgATP or MgADP protects against proteolysis; APS alone has no effect but augments the protection provided by MgADP. The results suggest that the loop lacks a fixed structure until MgATP or MgADP is bound. The subsequent conformational change together with the potential change promoted by the interaction of MgATP with Asp 61 may define the APS binding site. This model is consistent with the obligatory ordered substrate binding sequence (MgATP or MgADP before APS) as established from steady state kinetics and equilibrium binding studies.

Adenosine 5'-phosphosulfate (APS) kinase: diagnosing the mechanism of substrate inhibition.

Adenosine 5'-phosphosulfate (APS) kinase is subject to strong substrate inhibition by APS. The inhibition has been variously reported to be uncompetitive with respect to MgATP (resulting from the formation of a dead-end E. APS. MgADP complex) or competitive with MgATP (resulting from the formation of a dead-end E. APS complex). It is shown that these two types of substrate inhibition can be differentiated for ordered kinetic mechanisms by simple inspection of the v versus [APS] plots at different fixed concentrations of MgATP. Linear diagnostic plots are unnecessary. One diagnostic feature is the changing position of [APS]opt, the concentration of APS that yields the peak velocity. In the uncompetitive system, [APS]opt decreases asymptotically to a limit as the fixed [MgATP] is increased, while in the competitive system, [APS]opt increases continuously as the fixed [MgATP] is increased. A second (and more easily discerned) diagnostic feature is that, at any given inhibitory level of APS, enzyme activity relative to the velocity at [APS]opt (v/vopt) decreases as the fixed [MgATP] is increased in the uncompetitive system, while in the competitive system the relative activity increases as the fixed [MgATP] is increased. Normalized plots of v/vopt versus [APS] clearly display these distinguishing characteristics. The method confirmed that Penicillium chrysogenum APS kinase exhibits uncompetitive inhibition by APS.

Adenosine 5'-phosphosulfate kinase from Penicillium chrysogenum. site-directed mutagenesis at putative phosphoryl-accepting and ATP P-loop residues.

The properties of Penicillium chrysogenum adenosine 5'-phosphosulfate (APS) kinase mutated at Ser-107 were examined. Ser-107 is analogous to a serine of the E. coli enzyme that has been shown to serve as an intermediate acceptor in the transfer of a phosphoryl group from ATP to APS. Replacement of Ser-107 with alanine yielded an active enzyme with kinetic characteristics similar to those of wild-type APS kinase. Another mutant form of the enzyme in which Ser-107 was replaced by cysteine was also active. Covalent modification of Cys-107 eliminated catalytic activity, and substrates protected against modification. Mutation of Ser-97, of Ser-99, of Thr-103, of Ser-104 to alanine, or of Tyr-109 to phenylalanine also yielded an active enzyme. The cumulative results indicate that Ser-107 may reside in the substrate binding pocket of fungal APS kinase, but neither it nor any nearby hydroxy amino acid serves as an obligatory phophoryl acceptor in the 3'-phosphoadenylylsulfate synthesis reaction. The results also indicate that the absence of a serine at position 478 in the APS kinase-like C-terminal region of fungal ATP sulfurylase does not account for the lack of APS kinase activity in that enzyme. However, mutating the ATP P-loop residues in APS kinase to those found in the analogous C-terminal region of fungal ATP sulfurylase eliminated enzyme activity.