Young C. Kim

Mechanism of histone lysine methyl transfer revealed by the structure of SET7/9-AdoMet

The methylation of lysine residues of histones plays a pivotal role in the regulation of chromatin structure and gene expression. Here, we report two crystal structures of SET7/9, a histone methyltransferase (HMTase) that transfers methyl groups to Lys4 of histone H3, in complex with S‐adenosyl‐L‐methionine (AdoMet) determined at 1.7 and 2.3 Å resolution. The structures reveal an active site consisting of: (i) a binding pocket between the SET domain and a c‐SET helix where an AdoMet molecule in an unusual conformation binds; (ii) a narrow substrate‐specific channel that only unmethylated lysine residues can access; and (iii) a catalytic tyrosine residue. The methyl group of AdoMet is directed to the narrow channel where a substrate lysine enters from the opposite side. We demonstrate that SET7/9 can transfer two but not three methyl groups to unmodified Lys4 of H3 without substrate dissociation. The unusual features of the SET domain‐containing HMTase discriminate between the un‐ and methylated lysine substrate, and the methylation sites for the histone H3 tail.

Crystal structure of the eIF4A–PDCD4 complex

Tumor suppressor programmed cell death protein 4 (PDCD4) inhibits the translation initiation factor eIF4A, an RNA helicase that catalyzes the unwinding of secondary structure at the 5′-untranslated region of mRNAs and controls the initiation of translation. Here, we determined the crystal structure of the human eIF4A and PDCD4 complex. The structure reveals that one molecule of PDCD4 binds to the two eIF4A molecules through the two different binding modes. While the two MA3 domains of PDCD4 bind to one eIF4A molecule, the C-terminal MA3 domain alone of the same PDCD4 also interacts with another eIF4A molecule. The eIF4A–PDCD4 complex structure suggests that the MA3 domain(s) of PDCD4 binds perpendicular to the interface of the two domains of eIF4A, preventing the domain closure of eIF4A and blocking the binding of RNA to eIF4A, both of which are required events in the function of eIF4A helicase. The structure, together with biochemical analyses, reveals insights into the inhibition mechanism of eIF4A by PDCD4 and provides a framework for designing chemicals that target eIF4A.

Replica exchange simulations of transient encounter complexes in protein–protein association

Recent paramagnetic relaxation enhancement (PRE) studies on several weakly interacting protein complexes have unequivocally demonstrated the existence of transient encounter complexes. Here, we present a computational method to study protein–protein binding by creating equilibrium ensembles that include both specific and nonspecific protein complexes. In a joint analysis of simulation and experiment we explore the physical nature and underlying physicochemical characteristics of encounter complexes involving three protein–protein interactions of the bacterial phosphotransferase system. Replica exchange Monte Carlo simulations using a coarse-grained energy function recover the structures of the specific complexes and produce binding affinities in good agreement with experiment. Together with the specific complex, a relatively small number of distinct nonspecific complexes largely accounts for the measured PRE data. The combined relative population of the latter is less than ∼10%. The binding interfaces of the specific and nonspecific complexes differ primarily in size but exhibit similar amino acid compositions. We find that the overall funnel-shaped energy landscape of complex formation is dominated by the specific complex, a small number of structured nonspecific complexes, and a diffuse cloud of loosely bound complexes connecting the specific and nonspecific binding sites with each other and the unbound state. Nonspecific complexes may not only accelerate the binding kinetics by enhancing the rate of success of random diffusional encounters but also play a role in protein function as alternative binding modes.

Kinetic gating of the proton pump in cytochrome c oxidase

Cytochrome c oxidase (CcO), the terminal enzyme of the respiratory chain, reduces oxygen to water and uses the released energy to pump protons across a membrane. Here, we use kinetic master equations to explore the energetic and kinetic control of proton pumping in CcO. We construct models consistent with thermodynamic principles, the structure of CcO, experimentally known proton affinities, and equilibrium constants of intermediate reactions. The resulting models are found to capture key properties of CcO, including the midpoint redox potentials of the metal centers and the electron transfer rates. We find that coarse-grained models with two proton sites and one electron site can pump one proton per electron against membrane potentials exceeding 100 mV. The high pumping efficiency of these models requires strong electrostatic couplings between the proton loading (pump) site and the electron site (heme a), and kinetic gating of the internal proton transfer. Gating is achieved by enhancing the rate of proton transfer from the conserved Glu-242 to the pump site on reduction of heme a, consistent with the predictions of the water-gated model of proton pumping. The model also accounts for the phenotype of D-channel mutations associated with loss of pumping but retained turnover. The fundamental mechanism identified here for the efficient conversion of chemical energy into an electrochemical potential should prove relevant also for other molecular machines and novel fuel-cell designs.

Crystal structure of human Mre11: understanding tumorigenic mutations.

Mre11 plays an important role in repairing damaged DNA by cleaving broken ends and by providing a platform for other DNA repair proteins. Various Mre11 mutations have been identified in several types of cancer. We have determined the crystal structure of the human Mre11 core (hMre11), which contains the nuclease and capping domains. hMre11 dimerizes through the interfaces between loop β3-α3 from one Mre11 and loop β4-β5 from another Mre11, and between loop α2-β3 from one Mre11 and helices α2 and α3 from another Mre11, and assembles into a completely different dimeric architecture compared with bacterial or archaeal Mre11 homologs. Nbs1 binds to the region containing loop α2-β3 which participates in dimerization. The hMre11 structure in conjunction with biochemical analyses reveals that many tumorigenic mutations are primarily associated with Nbs1 binding and partly with nuclease activities, providing a framework for understanding how mutations inactivate Mre11.

Hybrid structural model of the complete human ESCRT-0 complex.

The human Hrs and STAM proteins comprise the ESCRT-0 complex, which sorts ubiquitinated cell surface receptors to lysosomes for degradation. Here we report a model for the complete ESCRT-0 complex based on the crystal structure of the Hrs-STAM core complex, previously solved domain structures, hydrodynamic measurements, and Monte Carlo simulations. ESCRT-0 expressed in insect cells has a hydrodynamic radius of RH = 7.9 nm and is a 1:1 heterodimer. The 2.3 Angstroms crystal structure of the ESCRT-0 core complex reveals two domain-swapped GAT domains and an antiparallel two-stranded coiled-coil, similar to yeast ESCRT-0. ESCRT-0 typifies a class of biomolecular assemblies that combine structured and unstructured elements, and have dynamic and open conformations to ensure versatility in target recognition. Coarse-grained Monte Carlo simulations constrained by experimental RH values for ESCRT-0 reveal a dynamic ensemble of conformations well suited for diverse functions.

Crowding induced entropy-enthalpy compensation in protein association equilibria.

A statistical mechanical theory is presented to predict the effects of macromolecular crowding on protein association equilibria, accounting for both excluded volume and attractive interactions between proteins and crowding molecules. Predicted binding free energies are in excellent agreement with simulation data over a wide range of crowder sizes and packing fractions. It is shown that attractive interactions between proteins and crowding agents counteract the stabilizing effects of excluded volume interactions. A critical attraction strength, for which there is no net effect of crowding, is approximately independent of the crowder packing fraction.

Modest Protein―Crowder Attractive Interactions Can Counteract Enhancement of Protein Association by Intermolecular Excluded Volume Interactions

We study the effects of attractive interactions between spherical crowders and protein residues on the thermodynamics and structure of two weakly binding protein complexes: ubiquitin/UIM1 and cytochrome c/cytochrome c peroxidase. Systematic replica exchange Monte Carlo (REMC) simulations are performed over a range of attraction strengths and crowder packing fractions using a transferable coarse-grained protein binding model. We find that moderate attractive interactions (≈0.2 kcal/mol) between crowders and protein residues can destabilize protein association, and therefore counteract the stabilizing effect of excluded volume interactions. The destabilization of protein binding, as measured by an increase in binding free energy, increases with increasing crowder packing fraction. For a critical attraction strength value, which is found to be approximately independent of crowder packing fraction, the destabilization due to attractions is exactly canceled by the stabilization effect of excluded volume interactions. This results in a net zero change in binding free energy with respect to a crowder-free solution. Further, we find that attractive interactions between crowders and protein residues can favor transiently bound encounter complexes over the native specific complexes in the bound state. We propose a simple theoretical model based on the scaled particle theory augmented by a mean-field attraction term that can explain our simulation results semiquantitatively.

Macromolecular crowding effects on protein–protein binding affinity and specificity

Macromolecular crowding in cells is recognized to have a significant impact on biological function, yet quantitative models for its effects are relatively undeveloped. The influence of crowding on protein-protein interactions is of particular interest, since these mediate many processes in the cell, including the self-assembly of larger complexes, recognition, and signaling. We use a residue-level coarse-grained model to investigate the effects of macromolecular crowding on the assembly of protein-protein complexes. Interactions between the proteins are treated using a fully transferable energy function, and interactions of protein residues with the spherical crowders are repulsive. We show that the binding free energy for two protein complexes, ubiquitin/UIM1 and cytochrome c/cytochrome c peroxidase, decreases modestly as the concentration of crowding agents increases. To obtain a quantitative description of the stabilizing effect, we map the aspherical individual proteins and protein complexes onto spheres whose radii are calculated from the crowder-excluded protein volumes. With this correspondence, we find that the change in the binding free energy due to crowding can be quantitatively described by the scaled particle theory model without any fitting parameters. The effects of a mixture of different-size crowders-as would be found in a real cell-are predicted by the same model with an additivity ansatz. We also obtain the remarkable result that crowding increases the fraction of specific complexes at the expense of nonspecific transient encounter complexes in a crowded environment. This result, due to the greater excluded volume of the nonspecific complexes, demonstrates that macromolecular crowding can have subtle functional effects beyond the relative stability of bound and unbound complexes.

Kinetic models of redox-coupled proton pumping

Cytochrome c oxidase, the terminal enzyme of the respiratory chain, pumps protons across the inner mitochondrial membrane against an opposing electrochemical gradient by reducing oxygen to water. To explore the fundamental mechanisms of such redox-coupled proton pumps, we develop kinetic models at the single-molecule level consistent with basic physical principles. We demonstrate that pumping against potentials >150 mV can be achieved purely through electrostatic couplings, given an asymmetric arrangement of charge centers; however, nonlinear gates are essential for highly efficient real enzymes. The fundamental requirements for proton pumping identified here highlight a possible evolutionary origin of cytochrome c oxidase pumping. The general design principles are relevant also for other molecular machines and suggest future applications in biology-inspired fuel cells.