Hiroko Kondo

Free-energy landscapes of protein domain movements upon ligand binding.

The conformation and functions of proteins are closely linked, and many proteins undergo conformational changes upon ligand binding. The X-ray crystallographic studies have revealed conformational differences in proteins between the liganded and unliganded states. Currently, the conformational transitions that originate in the ligand binding are explained on the basis of two representative models, the induced-fit and preexisting equilibrium dynamics models. However, the actual dynamics of the proteins remain ambiguous. Though these two models are the extreme ones, it is important to understand the difference between these two, particularly in structural biology and medicinal chemistry studies. Here, we clarified the difference in the mechanisms responsible for the conformational changes induced in two proteins upon ligand binding by examining computationally determined free-energy profiles of the apo- and holoproteins. The lysine/arginine/ornithine-binding protein and maltose/maltodextrin-binding protein were chosen as the target proteins, and the energy profiles were generated by a molecular simulation approach. Our results revealed that fluctuations in the apo state and protein-ligand interactions both play important roles in conformational transition, and the mechanism is highly influenced by the fluctuations in the apo state, which are unique to a particular structure.

Enhanced exchange algorithm without detailed balance condition for replica exchange method

The replica exchange method (REM) is a powerful tool for the conformational sampling of biomolecules. In this study, we propose an enhanced exchange algorithm for REM not meeting the detailed balance condition (DBC), but satisfying the balance condition in all considered exchanges between two replicas. Breaking the DBC can minimize the rejection rate and make an exchange process rejection-free as the number of replicas increases. To enhance the efficiency of REM, all possible pairs--not only the nearest neighbor--were considered in the exchange process. The test simulations of the alanine dipeptide confirmed the correctness of our method. The average traveling distance of each replica in the temperature distribution was also increased in proportion to an increase in the exchange rate. Furthermore, we applied our algorithm to the conformational sampling of the 10-residue miniprotein, chignolin, with an implicit solvent model. The results showed a faster convergence in the calculation of its free energy landscape, compared to that achieved using the normal exchange method of adjacent pairs. This algorithm can also be applied to the conventional near neighbor method and is expected to reduce the required number of replicas.

Structural basis for the membrane association of ankyrinG via palmitoylation.

By clustering various ion channels and transporters, ankyrin-G (AnkG) configures the membrane-excitation platforms in neurons and cardiomyocytes. AnkG itself localizes to specific areas on the plasma membrane via s-palmitoylation of Cys. However, the structural mechanism by which AnkG anchors to the membrane is not understood. In this study, we solved the crystal structures of the reduced and oxidized forms of the AnkG s-palmitoylation domain and used multiple long-term coarse-grained molecular dynamics simulations to analyze their membrane association. Here we report that the membrane anchoring of AnkG was facilitated by s-palmitoylation, defining a stable binding interface on the lipid membrane, and that AnkG without s-palmitoylation also preferred to stay near the membrane but did not have a unique binding interface. This suggests that AnkG in the juxtamembrane region is primed to accept lipid modification at Cys, and once that happens AnkG constitutes a rigid structural base upon which a membrane-excitation platform can be assembled.

Zn2+-Binding to the Voltage-Gated Proton Channel Hv1/VSOP

The voltage-gated proton channel (Hv1/VSOP) is inhibited by Zn2+, of which the binding site is located in the extracellular region. We utilized attenuated total reflection-Fourier transform infrared (ATR-FTIR) spectroscopy to examine the coordination structure by monitoring protein structural changes induced by Zn2+-binding. The Zn2+-induced difference ATR-FTIR spectra of Hv1 showed IR features that can be assigned to the histidine C5-N1 and carboxylate-COO- stretches as well as amide I changes likely in α-helical peptide bonds. Analysis of vibrational frequencies indicated that the Zn2+ is coordinated by the anionic carboxylate with monodentate mode and by the histidine at N1 (Nτ) position of the neutral imidazole form. Combined with quantum chemical calculations, the most probable coordination structure was proposed as a tetrahedral geometry with ligands of carboxylate and imidazole groups in addition to a water molecule.

The evolutionary process of mammalian sex determination genes focusing on marsupial SRYs

BackgroundMaleness in mammals is genetically determined by the Y chromosome. On the Y chromosome SRY is known as the mammalian male-determining gene. Both placental mammals (Eutheria) and marsupial mammals (Metatheria) have SRY genes. However, only eutherian SRY genes have been empirically examined by functional analyses, and the involvement of marsupial SRY in male gonad development remains speculative.ResultsIn order to demonstrate that the marsupial SRY gene is similar to the eutherian SRY gene in function, we first examined the sequence differences between marsupial and eutherian SRY genes. Then, using a parsimony method, we identify 7 marsupial-specific ancestral substitutions, 13 eutherian-specific ancestral substitutions, and 4 substitutions that occurred at the stem lineage of therian SRY genes. A literature search and molecular dynamics computational simulations support that the lineage-specific ancestral substitutions might be involved with the functional differentiation between marsupial and eutherian SRY genes. To address the function of the marsupial SRY gene in male determination, we performed luciferase assays on the testis enhancer of Sox9 core (TESCO) using the marsupial SRY. The functional assay shows that marsupial SRY gene can weakly up-regulate the luciferase expression via TESCO.ConclusionsDespite the sequence differences between the marsupial and eutherian SRY genes, our functional assay indicates that the marsupial SRY gene regulates SOX9 as a transcription factor in a similar way to the eutherian SRY gene. Our results suggest that SRY genes obtained the function of male determination in the common ancestor of Theria (placental mammals and marsupials). This suggests that the marsupial SRY gene has a function in male determination, but additional experiments are needed to be conclusive.

Structural insight of zinc binding of Hv1/VSOP in resting state

Atsushi Nakagawa1, Masayo Iwaki2, Hideki Kandori2, Hiroko Kondo3, Yasushige Yonezawa4, Yu Takano3, Hiroki Arima5, Yuichiro Fujiwara5, Kohei Takeshita1, Yasushi Okamura5 1Institute For Protein Research, Osaka University, Suita, Japan, 2Department of Frontier Materials, Nagoya Institute of Technology, Nagoya, Japan, 3Graduate School of Information Sciences, Hiroshima City University, Hiroshima, Japan, 4Institute of Advanced Technology, Kindai University, Kinokawa, Japan, 5Graduate School of Medicine, Osaka University, Suita, Japan E-mail: atsushi@protein.osaka-u.ac.jp