Crystal structure analysis and molecular dynamics simulations of arginase from Thermus thermophilus.

Arginase is a manganese-dependent metalloenzyme that catalyzes the hydrolysis of L-arginine to L-ornithine and urea. The product L-ornithine is an important component which has wide applications in the healthcare and pharmaceutical industry. Enzymatic biosynthesis of L-ornithine is one of the effective methods in which arginase is used as a bio-catalyst. Here, we report the crystal structure of arginase from Thermus thermophilus (TtArginase) in three different crystal forms. All structures were solved by molecular replacement and refined at 2.0 Å, 2.3 Å and 2.91 Å resolution respectively. TtArginase is compared with other structural homologs and the putative catalytic site residues were identified. To understand the thermophilic nature of TtArginase, the sequence and structural factors of TtArginase was compared with its mesophilic counterpart Bacillus subtilis arginase (BsArginase). To get insights on structural stability, molecular dynamics (MD) simulations were carried for TtArginase and BsArginase at three different temperatures (300 K, 333 K and 353 K). The results indicate that TtArginase is comparatively more stable than BsArginase. MD simulations were carried out in the absence of the metal ions at the active site which revealed high plasticity of the active site. The results suggest that metal ions are critical not only for the catalytic function, but also required for the maintenance of the proper active site geometry. Since arginase can be employed for large-scale industrial production of L-ornithine, the structural details of thermophilic arginases such as TtArginase will be helpful to engineer the protein to optimize its enzymatic action in a variety of conditions.Communicated by Ramaswamy H. Sarma.

Crystal structure analysis of pyrrolidone carboxyl peptidase from Thermus thermophilus.

Pyrrolidone carboxyl peptidase (PCP) hydrolytically removes the L-pyroglutamic acid from the amino terminal region of pyroglutamyl proteins or peptides. So far, only a limited number of structures of PCP have been solved. Here we report the crystal structure of pyrrolidone carboxyl peptidase from Thermus thermophilus (TtPCP) which has been solved using the molecular replacement method and refined at 1.9 Å resolution. TtPCP follows the α/ß/α architecture in which the central ß-sheets are surrounded by α-helices on both sides. The inter subunit contact between two monomers consists of two short antiparallel ß-strands and part of a long protrusion loop. By comparing the TtPCP with its structural homologs, we identified the putative catalytic triad residues as Glu76, Cys139 and His160. A unique disulfide link found in some homologs of TtPCP, formed between two monomers that provide thermal stability to the protein, is not observed in TtPCP. Hence, being a thermophilic protein, the putative thermal stability of TtPCP could be due to more intra and inter-molecular hydrogen bonds, hydrophobic and ion pair interactions when compared with its mesophilic counterpart. The structural details of TtPCP will be helpful to understand the basis of the intrinsic stability of thermophilic proteins. Also, it could be useful for protein engineering.

Structural and functional characterization of a putative carbonic anhydrase from Geobacillus kaustophilus reveals its cambialistic function.

Carbonic anhydrases (CA) are the most ubiquitous ancient zinc metalloenzymes known. Here we report the structural and functional analysis of a hypothetical protein GK2848 from Geobacillus kaustophilus. The analysis revealed that it belongs to the γ-class of CA (termed as Cag). Only a limited number of γ-class CA's have been characterized till date. Interestingly Cag contains magnesium at its active site instead of a traditional zinc ion. Based on the structural and sequence comparison with similar γ-CA's the putative active site residues of Cag were identified. This analysis revealed that an important catalytic residue and a proton shuttle residue (Glu62 and Glu84 respectively) of Cam (previously characterized γ-CA from Methanosarcina thermophila) are absent in Cag, however certain other active site residues are conserved both in Cag and Cam. This suggests that Cag uses a different set of residues for the reversible hydration of CO2 to HCO3- when compared with Cam. Inductively Coupled Plasma - Optical Emission Spectrometry (ICP-OES) and 25Mg and 67Zn NMR studies on Cag and its mutants revealed that either Mg or Zn can occupy the active site which suggests the cambialistic nature of the enzyme.

The crystal structures of Thermus thermophilus CMP kinase complexed with a phosphoryl group acceptor and donor.

Nucleoside monophosphate kinases play crucial roles in biosynthesis and regeneration of nucleotides. These are bi-substrate enzymes that catalyze reversible transfers of a phosphoryl group between ATP and nucleoside monophosphate. These enzymes are comprised of the CORE domain, the NMP-binding domain, and the LID domain. Large conformational rearrangement of the three domains occurs during the catalytic cycle. Although many structures of CMP kinase have been determined, only limited structural information has been available on the conformational changes along the reaction pathway. We determined five crystal structures of CMP kinase of Thermus thermophilus HB8 in ligand-free form and the CMP "open", CMP "closed", ADP-CDP-Gd3+-, and CDP-bound forms at resolutions of 1.7, 2.2, 1.5, 1.6, and 1.7 Å, respectively. The ligand-free form was in an open conformation, whereas the structures of the CMP "closed", ADP-CDP-Gd3+-, and CDP-bound forms were in a closed conformation, in which the shift of the NMP-binding domain and LID domain caused closure of the substrate-binding cleft. Interestingly, the CMP "open" form was in an open conformation even with CMP bound, implying intrinsic conformational fluctuation. The structure of the ADP-CDP complex is the first structure of CMP kinase with a phosphoryl group donor and an acceptor. Upon simultaneous binding of ADP and CDP, the side chains of several residues in the LID domain moved toward the nucleotides without global open-closed conformational changes compared to those in the CMP "closed" and CDP complexes. These global and local conformational changes may be crucial for the substrate recognition and catalysis. The terminal phosphate groups of ADP and CDP had similar geometry to those of two ADP in AMP kinase, suggesting common catalytic mechanisms to other nucleoside monophosphate kinases. Our findings are expected to contribute to detailed understanding of the reaction mechanism of CMP kinase.

Resistance to UV Irradiation Caused by Inactivation of nurA and herA Genes in Thermus thermophilus.

NurA and HerA are thought to be essential proteins for DNA end resection in archaeal homologous recombination systems. Thermus thermophilus, an extremely thermophilic eubacterium, has proteins that exhibit significant sequence similarity to archaeal NurA and HerA. To unveil the cellular function of NurA and HerA in T. thermophilus, we performed phenotypic analysis of disruptant mutants of nurA and herA with or without DNA-damaging agents. The nurA and herA genes were not essential for survival, and their deletion had no effect on cell growth and genome integrity. Unexpectedly, these disruptants of T. thermophilus showed increased resistance to UV irradiation and mitomycin C treatment. Further, these disruptants and the wild type displayed no difference in sensitivity to oxidative stress and a DNA replication inhibitor. T. thermophilus NurA had nuclease activity, and HerA had ATPase. The overexpression of loss-of-function mutants of nurA and herA in the respective disruptants showed no complementation, suggesting their enzymatic activities were involved in the UV sensitivity. In addition, T. thermophilus NurA and HerA interacted with each other in vitro and in vivo, forming a complex with 2:6 stoichiometry. These results suggest that the NurA-HerA complex has an architecture similar to that of archaeal counterparts but that it impairs, rather than promotes, the repair of photoproducts and DNA cross-links in T. thermophilus cells. This cellular function is distinctly different from that of archaeal NurA and HerA.IMPORTANCE Many nucleases and helicases are engaged in homologous recombination-mediated DNA repair. Previous in vitro analyses in archaea indicated that NurA and HerA are the recombination-related nuclease and helicase. However, their cellular function had not been fully understood, especially in bacterial cells. In this study, we performed in vivo analyses to address the cellular function of nurA and herA in an extremely thermophilic bacterium, Thermus thermophilus As a result, T. thermophilus NurA and HerA exhibited an interfering effect on the repair of several instances of DNA damage in the cell, which is in contrast to the results in archaea. This finding will facilitate our understanding of the diverse cellular functions of the recombination-related nucleases and helicases.

Indispensable residue for uridine binding in the uridine-cytidine kinase family.

Uridine-cytidine kinase (UCK), including human UCK2, are a family of enzymes that generally phosphorylate both uridine and cytidine. However, UCK of Thermus thermophilus HB8 (ttCK) phosphorylates only cytidine. This cytidine-restricted activity is thought to depend on Tyr93, although the precise mechanism remains unresolved. Exhaustive mutagenesis of Tyr93 in ttCK revealed that the uridine phosphorylation activity was restored only by replacement of Tyr93 with His or Gln. Replacement of His117 in human UCK2, corresponding to residue Tyr93 in ttCK, by Tyr resulted in a loss of uridine phosphorylation activity. These findings indicated that uridine phosphorylation activity commonly depends on a single residue in the UCK family.

Crystal structure and DNA-binding property of the ATPase domain of bacterial mismatch repair endonuclease MutL from Aquifex aeolicus.

DNA mismatch repair (MMR) system corrects mismatched bases that are generated mainly by DNA replication errors. The repair system excises the error-containing single-stranded region and enables the re-synthesis of the strand. In the early reactions of MMR, MutL endonuclease incises the newly-synthesized/error-containing strand of the duplex to initiate the downstream excision reaction. MutL endonuclease consists of the N-terminal ATPase and C-terminal endonuclease domains. In this study, we report the crystal structure of the ATPase domain of MutL endonuclease from Aquifex aeolicus. The overall structure of the domain was similar to those of human MutL homologs and Escherichia coli MutL, although E. coli MutL has no endonuclease activity. The ATPase domain was comprised of two subdomains: the N-terminal ATP-binding subdomain and the C-terminal α-ß sandwich subdomain. Site-directed mutagenesis experiment identified DNA-interacting eight basic amino acid residues, which were distributed across both the two subdomains and formed a DNA-binding cleft. Docking simulation between the structures of the ATPase and endonuclease domains generated a reliable model structure for the full-length A. aeolicus MutL, which satisfies our previous result of small-angle X-ray scattering analysis. On the basis of the model structure and further experimental results, we concluded that the two separate DNA-binding sites in the full-length A. aeolicus MutL simultaneously bind a dsDNA molecule.

Crystal structure of Aquifex aeolicus gene product Aq1627: a putative phosphoglucosamine mutase reveals a unique C-terminal end-to-end disulfide linkage.

The Aq1627 gene from Aquifex aeolicus, a hyperthermophilic bacterium has been cloned and overexpressed in Escherichia coli. The protein was purified to homogeneity and its X-ray crystal structure was determined to 1.3 Å resolution using multiple wavelength anomalous dispersion phasing. The structural and sequence analysis of Aq1627 is suggestive of a putative phosphoglucosamine mutase. The structural features of Aq1627 further indicate that it could belong to a new subclass of the phosphoglucosamine mutase family. Aq1627 structure contains a unique C-terminal end-to-end disulfide bond, which links two monomers and this structural information can be used in protein engineering to make proteins more stable in different applications.

The Lon protease-like domain in the bacterial RecA paralog RadA is required for DNA binding and repair.

Homologous recombination (HR) plays an essential role in the maintenance of genome integrity. RecA/Rad51 paralogs have been recognized as an important factor of HR. Among them, only one bacterial RecA/Rad51 paralog, RadA, is involved in HR as an accessory factor of RecA recombinase. RadA has a unique Lon protease-like domain (LonC) at its C terminus, in addition to a RecA-like ATPase domain. Unlike Lon protease, RadA's LonC domain does not show protease activity but is still essential for RadA-mediated DNA repair. Reconciling these two facts has been difficult because RadA's tertiary structure and molecular function are unknown. Here, we describe the hexameric ring structure of RadA's LonC domain, as determined by X-ray crystallography. The structure revealed the two positively charged regions unique to the LonC domain of RadA are located at the intersubunit cleft and the central hole of a hexameric ring. Surprisingly, a functional domain analysis demonstrated the LonC domain of RadA binds DNA, with site-directed mutagenesis showing that the two positively charged regions are critical for this DNA-binding activity. Interestingly, only the intersubunit cleft was required for the DNA-dependent stimulation of ATPase activity of RadA, and at least the central hole was essential for DNA repair function. Our data provide the structural and functional features of the LonC domain and their function in RadA-mediated DNA repair.

Crystal structure analysis of a hypothetical protein (MJ0366) from Methanocaldococcus jannaschii revealed a novel topological arrangement of the knot fold.

The crystal structure of a hypothetical protein MJ0366, derived from Methanocaldococcus jannaschii was solved at 1.9 Å resolution using synchrotron radiation. MJ0366 was crystallized as a monomer and has knot structural arrangement. Intriguingly, the solved structure consists of novel 'KNOT' fold conformation. The 31 trefoil knot was observed in the structure. The N-terminal and C-terminal ends did not participate in knot formation.

Proteome-wide identification of lysine propionylation in thermophilic and mesophilic bacteria: Geobacillus kaustophilus, Thermus thermophilus, Escherichia coli, Bacillus subtilis, and Rhodothermus marinus.

Recent studies have revealed the physiological significance of post-translational lysine acylations such as acetylation in the regulation of various cellular processes. Here, we characterized lysine propionylation, a recently discovered post-translational acylation, in five representative bacteria: Geobacillus kaustophilus, Thermus thermophilus, Escherichia coli, Bacillus subtilis, and Rhodothermus marinus. Using antibody-based propionyl peptide enrichment followed by identification with nano-liquid chromatography tandem mass spectrometry, we showed that proteins were subject to lysine propionylation in all five bacterial species analyzed. Notably, many propionylations were identified in the Bacillus-related, thermophilic eubacterium G. kaustophilus, but fewer in the mesophilic eubacterium B. subtilis, suggesting that propionylation event abundance is independent of phylogenetic relationship. We further found propionylation sites in the thermophilic eubacterium T. thermophilus, but the thermophilic eubacterium R. marinus showed the fewest number of sites, indicating that growth temperature is not a determinant of propionylation state. In silico analyses demonstrated that lysine propionylation is related to metabolic pathways, particularly those controlled by acyl-CoA synthetases, similar to lysine acetylation. We also detected dozens of propionylation sites at positions important for protein functions across bacteria, demonstrating the regulatory mechanisms affected by lysine propionylations. Our proteome-wide analyses across bacteria thus provide insights into the general functions of lysine propionylation.

Proteome-wide identification of lysine succinylation in thermophilic and mesophilic bacteria.

Lysine succinylation, one of post-translational acylations conserved from eukaryotes to bacteria, plays regulatory roles in various cellular processes. However, much remains unknown about the general and specific characteristics of lysine succinylation among bacteria, and about its functions different from those of other acylations. In this study, we characterized lysine succinylation, a newly discovered widespread type of lysine acylation in five bacterial species with different characteristics such as optimal growth temperature and cell wall structure. This study is the first to demonstrate that succinylation is general phenomenon occurring not only in mesophiles but also in thermophiles. Mapping of succinylation sites on protein structures revealed that succinylation occurs at many lysine residues important for protein function. Comparison of the succinylation sites in the five bacterial species provides insights regarding common protein regulation mechanisms utilizing lysine succinylation. Many succinylation sites were conserved among five bacteria, especially between Geobacillus kaustophilus and Bacillus subtilis, some of which are functionally important sites. Furthermore, systematic comparison of the succinyl-proteome results and our previous propionyl-proteome results showed that the abundance of these two types of acylations is considerably different among the five bacteria investigated. Many succinylation and propionylation events were detected in G. kaustophilus, whereas Escherichia coli and B. subtilis exhibited high succinylation and low propionylation; low succinylation and high propionylation were identified in Thermus thermophilus, and low succinylation and propionylation were observed in Rhodothermus marinus. Comparison of the characteristics of lysine succinylation and lysine propionylation suggested these two types of acylation play different roles in cellular processes.

Molecular mechanisms of substrate specificities of uridinecytidine kinase.

A uridine-cytidine kinase (UCK) catalyzes the phosphorylation of uridine (Urd) and cytidine (Cyd) and plays a significant role in the pyrimidine-nucleotide salvage pathway. Unlike ordinary ones, UCK from Thermus thermophilus HB8 (ttCK) loses catalytic activity on Urd due to lack of a substrate binding ability and possesses an unusual amino acid, i.e. tyrosine 93 (Tyr93) at the binding site, whereas histidine (His) is located in the other UCKs. Mutagenesis experiments revealed that a replacement of Tyr93 by His or glutamine (Gln) recovered catalytic activity on Urd. However, the detailed molecular mechanism of the substrate specificity has remained unclear. In the present study, we performed molecular dynamics simulations on the wild-type ttCK, two mutant ttCKs, and a human UCK bound to Cyd and three protonation forms of Urd to elucidate their substrate specificity. We found three residues, Tyr88, Tyr/His/Gln93 and Arg152 in ttCKs, are important for recognizing the substrates. Arg152 contributes to induce a closed form of the binding site to retain the substrate, and the N3 atom of Urd needed to be deprotonated. Although Tyr88 tightly bound Cyd, it did not sufficiently bind Urd because of lack of the hydrogen bonding. His/Gln93 complemented the interaction of Tyr88 and raised the affinity of ttCK to Urd. The crucial distinction between Tyr and His or Gln was a role in the hydrogen-bonding network. Therefore, the ability to form both hydrogen-bonding donor and accepter is required to bind both Urd and Cyd.

Crystal structures of a subunit of the formylglycinamide ribonucleotide amidotransferase, PurS, from Thermus thermophilus, Sulfolobus tokodaii and Methanocaldococcus jannaschii.

The crystal structures of a subunit of the formylglycinamide ribonucleotide amidotransferase, PurS, from Thermus thermophilus, Sulfolobus tokodaii and Methanocaldococcus jannaschii were determined and their structural characteristics were analyzed. For PurS from T. thermophilus, two structures were determined using two crystals that were grown in different conditions. The four structures in the dimeric form were almost identical to one another despite their relatively low sequence identities. This is also true for all PurS structures determined to date. A few residues were conserved among PurSs and these are located at the interaction site with PurL and PurQ, the other subunits of the formylglycinamide ribonucleotide amidotransferase. Molecular-dynamics simulations of the PurS dimer as well as a model of the complex of the PurS dimer, PurL and PurQ suggest that PurS plays some role in the catalysis of the enzyme by its bending motion.

A putative adenosine kinase family protein possesses adenosine diphosphatase activity.

Adenosine kinase is a potential target for development of new types of drugs. The COG1839 family has been defined as "adenosine-specific kinase" family based on structural analysis and the adenosine-binding ability of a family member, PAE2307. However, there has been no experimental evidence with regard to the enzymatic function of this protein family. Here we measured the enzymatic activity of TTHA1091, a COG1839 family protein from Thermus thermophilus HB8. The phosphorylation of adenosine by TTHA1091 was undetectable when ATP or ADP were used as phosphate donor. However, the degradation of ADP to AMP was detected, indicating that this protein possessed adenosine diphosphatase (ADPase) activity. The (ADPase) activity was inhibited by divalent cations and was specific to ADP and CDP. Thus, this study provides the first experimental evidence for the enzymatic function of the "adenosine-specific kinase" family and suggests a need to reexamine its functional annotation.

Crystal structure of a hypothetical protein, TTHA0829 from Thermus thermophilus HB8, composed of cystathionine-ß-synthase (CBS) and aspartate-kinase chorismate-mutase tyrA (ACT) domains.

TTHA0829 from Thermus thermophilus HB8 has a molecular mass of 22,754 Da and is composed of 210 amino acid residues. The expression of TTHA0829 is remarkably elevated in the latter half of logarithmic growth phase. TTHA0829 can form either a tetrameric or dimeric structure, and main-chain folding provides an N-terminal cystathionine-ß-synthase (CBS) domain and a C-terminal aspartate-kinase chorismate-mutase tyrA (ACT) domain. Both CBS and ACT are regulatory domains to which a small ligand molecule can bind. The CBS domain is found in proteins from organisms belonging to all kingdoms and is observed frequently as two or four tandem copies. This domain is considered as a small intracellular module with a regulatory function and is typically found adjacent to the active (or functional) site of several enzymes and integral membrane proteins. The ACT domain comprises four ß-strands and two α-helices in a ßαßßαß motif typical of intracellular small molecule binding domains that help control metabolism, solute transport and signal transduction. We discuss the possible role of TTHA0829 based on its structure and expression pattern. The results imply that TTHA0829 acts as a cell-stress sensor or a metabolite acceptor.

A specific single-stranded DNA induces a distinct conformational change in the nucleoid-associated protein HU.

In prokaryotic cells, genomic DNA forms an aggregated structure with various nucleoid-associated proteins (NAPs). The functions of genomic DNA are cooperatively modulated by NAPs, of which HU is considered to be one of the most important. HU binds double-stranded DNA (dsDNA) and serves as a structural modulator in the genome architecture. It plays important roles in diverse DNA functions, including replication, segregation, transcription and repair. Interestingly, it has been reported that HU also binds single-stranded DNA (ssDNA) regardless of sequence. However, structural analysis of HU with ssDNA has been lacking, and the functional relevance of this binding remains elusive. In this study, we found that ssDNA induced a significant change in the secondary structure of Thermus thermophilus HU (TtHU), as observed by analysis of circular dichroism spectra. Notably, this change in secondary structure was sequence specific, because the complementary ssDNA or dsDNA did not induce the change. Structural analysis using nuclear magnetic resonance confirmed that TtHU and this ssDNA formed a unique structure, which was different from the previously reported structure of HU in complex with dsDNA. Our data suggest that TtHU undergoes a distinct structural change when it associates with ssDNA of a specific sequence and subsequently exerts a yet-to-be-defined function.

Crystal structures and ligand binding of PurM proteins from Thermus thermophilus and Geobacillus kaustophilus.

Crystal structures of 5-aminoimidazole ribonucleotide (AIR) synthetase, also known as PurM, from Thermus thermophilus (Tt) and Geobacillus kaustophilus (Gk) were determined. For TtPurM, the maximum resolution was 2.2 Å and the space group was P21212 with four dimers in an asymmetric unit. For GkPurM, the maximum resolution was 2.2 Å and the space group was P21212 with one monomer in asymmetric unit. The biological unit is dimer for both TtPurM and GkPurM and the dimer structures were similar to previously determined structures of PurM in general. For TtPurM, ∼50 residues at the amino terminal were disordered in the crystal structure whereas, for GkPurM, the corresponding region covered the ATP-binding site forming an α helix in part, suggesting that the N-terminal region of PurM changes its conformation upon binding of ligands. FGAM binding site was predicted by the docking simulation followed by the MD simulation based on the SO4 (2-) binding site found in the crystal structure of TtPurM.

Structural and Biochemical Studies on the Reaction Mechanism of Uridine-Cytidine Kinase.

Uridine-cytidine kinase catalyzes phosphorylation of the pyrimidine nucleosides uridine and cytidine and plays an important role in nucleotide metabolism. However, the detailed molecular mechanism of these reactions remains to be elucidated. Here, we determined the structure of the ternary complex of Uridine-cytidine kinase from Thermus thermophilus HB8 with both cytidine and ß,γ-methyleneadenosine 5'-triphosphate, a non-hydrolysable ATP analogue. Substrate binding is accompanied by substantial domain movement that allows the substrate-binding cleft to close. The terminal phosphodiester bond of the ATP analogue is in an ideal location for an inline attack of the 5'-hydroxyl group of cytidine. Asp40 is located near the 5'-hydroxyl group of cytidine. Mutation of this conserved residue to Asn or Ala resulted in a complete loss of enzyme activity, which is consistent with the notion that Asp40 acts as a general base that activates the 5'-hydroxyl group of cytidine. The pH profile of the activity showed an apparent pK a value of 7.4. Based on this structure, a likely mechanism of the catalytic step is discussed.

Crystal structure analysis of ornithine transcarbamylase from Thermus thermophilus --HB8 provides insights on the plasticity of the active site.

The enzymatic biosynthesis of L-arginine involves complex, sequential action of many enzymes and ornithine transcarbamylase (OTCase) is one of the essential enzymes in the pathway. In mammals OTCase is part of the urea cycle. Arginine is used in a variety of pharmaceutical and industrial applications and therefore engineering arginine biosynthesis pathway for overproduction of arginine has gained importance. On the other hand, it was found that detrimental mutations in the human OTCase gene resulted clinical hyperammonemia, with subsequent neurological damage. Therefore a better understanding of the structure-function relationship of this enzyme from various sources could be useful for modifying its enzymatic action. Here we report the structure of ornithine transcarbamylase of Thermus thermophilus HB8 (aTtOTCase) at 2.0 Å resolution. On comparison with its homologs, aTtOTCase showed maximum variation at the substrate binding loops namely 80s and SMG/240s loops. The active site geometry of aTtOTCase is unique among its homologs where the side chain of certain residues (Leu57, Arg58 and Arg288) is oriented differently. To study the structural insights of substrate binding in aTtOTCase, docking of carbamoyl phosphate (CP) and ornithine (Orn) was carried out sequentially. Both substrates were unable to bind in a proper orientation in the active site pocket and this could be due to the differently oriented side chains. This suggests that the active site geometry should also undergo fine tuning besides the large structural changes as the enzyme switches from completely open to a substrate bound closed state.