Synthesis of pyrazole-based hybrid molecules: search for potent multidrug resistance modulators

The hybrid molecules have been designed on the basis of the structural features of pyrazole-based drugs and MDR modulator propafenone. A simple synthetic strategy and solvent-based regioselectivity have been used for the synthesis of newly designed molecules and they are evaluated for their interactions with P-glycoprotein (P-gp). Some of the molecules show considerable interactions with P-gp and compounds 15, 28 and 40 could be the potential candidates for their use as MDR modulators.     

The extracellular loop between TM5 and TM6 of P-glycoprotein is required for reactivity with monoclonal antibody UIC2.

P-glycoprotein (P-gp), encoded by the MDR1 gene, is a plasma membrane transporter which confers resistance to many chemotherapeutic drugs. Monoclonal antibodies raised against P-gp have been used as tools to study P-gp topology and activity. Monoclonal antibody UIC2 recognizes a functional conformation of P-gp on the cell surface and blocks P-gp-mediated drug transport. Knowledge about the UIC2 epitope and the mechanism of its inhibitory effects may be helpful for understanding P-gp structure and developing P-gp inhibitors. In the present work, using several chimeras of MDR1 and MDR2, we found that the native sequence of the predicted extracellular loop between transmembrane domains (TM) 5 and 6 of P-gp is necessary, but not sufficient, for UIC2 reactivity. In addition, UIC2 reactivity is also affected by mutations in TM6, a region known to be involved in interactions of P-gp with substrates. These observations suggest that residues in the extracellular loop between TM5 and TM6 are directly involved in the display of the UIC2 epitope. Since TM6 has been shown to be actively involved in drug transport process, the proximity of this region to TM6 may help to explain why UIC2 binding is sensitive to the functional state of P-gp and why binding of UIC2 inhibits P-gp-mediated drug transport.     

Different modalities of intercellular membrane exchanges mediate cell-to-cell p-glycoprotein transfers in MCF-7 breast cancer cells

Multi-drug resistance (MDR) is a phenomenon by which tumor cells exhibit resistance to a variety of chemically unrelated chemotherapeutic drugs. The classical form of multidrug resistance is connected to overexpression of membrane P-glycoprotein (P-gp), which acts as an energy dependent drug efflux pump. P-glycoprotein expression is known to be controlled by genetic and epigenetic mechanisms. Until now processes of P-gp gene up-regulation and resistant cell selection were considered sufficient to explain the emergence of MDR phenotype within a cell population. Recently, however, "non-genetic" acquisitions of MDR by cell-to-cell P-gp transfers have been pointed out. In the present study we show that intercellular transfers of functional P-gp occur by two different but complementary modalities through donor-recipient cells interactions in the absence of drug selection pressure. P-glycoprotein and drug efflux activity transfers were followed over 7 days by confocal microscopy and flow cytometry in drug-sensitive parental MCF-7 breast cancer cells co-cultured with P-gp overexpressing resistant variants. An early process of remote transfer was established based on the release and binding of P-gp-containing microparticles. Microparticle-mediated transfers were detected after only 4 h of incubation. We also identify an alternative mode of transfer by contact, consisting of cell-to-cell P-gp trafficking by tunneling nanotubes bridging neighboring cells. Our findings supply new mechanistic evidences for the extragenetic emergence of MDR in cancer cells and indicate that new treatment strategies designed to overcome MDR may include inhibition of both microparticles and Tunneling nanotube-mediated intercellular P-gp transfers.     

Semi-quantitative RT-PCR method to estimate full-length mRNA levels of the multidrug resistance gene

Expression levels of P-glycoprotein (P-gp), the transporter encoded by the human multidrug resistance gene (MDR1), may play an important role in drug disposition. The ability to quantitate full-length MDR1 mRNA levels may be predictive of P-gp expression and function. Therefore, a semi-quantitative RT-PCR assay was developed to assess full-length MDR1 mRNA levels. Levels offull-length 3.8-kb MDR1 mRNA were estimated by comparing PCR amplification of the RNA extract with that of an internal standard, deltaMDR1. The 2.9-kb deltaMDR1 competitor RNA standard was constructed by deleting 965 bpfrom the interior of MDR1 mRNA. The full-length MDR1 and deltaMDR1 share identical 5' and 3'primer binding sequences, allowing for their simultaneous amplification in the same RT-PCR. With this approach, MDR1 mRNA levels can be sensitively and reliably estimated with a detection limit of 2000 copies. Full-length MDR1 mRNA levels in various human cell lines and lymphocytes from leukemia patients varied over 100-fold, ranging from 0.3 to 36.5 x 10(5) copies/microg total RNA. The semi-quantitative full-length RT-PCR assay may be useful in estimating MDR1 mRNA levels to assess P-gp expression, which may be important in studying the role of P-gp in drug disposition and cancer chemotherapy efficacy.     

New insights into the P-glycoprotein-mediated effluxes of rhodamines.

Multidrug resistance (MDR) in tumour cells is often caused by the overexpression of the plasma drug transporter P-glycoprotein (P-gp). This protein is an active efflux pump for chemotherapeutic drugs, natural products and hydrophobic peptides. Despite the advances of recent years, we still have an unclear view of the molecular mechanism by which P-gp transports such a wide diversity of compounds across the membrane. Measurement of the kinetic characteristics of substrate transport is a powerful approach to enhancing our understanding of their function and mechanism. The aim of the present study was to further characterize the transport of several rhodamine analogues, either positively charged or zwitterionic. We took advantage of the intrinsic fluorescence of rhodamines and performed a flow-cytometric analysis of dye accumulation in the wild-type drug sensitive K562 that do not express P-gp and its MDR subline that display high levels of MDR. The measurements were made in real time using intact cells. The kinetic parameter, ka = VM/km, which is a measure of the efficiency of the P-gp-mediated efflux of a substrate was similar for almost all the rhodamine analogues tested. In addition these values were compared with those determined previously for the P-gp-mediated efflux of anthracycline. Our conclusion is that the compounds of these two classes of molecules, anthracyclines and rhodamines, are substrates of P-gp and that their pumping rates at limiting low substrate concentration are similar. The findings presented here are the first to show quantitative information about the kinetic parameters for P-gp-mediated efflux of rhodamine analogues in intact cells.     

Clitocine Reversal of P-Glycoprotein Associated Multi-Drug Resistance through Down-Regulation of Transcription Factor NF-κB in R-HepG2 Cell Line

Multidrug resistance(MDR)is one of the major reasons for failure in cancer chemotherapy and its suppression may increase the efficacy of therapy. The human multidrug resistance 1 (MDR1) gene encodes the plasma membrane P-glycoprotein (P-gp) that pumps various anti-cancer agents out of the cancer cell. R-HepG2 and MES-SA/Dx5 cells are doxorubicin induced P-gp over-expressed MDR sublines of human hepatocellular carcinoma HepG2 cells and human uterine carcinoma MES-SA cells respectively. Herein, we observed that clitocine, a natural compound extracted from Leucopaxillus giganteus, presented similar cytotoxicity in multidrug resistant cell lines compared with their parental cell lines and significantly suppressed the expression of P-gp in R-HepG2 and MES-SA/Dx5 cells. Further study showed that the clitocine increased the sensitivity and intracellular accumulation of doxorubicin in R-HepG2 cells accompanying down-regulated MDR1 mRNA level and promoter activity, indicating the reversal effect of MDR by clitocine. A 5'-serial truncation analysis of the MDR1 promoter defined a region from position -450 to -193 to be critical for clitocine suppression of MDR1. Mutation of a consensus NF-κB binding site in the defined region and overexpression of NF-κB p65 could offset the suppression effect of clitocine on MDR1 promoter. By immunohistochemistry, clitocine was confirmed to suppress the protein levels of both P-gp and NF-κB p65 in R-HepG2 cells and tumors. Clitocine also inhibited the expression of NF-κB p65 in MES-SA/Dx5. More importantly, clitocine could suppress the NF-κB activation even in presence of doxorubicin. Taken together; our results suggested that clitocine could reverse P-gp associated MDR via down-regulation of NF-κB.     

Suppression of multidrug resistance by treatment with TRAIL in human ovarian and breast cancer cells with high level of c-Myc

In this study, we investigated the role of c-Myc in overcoming multidrug resistance (MDR) in human ovarian and breast cancer cells by TRAIL. We showed that P-gp expressing MDR variants (Hey A8-MDR and MCF7-MDR cells) with high level of c-Myc were highly susceptible to TRAIL treatment when compared to their drug-sensitive parental human ovarian cancer Hey A8 and breast MCF-7 cells, respectively. Up-regulation of DR5 TRAIL receptor and down-regulation of c-FLIP and the promotion of caspase-dependent cell death, which contribute to TRAIL sensitization of MDR cells, were regulated by the over-expressed c-Myc in the MDR cells. After targeted inhibition of c-Myc with specific siRNA, these responses to TRAIL disappeared and TRAIL-induced apoptosis was also suppressed in MCF7-MDR cells. Treatment with TRAIL significantly reduced P-glycoprotein (P-gp)-mediated efflux of rhodamine123 in both Hey A8-MDR and MCF7-MDR cells. Furthermore, TRAIL significantly potentiated the cytotoxicity of vinblastine, vincristine, doxorubicin and VP-16 that are P-gp substrate anticancer drugs in both MDR cells, which resulted in the reversal effect of TRAIL on the MDR phenotype. The present study shows for the first time that elevated c-Myc expression in the MDR cells plays a critical role in overcoming MDR by TRAIL that can act as a specific sensitizer for P-gp substrate anticancer drug.     

In vitro activity of novel dual action MDR anthranilamide modulators with inhibitory activity on CYP-450 (Part 2)

Synthesis and in vitro cytotoxicity assays of new anthranilamide MDR modulators have been performed to assess their inhibition potency on the P-glycoprotein (P-gp) transporter. Previous studies showed that the replacement of the aromatic spacer group between nitrogen atoms (N(1) and N(2)) in the P-gp inhibitor XR9576 with ethyl or propyl chain is optimal for P-gp inhibition potency. To confirm that observation, the ethyl or the propyl linker arm was replaced with a pyrrolidine or an alicyclic group such as cyclohexyl. In addition, an arylpiperazinyl group and two methoxyl groups onto the anthranilic part were introduced to assess their effect on the anti P-gp activity. Five molecules were prepared and evaluated on CEM/VLB500. All new anthranilamides were more potent than verapamil, most of them exhibited a lower cytotoxicity than XR9576. Compound 5 was the most potent and its inhibition activity was similar to XR9576. Interestingly, in vitro biotransformation studies of compounds 4 and 5 using human CYP-450 isoforms revealed, that conversely to XR9576, compounds 4 and 5 inhibited CYP3A4, an enzyme that colocalizes with P-gp in the intestine and contributes to tumor cell chemoresistance by enhancing the biodisposition of numerous drugs, notably paclitaxel. In that context, 5 might be suitable for further drug development.     

Phosphorylation of RNA helicase A by DNA-dependent protein kinase is indispensable for expression of the MDR1 gene product P-glycoprotein in multidrug-resistant human leukemia cells

Development of multidrug resistance (MDR) in cancer frequently involves overexpression of the MDR1 gene product P-glycoprotein (P-gp), a drug transporter which severely impedes the efficacy of chemotherapy. Because intensive efforts to identify therapeutics that reverse MDR by inhibiting the drug transport activity of P-gp have not yet met with success, we have focused on the alternative strategy of targeting MDR1 promoter activation to knockdown P-gp expression in cancer cells. We recently identified RNA helicase A (RHA) inhibition as a rational strategy to downregulate P-gp in leukemia cells by showing that RHA RNAi knockdown abrogated P-gp expression in MDR variants of human leukemia HL-60 cells. In that report, we also demonstrated that RHA activated the MDR1 promoter in the MDR variant cells but not in the drug-sensitive counterpart. This led us to hypothesize that P-gp induction by RHA required cooperation with another factor present only in the MDR variants. Here, we identify the RHA cooperating factor as DNA-PK catalytic subunit (cs), and we show that DNA-PKcs resides with RHA at the MDR1 promoter in a multiprotein complex. Furthermore, targeted DNA-PKcs inhibition abrogated P-gp expression in the MDR variant cells. We demonstrate that constitutive multisite RHA phosphorylation producing retarded migration in SDS-PAGE is catalyzed by DNA-PKcs in the MDR variants, and does not occur in the parental cells, which are DNA-PKcs deficient. The indispensable role played by DNA-PK in P-gp overexpression in MDR leukemia cells in this report identifies targeted DNA-PK inhibition as a rational strategy to reverse drug resistance in cancer.     

Biophysical characterization of MDR breast cancer cell lines reveals the cytoplasm is critical in determining drug sensitivity

Dielectrophoresis (DEP) was used to examine a panel of MCF-7 cell lines comprising parental MCF-7 cells and MDR derivatives: MCF-7TaxR (paclitaxel-resistant, P-glycoprotein (P-gp) positive), MCF-7DoxR (doxorubicin-resistant MRP2 positive) plus MCF-7MDR1 (MDR1 transfected, P-gp positive). MCF-7DoxR and MCF-7MDR1 were broadly cross-resistant to natural product anticancer agents, whereas MCF-7TaxR cells were not, contrary to P-gp expression. Whilst DEP revealed modest membrane changes in MDR sub-lines, we saw significant changes in their cytoplasmic conductivity: MCF-7TaxR相似文献   

Isopetasin and S-isopetasin as novel P-glycoprotein inhibitors against multidrug-resistant cancer cells

BackgroundA major problem of cancer treatment is the development of multidrug resistance (MDR) to chemotherapy. MDR is caused by different mechanisms such as the expression of the ABC-transporters P-glycoprotein (P-gp, MDR1, ABCB1) and breast cancer resistance protein (BCRP, ABCG2). These transporters efflux xenobiotic toxins, including chemotherapeutics, and they were found to be overexpressed in different cancer types.PurposeIdentification of novel molecules that overcome MDR by targeting ABC-transporters.MethodsResazurin reduction assay was used for cytotoxicity test. AutoDock 4.2. was used for molecular docking. The function of P-gp and BCRP was tested using a doxorubicin uptake assay and an ATPase assay. ROS generation was detected using flow cytometry for the measurement of H₂DCFH-DA fluorescence. Annexin/PI staining was applied for the detection of apoptosis. Bioinformatic analyses were performed using LigandScout 3.12. software and DataWarrior software.ResultsIn our search for new molecules that selectively act against resistant phenotypes, we identified isopetasin and S-isopetasin, which are bioactive natural products from Petasites formosanus. They exerted collateral sensitivity towards leukemia cells with high P-gp expression in CEM/ADR5000 cells, compared to sensitive wild-type CCRF-CEM leukemia cells. Also, they revealed considerable activity towards breast cancer cells overexpressing breast cancer resistance protein, MDA-MB-231-BCRP clone 23. This motivated us to investigate whether the function of P-gp was inhibited. In-silico results showed the compounds bound with high affinity and interacted with key amino acid residues in P-gp . Then, we found that the two compounds increased doxorubicin accumulation in P-gp overexpressing CEM/ADR5000 by three-fold compared to cells without inhibitor. P-gp-mediated drug efflux was ATP-dependent. Isopetasin and S-isopetasin increased the ATPase activity of human P-gp in a comparable fashion as verapamil used as control P-gp inhibitor. As isopetasin and S-isopetasin exerted dual roles, first as cytotoxic compounds and then as P-gp inhibitors, we suggested that their P-gp inhibition is part of a larger complex of mechanisms to induce cell death in cancer patients. P-gp dysfunction induces mitochondrial stress to generate ATP. Upon continuing stress by P-gp inhibition, the mitochondria generate reactive oxygen species (ROS). Initially established for verapamil, this theory was validated in the present study for isopetasin and S-isopetasin, as treatment with the two candidates increased ROS levels in CEM/ADR5000 cells followed by apoptosis.ConclusionOur study highlights the importance of isopetasin and S-isopetasin as novel ROS-generating and apoptosis-inducing P-gp inhibitors.     

Designed P-glycoprotein inhibitors with triazol-tetrahydroisoquinoline-core increase doxorubicin-induced mortality in multidrug resistant K562/A02 cells

Multidrug resistance (MDR) refers to the cross-resistance of cancer cells to one drug, accompanied by other drugs with different mechanisms and structures, which is one of the main obstacles of clinical chemotherapy. Overexpression of P-glycoprotein (P-gp) was an extensively studied cause of MDR. Therefore, inhibiting P-gp have become an important strategy to reverse MDR. In this study, two series of triazole-tetrahydroisoquinoline-core P-gp inhibitors were designed and synthesized. Among them, compound I-5 had a remarkable reversal activity of MDR activity and the preliminary mechanism study was also carried out. All the results proved that compound I-5 was considered as a promising P-gp-mediated MDR reversal candidate.     

A novel flavonoid from Fissistigma cupreonitens, 5‑hydroxy‑7,8‑dimethoxyflavanone,competitively inhibited the efflux function of human P-glycoprotein and reversed cancer multi-drug resistance

BackgroundP-glycoprotein (P-gp) over-expression plays a vital role in not only systemic drug bioavailability but also cancer multi-drug resistance (MDR). Develop functional inhibitors of P-gp can conquer both problems.Purpose and study designThe aim of the present study was to research the P-gp modulating effects and MDR reversing ability of a novel flavonoid from Fissistigma cupreonitens, the underlying inhibitory mechanisms were further elucidated as well.MethodsCalcein-AM, rhodamine 123, and doxorubicin were fluorescent substrates for the evaluation of P-gp inhibitory function and detailed drug binding modes. Docking simulation was performed to reveal the in silico molecular bonding. ATPase assay and MDR1 shift assay were adopted to reveal the ATP consumption and conformational change of P-gp. The MDR reversing effects were demonstrated through cytotoxicity, cell cycle, and apoptosis analyses.Results5‑hydroxy‑7,8‑dimethoxyflavanone inhibited the efflux of rhodamine 123 and doxorubicin in a competitive manner, and increased the intracellular fluorescence of calcein at a concentration as low as 2.5 μg/ml. 5‑hydroxy‑7,8‑dimethoxyflavanone slightly changed P-gp's conformation and only stimulated ATPase at very high concentration (100 μg/ml). The docking results showed that 5‑hydroxy‑7,8‑dimethoxyflavanone and verapamil exhibited similar binding affinity to P-gp. The MDR reversing effects were prominent in the vincristine group, the reversal folds were 23.01 and 13.03 when combined with 10 μg/ml 5‑hydroxy‑7,8‑dimethoxyflavanone in the P-gp over-expressing cell line (ABCB1/Flp-In™-293) and MDR cancer cell line (KB/VIN), respectively.ConclusionThe present study demonstrated that 5‑hydroxy‑7,8‑dimethoxyflavanone was a novel effective flavonoid in the P-gp efflux inhibition and in vitro cancer MDR reversion.     

Azidopine noncompetitively interacts with vinblastine and cyclosporin A binding to P-glycoprotein in multidrug resistant cells.

It is believed that P-glycoprotein (P-gp) is an energy-dependent drug efflux pump responsible for decreased drug accumulation in multidrug resistant (MDR) cells. In this study, we investigated whether azidopine, a photoactive dihydropyridine calcium channel blocker, is transported by P-gp in MDR Chinese hamster lung cells, DC-3F/VCRd-5L, and whether its binding site(s) on P-gp are distinct from those of Vinca alkaloids and cyclosporins. The efflux of azidopine from MDR cells was energy-dependent and inhibited by the cytotoxic agent vinblastine (VBL). Cyclosporin A (CsA), a modulator of MDR, also increased azidopine accumulation in MDR cells by decreasing the energy-dependent efflux of azidopine. P-gp in these cells was the only protein specifically bound to [3H]azidopine in photoaffinity experiments. The specific photoaffinity labeling of P-gp by [3H]azidopine was inhibited by CsA, SDZ 33-243, nonradioactive azidopine, and VBL with median concentrations (IC50) of 0.5, 0.62, 1.7, and 25 microM, respectively. The equilibrium binding of azidopine to plasma membranes of MDR variant DC-3F/VCRd-5L cells showed a single class of specific binding sites having a dissociation constant of 1.20 microM and a maximum binding capacity of 4.47 nmol/mg of protein. Kinetic analysis indicated that the inhibitory effect of VBL and CsA on azidopine binding to plasma membranes of MDR cells was noncompetitive, indicating that azidopine binds to P-gp at a binding site(s) different from the binding site(s) of these drugs.     

MDR1基因多态性及其临床相关性研究进展

体内外研究证明,人体中P—gP在药物的吸收、分布、代谢和排泄（ADME）过程中发挥了非常重要的作用。多药耐药基因MDR1（ABCB1）是P-gP的编码基因。药物基因组学和遗传药理学研究发现在不同个体中MDR1基因多态性与P—gP表达和功能的改变密切相关,而且这些多态位点存在基因型分布和等位基因频率的种族差异性。近几年,已陆续发现在MDR1基因中有50处单核苷酸多态性（SNPs）和3处插入与缺失多态性。随后,大量文献报道某些位点的SNPs如C3435T会使个体患病的易感性增加。因此人们相信,深入研究MDR1基因多态性与P—gP的生理和生化方面的相关性将对个体医疗有着非常深远的意义。文章总结了国外最新的研究进展并结合本实验室的工作着重讨论了4个方面：1）P—gP对药代动力学性质的影响：2）MDR1基因多态性及其对遗传药理学性质的影响;3）MDR1^C3435T的单核苷酸多态性与P-gP表达和功能之间的相关性：4）MDR1基因多态性与人类某些疾病之间的相关性。     

Genes of multidrug resistance in haematological malignancies

Since the early 1970s, multiple drug resistance has been known to exist in cancer cells and is thought to be attributable to a membrane-bound, energy-dependent pump protein (P-glycoprotein [P-gp]) capable of extruding various related and unrelated chemotherapeutic drugs. The development of refractory disease in haematological malignancies is frequently associated with the expression of one or several multidrug resistance (MDR) genes. MDR1, multidrug resistance-associated protein (MRP) and lung-resistance protein (LRP) have been identified as important adverse prognostic factors. Recently it has become possible to reverse clinical MDR by blocking P-gp-mediated drug efflux. The potential relevance of these reversal agents of MDR as well as the potential new approaches to treat the refractory disease are discussed in this article. In addition, an array of different molecules and mechanisms by which resistant cells can escape the cytotoxic effect of anticancer drugs has now been identified. These molecules and mechanisms include apoptosis-related proteins and drug inactivation enzymes. Resistance to chemotherapy is believed to cause treatment failure in more than 50% patients. Clearly, if drug resistance could be overcome, the impact on survival would be highly significant. This review focuses on molecular mechanism of drug resistance in haematological malignancies with emphasis on molecules involved in MDR. In addition, it brings the survey of methods involved in determination of MDR, in particular P-gp/MDR1, MRP and LRP.     

Bivalent probes of the human multidrug transporter P-glycoprotein

A small library of bivalent agents was designed to probe the substrate binding sites of the human multidrug transporter P-glycoprotein (P-gp). The bivalent agents were composed of two copies of the P-gp substrate emetine, linked by tethers of varied composition. An optimum distance between the emetine molecules of approximately 10 A was found to be necessary for blocking transport of the known fluorescent substrate rhodamine 123. Additionally, it was determined that hydrophobic tethers were optimal for bridging the bivalent compounds; hydrophilic or cationic moieties within the tether had a detrimental effect on inhibition of transport. In addition to acting as probes of P-gp's drug binding sites, these agents were also potent inhibitors of P-gp. One agent, EmeC5, had IC50 values of 2.9 microM for inhibiting transport of rhodamine 123 and approximately 5 nM for inhibiting the binding of a known P-gp substrate, [125I]iodoarylazidoprazosin. Although EmeC5 is an inhibitor of P-gp and was shown to interact directly with P-gp in one or more of the substrate binding sites, our data suggest that it is either not a P-gp transport substrate itself or a poor one. Most significantly, EmeC5 was shown to reverse the MDR phenotype of MCF-7/DX1 cells when co-administered with a cytotoxic agent, such as doxorubicin.     

Genomics and the mechanism of P-glycoprotein (ABCB1)

The development of effective clinical interventions against multidrug resistance (MDR) in cancer remains a significant challenge. Single nucleotide polymorphisms (SNPs) contribute to wide variations in how individuals respond to medications and there are several SNPs in human P-glycoprotein (P-gp) that may influence the interactions of drug-substrates with the transporter. Interestingly, even some of the synonymous SNPs have functional consequences for P-gp. It is also becoming increasingly evident that an understanding of the transport pathway of P-gp may be necessary to design effective modulators. In this review we discuss: (1) The potential importance of SNPs (both synonymous and non-synonymous) in MDR and (2) How new concepts that have emerged from structural studies with isolated nucleotide binding domains of bacterial ABC transporters have prompted biochemical studies on P-gp, leading to a better understanding of the mechanism of P-gp mediated transport. Our results suggest that the power-stroke is provided only after formation of the pre-hydrolysis transition-like (E·S) state during ATP hydrolysis.