Structural Insight into Anaphase Promoting Complex 3 Structure and Docking with a Natural Inhibitory Compound.

BACKGROUND: Anaphase promoting complex (APC) is the biggest Cullin-RING E3 ligase and is very important in cell cycle control; many anti-cancer agents target this. APC controls the onset of chromosome separation and mitotic exit through securin and cyclin B degradation, respectively. Its APC3 subunit identifies the APC activators-Cdh1 and Cdc20. MATERIALS AND METHODS: The structural model of the APC3 subunit of APC was developed by means of computational techniques; the binding of a natural inhibitory compound to APC3 was also investigated. RESULTS: It was found that APC3 structure consists of numerous helices organized in anti-parallel and the overall model is superhelical of tetratrico-peptide repeat (TPR) domains. Furthermore, binding pocket of the natural inhibitory compound as APC3 inhibitor was shown. CONCLUSION: The findings are beneficial to understand the mechanism of the APC activation and design inhibitory compounds.

Computational and nonglycosylated systems: a simpler approach for development of nanosized PEGylated proteins.

Cysteine PEGylation includes several steps, and is difficult to manage in practice. In the current investigation, the cysteine PEGylation of erythropoietin analogs was examined using computational and nonglycosylated systems to define a simpler approach for specific PEGylation. Two model analogs (E31C and E89C) were selected for PEGylation based on lowest structural deviation from the native form, accessibility, and nucleophilicity of the free thiol group. The selected analogs were cloned and the expression was assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot using Coomassie blue staining and anti-His monoclonal antibody, respectively. PEGylation with 20 kDa mPEG-maleimide resulted in 79% and 82% conjugation yield for E31C and E89C nonglycosylated erythropoietin (ngEPO) analogs, respectively. The size distribution and charge analysis showed an increase in size and negative charge of the PEGylated forms compared with nonconjugated ones. Biological assay revealed that E31C and E89C mutations and subsequent PEGylation of ngEPO analogs have no deleterious effects on in vitro biological activity when compared to CHO-derived recombinant human erythropoietin. In addition, PEG-conjugated ngEPOs showed a significant increase in plasma half-lives after injection into rats when compared to nonconjugated ones. The development of the cysteine-PEGylated proteins using nonglycosylated expression system and in silico technique can be considered an efficient approach in terms of optimization of PEGylation parameters, time, and cost.

Growth inhibition of MDA-MB-231 cell line by peptides designed based on uPA.

Interaction between urokinase-type plasminogen activator (uPA) and its receptor (uPAR) plays an important role in the progression of numerous cancer types including breast cancer by promoting tumor initiating, proliferation, invasion and metastasis. Hence, disruption of this interaction inhibits their downstream cascades and subsequently tumor growth. For this, we created two series of 8 and 10 amino acids linear peptides, derived from uPA binding region to target uPAR and studied the inhibition of proliferation in MDA-MB-231 cell line. Results revealed that all of the 10-mer peptides inhibited breast cancer cell proliferation significantly with maximum 40% inhibition of 103 peptides. Meanwhile, none of the 8-mer peptides showed significant toxicity. Current results indicate that the linear 10-mer peptides which mimic a small part of a sequence of a binding domain of uPA to uPAR could be exploited to design a novel class of anti-cancer agents.

Design, synthesis and biological evaluation of novel anti-cytokine 1,2,4-triazine derivatives.

A series of 16 novel 1,2,4-triazine derivatives bearing hydrazone moiety (7a-7p) have been designed, synthesized and evaluated for their activity to inhibit IL-1ß and TNF-α production. All compounds are reported for the first time. The chemical structures of all compounds were confirmed by spectroscopic methods and elemental analyzes. Most of the synthesized compounds were proved to have potent anti-cytokine activity and low toxicity on PBMC and MCF-7 cell lines. Compounds 7f, 7k, 7l and 7j presented simultaneously good levels of inhibition of both cytokines. Moreover, compound 7l exhibited good anti-inflammatory effect in carrageenan-induced rat paw edema. The results of Western blotting demonstrated that the anti-cytokine potential of compound 7l is mainly mediated through the inhibition of p38 MAPK signaling pathway. Molecular docking was performed to position compound 7l into p38α binding site in order to explore the potential target. The information of this work might be helpful for the design and synthesis of novel scaffold toward the development of new therapeutic agent to fight against inflammatory diseases.

Phenylimino-2H-chromen-3-carboxamide derivatives as novel small molecule inhibitors of ß-secretase (BACE1).

The inhibition of ß secretase (BACE1) is potentially important approach to treatment of Alzheimer disease (AD). A novel series of 4-bromophenyl piperazine derivatives coupled to the phenylimino-2H-chromen-3-carboxamide scaffold were investigated as BACE1 inhibitors in this study. Docking study suggested that the phenyl-imino group of the scaffold establishes favorable π-π stacking interaction with side chain of Phe108 of flap pocket. Some of the docking proposed derivatives were synthesized and evaluated for BACE1 inhibitory activity using a FRET-based assay. High BACE1 inhibitory activities were observed from derivatives containing fused heteroaromtic groups attached through the aliphatic linkage to the N4-piperazine moiety, which may be attributed to the engagement of effective interactions with S1-S'1 sub-pocket residues. Of the most potent compounds, 9e displayed an IC50 value for BACE1 of 98 nM. Some of these derivatives demonstrated good inhibitory activity on Aß production in N2a-APPswe cells at 5 and 10 µM. These compounds might be considered as promising BACE1 inhibitory agents that could lower Aß production in AD.

Computational evaluation of some indenopyrazole derivatives as anticancer compounds; application of QSAR and docking methodologies.

A computational procedure was performed on some indenopyrazole derivatives. Two important procedures in computational drug discovery, namely docking for modeling ligand-receptor interactions and quantitative structure activity relationships were employed. MIA-QSAR analysis of the studied derivatives produced a model with high predictability. The developed model was then used to evaluate the bioactivity of 54 proposed indenopyrazole derivatives. In order to confirm the obtained results through this ligand-based method, docking was performed on the selected compounds. An ADME-Tox evaluation was also carried out to search for more suitable compounds. Satisfactory bioactivities and ADME-Tox profiles for two of the compounds, namely 62 and S13, propose that further studies should be performed on such devoted chemical structures.

Characterization of adenosine receptor in its native environment: insights from molecular dynamics simulations of palmitoylated/glycosylated, membrane-integrated human A(2B) adenosine receptor.

Selective A(2B) receptor antagonists and agonists may play a role in important pathologies such as gastrointestinal, neurological (i.e., Alzheimer disease and dementia) and hypersensitive disorders (i.e., asthma), diabetes, atherosclerosis, restenosis and cancer. Hence, it is regarded as a good target for the development of clinically useful agents. In this study, the effects of lipid bilayer, N-acetylglucosamine and S-palmitoyl on the dynamic behavior of A(2B)AR model is explored. Homology modeling, molecular docking and molecular dynamics simulations were performed to explore structural features of A(2B)AR in the presence of lipid bilayer. Twenty ns MD simulation was performed on the constructed model inserted in a hydrated lipid bilayer to examine stability of the best model. OSIP339391 as the most potent antagonist was docked in the active site of the model. Another MD simulation was performed on the ligand-protein complex to explore effects of the bilayer on this complex. A similar procedure was performed for the modified protein with N-acetylglucosamine and S-palmitoyl moieties in its structure. Phe173 and Glu174 located in EL2 were determined to be involved in ligand-receptor interactions through π-π stacking and hydrogen bonding. Asn254 was crucial to form hydrogen-bonding. The reliability of the model was assessed through docking using both commercial and synthetic antagonists and an r(2) of 0.70 was achieved. Our results show that molecular dynamics simulations of palmitoylated/glycosylated, membrane-integrated human A(2B)AR in its native environment is a possible approach and this model can be used for designing potent and selective A(2B)AR antagonists.

Design, modeling, and expression of erythropoietin cysteine analogs in Pichia pastoris: improvement of mean residence times and in vivo activities through cysteine-specific PEGylation.

In this study, the low-cost production of recombinant human erythropoietin cysteine analogs (Cys-rhEPOs) from Pichia pastoris and the potential to increase their serum residency and in vivo activity through cysteine-specific PEGylation were investigated. Three-dimensional structures of several Cys-rhEPOs were generated using homology modeling, and three stable Cys-rhEPOs were selected on the basis of model stability in molecular dynamics simulation and surface accessibility of the inserted cysteine. cDNAs encoding Cys-rhEPOs were constructed by site-directed mutagenesis and expressed as secreted proteins in flask cultures of P. pastoris. The selection of highly expressing clones and the optimization of certain culture parameters resulted in protein expression levels of 100-170 mg/l. Purified Cys-rhEPOs were cysteine-specifically PEGylated using 20 kDa and 30 kDa mPEG-maleimides (methoxy polyethylene glycol-maleimides). The E89CEPO analog with the highest (96.6%) cysteine accessibility was conjugated to PEG-polymers with the largest yields (about 80%). In comparison with rhEPO, 30 kDa PEG-E89CEPO demonstrated a significant (approximately 30%) increase in the mean residence time. Whereas the in vitro activities of 30 kDa PEG-E89CEPO were comparable to those of rhEPO, the in vivo activity of this conjugate was more prolonged compared to rhEPO (12 days vs. 7 days). Our results demonstrate that the site-specific PEGylation of Pichia-expressed EPO analogs may be considered as a promising approach for generating cost-effective and long-acting erythropoiesis-stimulating agents.

Protein-x of hepatitis B virus in interaction with CCAAT/enhancer-binding protein α (C/EBPα)--an in silico analysis approach.

BACKGROUND: Even though many functions of protein-x from the Hepatitis B virus (HBV) have been revealed, the nature of protein-x is yet unknown. This protein is well-known for its transactivation activity through interaction with several cellular transcription factors, it is also known as an oncogene. In this work, we have presented computational approaches to design a model to show the structure of protein-x and its respective binding sites associated with the CCAAT/enhancer-binding protein α (C/EBPα). C/EBPα belongs to the bZip family of transcription factors, which activates transcription of several genes through its binding sites in liver and fat cells. The C/EBPα has been shown to bind and modulate enhancer I and the enhancer II/core promoter of HBV. In this study using the bioinformatics tools we tried to present a reliable model for the protein-x interaction with C/EBPα. RESULTS: The amino acid sequence of protein-x was extracted from UniProt [UniProt:Q80IU5] and the x-ray crystal structure of the partial CCAAT-enhancer α [PDB:1NWQ] was retrieved from the Protein Data Bank (PDB). Similarity search for protein-x was carried out by psi-blast and bl2seq using NCBI [GenBank: BAC65106.1] and Local Meta-Threading-Server (LOMETS) was used as a threading server for determining the maximum tertiary structure similarities. Advanced MODELLER was implemented to design a comparative model, however, due to the lack of a suitable template, Quark was used for ab initio tertiary structure prediction.The PDB-blast search indicated a maximum of 23% sequence identity and 33% similarity with crystal structure of the porcine reproductive and respiratory syndrome virus leader protease Nsp1α [PDB:3IFU]. This meant that protein-x does not have a suitable template to predict its tertiary structure using comparative modeling tools, therefore we used QUARK as an ab initio 3D prediction approach. Docking results from the ab initio tertiary structure of protein-x and crystal structure of the C/EBPα- DNA region [PDB:1NWQ] illustrated the protein-binding site interactions. Indeed, the N-terminal part of 1NWQ has a high affinity for certain regions in protein-x (e.g. from Ala76 to Ser101 and Thr105 to Glu125). CONCLUSION: In this study, we predicted the structure of protein-x of HBV in interaction with C/EBPα. The docking results showed that protein-x has an interaction synergy with C/EBPα. However, despite previous experimental data, protein-x was found to interact with DNA. This can lead to a better understanding of the function of protein-x and may provide an opportunity to use it as a therapeutic target.

Design, modeling, expression, and chemoselective PEGylation of a new nanosize cysteine analog of erythropoietin.

BACKGROUND: Recombinant human erythropoietin (rhEPO) is considered to be one of the most pivotal pharmaceutical drugs in the market because of its clinical application in the treatment of anemia-associated disorders worldwide. However, like other therapeutic proteins, it does not have suitable pharmacokinetic properties for it to be administrated at least two to three times per week. Chemoselective cysteine PEGylation, employing molecular dynamics and graphics in in silico studies, can be considered to overcome such a problem. METHODS: A special kind of EPO analog was elicited based on a literature review, homology modeling, molecular dynamic simulation, and factors affecting the PEGylation reaction. Then, cDNA of the selected analog was generated by site-directed mutagenesis and subsequently cloned into the expression vector. The construct was transfected to Chinese hamster ovary/dhfr(-) cells, and highly expressed clones were selected via methotrexate amplification. Ion-immobilized affinity and size exclusion (SE) chromatography techniques were used to purify the expressed analog. Thereafter, chemoselective PEGylation was performed and a nanosize PEGylated EPO was obtained through dialysis. The in vitro biologic assay and in vivo pharmacokinetic parameters were studied. Finally, E31C analog Fourier transform infrared, analytical SE-high-performance liquid chromatography, zeta potential, and size before and after PEGylation were characterized. RESULTS: The findings indicate that a novel nanosize EPO31-PEG has a five-fold longer terminal half-life in rats with similar biologic activity compared with unmodified rhEPO in proliferation cell assay. The results also show that EPO31-PEG size and charge versus unmodified protein was increased in a nanospectrum, and this may be one criterion of EPO biologic potency enhancement. DISCUSSION: This kind of novel engineered nanosize PEGylated EPO has remarkable advantages over rhEPO.