Your search keyword '"Structural bioinformatics"' showing total 17 results

1. Molecular Dynamics Simulation of Kir6.2 Variants Reveals Potential Association with Diabetes Mellitus.

Author

Elangeeb, Mohamed E., Elfaki, Imadeldin, Eleragi, Ali M. S., Ahmed, Elsadig Mohamed, Mir, Rashid, Alzahrani, Salem M., Bedaiwi, Ruqaiah I., Alharbi, Zeyad M., Mir, Mohammad Muzaffar, Ajmal, Mohammad Rehan, Tayeb, Faris Jamal, and Barnawi, Jameel

Subjects

*POTASSIUM channels, *MOLECULAR dynamics, *MATURITY onset diabetes of the young, *DIABETES, *STRUCTURAL bioinformatics, *GENETIC testing

Abstract

Diabetes mellitus (DM) represents a problem for the healthcare system worldwide. DM has very serious complications such as blindness, kidney failure, and cardiovascular disease. In addition to the very bad socioeconomic impacts, it influences patients and their families and communities. The global costs of DM and its complications are huge and expected to rise by the year 2030. DM is caused by genetic and environmental risk factors. Genetic testing will aid in early diagnosis and identification of susceptible individuals or populations using ATP-sensitive potassium (KATP) channels present in different tissues such as the pancreas, myocardium, myocytes, and nervous tissues. The channels respond to different concentrations of blood sugar, stimulation by hormones, or ischemic conditions. In pancreatic cells, they regulate the secretion of insulin and glucagon. Mutations in the KCNJ11 gene that encodes the Kir6.2 protein (a major constituent of KATP channels) were reported to be associated with Type 2 DM, neonatal diabetes mellitus (NDM), and maturity-onset diabetes of the young (MODY). Kir6.2 harbors binding sites for ATP and phosphatidylinositol 4,5-diphosphate (PIP2). The ATP inhibits the KATP channel, while the (PIP2) activates it. A Kir6.2 mutation at tyrosine330 (Y330) was demonstrated to reduce ATP inhibition and predisposes to NDM. In this study, we examined the effect of mutations on the Kir6.2 structure using bioinformatics tools and molecular dynamic simulations (SIFT, PolyPhen, SNAP2, PANTHER, PhD&SNP, SNP&Go, I-Mutant, MuPro, MutPred, ConSurf, HOPE, and GROMACS). Our results indicated that M199R, R201H, R206H, and Y330H mutations influence Kir6.2 structure and function and therefore may cause DM. We conclude that MD simulations are useful techniques to predict the effects of mutations on protein structure. In addition, the M199R, R201H, R206H, and Y330H variant in the Kir6.2 protein may be associated with DM. These results require further verification in protein–protein interactions, Kir6.2 function, and case-control studies. [ABSTRACT FROM AUTHOR]

Published

2024

2. Recent Progress of Protein Tertiary Structure Prediction.

Author

Wuyun, Qiqige, Chen, Yihan, Shen, Yifeng, Cao, Yang, Hu, Gang, Cui, Wei, Gao, Jianzhao, and Zheng, Wei

Subjects

*PROTEIN structure prediction, *DEEP learning, *LANGUAGE models, *AMINO acid sequence, *PROTEIN structure, *STRUCTURAL bioinformatics

Abstract

The prediction of three-dimensional (3D) protein structure from amino acid sequences has stood as a significant challenge in computational and structural bioinformatics for decades. Recently, the widespread integration of artificial intelligence (AI) algorithms has substantially expedited advancements in protein structure prediction, yielding numerous significant milestones. In particular, the end-to-end deep learning method AlphaFold2 has facilitated the rise of structure prediction performance to new heights, regularly competitive with experimental structures in the 14th Critical Assessment of Protein Structure Prediction (CASP14). To provide a comprehensive understanding and guide future research in the field of protein structure prediction for researchers, this review describes various methodologies, assessments, and databases in protein structure prediction, including traditionally used protein structure prediction methods, such as template-based modeling (TBM) and template-free modeling (FM) approaches; recently developed deep learning-based methods, such as contact/distance-guided methods, end-to-end folding methods, and protein language model (PLM)-based methods; multi-domain protein structure prediction methods; the CASP experiments and related assessments; and the recently released AlphaFold Protein Structure Database (AlphaFold DB). We discuss their advantages, disadvantages, and application scopes, aiming to provide researchers with insights through which to understand the limitations, contexts, and effective selections of protein structure prediction methods in protein-related fields. [ABSTRACT FROM AUTHOR]

Published

2024

3. Structural Outlier Detection and Zernike–Canterakis Moments for Molecular Surface Meshes—Fast Implementation in Python.

Author

Banach, Mateusz

Subjects

*OUTLIER detection, *STRUCTURAL bioinformatics, *PYTHON programming language, *MOLECULAR shapes, *QUATERNARY structure, *DATABASES

Abstract

Object retrieval systems measure the degree of similarity of the shape of 3D models. They search for the elements of the 3D model databases that resemble the query model. In structural bioinformatics, the query model is a protein tertiary/quaternary structure and the objective is to find similarly shaped molecules in the Protein Data Bank. With the ever-growing size of the PDB, a direct atomic coordinate comparison with all its members is impractical. To overcome this problem, the shape of the molecules can be encoded by fixed-length feature vectors. The distance of a protein to the entire PDB can be measured in this low-dimensional domain in linear time. The state-of-the-art approaches utilize Zernike–Canterakis moments for the shape encoding and supply the retrieval process with geometric data of the input structures. The BioZernike descriptors are a standard utility of the PDB since 2020. However, when trying to calculate the ZC moments locally, the issue of the deficiency of libraries readily available for use in custom programs (i.e., without relying on external binaries) is encountered, in particular programs written in Python. Here, a fast and well-documented Python implementation of the Pozo–Koehl algorithm is presented. In contrast to the more popular algorithm by Novotni and Klein, which is based on the voxelized volume, the PK algorithm produces ZC moments directly from the triangular surface meshes of 3D models. In particular, it can accept the molecular surfaces of proteins as its input. In the presented PK-Zernike library, owing to Numba's just-in-time compilation, a mesh with 50,000 facets is processed by a single thread in a second at the moment order 20. Since this is the first time the PK algorithm is used in structural bioinformatics, it is employed in a novel, simple, but efficient protein structure retrieval pipeline. The elimination of the outlying chain fragments via a fast PCA-based subroutine improves the discrimination ability, allowing for this pipeline to achieve an 0.961 area under the ROC curve in the BioZernike validation suite (0.997 for the assemblies). The correlation between the results of the proposed approach and of the 3D Surfer program attains values up to 0.99. [ABSTRACT FROM AUTHOR]

Published

2024

4. Identifying Potential Molecular Targets in Fungi Based on (Dis)Similarities in Binding Site Architecture with Proteins of the Human Pharmacolome.

Author

Bedoya-Cardona, Johann E., Rubio-Carrasquilla, Marcela, Ramírez-Velásquez, Iliana M., Valdés-Tresanco, Mario S., and Moreno, Ernesto

Subjects

*DRUG target, *ECHINOCANDINS, *DRUG repositioning, *BINDING sites, *FUNGAL proteins, *MITOGEN-activated protein kinases, *MITOGENS

Abstract

Invasive fungal infections represent a public health problem that worsens over the years with the increasing resistance to current antimycotic agents. Therefore, there is a compelling medical need of widening the antifungal drug repertoire, following different methods such as drug repositioning, identification and validation of new molecular targets and developing new inhibitors against these targets. In this work we developed a structure-based strategy for drug repositioning and new drug design, which can be applied to infectious fungi and other pathogens. Instead of applying the commonly accepted off-target criterion to discard fungal proteins with close homologues in humans, the core of our approach consists in identifying fungal proteins with active sites that are structurally similar, but preferably not identical to binding sites of proteins from the so-called "human pharmacolome". Using structural information from thousands of human protein target-inhibitor complexes, we identified dozens of proteins in fungal species of the genera Histoplasma, Candida, Cryptococcus, Aspergillus and Fusarium, which might be exploited for drug repositioning and, more importantly, also for the design of new fungus-specific inhibitors. As a case study, we present the in vitro experiments performed with a set of selected inhibitors of the human mitogen-activated protein kinases 1/2 (MEK1/2), several of which showed a marked cytotoxic activity in different fungal species. [ABSTRACT FROM AUTHOR]

Published

2023

5. Identifying Potential Molecular Targets in Fungi Based on (Dis)Similarities in Binding Site Architecture with Proteins of the Human Pharmacolome

Author

Johann E. Bedoya-Cardona, Marcela Rubio-Carrasquilla, Iliana M. Ramírez-Velásquez, Mario S. Valdés-Tresanco, and Ernesto Moreno

Subjects

fungal pathogens, drug repurposing, drug development, new therapeutic targets, structural bioinformatics, MEK inhibitors, Organic chemistry, QD241-441

Abstract

Invasive fungal infections represent a public health problem that worsens over the years with the increasing resistance to current antimycotic agents. Therefore, there is a compelling medical need of widening the antifungal drug repertoire, following different methods such as drug repositioning, identification and validation of new molecular targets and developing new inhibitors against these targets. In this work we developed a structure-based strategy for drug repositioning and new drug design, which can be applied to infectious fungi and other pathogens. Instead of applying the commonly accepted off-target criterion to discard fungal proteins with close homologues in humans, the core of our approach consists in identifying fungal proteins with active sites that are structurally similar, but preferably not identical to binding sites of proteins from the so-called “human pharmacolome”. Using structural information from thousands of human protein target-inhibitor complexes, we identified dozens of proteins in fungal species of the genera Histoplasma, Candida, Cryptococcus, Aspergillus and Fusarium, which might be exploited for drug repositioning and, more importantly, also for the design of new fungus-specific inhibitors. As a case study, we present the in vitro experiments performed with a set of selected inhibitors of the human mitogen-activated protein kinases 1/2 (MEK1/2), several of which showed a marked cytotoxic activity in different fungal species.

Published

2023

6. Effective Use of Empirical Data for Virtual Screening against APJR GPCR Receptor

Author

Laura C. E. Manoliu, Eliza C. Martin, Adina L. Milac, and Laurentiu Spiridon

Subjects

structural bioinformatics, molecular docking, Alzheimer, apelin receptor, Organic chemistry, QD241-441

Abstract

Alzheimer’s disease is a neurodegenerative disorder incompatible with normal daily activity, affecting one in nine people. One of its potential targets is the apelin receptor (APJR), a G-protein coupled receptor, which presents considerably high expression levels in the central nervous system. In silico studies of APJR drug-like molecule binding are in small numbers while high throughput screenings (HTS) are already sufficiently many to devise efficient drug design strategies. This presents itself as an opportunity to optimize different steps in future large scale virtual screening endeavours. Here, we ran a first stage docking simulation against a library of 95 known binders and 3829 generated decoys in an effort to improve the rescoring stage. We then analyzed receptor binding site structure and ligands binding poses to describe their interactions. As a result, we devised a simple and straightforward virtual screening Stage II filtering score based on search space extension followed by a geometric estimation of the ligand—binding site fitness. Having this score, we used an ensemble of receptors generated by Hamiltonian Monte Carlo simulation and reported the results. The improvements shown herein prove that our ensemble docking protocol is suited for APJR and can be easily extrapolated to other GPCRs.

Published

2021

7. Scalable Extraction of Big Macromolecular Data in Azure Data Lake Environment

Author

Dariusz Mrozek, Tomasz Dąbek, and Bożena Małysiak-Mrozek

Subjects

data processing, Cloud computing, Big Data, data extraction, data lake, parallel computing, querying, proteins, nucleic acids, macromolecules, 3D structure, structural bioinformatics, Organic chemistry, QD241-441

Abstract

Calculation of structural features of proteins, nucleic acids, and nucleic acid-protein complexes on the basis of their geometries and studying various interactions within these macromolecules, for which high-resolution structures are stored in Protein Data Bank (PDB), require parsing and extraction of suitable data stored in text files. To perform these operations on large scale in the face of the growing amount of macromolecular data in public repositories, we propose to perform them in the distributed environment of Azure Data Lake and scale the calculations on the Cloud. In this paper, we present dedicated data extractors for PDB files that can be used in various types of calculations performed over protein and nucleic acids structures in the Azure Data Lake. Results of our tests show that the Cloud storage space occupied by the macromolecular data can be successfully reduced by using compression of PDB files without significant loss of data processing efficiency. Moreover, our experiments show that the performed calculations can be significantly accelerated when using large sequential files for storing macromolecular data and by parallelizing the calculations and data extractions that precede them. Finally, the paper shows how all the calculations can be performed in a declarative way in U-SQL scripts for Data Lake Analytics.

Published

2019

8. Editorial of Special Issue Ruthenium Complex: The Expanding Chemistry of the Ruthenium Complexes.

Author

Dragutan, Ileana, Dragutan, Valerian, and Demonceau, Albert

Subjects

*RUTHENIUM, *MOLECULAR structure, *SPECTRUM analysis, *MOLECULAR size, *STRUCTURAL bioinformatics

Abstract

Recent trends in Ru complex chemistry are surveyed with emphasis on the development of anticancer drugs and applications in catalysis, polymers, materials science and nanotechnology. [ABSTRACT FROM AUTHOR]

Published

2015

9. Identification of Persuasive Antiviral Natural Compounds for COVID-19 by Targeting Endoribonuclease NSP15: A Structural-Bioinformatics Approach

Author

Amir Saeed, Mohd Saeed, Mousa M Alreshidi, and Jahoor Alam

Subjects

030303 biophysics, Endoribonuclease, NSP15, Druggability, Pharmaceutical Science, Computational biology, Molecular Dynamics Simulation, Viral Nonstructural Proteins, Ligands, Antiviral Agents, Article, Analytical Chemistry, lcsh:QD241-441, 03 medical and health sciences, Structural bioinformatics, Viral life cycle, lcsh:Organic chemistry, Catalytic Domain, Drug Discovery, Endoribonucleases, natural compounds, Physical and Theoretical Chemistry, 030304 developmental biology, 0303 health sciences, Virtual screening, biology, Chemistry, SARS-CoV-2, Organic Chemistry, RNA, RNA virus, Hydrogen Bonding, biology.organism_classification, virtual screening, molecular dynamics, High-Throughput Screening Assays, COVID-19 Drug Treatment, Molecular Docking Simulation, Chemistry (miscellaneous), Docking (molecular), Molecular Medicine, Hydrophobic and Hydrophilic Interactions

Abstract

SARS-CoV-2 is a positive-stranded RNA virus that bundles its genomic material as messenger-sense RNA in infectious virions and replicates these genomes through RNA intermediates. Several virus-encoded nonstructural proteins play a key role during the viral life cycle. Endoribonuclease NSP15 is vital for the replication and life cycle of the virus, and is thus considered a compelling druggable target. Here, we performed a combination of multiscoring virtual screening and molecular docking of a library of 1624 natural compounds (Nuclei of Bioassays, Ecophysiology and Biosynthesis of Natural Products (NuBBE) database) on the active sites of NSP15 (PDB:6VWW). After sequential high-throughput screening by LibDock and GOLD, docking optimization by CDOCKER, and final scoring by calculating binding energies, top-ranked compounds NuBBE-1970 and NuBBE-242 were further investigated via an indepth molecular-docking and molecular-dynamics simulation of 60 ns, which revealed that the binding of these two compounds with active site residues of NSP15 was sufficiently strong and stable. The findings strongly suggest that further optimization and clinical investigations of these potent compounds may lead to effective SARS-CoV-2 treatment.

Published

2020

10. Modeling to Understand Plant Protein Structure-Function Relationships—Implications for Seed Storage Proteins

Author

Mikael S. Hedenqvist, Eva Johansson, Joel Markgren, and Faiza Rasheed

Subjects

Models, Molecular, Computer science, Pharmaceutical Science, Review, 02 engineering and technology, Computational biology, globulin, Analytical Chemistry, Modeling and simulation, lcsh:QD241-441, Structure-Activity Relationship, 03 medical and health sciences, Structural bioinformatics, Protein structure, lcsh:Organic chemistry, Glutelin, Drug Discovery, Industry, Storage protein, Physical and Theoretical Chemistry, Prolamin, albumin, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, Seed Storage Proteins, Organic Chemistry, monte carlo simulation, computer.file_format, 021001 nanoscience & nanotechnology, Protein Data Bank, molecular dynamics simulation, chemistry, Food, Chemistry (miscellaneous), Plant protein, biology.protein, Molecular Medicine, 0210 nano-technology, computer, glutelin, prolamin

Abstract

Proteins are among the most important molecules on Earth. Their structure and aggregation behavior are key to their functionality in living organisms and in protein-rich products. Innovations, such as increased computer size and power, together with novel simulation tools have improved our understanding of protein structure-function relationships. This review focuses on various proteins present in plants and modeling tools that can be applied to better understand protein structures and their relationship to functionality, with particular emphasis on plant storage proteins. Modeling of plant proteins is increasing, but less than 9% of deposits in the Research Collaboratory for Structural Bioinformatics Protein Data Bank come from plant proteins. Although, similar tools are applied as in other proteins, modeling of plant proteins is lagging behind and innovative methods are rarely used. Molecular dynamics and molecular docking are commonly used to evaluate differences in forms or mutants, and the impact on functionality. Modeling tools have also been used to describe the photosynthetic machinery and its electron transfer reactions. Storage proteins, especially in large and intrinsically disordered prolamins and glutelins, have been significantly less well-described using modeling. These proteins aggregate during processing and form large polymers that correlate with functionality. The resulting structure-function relationships are important for processed storage proteins, so modeling and simulation studies, using up-to-date models, algorithms, and computer tools are essential for obtaining a better understanding of these relationships.

Published

2020

11. Site Density Functional Theory and Structural Bioinformatics Analysis of the SARS-CoV Spike Protein and hACE2 Complex.

Author

Kumawat, Nitesh, Tucs, Andrejs, Bera, Soumen, Chuev, Gennady N., Valiev, Marat, Fedotova, Marina V., Kruchinin, Sergey E., Tsuda, Koji, Sljoka, Adnan, and Chakraborty, Amit

Subjects

*DENSITY functional theory, *STRUCTURAL bioinformatics, *SARS virus, *PROTEIN domains, *CHIMERIC proteins, *VIRAL proteins

Abstract

The entry of the SARS-CoV-2, a causative agent of COVID-19, into human host cells is mediated by the SARS-CoV-2 spike (S) glycoprotein, which critically depends on the formation of complexes involving the spike protein receptor-binding domain (RBD) and the human cellular membrane receptor angiotensin-converting enzyme 2 (hACE2). Using classical site density functional theory (SDFT) and structural bioinformatics methods, we investigate binding and conformational properties of these complexes and study the overlooked role of water-mediated interactions. Analysis of the three-dimensional reference interaction site model (3DRISM) of SDFT indicates that water mediated interactions in the form of additional water bridges strongly increases the binding between SARS-CoV-2 spike protein and hACE2 compared to SARS-CoV-1-hACE2 complex. By analyzing structures of SARS-CoV-2 and SARS-CoV-1, we find that the homotrimer SARS-CoV-2 S receptor-binding domain (RBD) has expanded in size, indicating large conformational change relative to SARS-CoV-1 S protein. Protomer with the up-conformational form of RBD, which binds with hACE2, exhibits stronger intermolecular interactions at the RBD-ACE2 interface, with differential distributions and the inclusion of specific H-bonds in the CoV-2 complex. Further interface analysis has shown that interfacial water promotes and stabilizes the formation of CoV-2/hACE2 complex. This interaction causes a significant structural rigidification of the spike protein, favoring proteolytic processing of the S protein for the fusion of the viral and cellular membrane. Moreover, conformational dynamics simulations of RBD motions in SARS-CoV-2 and SARS-CoV-1 point to the role in modification of the RBD dynamics and their impact on infectivity. [ABSTRACT FROM AUTHOR]

Published

2022

12. Scalable Extraction of Big Macromolecular Data in Azure Data Lake Environment

Author

Bożena Małysiak-Mrozek, Dariusz Mrozek, and Tomasz Dąbek

Subjects

Big Data, Computer science, querying, Macromolecular Substances, Big data, Protein Data Bank (RCSB PDB), Pharmaceutical Science, nucleic acids, macromolecules, Cloud computing, 02 engineering and technology, data extraction, 3D structure, Article, Analytical Chemistry, Computational science, lcsh:QD241-441, 03 medical and health sciences, Structural bioinformatics, lcsh:Organic chemistry, data lake, 020204 information systems, Drug Discovery, 0202 electrical engineering, electronic engineering, information engineering, Physical and Theoretical Chemistry, Databases, Protein, 030304 developmental biology, 0303 health sciences, Data processing, business.industry, parallel computing, Organic Chemistry, Computational Biology, Proteins, computer.file_format, structural bioinformatics, Cloud Computing, Protein Data Bank, Data extraction, Chemistry (miscellaneous), Scalability, Molecular Medicine, Nucleic Acid Conformation, business, computer, data processing, Software

Abstract

Calculation of structural features of proteins, nucleic acids, and nucleic acid-protein complexes on the basis of their geometries and studying various interactions within these macromolecules, for which high-resolution structures are stored in Protein Data Bank (PDB), require parsing and extraction of suitable data stored in text files. To perform these operations on large scale in the face of the growing amount of macromolecular data in public repositories, we propose to perform them in the distributed environment of Azure Data Lake and scale the calculations on the Cloud. In this paper, we present dedicated data extractors for PDB files that can be used in various types of calculations performed over protein and nucleic acids structures in the Azure Data Lake. Results of our tests show that the Cloud storage space occupied by the macromolecular data can be successfully reduced by using compression of PDB files without significant loss of data processing efficiency. Moreover, our experiments show that the performed calculations can be significantly accelerated when using large sequential files for storing macromolecular data and by parallelizing the calculations and data extractions that precede them. Finally, the paper shows how all the calculations can be performed in a declarative way in U-SQL scripts for Data Lake Analytics.

Published

2019

13. Effective Use of Empirical Data for Virtual Screening against APJR GPCR Receptor.

Author

Manoliu, Laura C. E., Martin, Eliza C., Milac, Adina L., and Spiridon, Laurentiu

Subjects

*HIGH throughput screening (Drug development), *DATA integrity, *BINDING sites, *MONTE Carlo method, *DRUG design, *G protein coupled receptors

Abstract

Alzheimer's disease is a neurodegenerative disorder incompatible with normal daily activity, affecting one in nine people. One of its potential targets is the apelin receptor (APJR), a G-protein coupled receptor, which presents considerably high expression levels in the central nervous system. In silico studies of APJR drug-like molecule binding are in small numbers while high throughput screenings (HTS) are already sufficiently many to devise efficient drug design strategies. This presents itself as an opportunity to optimize different steps in future large scale virtual screening endeavours. Here, we ran a first stage docking simulation against a library of 95 known binders and 3829 generated decoys in an effort to improve the rescoring stage. We then analyzed receptor binding site structure and ligands binding poses to describe their interactions. As a result, we devised a simple and straightforward virtual screening Stage II filtering score based on search space extension followed by a geometric estimation of the ligand—binding site fitness. Having this score, we used an ensemble of receptors generated by Hamiltonian Monte Carlo simulation and reported the results. The improvements shown herein prove that our ensemble docking protocol is suited for APJR and can be easily extrapolated to other GPCRs. [ABSTRACT FROM AUTHOR]

Published

2021

14. Multiscale Virtual Screening Optimization for Shotgun Drug Repurposing Using the CANDO Platform.

Author

Hudson, Matthew L., Samudrala, Ram, Tutone, Marco, and Almerico, Anna Maria

Subjects

*DRUG utilization, *SHOTGUNS, *PROTEIN structure, *CLINICAL indications, *MOLECULAR docking

Abstract

Drug repurposing, the practice of utilizing existing drugs for novel clinical indications, has tremendous potential for improving human health outcomes and increasing therapeutic development efficiency. The goal of multi-disease multitarget drug repurposing, also known as shotgun drug repurposing, is to develop platforms that assess the therapeutic potential of each existing drug for every clinical indication. Our Computational Analysis of Novel Drug Opportunities (CANDO) platform for shotgun multitarget repurposing implements several pipelines for the large-scale modeling and simulation of interactions between comprehensive libraries of drugs/compounds and protein structures. In these pipelines, each drug is described by an interaction signature that is compared to all other signatures that are subsequently sorted and ranked based on similarity. Pipelines within the platform are benchmarked based on their ability to recover known drugs for all indications in our library, and predictions are generated based on the hypothesis that (novel) drugs with similar signatures may be repurposed for the same indication(s). The drug-protein interactions used to create the drug-proteome signatures may be determined by any screening or docking method, but the primary approach used thus far has been BANDOCK, our in-house bioanalytical or similarity docking protocol. In this study, we calculated drug-proteome interaction signatures using the publicly available molecular docking method Autodock Vina and created hybrid decision tree pipelines that combined our original bio- and chem-informatic approach with the goal of assessing and benchmarking their drug repurposing capabilities and performance. The hybrid decision tree pipeline outperformed the two docking-based pipelines from which it was synthesized, yielding an average indication accuracy of 13.3% at the top10 cutoff (the most stringent), relative to 10.9% and 7.1% for its constituent pipelines, and a random control accuracy of 2.2%. We demonstrate that docking-based virtual screening pipelines have unique performance characteristics and that the CANDO shotgun repurposing paradigm is not dependent on a specific docking method. Our results also provide further evidence that multiple CANDO pipelines can be synthesized to enhance drug repurposing predictive capability relative to their constituent pipelines. Overall, this study indicates that pipelines consisting of varied docking-based signature generation methods can capture unique and useful signals for accurate comparison of drug-proteome interaction signatures, leading to improvements in the benchmarking and predictive performance of the CANDO shotgun drug repurposing platform. [ABSTRACT FROM AUTHOR]

Published

2021

15. Structure-Dependent Activity of Plant-Derived Sweeteners.

Author

Ҫiçek, Serhat Sezai, Sippl, Wolfgang, and Ntie-Kang, Fidele

Subjects

*SWEETNESS (Taste), *NATURAL sweeteners, *SWEETENERS, *TASTE receptors, *STRUCTURAL bioinformatics, *STRUCTURE-activity relationships, *CHEMICAL plants, *DENTAL clinics

Abstract

Human sensation for sweet tastes and the thus resulting over-consumption of sugar in recent decades has led to an increasing number of people suffering from caries, diabetes, and obesity. Therefore, a demand for sugar substitutes has arisen, which increasingly has turned towards natural sweeteners over the last 20 years. In the same period, thanks to advances in bioinformatics and structural biology, understanding of the sweet taste receptor and its different binding sites has made significant progress, thus explaining the various chemical structures found for sweet tasting molecules. The present review summarizes the data on natural sweeteners and their most important (semi-synthetic) derivatives until the end of 2019 and discusses their structure–activity relationships, with an emphasis on small-molecule high-intensity sweeteners. [ABSTRACT FROM AUTHOR]

Published

2020

16. Human Copper-Containing Amine Oxidases in Drug Design and Development.

Author

Vakal, Serhii, Jalkanen, Sirpa, Dahlström, Käthe M., Salminen, Tiina A., and Liu, Aimin

Subjects

*DRUG design, *AMINE oxidase, *OXIDASES, *MONOAMINE transporters, *DRUG development, *DRUG side effects, *STRUCTURAL bioinformatics

Abstract

Two members of the copper-containing amine oxidase family are physiologically important proteins: (1) Diamine oxidase (hDAO; AOC1) with a preference for diamines is involved in degradation of histamine and (2) Vascular adhesion protein-1 (hVAP-1; AOC3) with a preference for monoamines is a multifunctional cell-surface receptor and an enzyme. hVAP-1-targeted inhibitors are designed to treat inflammatory diseases and cancer, whereas the off-target binding of the designed inhibitors to hDAO might result in adverse drug reactions. The X-ray structures for both human enzymes are solved and provide the basis for computer-aided inhibitor design, which has been reported by several research groups. Although the putative off-target effect of hDAO is less studied, computational methods could be easily utilized to avoid the binding of VAP-1-targeted inhibitors to hDAO. The choice of the model organism for preclinical testing of hVAP-1 inhibitors is not either trivial due to species-specific binding properties of designed inhibitors and different repertoire of copper-containing amine oxidase family members in mammalian species. Thus, the facts that should be considered in hVAP-1-targeted inhibitor design are discussed in light of the applied structural bioinformatics and structural biology approaches. [ABSTRACT FROM AUTHOR]

Published

2020

17. Scalable Extraction of Big Macromolecular Data in Azure Data Lake Environment.

Author

Mrozek, Dariusz, Dąbek, Tomasz, and Małysiak-Mrozek, Bożena

Subjects

*MACROMOLECULES, *PROTEIN structure, *NUCLEIC acids, *EXTRACTION (Chemistry), *EXTRACTION apparatus

Abstract

Calculation of structural features of proteins, nucleic acids, and nucleic acid-protein complexes on the basis of their geometries and studying various interactions within these macromolecules, for which high-resolution structures are stored in Protein Data Bank (PDB), require parsing and extraction of suitable data stored in text files. To perform these operations on large scale in the face of the growing amount of macromolecular data in public repositories, we propose to perform them in the distributed environment of Azure Data Lake and scale the calculations on the Cloud. In this paper, we present dedicated data extractors for PDB files that can be used in various types of calculations performed over protein and nucleic acids structures in the Azure Data Lake. Results of our tests show that the Cloud storage space occupied by the macromolecular data can be successfully reduced by using compression of PDB files without significant loss of data processing efficiency. Moreover, our experiments show that the performed calculations can be significantly accelerated when using large sequential files for storing macromolecular data and by parallelizing the calculations and data extractions that precede them. Finally, the paper shows how all the calculations can be performed in a declarative way in U-SQL scripts for Data Lake Analytics. [ABSTRACT FROM AUTHOR]

Published

2019