Introducing Catastrophe-QSAR. Application on Modeling Molecular Mechanisms of Pyridinone Derivative-Type HIV Non-Nucleoside Reverse Transcriptase Inhibitors

Putz, Mihai V.; Lazea, Marius; Putz, Ana-Maria; Duda-Seiman, Corina

doi:10.3390/ijms12129533

Cited by 8 publications

(4 citation statements)

References 54 publications

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“…As a consequence, neuro-self-organization is correspondingly advanced by the reduction of the archetypal precursor of epileptic seizures to cusp synergetics [ 65 ]. Lastly, but not least, the catastrophe approach enters chemistry through the need to unitarily characterize chemical bonding through elementary processes, leading to the so-called bonding evolution theory; it also triggered the reformulation of the electronic localization functions [ 66 , 67 ]. Catastrophe theory was nevertheless successfully grounded on Hilbert space modeling with the aid of density matrix and non-linear evolution-specific tools including non-commutative (quantum open) systems [ 68 ].…”

Section: The Special Computing Trace Of Algebraic Structure-activimentioning

confidence: 99%

Chemical Structure-Biological Activity Models for Pharmacophores’ 3D-Interactions

Putz

Duda-Seiman

et al. 2016

IJMS

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Within medicinal chemistry nowadays, the so-called pharmaco-dynamics seeks for qualitative (for understanding) and quantitative (for predicting) mechanisms/models by which given chemical structure or series of congeners actively act on biological sites either by focused interaction/therapy or by diffuse/hazardous influence. To this aim, the present review exposes three of the fertile directions in approaching the biological activity by chemical structural causes: the special computing trace of the algebraic structure-activity relationship (SPECTRAL-SAR) offering the full analytical counterpart for multi-variate computational regression, the minimal topological difference (MTD) as the revived precursor for comparative molecular field analyses (CoMFA) and comparative molecular similarity indices analysis (CoMSIA); all of these methods and algorithms were presented, discussed and exemplified on relevant chemical medicinal systems as proton pump inhibitors belonging to the 4-indolyl,2-guanidinothiazole class of derivatives blocking the acid secretion from parietal cells in the stomach, the 1-[(2-hydroxyethoxy)-methyl]-6-(phenylthio)thymine congeners’ (HEPT ligands) antiviral activity against Human Immunodeficiency Virus of first type (HIV-1) and new pharmacophores in treating severe genetic disorders (like depression and psychosis), respectively, all involving 3D pharmacophore interactions.

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Section: The Special Computing Trace Of Algebraic Structure-activimentioning

confidence: 99%

Chemical Structure-Biological Activity Models for Pharmacophores’ 3D-Interactions

Putz

Duda-Seiman

et al. 2016

IJMS

Self Cite

View full text Add to dashboard Cite

show abstract

“…Note that the Euclidean distance itself employs the square of the correlations factors, i.e. , a higher order statistical framework, which nevertheless may be further enriched with other statistical outputs and factors, although all directly or indirectly depend on the correlation factor [155].…”

Section: Resultsmentioning

confidence: 99%

Determining Chemical Reactivity Driving Biological Activity from SMILES Transformations: The Bonding Mechanism of Anti-HIV Pyrimidines

Putz

Dudaş

2013

Molecules

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Abstract:Assessing the molecular mechanism of a chemical-biological interaction and bonding stands as the ultimate goal of any modern quantitative structure-activity relationship (QSAR) study. To this end the present work employs the main chemical reactivity structural descriptors (electronegativity, chemical hardness, chemical power, electrophilicity) to unfold the variational QSAR though their min-max correspondence principles as applied to the Simplified Molecular Input Line Entry System (SMILES) transformation of selected uracil derivatives with anti-HIV potential with the aim of establishing the main stages whereby the given compounds may inhibit HIV infection. The bonding can be completely described by explicitly considering by means of basic indices and chemical reactivity principles two forms of SMILES structures of the pyrimidines, the Longest SMILES Molecular Chain (LoSMoC) and the Branching SMILES (BraS), respectively, as the effective forms involved in the anti-HIV activity mechanism and according to the present work, also necessary intermediates in molecular pathways targeting/docking biological sites of interest.

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“…It requires strategies where it is possible to identify minimal regularities. Within the group of Supervised learning algorithms there are some that focus on relating chemical structure to biological activity, evaluating only one physico-chemical property and obtaining the best results in the identification of the main action or function of a protein, these algorithms are called Quantitative structure-activity relationship models (QSAR models) (Putz et al, 2011). The more than 80 QSAR algorithms known (Qureshi et al, 2014) use physico-chemical metrics involving the linear representation and/or the 3D structure of the protein and evaluate one or more properties simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Structure and function relationships of proteins based on polar profile: a review.

2016

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Proteins in the post-genome era impose diverse research challenges, the main are the understanding of their structure-function mechanism, and the growing need for new pharmaceutical drugs, particularly antibiotics that help clinicians treat the ever- increasing number of Multidrug-Resistant Organisms (MDROs). Although, there is a wide range of mathematical-computational algorithms to satisfy the demand, among them the Quantitative Structure-Activity Relationship algorithms that have shown better performance using a characteristic training data of the property searched; their performance has stagnated regardless of the number of metrics they evaluate and their complexity. This article reviews the characteristics of these metrics, and the need to reconsider the mathematical structure that expresses them, directing their design to a more comprehensive algebraic structure. It also shows how the main function of a protein can be determined by measuring the polarity of its linear sequence, with a high level of accuracy, and how such exhaustive metric stands as a "fingerprint" that can be applied to scan the protein regions to obtain new pharmaceutical drugs, and thus to establish how the singularities led to the specialization of the protein groups known today.

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Introducing Catastrophe-QSAR. Application on Modeling Molecular Mechanisms of Pyridinone Derivative-Type HIV Non-Nucleoside Reverse Transcriptase Inhibitors

Cited by 8 publications

References 54 publications

Chemical Structure-Biological Activity Models for Pharmacophores’ 3D-Interactions

Chemical Structure-Biological Activity Models for Pharmacophores’ 3D-Interactions

Determining Chemical Reactivity Driving Biological Activity from SMILES Transformations: The Bonding Mechanism of Anti-HIV Pyrimidines

Structure and function relationships of proteins based on polar profile: a review.

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