DIE WIRKUNG VERSCHIEDENER, ÜBER DIE PFLANZE ZUGEFÜHRTER ANTIBIOTICA AUF ENTWICKLUNG UND FERTILITÄT DER SCHWARZEN BOHNENBLATTLAUS APHIS FABAE

Zusammenfassung Unter dem Einfluss verschiedener Antibiotica wird die Larvalentwicklung von Bohnenblattläusen stark gehemmt. Diese Substanzen bedingen ausserdem geringere Größe und vermindertes Gewicht der Aphiden im Vergleich zu unbehandelten Kontrolltieren. Je nach Art und Konzentration des verwendeten Antibioticums bleiben die Aphiden entweder völlig steril oder ihre Reproduktionsfähigkeit wird unterschiedlich stark herabgesetzt. Bereits eine einbis zweitägige Terramycinaufnahme durch Aphiden während des ersten Larvenstadiums ist ausreichend, um beim adulten Tier völlige Sterilität hervorzurufen.

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Summary A considerable delay in larval development of black bean aphids was observed when they were kept permanently on Vicia faba plants in solutions containing antibiotics. The reduction in the weight and size of the aphids on treated plants were also marked in comparison with those on untreated plants. Furthermore, total sterility was observed in certain cases and reduced reproductive rate in others. This effect was related to the chemical constitution, and the concentration of the antibiotics tested. The most effective substances were: terramycin, aureomycin, tetracyclin, chloramphenicol, and reverin. All other antibiotics had none or only a slight impact on reproduction. Even when young larvae fed for a short period (one or two days) on terramycin treated plants, total sterility resulted. The relation between the larval development and reproductive rate of aphids, and the destruction of their symbiotes by antibiotics is discussed.

     

Role of large hydrophobic residues in proteins

Large Hydrophobic Residues (LHR) such as phenylalanine, isoleucine, leucine, methionine and valine play an important role in protein structure and activity. We describe the role of LHR in complete set of protein sequences in 15 different species. That is the distribution of LHR in different proteins of different species is reported. It is observed that the proteins prefer to have 27% of large hydrophobic residues in total and all along the sequence. It is also observed that proteins accumulate more LHR in its active sites. A window analysis on these protein sequences shows that the 27% of LHR is more frequent at window length of 45 amino acids. The influenza virus and P. falciparum show a random distribution of LHR in its proteins compared to other model organisms.     

In silico insights on tankyrase protein: A potential target for colorectal cancer

Abstract

The Wnt/β-catenin pathway plays an important regulatory role in cancer signaling and cell regenerative mechanisms. Its suppression has long been considered as an important challenge of anticancer treatment and management. The poly(ADP-ribose) polymerase (PARP) family represented as a new class of therapeutic targets with diverse potential disease indications. Tankyrase (TNKS) is considered to be a potential target for the intervention of various cancers. The main objective of the work is to explore the molecular and quantum mechanics of the drug-like compounds and to identify the potential inhibitors for TNKS protein using the structure and ligand-based virtual screening from several databases and to explore the binding pocket and interactions of active residues. The screened compounds were further filtered using binding-free energy calculation and molecular dynamics simulation studies. The results have provided a strong molecular knowledge of TNKS and offered top hit potent inhibitors. The identified lead compounds LC_40781, LC_40777, LC_39767, LC_8346, NCI_682438, and NCI_721141 were observed to have potent activity against TNKS protein. The hydrogen bonding of compounds with Asp1198, His1201, Tyr1203 in TNKS1 and Gly1032, Ser1068 in TNKS2 are the key interactions plays a major role in binding energy. Therefore, the outcome of the study would help for further validation and provides valuable information to guide the future TNKS-specific inhibitor designing.

Communicated by Ramaswamy H. Sarma     

Development of a theoretical model for the inhibition of nsP3 protease of Chikungunya virus using pyranooxazoles

Abstract

Chikungunya virus (CHIKV) causes Chikungunya fever (CHIKF) and till date no effective medicine for its cure is available in market. Different research groups find various possible interactions between small molecules and non-structural proteins, viz. nsP3, one of the most important viral elements in CHIKV. In this work, authors have studied the interactions of nsP3 protease of CHIKV with pyranooxazoles. Initially, a one-pot three-component reaction was designed using oxazolidine-2,4-dione, benzaldehyde and cyanoethylacetate to get a proposed biological active molecule, i.e. based on pyranooxazoles. The mechanism for the synthesis of the product based on pyranooxazole was studied through density functional theory (DFT) using Gaussian. Then, a library of the obtained pyranooxazole was created through computational tools by varying the substituents. Further, virtual screening of the designed library of pyranooxazoles (200 compounds) against nsP3 protease of CHIKV was performed. Herein, CMPD 104 showed strongest binding affinity toward the targeted nsP3 protease of CHIKV, based on the least binding energy obtained from docking. Based on docking results, the pharmacological, toxicity, biological score and Lipinski’s filters were studied. Further, DFT studies of top five compounds were done using Gaussian. Molecular dynamics (MD) simulation of nsP3 protease of CHIKV with and without 104 was performed using AMBER18 utilizing ff14SB force field in three steps (minimization, equilibration and production). This work is emphasized to designing of one-pot three-component synthesis and to develop a theoretical model to inhibit the nsP3 protease of CHIKV. Abbreviations CHIKF Chikungunya fever

CHIKV Chikungunya virus

DFT density functional theory

DS Discovery Studio

MD molecular dynamics

MM-GBSA molecular mechanics-generalized born surface area

MMV Molegro molecular viewer

Communicated by Ramaswamy H. Sarma