Current Drug Discovery Technologies - Volume 15, Issue 3, 2018

Background: Heterocycles containing thiazole, a moiety with sulfur and nitrogen is a core structure which is found in a number of biologically active compounds. The thiazole ring is notable as a component of the certain natural products, such as vitamin B1 (thiamine) and penicillins. Thiazole is also known as wonder nucleus and has uses in different biological fields. A number of new compounds contain heterocycle thiazole moieties, thus it is one of the important areas of research. Methods: We searched the scientific database using relevant keywords. Among the searched literature only peer-reviewed papers were collected which addresses our questions. The retrieved quality research articles were screened and analyzed critically. The key findings of these studies were included along with their importance. Results: The quality research articles included in this review were selected for the lifethreatening diseases i.e. diabetes, which is one of the serious issues all over the globe with an estimated worldwide prevalence in 2016 of 422 million people, which is expected to rise double to by 2030. Since 1995, there has been an explosion of the introduction of new classes of pharmacological agents having thiazole moieties. However, most of the drugs can cause noncompliance, hypoglycemia, and obesity. Thus, new antidiabetic drugs with thiazole moieties came up with improved compliance and reduced side effects such as pioglitazone (Actos), rosiglitazone (Avandia), netoglitazone, DRF-2189, PHT46, PMT13, DRF-2519. With such a great importance, research in thiazole is part of many academic and industrial laboratories worldwide. Conclusion: The present review describes the importance of thiazole nucleus and its derivatives as antidiabetic agents with an emphasis on the past as well as recent developments.

Background: Thiazoles are promising scaffolds in the area of medicinal and pharmaceutical chemistry and have accounted to show different pharmacophoric properties. For the last years, thiazole derivatives have focused too much attention to develop different new CNS active agents. It has been broadly used to generate diverse therapeutic agents against various CNS targets. Histamine H3 receptors are seriously involved in the pathophysiology of numerous disorders of the central nervous system. Method: The literature survey has been done using different database from peerreviewed journals. The quality of repossessed papers was evaluated using standard tools. The details of important papers were described to focus on the potency of thiazole containing heterocycles with CNS activity. Result: Eighty nine papers were included in the review indicating thiazole containing heterocycles with CNS activity. (1) to (30) papers included different thiazole derivatives impregnated withCNS activity. Different CNS agents have been shown in references (37) to (56). The remaining papers have been searched for anticonvulsant agents (57) to (78) and other miscellaneous activities from (79) to (89). Conclusion: A detailed investigation has been carried out on thiazoles and its derivatives to judge its efficacy to overcome several CNS disorders. This article covers the recent updates of thiazole and its derivative with CNS activity already present in literature and will definitely provide a better platform for the production and development of potent thiazole based CNS vigorous drugs in near future.

Background: Heterocyclic compounds are the main class of medicinally important compounds. Many heterocyclic compounds bearing a five-membered ring in their structure have a good spectrum of biological activities. Thiazole is an important class of five-membered heterocyclic compounds. Thiazole and its derivatives exhibited a broad range of biological activities due to the presence of various reaction posseses. Thiazole, heterocyclic nucleus is present in several potent pharmacologically active molecules such as Sulfathiazole (antimicrobial drug), Ritonavir (antiretroviral drug), Tiazofurin (antineoplastic drug) and Abafungin (antifungal drug) etc. The search for some novel biologically active thiazoles is to be continued in the field of medicinal chemistry for investigators. An aim of this review is to identify and try making a SAR (Structure Activity Relationship) of substituted thiazole nucleus as possible new antimalarials. Method: Author undertook a structured search of bibliographic databases for peerreviewed research literature using a focused review question and inclusion/exclusion criteria. The quality of retrieved papers was appraised using standard tools. The characteristics of screened papers were described, and a deductive qualitative content analysis methodology was applied to analyse the interventions and findings of included studies using a conceptual framework. Result: Fifteen papers were included in the review; the majority were described about many biological activity of thiazole nucleus. Seven papers were find that had impacted upon the thaizoles as antimalarials. Some papers focused on the design, synthesis and antimalarial activity evaluation of thiazole derivatives. This review identified and made a SAR (Structure Activity Relationship) of substituted thiazole nucleus as possible new antimalarials. Conclusion: This review describes ongoing research in the search for novel thiazoles as targets and new antimalarial drug molecules.

Background: The thiazolide nitazoxanide (NTZ) is a broad-spectrum antiinfective drug that adversely affects viability, growth, and proliferation of a range of extracellular and intracellular protozoan, helminths, anaerobic and microaerophilic bacteria, and viruses. Method: Current review compiled the potential chemotherapeutic efficacy of NTZ against a variety of such disease-causing macro and/or micro-organisms as well as neoplastic cells, using various search engines viz. Web of Science, Scopus and Pub- Med up to February 2017. Result: The most accepted anti-infective mechanism of NTZ involves impairment of the energy metabolism in anaerobic pathogens by inhibition of the pyruvate: ferredoxin/ flavodoxin oxidoreductase (PFOR). In parasitic-protozoan NTZ also induces lesions/voids in the cell membrane and depolarises the mitochondrial membrane along with the inhibition of quinone oxidoreductase NQO1, nitroreductase-1 and protein disulphide isomerase. NTZ also inhibits the glutathione-S-transferase (a major detoxifying enzyme) and modulates a gene (avr-14 gene) encoding for the alphatype subunit of glutamate-gated chloride ion channel present in the nematodes. Apart from well recognized non-competitive inhibition of the PFOR in anaerobic bacteria, NTZ also showed a variety of other antibacterial mechanisms viz. inhibits pyruvate dehydrogenase in the Escherichia coli, disrupts the membrane potential and pH homeostasis in the Mycobacterium tuberculosis, suppresses the chaperone/usher (CU) pathway of the gram-negative bacteria and stimulates host macrophage autophagy in the tubercular patients. NTZ also suppresses the viral replication by inhibiting maturation of the viral hemagglutinin and the viral transcription factor immediate early 2 (IE2) as well as by activating the eukaryotic translation initiation factor 2α (an antiviral intracellular protein). Additionally, NTZ expresses inhibitory effect on the tumour cell progression by modulating drug detoxification (glutathione-S-transferase P1), unfolded protein response, autophagy, anti-cytokines activities and c-Myc inhibition. Conclusion: These potentially versatile molecular interactions of NTZ within invading pathogen(s) and immunomodulatory efficacy over the hosts, justify the multifunctional chemotherapeutic significance of this chemical agent.

Background: Thiazole is one of the leading heterocyclic five-member ring compounds that contain nitrogen and sulphur atom. Many natural and/or synthetic compounds contain thiazole as an essential moiety and possess diverse therapeutic activities. The thiazole ring was modified at different positions to generate new molecules with potent antibacterial activities. Thus, the present review enumerates the antibacterial importance of thiazole and its derivatives. Method: The mining of literature has been performed using different database which includes only peer-reviewed journals. The quality of retrieved papers was appraised using standard tools. Moreover, the significant papers were described in detail to focus on thiazole derivatives showing considerable antibacterial activity. Result: The present review describes the chemistry, SAR (Structure Activity Relationship) studies and antibacterial importance of thiazole with different synthetic procedures. Conclusion: This particular study certainly benefits the researchers interested in exploiting the antibacterial activity of thiazoles in search of novel agents.

Glycogen synthase kinase-3 (GSK-3) is a multifunctional serine/threonine (ser/thr) kinase that was originally identified as a regulator of glycogen metabolism and coupled with insulin signaling. Due to multifunctionality of this enzyme, it is found to play an important role in the onset and progression of various human diseases. Thiazole nucleus has received special attention by medicinal chemists because of its wide therapeutic potential. The objective of this review is to cover all the aspects of GSK-3β enzyme including its clinical implications, types of inhibitors with special reference to thiazole as GSK-3β inhibitor. Literature search was performed using Pubmed/Medline and Google Scholar to search for articles published in English language.

Introduction: Peptides are fragments of proteins with significant biological activities. These peptides are encoded in the protein sequence. Initially, such peptides are inactive in their parental form, unless proteolytic enzymes are released. These peptides exhibit various functions and play a therapeutic role in the body. Objective: Besides the therapeutic and physiological activities of peptides, the main purpose of this study was to highlight the safety aspects of peptides. Method: We performed an organized toxicity and search of available literature using PubMed, Google Scholar, Medline, EMBASE, Reaxys and Scopus databases. All the relevant citations including research and review articles about the toxicity of biologically active peptides were evaluated and gathered in this study. Result: Biological peptides are widely used in the daily routine ranging from food production to the cosmetics industry and also they have a beneficial role in the treatment and prevention of different diseases. These peptides are manufactured by both chemical and biotechnological techniques, which show negligible toxicity, however, some naturally occurring peptides and enzymes may induce high toxicity. Depending upon the demand and expected use in the food or pharmaceutical industry, we need different approaches to acertain the safety of these peptides preferentially through in silico methods. Conclusion: Intestinal wall disruption, erythrocytes and lymphocytes toxicity, free radical production, enzymopathic and immunopathic tissue damage and cytotoxicity due to the consumption of peptides are the main problems in the biological system that lead to various complicated disorders. Therefore, before considering biologically active peptides for food production and for therapeutic purpose, it is first necessary to evaluate the immunogenicity and toxicities of peptides.

Background: Cicer arietinum is one of the popular legumes in the most parts of the world. It is known for a long time in Asia because of the many possibilities of its application. Cicer arietinum has benefits for the skin regarding safe ingredients. Some of these ingredients are recommended in skin care. Methods: This study aimed to introduce the benefits of Cicer arietinum by reviewing of traditional literature from 10th to 21th century and also conventional medicine for its safe ingredients by searching the electronic data banks such as ISI, Pub Med and Scopus. Results: The results showed that Cicer arietinum has many ingredients such as Phenolic compounds, allantoin and amino acids that affect the skin problems. Also, great traditional Persian scientists such as Avicenna and Razi suggested about the cutaneous benefits of Cicer arietinum. Conclusion: The findings of this study can help the researchers in producing better cosmetic and therapeutic products.

Background and Objective: HCMV infection may cause neurodevelopmental disorders, including intellectual disability, hearing loss, cortical malformations, and calcifications. Theorizing about the still unknown molecular basis of HCMV-related diseases, this study analyzes the peptide sharing between HCMV, strains AD169 and Merlin, and human proteins, searching for shared sequences that might lead to crossreactive autoimmune injuries in the brain during immune responses following HCMV infection. Method: HCMV proteins were analyzed for peptides shared with the human proteome using the Pir Peptide Match resource. Result: Numerous HCMV peptides (ranging from 9 to 13 mer in length) are disseminated through hundreds of human proteins. The peptide sharing mostly involves crucial neurodevelopmental antigens such as PITX3, implicated in the differentiation of meso-diencephalic dopaminergic neurons; SIX3, which controls proper anterioposterior patterning of the diencephalon and formation of the rostral diencephalon during forebrain development; and ZIC2, which plays a fundamental role in the early stage of organogenesis of the central nervous system. Conclusion: This study describes a HCMV vs human peptide overlap that may represent a crossreactive platform linking the pathologic sequelae of HCMV infection to the immune anti-HCMV response. The data could inform development of effective and safe immune therapeutic/preventive approaches against HCMV infections.

Background: Risperidone is an antipsychotic drug. In blood, this drug binds mainly to human serum albumin (HSA) and is also transported by HSA. Method: To study certain details of the interaction between risperidone and HSA, a fluorescent dye CAPIDAN was used as a reporter. This dye specifically fluoresces from HSA in serum and is highly sensitive to structural changes in HSA including pathology-induced changes. Interaction of CAPIDAN with HSA has been studied using time-resolved fluorescence techniques. Result: The addition of phenylbutazone, a marker for the HSA drug-binding site I, leads to displacement of CAPIDAN from this site due to direct competition between phenylbutazone and the dye. The addition of risperidone induces a response of CAPIDAN fluorescence that is highly similar to its response to phenylbutazone. This response depends strongly on ionic strength and is very similar in both cases, phenylbutazone and risperidone. This similarity suggests that risperidone binds to HSA in the region of site I. In this site, the risperidone molecule probably covers the positive charge of Arginine 218 or Arginine 222 preventing their interaction with the CAPIDAN negatively charged carboxyl group. This effect was observed both in isolated HSA and in serum, suggesting similarity of the interaction. Conclusion: Thus, risperidone is able to prevent binding of organic anions (i.e. CAPIDAN as a drug-like molecule) to HSA.