Melamine contamination and associated health risks: Gut microbiota does make a difference.

Melamine is a nitrogenous organic compound containing high amounts of nitrogen, which is interpreted as high protein in various standard protein measuring tests, therefore added to foods to boost the protein content. Illegal addition of melamine has been in practice by food manufacturers, which leads to toxicity and stone formation in kidneys of individuals consuming melamine-contaminated milk products. A focused and thorough structured search of bibliographic databases for peer-reviewed researches reported in the literature was carried out with a focused attention on melamine contamination, associated health risks, and the role of gut microbiota. The overall outcomes of the research and review articles pertaining to searched keywords along with analysis of the interventions have been described employing a deductive qualitative content analysis approach. Current review focuses on the various health risks associated with consumption of melamine-contaminated foods and the need to develop better and effective methods for its testing. Moreover, the importance of gut microbiota in mediating toxicity due to melamine has also been discussed as there is a link between toxicity and activities of gut microbiota.

Understanding the microbiome: Emerging biomarkers for exploiting the microbiota for personalized medicine against cancer.

The human body is a home to more than 1 trillion microbes with a diverse variety of commensal microbes that play a crucial role towards the health of the individual. These microbes occupy different habitats such as gut, skin, vagina, oral etc. Not only the types and abundance of microbes are different in different organs, but also these may differ in different individuals. The genome of these microbiota and their ecosystem constitute to form a microbiome. Factors such as diet, environment, host genetics etc. may be the reason behind the wide microbial diversity. A number of studies performed on human microbiome have revealed that microbiota present in healthy and diseased individuals are distinct. Altered microbiome is many a times the reason behind the overexpression of genes which may cause complex diseases including cancer. Manipulation of the human microbiome can be done by microbial supplements such as probiotics or synbiotics, diet or prebiotics and microbial suppression strategies using antibiotics. Recent advances in genome sequencing technologies and metagenomic analysis provide us the broader understanding of these commensal microbes and highlighting the distinctive features of microbiome during healthy and disease states. Molecular pathological epidemiology (MPE) studies have been very helpful in providing insights into the pathological process behind disease evolution and progression by determining the specific etiological factors. New emerging field of research targets the microbiome for therapeutic purposes by which personalized medicines can be made for treating various types of tumors. Screening programmes might be helpful in identifying patients who are at the verge of developing cancer and in delivering appropriate approaches according to individual risk modes so that disease could be prevented.

Analytical profiling of mutations in quinolone resistance determining region of gyrA gene among UPEC.

Mutations in gyrA are the primary cause of quinolone resistance encountered in gram-negative clinical isolates. The prospect of this work was to analyze the role of gyrA mutations in eliciting high quinolone resistance in uropathogenic E.coli (UPEC) through molecular docking studies. Quinolone susceptibility testing of 18 E.coli strains isolated from UTI patients revealed unusually high resistance level to all the quinolones used; especially norfloxacin and ciprofloxacin. The QRDR of gyrA was amplified and sequenced. Mutations identified in gyrA of E.coli included Ser83Leu, Asp87Asn and Ala93Gly/Glu. Contrasting previous reports, we found Ser83Leu substitution in sensitive strains. Strains with S83L, D87N and A93E (A15 and A26) demonstrated norfloxacin MICs ≥1024mg/L which could be proof that Asp87Asn is necessary for resistance phenotype. Resistance to levofloxacin was comparatively lower in all the isolates. Docking of 4 quinolones (ciprofloxacin, ofloxacin, levofloxacin and norfloxacin) to normal and mutated E.coli gyrase A protein demonstrated lower binding energies for the latter, with significant displacement of norfloxacin in the mutated GyrA complex and least displacement in case of levofloxacin.

Melamine binding with arachidonic acid binding sites of albumin is a potential mechanism for melamine-induced inflammation.

Melamine adulteration of food is a public health concern. It has been seen that melamine causes disease in many organs. Melamine-induced kidney disease is a well-recognized clinicopathological entity. Inflammation is thought to be important in melamine-induced pathology. Melamine is expected to bind with albumin because it has a positive charge. Albumin binds arachidonic acid. So if binding of melamine with albumin takes place, it has the potential to displace arachidonic acid from the albumin bound state. This phenomenon may be the source of mediators of inflammation in the melamine exposure state. This aspect is investigated in the present study by docking and molecular dynamics simulation. It is observed that melamine binds with some known arachidonic acid binding sites of albumin. This can lead to formation of more free arachidonic acid. It is also observed that melamine does not bind with extracellular signal regulated kinase 2 (ERK2). Therefore, the signal transduction mediated process involving ERK2 is not a likely mechanism of melamine-induced inflammation. Therefore, we think that an increased free arachidonic acid level may contribute more to inflammation in the melamine exposure state.