Antimicrobial resistance landscape in a metropolitan city context using open drain wastewater-based metagenomic analysis.

One Health concept recognizes the inextricable interactions of diverse ecosystems and their subsequent effect on human, animal and plant health. Antimicrobial resistance (AMR) is a major One Health concern and is predicted to cause catastrophes if appropriate measures are not implemented. To understand the AMR landscape in a south Indian metropolitan city, metagenomic analysis of open drains was performed. The data suggests that in January 2022, macrolide class of antibiotics contributed the highest resistance of 40.1% in the city, followed by aminoglycoside- 24.4%, tetracycline- 11.3% and lincosamide- 6.7%. The 'mutations in the 23S rRNA gene conferring resistance to macrolide antibiotics' were the major contributor of resistance with a prevalence of 39.7%, followed by '16s rRNA with mutation conferring resistance to aminoglycoside antibiotics'- 22.2%, '16S rRNA with mutation conferring resistance to tetracycline derivatives'- 9.2%, and '23S rRNA with mutation conferring resistance to lincosamide antibiotics'- 6.7%. The most prevalent antimicrobial resistance gene (ARG) 'mutations in the 23S rRNA gene conferring resistance to macrolide antibiotics' was present in multiple pathogens including Escherichia coli, Campylobacter jejuni, Acinetobacter baumannii, Streptococcus pneumoniae, Pseudomonas aeruginosa, Neisseria gonorrhoeae, Klebsiella pneumoniae and Helicobacter pylori. Most of the geographical locations in the city showed a similar landscape for AMR. Considering human mobility and anthropogenic activities, such an AMR landscape could be common across other regions too. The data indicates that pathogens are evolving and acquiring antibiotic resistance genes to evade antibiotics of multiple major drug classes in diverse hosts. The outcomes of the study are relevant not only in understanding the resistance landscape at a broader level but are also important for identifying the resistant drug classes, the mechanisms of gaining resistance and for developing new drugs that target specific pathways. This kind of surveillance protocol can be extended to regions in other developing countries to assess and combat the problem of antimicrobial resistance.

mRNA biotherapeutics landscape for rare genetic disorders.

The medical emergency of COVID-19 brought to the forefront mRNA vaccine technology where the mRNA vaccine candidates mRNA-1273 and BNT162b2 displayed superlative and more than 90% efficacy in protecting against SARS-CoV2 infections. Rare genetic disorders are rare individually, but collectively they are common and represent a medical emergency. In mRNA biotherapeutic technology, administration of a therapeutic protein-encoding mRNA-nanoparticle formulation allows for in vivo production of therapeutic proteins to functionally complement the protein functions lacking in rare disease patients. The platform nature of mRNA biotherapeutic technology propels rare disease drug discovery and, owing to the scalable and synthetic nature of mRNA manufacturing, empowers parallel product development using a universal production pipeline. This review focuses on the advantages of mRNA biotherapeutic technology over current therapies for rare diseases and provides summaries for the proof-of-concept preclinical studies performed to demonstrate the potential of mRNA biotherapeutic technology. Apart from preclinical studies, this review also spotlights the clinical trials currently being conducted for mRNA biotherapeutic candidates. Currently, seven mRNA biotherapeutic candidates have entered clinical trials for rare diseases, and of them, 3 candidates entered in the year 2023 alone. The rapid pace of clinical development promises a future where, as with mRNA vaccines for COVID-19, mRNA biotherapeutic technology would combat an emergency of rare genetic disorders.

Spinal muscular atrophy: Molecular mechanism of pathogenesis, diagnosis, therapeutics, and clinical trials in the Indian context.

Spinal muscular atrophy (SMA) is a neuromuscular, rare genetic disorder caused due to loss-of-function mutations in the survival motor neuron-1 (SMN1) gene, leading to deficiency of the SMN protein. The severity of the disease phenotype is inversely proportional to the copy number of another gene, SMN2, that differs from SMN1 by a few nucleotides. The current diagnostic methods for SMA include symptom-based diagnosis, biochemical methods like detection of serum creatine kinase, and molecular detection of disease-causing mutations using polymerase chain reaction (PCR), multiplex ligation-dependent probe amplification (MLPA), and exome or next-generation sequencing (NGS). Along with detection of the disease-causing mutation in the SMN1 gene, it is crucial to identify the copy number of the SMN2 gene, which is a disease modifier. Therapeutic options like gene therapy, antisense therapy, and small molecules are available for SMA, but, the costs are prohibitively high. This review discusses the prevalence, diagnosis, available therapeutic options for SMA, and their clinical trials in the Indian context, and highlights the need for measures to make indigenous diagnostic and therapeutic interventions.

Isolation of a non-genomic origin fluoroquinolone responsive regulatory element using a combinatorial bioengineering approach.

Advances in chemical biology have led to selection of synthetic functional nucleic acids for in vivo applications. Discovery of synthetic nucleic acid regulatory elements has been a long-standing goal of chemical biologists. Availability of vast genome level genetic resources has motivated efforts for discovery and understanding of inducible synthetic genetic regulatory elements. Such elements can lead to custom-design of switches and sensors, oscillators, digital logic evaluators and cell-cell communicators. Here, we describe a simple, robust and universally applicable module for discovery of inducible gene regulatory elements. The distinguishing feature is the use of a toxic peptide as a reporter to suppress the background of unwanted bacterial recombinants. Using this strategy, we show that it is possible to isolate genetic elements of non-genomic origin which specifically get activated in the presence of DNA gyrase A inhibitors belonging to fluoroquinolone (FQ) group of chemicals. Further, using a system level genetic resource, we prove that the genetic regulation is exerted through histone-like nucleoid structuring (H-NS) repressor protein. Till date, there are no reports of in vivo selection of non-genomic origin inducible regulatory promoter like elements. Our strategy opens an uncharted route to discover inducible synthetic regulatory elements from biologically-inspired nucleic acid sequences.