Polyamine as a microenvironment factor in resistance to antibiotics.

One of the main issues in modern medicine is the decrease in the efficacy of antibiotic therapy against resistant microorganisms. The advent of antimicrobial resistance has added significantly to the impact of infectious diseases, in number of infections, as well as added healthcare costs. The development of antibiotic tolerance and resistance is influenced by a variety of environmental variables, and it is important to identify these environmental factors as part of any strategy for combating antibiotic resistance. The review aims to emphasize that biogenic polyamines are one of such environmental cues that impacts the antibiotic resistance in bacteria. The biogenic polyamines can help bacteria acquire resistance to antibiotics either by regulating the level of number of porin channels in the outer membrane, by modifying the outer membrane liposaccharides or by protecting macromolecule from antibiotic stress. Thus, understanding the way polyamines function in bacteria can thus be beneficial while designing the drugs to combat diseases.

Spermidine promotes lysozyme tolerance and acid stress resistance in Streptococcus pyogenes M3.

Streptococcus pyogenes are Gram-positive opportunistic pathogens residing in the human nasopharynx and skin. Changes in environmental conditions, such as pH, temperature and availability of essential ions, can stimulate the expression of S. pyogenes virulence factors. One such factor could be the availability of an extracellular pool of polyamines. Polyamines are synthesized from amino acids, and are universally present in the environment. Polyamines have been implicated in the ecology of pathogenesis by modulating quorum sensing, host adaptation and virulence. Polyamines mediate pathogenesis and help the pathogen resist environmental stress. In this study, we investigated the ability of the polyamine, spermidine, to promote acid stress survival of S. pyogenes. S. pyogenes does not synthesize spermidine, but the extracellular pool of spermidine constituted by the host and microbiome could be utilized as a signalling molecule. We report that spermidine promotes acid stress resistance in S. pyogenes. Moreover, spermidine affects the morphology of S. pyogenes by decreasing the cell size and increasing the dltA gene expression. Along with dltA, spermidine upregulated the gene expression of cell wall-modifying genes such as mur, pgdA, pepO and srtA, which might help the bacteria to resist acidic stress.

CRISPR/Cas 9-Based Editing in the Production of Bioactive Molecules.

Plants, fungi, and bacteria synthesize a wide range of secondary metabolites that exhibit diverse biological activities. These bioactives, due to their potential benefits in research and therapeutics, have gained immense industrial importance. There is a need to synthesize these bioactives at significantly higher concentrations using cost-effective measures to be economically viable. However, the broader study of industrially important secondary metabolites has been hindered, thus, far due to a shortage of reliable, comparatively easy, and highly effective gene manipulation techniques. With the advent of Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR/Cas), there is a revolution in the field of genetic engineering. CRISPR/Cas system, due to its simplicity and ease of use. This has widened its application in plant breeding, strain improvement, and engineering the metabolic pathways involved in the biochemical synthesis of industrially valuable bioactive. This review briefly introduces the CRISPR/Cas9 system and summarizes the applications of CRISPR/Cas9-mediated editing tools for the production of plant and fungal-derived bioactives.