Novel role of Wag31 in protection of mycobacteria under oxidative stress

Wag31 of Mycobacterium tuberculosis belongs to the DivIVA family of proteins known to regulate cell morphology in Gram-positive bacteria. Here we demonstrate an unrecognized, novel role of Wag31 in oxidatively stressed mycobacteria. We report the cleavage of penicillin-binding protein 3 (PBP3) by the intramembrane metalloprotease Rv2869c (MSMEG_2579) in oxidatively stressed cells. Amino acids ¹⁰²A and ¹⁰³A of PBP3 are required for Rv2869c-mediated cleavage. Wag31_MTB, by virtue of its interaction with PBP3 through amino acid residues ⁴⁶NSD⁴⁸, protects it from oxidative stress-induced cleavage. PBP3 undergoes cleavage in Mycobacterium smegmatis (strain PM2) harbouring wag31 (Δ⁴⁶NSD⁴⁸) instead of the wild type, with concomitant reduction in ability to withstand oxidative stress. Overexpression of Wag31(Δ⁴⁶NSD⁴⁸) attenuates the survival of M. tuberculosis in macrophages with concomitant cleavage of PBP3, and renders the organism more susceptible towards hydrogen peroxide as well as drugs which generate reactive oxygen species, namely isoniazid and ofloxacin. We propose that targeting Wag31 could enhance the activity of mycobactericidal drugs which are known to generate reactive oxygen species.     

Synthesis, pulse radiolysis, and in vitro radioprotection studies of melatoninolipoamide, a novel conjugate of melatonin and alpha-lipoic acid

A novel conjugate of melatonin 2 and alpha-lipoic acid 4 has been prepared using DCC mediated coupling. The conjugate named melatoninolipoamide has been assigned its structure 1 on the basis of spectral analysis (UV, IR, NMR, and EI-MS). Pulse radiolysis studies of the conjugate were carried out in aqueous solutions with both oxidizing and reducing radicals. The results indicate that the melatonin moiety of the conjugate reacts preferably with oxidizing radicals and the lipoic acid moiety exhibits preferential reaction with reducing radicals. The in vitro radioprotection ability of 1 was examined by gamma-radiation induced lipid peroxidation in liposomes and hemolysis of erythrocytes, and compared the results with those of melatonin and alpha-lipoic acid. The studies suggest that the conjugate can be explored as a probable radioprotector.     

Genetic diversity analysis of 60 ginger germplasm core accessions using ISSR and SSR markers

Molecular techniques play a critical role in studies of phylogeny and, thus, have been applied to understand the distribution and extent of genetic variation within and between species. In the present study, a genetic analysis was undertaken using molecular markers (9 ISSR and 13 SSR) on 60 ginger cultivars from different regions of the eastern coast of India (Odisha). The data obtained with 22 polymorphic markers revealed moderate to high diversity in the collection. Both ISSR and SSR markers were efficient in distinguishing all the 60 ginger cultivars. A total of 42 and 160 polymorphic bands were observed with ISSR and SSR markers, respectively. However, SSR markers were observed to be better at displaying average polymorphism (63.29%) than ISSR markers (55%). Analysis of molecular variance results showed that 52 and 66% of the variation occurred among different ginger populations, whereas 48 and 34% of the variation was found within populations, respectively, using ISSR and SSR markers, indicating that ginger cultivars display significant genetic diversity at the population level. Principal coordinates analysis and the dendrogram constructed out of combined data of both markers showed grouping of ginger accessions to their respective area of collection, indicating geographical closeness due to genetic similarity irrespective of the relationship that exists at the morphological level.     

Requirement of rRNA methylation for 80S ribosome assembly on a cohort of cellular internal ribosome entry sites

Protein syntheses mediated by cellular and viral internal ribosome entry sites (IRESs) are believed to have many features in common. Distinct mechanisms for ribosome recruitment and preinitiation complex assembly between the two processes have not been identified thus far. Here we show that the methylation status of rRNA differentially influenced the mechanism of 80S complex formation on IRES elements from the cellular sodium-coupled neutral amino acid transporter 2 (SNAT2) versus the hepatitis C virus mRNA. Translation initiation involves the assembly of the 48S preinitiation complex, followed by joining of the 60S ribosomal subunit and formation of the 80S complex. Abrogation of rRNA methylation did not affect the 48S complex but resulted in impairment of 80S complex assembly on the cellular, but not the viral, IRESs tested. Impairment of 80S complex assembly on the amino acid transporter SNAT2 IRES was rescued by purified 60S subunits containing fully methylated rRNA. We found that rRNA methylation did not affect the activity of any of the viral IRESs tested but affected the activity of numerous cellular IRESs. This work reveals a novel mechanism operating on a cohort of cellular IRESs that involves rRNA methylation for proper 80S complex assembly and efficient translation initiation.     

Hydration of protein–RNA recognition sites

We investigate the role of water molecules in 89 protein–RNA complexes taken from the Protein Data Bank. Those with tRNA and single-stranded RNA are less hydrated than with duplex or ribosomal proteins. Protein–RNA interfaces are hydrated less than protein–DNA interfaces, but more than protein–protein interfaces. Majority of the waters at protein–RNA interfaces makes multiple H-bonds; however, a fraction do not make any. Those making H-bonds have preferences for the polar groups of RNA than its partner protein. The spatial distribution of waters makes interfaces with ribosomal proteins and single-stranded RNA relatively ‘dry’ than interfaces with tRNA and duplex RNA. In contrast to protein–DNA interfaces, mainly due to the presence of the 2′OH, the ribose in protein–RNA interfaces is hydrated more than the phosphate or the bases. The minor groove in protein–RNA interfaces is hydrated more than the major groove, while in protein–DNA interfaces it is reverse. The strands make the highest number of water-mediated H-bonds per unit interface area followed by the helices and the non-regular structures. The preserved waters at protein–RNA interfaces make higher number of H-bonds than the other waters. Preserved waters contribute toward the affinity in protein–RNA recognition and should be carefully treated while engineering protein–RNA interfaces.     

Identification and evaluation of antioxidant, analgesic/anti-inflammatory activity of the most active ninhydrin-phenol adducts synthesized

Treatment of phenols with ninhydrin in acidic medium afforded 2-hydroxy-2-(ortho-hydroxy-phenyl/naphthyl)-1,3-dioxoindanes, which being unstable were isolated in their hemiketal forms. These synthesized compounds were subjected to TLC screening for radical scavenging and in vitro lipoxgenase and cycloxygenase enzyme inhibition assays. The best compound was identified and studied in detail for steady-state and time-resolved free radical kinetics, viz., DPPH, ABTS(-), *OH and rate constants for these reactions were evaluated. The best compound was also subjected to in vivo anti-inflammatory and analgesic activities in which the compound showed good promise for further structural optimization.