Harnessing plant growth-promoting rhizobacteria, Bacillus subtilis and B. aryabhattai to combat salt stress in rice: a study on the regulation of antioxidant defense, ion homeostasis, and photosynthetic parameters.

Introduction: The ongoing global expansion of salt-affected land is a significant factor, limiting the growth and yield of crops, particularly rice (Oryza sativa L). This experiment explores the mitigation of salt-induced damage in rice (cv BRRI dhan100) following the application of plant growth-promoting rhizobacteria (PGPR). Methods: Rice seedlings, at five- and six-weeks post-transplanting, were subjected to salt stress treatments using 50 and 100 mM NaCl at seven-day intervals. Bacterial cultures consisting of endophytic PGPR (Bacillus subtilis and B. aryabhattai) and an epiphytic PGPR (B. aryabhattai) were administered at three critical stages: transplantation of 42-day-old seedlings, vegetative stage at five weeks post-transplantation, and panicle initiation stage at seven weeks post-transplantation. Results: Salt stress induced osmotic stress, ionic imbalances, and oxidative damage in rice plants, with consequent negative effects on growth, decrease in photosynthetic efficiency, and changes in hormonal regulation, along with increased methylglyoxal (MG) toxicity. PGPR treatment alleviated salinity effects by improving plant antioxidant defenses, restoring ionic equilibrium, enhancing water balance, increasing nutrient uptake, improving photosynthetic attributes, bolstering hormone synthesis, and enhancing MG detoxification. Discussion: These findings highlight the potential of PGPR to bolster physiological and biochemical functionality in rice by serving as an effective buffer against salt stress-induced damage. B. subtilis showed the greatest benefits, while both the endophytic and epiphytic B. aryabhattai had commendable effects in mitigating salt stress-induced damage in rice plants.

Complete genome and plasmid sequence of a novel Bacillus sp. BD59S, a parasporal protein synthesizing bacterium.

Parasporal crystalline inclusion proteins of some Bacillus spp. are of paramount importance due to their insecticidal, nematocidal, and cancer cell killing capabilities. Here, we present a brief report of the complete genome sequence of Bacillus sp. BD59S, a bacterium that produced HeLa cell-killing parasporal crystalline inclusion proteins. From genome sequencing and assembly, we found that the bacterium has one circular chromosome and two large plasmids, pBTBD59S1 and pBTBD59S2. The size of the chromosome is 5283,933 bp with a 35.4% GC content, consisting of 5938 genes and 5550 protein-coding sequences (CDSs), 25 complete rRNAs (5S, 16S, 23S), 98 tRNAs, 5 ncRNAs, 260 pseudo-genes, and 356 subsystems. Complete plasmid sequence of pBTBD59S1 comprises a total size of 162,149 bp with 33.4% GC content, 192 CDSs, and 13 subsystems. The other plasmid pBTBD59S2, is 199,209 bp long with 32.9% GC content, 179 CDSs, and 11 subsystems. Analyses by NCBI microbial genome BLAST, phylogenetic genome tree, and BLAST ring image generator (BRIG) revealed that BD59S belongs to Bacillus cereus group, and is more close to B. thuringiensis. Further, the strain possesses 57.04 kDa and 54.42 kDa Cry protein-coding genes, which show significant similarities with cancer cell-killing parasporin proteins of B. thuringiensis strains.

Complete Genome Sequence of Bacillus subtilis Strain MH1, Which Has a High Level of Bacteriocin-Like Activity, Isolated from Soil in Bangladesh.

Bacillus subtilis MH1 demonstrates a high level of bacteriocin activity against several pathogenic bacteria. We announce here the full-genome sequence of strain MH1, isolated from soil in Bangladesh. This genome length is 4,094,053 bp, with 43.5% GC content, 4,217 coding sequences (CDS), 10 rRNA, 84 tRNA, and 1 transfer-messenger RNA (tmRNA).

Novel toxicity of Bacillus thuringiensis strains against the melon fruit fly, Bactrocera cucurbitae (Diptera: Tephritidae).

Bactrocera cucurbitae (melon fruit fly) is one of the most detrimental vegetable-damaging pests in Bangladesh. The toxicity of Bacillus thuringiensis (Bt) has been reported against a few genera of Bactrocera in addition to numerous other insect species. Bt strains, harbouring cry1A-type genes were, therefore, assayed in vivo against the 3(rd) instar larvae of B. cucurbitae in this study. The biotype-based prevalence of cry1 and cry1A genes was calculated to be 30.8% and 11.16%, respectively, of the test strains (n=224) while their prevalence was greatest in biotype kurstaki. Though three indigenous Bt strains from biotype kurstaki with close genetic relationship exhibited higher toxicity, maximum mortalities were recorded for Btk HD-73 (96%) and the indigenous Bt JSc1 (93%). LC50 and LC99 values were determined to be 6.81 and 8.32 for Bt JSc1, 7.30 and 7.92 for Bt SSc2, and 6.99 and 7.67 for Btk HD-73, respectively. The cause of toxicity and its variation among the strains was found to be correlated with the synergistic toxic effects of cry1, cry2, cry3 and cry9 gene products, i.e. relevant Cry proteins. The novel toxicity of the B. thuringiensis strains against B. cucurbitae revealed in the present study thus will help in developing efficient and eco-friendly control measures such as Bt biopesticides and transgenic Bt cucurbits.