DNA sequence analysis of a putative primary replicon from a cryptic plasmid pNM214 of a hydrocarbon utilizing marine <Emphasis Type="Italic">Bacillus</Emphasis> strain NM21

Marine Bacillus strain NM21 isolated from hydrocarbon-contaminated site at Naval Harbour, Mumbai grows on high-speed diesel as a source of carbon and energy. This bacterium harbours four plasmids in it. The smallest plasmid, pNM214 was digested with EcoRI enzyme and cloned in pUC19 vector. The clone Om4 containing largest insert of >3.5 kb was sequenced by primer walking. DNA sequence analysis showed this fragment to be homologous to replication initiation protein (rep) gene and dso (double strand origin) of different plasmids from Bacillus subtilis and Bacillus pumilus species. The putative rep gene sequence of pNM214 showed 74.3–91.6% DNA identity to B. subtilis plasmids (pTA1015, pTA1060 and pTA1040) and 86.3% to 88.9% DNA identity to B. pumilus plasmids (pPL7065, pPL10 and pSH1452). The translated amino acid sequence of rep shows that it contains all the three conserved motifs present in the Rep protein of pC194 family of plasmids. DNA sequence comparison of putative dso of pNM214 with other bacillus plasmids belonging to pC194 group shows that it contains highly conserved nick site sequence 5′-TCTTTTCTTATCTTGATA-3′ and surrounding inverted repeats. Thus, it indicates that pNM214 to be a rolling circle replicating plasmid belonging to the pC194 group. The presence of rep and dso like sequences in the sequenced EcoRI fragment indicate that the cloned fragment contain putative primary replicon of pNM214.     

Studies on the structure—activity relationship among aliphatic and aromatic bisguanylhydrazones and some related compounds

A total of 18 compounds consisting of 7 aliphatic and 7 aromatic bis(guanylhydrazones), p-quinone-bis(guanylhydrazone), one monoguanylhydrazone, one diamidine and one diguanidine were studied spectrophotometrically to determine their ability to interact with native calf-thymus DNA and the possible correlation of binding with biological activity. In each case, the ability of a compound to bind to DNA correlated with its ability to inhibit the activity of DNA-dependent DNA polymerase (EC 2.7.7.7) extracted from mouse leukemia L1210 cells. For example, all the aromatic bis-guanylhydrazones and diamidine (hydroxystilbamidine), which were good inhibitors of the enzyme activity, showed a biphasic interaction with DNA. All the aliphatic compounds displayed no detectable interaction with DNA in the Tris buffer used, and were also poor inhibitors of the polymerase activity. Interaction of decamethylene diguanide (Synthalin) with DNA could not be determined because the compound does not absorb light in the UV-VIS region. However, in similarity with other aliphatic compounds, this agent was a poor inhibitor of DNA polymerase reaction. The p-quinone-bis(guanylhydrazone) and p-phenylbenzaldehyde-monoguanylhydrazone showed only a monophasic interaction with DNA and caused an intermediate inhibition of the enzyme activity. When tested for possible anti-leukemic activity against i.p. L1210 leukemia in syngeneic DBA/2J mice, all the aromatic bisguanylhydrazones as well as hydroxystilbamidine caused prolongation of survival of tumor-bearing mice. Among the aliphatic bisguanylhydrazones, all of which showed no binding to DNA and caused at the most only a very slight inhibition of DNA polymerase, only methylglyoxal-bis(guanylhydrazone) (CH₃-G) had antileukemic activity. Synthalin also inhibited leukemic growth. Evidences presented indicate that the mechanisms of action of aliphatic and aromatic bisguanylhydrazones may be quite different. Furthermore, the ability to bind to DNA may be a useful criterion to predict the antileukemic activity of aromatic guanylhydrazones and possibly other aromatic bis-cationic compounds, but not that of aliphatic congeners.     

Four marine-derived fungi for bioremediation of raw textile mill effluents

Textile dye effluents pose environmental hazards because of color and toxicity. Bioremediation of these has been widely attempted. However, their widely differing characteristics and high salt contents have required application of different microorganisms and high dilutions. We report here decolorization and detoxification of two raw textile effluents, with extreme variations in their pH and dye composition, used at 20–90% concentrations by each of the four marine-derived fungi. Textile effluent A (TEA) contained an azo dye and had a pH of 8.9 and textile effluent B (TEB) with a pH of 2.5 contained a mixture of eight reactive dyes. The fungi isolated from mangroves and identified by 18S and ITS sequencing corresponded to two ascomycetes and two basidiomycetes. Each of these fungi decolorized TEA by 30–60% and TEB by 33–80% used at 20–90% concentrations and salinity of 15 ppt within 6 days. This was accompanied by two to threefold reduction in toxicity as measured by LC₅₀ values against Artemia larvae and 70–80% reduction in chemical oxygen demand and total phenolics. Mass spectrometric scan of effluents after fungal treatment revealed degradation of most of the components. The ascomycetes appeared to remove color primarily by adsorption, whereas laccase played a major role in decolorization by basidiomycetes. A process consisting of a combination of sorption by fungal biomass of an ascomycete and biodegradation by laccase from a basidiomycete was used in two separate steps or simultaneously for bioremediation of these two effluents.