Inhibition of pathogenic bacterial biofilm by biosurfactant produced by Lysinibacillus fusiformis S9

A biosurfactant producing microbe isolated from a river bank was identified as Lysinibacillus fusiformis S9. It was identified with help of biochemical tests and 16S rRNA gene phylogenetic analysis. The biosurfactant S9BS produced was purified and characterized as glycolipid. The biosurfactant showed remarkable inhibition of biofilm formation by pathogenic bacteria like Escherichia coli and Streptococcus mutans. It was interesting to note that at concentration of 40 μg ml^?1 the biosurfactant did not show any bactericidal activity but restricted the biofilm formation completely. L. fusiformis is reported for the first time to produce a glycolipid type of biosurfactant capable of inhibiting biofilm formation by pathogenic bacteria. The biosurfactant inhibited bacterial attachment and biofilm formation equally well on hydrophilic as well as hydrophobic surfaces like glass and catheter tubing. This property is significant in many biomedical applications where the molecule should help in preventing biofouling of surfaces without being toxic to biotic system.     

A Unified Scheme for Initiation and Conformational Adaptation of Human Apolipoprotein E N-terminal Domain upon Lipoprotein Binding and for Receptor Binding Activity

We report here a high-resolution NMR structure of the complete receptor-binding domain of human apolipoprotein E3 (apoE3-NT). Similar to the crystal structure of apoE-NT, the NMR structure displayed an elongated four-helix bundle. However, additional unique structural features were also observed. The segments in the N and C termini, which were missing in the crystal structure, formed α-helices having extensive tertiary contacts with the bundle, which oriented these short helices at specific positions for receptor binding activity. Several buried hydrophilic residues observed in the bundle were located strategically between helices 1 and 2 and between helices 3 and 4, significantly destabilizing these helix-helix interfaces. In addition, these buried hydrophilic residues formed buried H-bonds, which may play a key role in specific lipid-free helix bundle recovery. A short helix, nHelix C, was fully solvent-exposed and nearly perpendicular to the bundle. This short helix likely plays a critical role in initiating protein-lipid interaction, causing a preferred conformational adaptation of the bundle at the weaker helix-helix interfaces. This produces an open conformation with two lobes of helices, helices 1 and 4 and helices 2 and 3, which may be the competent conformation for receptor binding activity. Thus, the NMR structure suggests a unified scheme for the initiation and helix bundle opening of apoE-NT upon lipoprotein-binding and for receptor binding activity.Human apolipoprotein E (apoE)² is a 299-residue plasma-exchangeable apolipoprotein with the primary function of transporting lipids from one tissue to another. ApoE performs its functions via interactions with the low-density lipoprotein receptor (LDLR) superfamily (1). The high affinity binding of apoE to the receptors allows apoE-associated lipoprotein particles to be targeted for endocytosis and intracellular degradation. As a subclass of high-density lipoprotein, apoE also influences both cholesterol efflux and influx, thus playing an important role in reverse cholesterol transport (2, 3). Three major isoforms of apoE have been identified: ApoE3 has a cysteine at position 112 and an arginine at position 158, whereas apoE2 has cysteines and apoE4 has arginines at both positions. Although these isoforms differ in only two residues, they show profound functional differences. Recent evidence indicates that apoE is also critical in several other important biological processes, including Alzheimer disease, cognitive functioning, immunoregulation, cell signaling, and infectious diseases (4).ApoE is a two-domain protein that contains a 22-kDa N-terminal domain (residues 1-191) and a 10-kDa C-terminal domain (residues 216-299) linked by a protease sensitive hinge region. Although the N-terminal domain of apoE (apoE-NT) is primarily responsible for LDL-receptor binding, the C-terminal domain (apoE-CT) binds to lipoprotein with a high affinity (1). The x-ray crystal structure of lipid-free apoE-NT reveals a globular up-and-down four-helix bundle (5). The major receptor-binding region, residues 130-150, is located on the fourth helix. The positively charged residues (Lys and Arg) in this region are critical for interacting with the negatively charged residues in the receptor (1, 6). This structure only contains residues 24-164, whereas the rest of the regions are disordered. However, experimental evidence indicates that regions beyond residues 24-164 are also critical for LDLR binding activity. For example, deletion of residues 167-185 reduces the apoE3 LDLR binding activity to 15%, and a mutation at position Arg-172 reduces the LDLR binding activity to only ∼2% (7). In addition, an E3K mutant of apoE3 enhances the LDLR binding activity by 2-fold (8). Although the x-ray crystal structure of apoE-NT provides a structural explanation of the major receptor-binding domain of apoE, this structure does not explain the above described important experimental data. Thus, our understanding of the structural basis of the receptor binding activity of apoE remains incomplete.Previous studies using truncation mutants have shown that apoE(1-183) displays nearly 100% LDLR binding activity (9), suggesting that residues beyond position 183 are not important in LDLR binding. We report here a high-resolution NMR structure of the complete LDLR-binding domain of apoE3. Interestingly, our NMR structure shows that the N and C termini form α-helical structures that have extensive contacts with the helix bundle, orienting the two termini at specific positions for potential receptor binding. The NMR structure also displays several novel structural features that may provide the structural basis of a unified scheme for initiation and conformational adaptation of apoE-NT upon lipoprotein binding.     

The changing epitome of species identification – DNA barcoding

The discipline taxonomy (the science of naming and classifying organisms, the original bioinformatics and a basis for all biology) is fundamentally important in ensuring the quality of life of future human generation on the earth; yet over the past few decades, the teaching and research funding in taxonomy have declined because of its classical way of practice which lead the discipline many a times to a subject of opinion, and this ultimately gave birth to several problems and challenges, and therefore the taxonomist became an endangered race in the era of genomics. Now taxonomy suddenly became fashionable again due to revolutionary approaches in taxonomy called DNA barcoding (a novel technology to provide rapid, accurate, and automated species identifications using short orthologous DNA sequences). In DNA barcoding, complete data set can be obtained from a single specimen irrespective to morphological or life stage characters. The core idea of DNA barcoding is based on the fact that the highly conserved stretches of DNA, either coding or non coding regions, vary at very minor degree during the evolution within the species. Sequences suggested to be useful in DNA barcoding include cytoplasmic mitochondrial DNA (e.g. cox1) and chloroplast DNA (e.g. rbcL, trnL-F, matK, ndhF, and atpB rbcL), and nuclear DNA (ITS, and house keeping genes e.g. gapdh). The plant DNA barcoding is now transitioning the epitome of species identification; and thus, ultimately helping in the molecularization of taxonomy, a need of the hour. The ‘DNA barcodes’ show promise in providing a practical, standardized, species-level identification tool that can be used for biodiversity assessment, life history and ecological studies, forensic analysis, and many more.     

Butterfly communities along an elevational gradient in the Tons valley,Western Himalayas: Implications of rapid assessment for insect conservation

As time and money is limited, explicit, cost-effective, quick, and appropriate methods are needed to assist conservation planners and managers for making quick decisions. Butterflies promise to be a good model for rapid assessment and habitat monitoring studies because they are widespread, conspicuous, and easily recognizable and they are effective indicators of forest health. We conducted a rapid assessment of butterflies at five disturbance gradient sites that varied in elevation from 900 m a.s.l. to 3500 m a.s.l. for 20 days during March–April 2010 and recorded 79 butterfly species and 1504 individuals in the Tons valley in Western Himalayas. We were able to sample approximately 77% (123 species) of the estimated species richness on continuing the sampling until July 2010. Species richness at the study site is estimated to be 159 (95% CI: 145–210) species. Diversity was highest in heterogeneous habitats and decreased towards homogeneous habitats. Unique species were highly restricted to lowest disturbed sites. Using Pearson's correlation analysis, the strongest vegetative predictors of butterfly richness were plant species richness, canopy cover, and herb and shrub density. Butterfly species richness and abundance were highly correlated with altitude, temperature, relative humidity, fire signs, and livestock abundance. We also found positive cross-taxon correlation among butterflies, moths, and beetles across sites, indicating that butterflies can be used as surrogate or indicator taxa for insect conservation. Short sampling periods providing comprehensive estimates of species richness were reliable for identifying habitats and sites with the most conservation value in the Tons valley landscape.     

Effects of NADH and thiol compounds on wheat leaf nitrate reductase

The initial activity of wheat leaf nitrate reductase was depressed on inclusion of the following thiol compounds; dithiothreitol, dithioerythreitol or mercaptoethanol, but not cysteine and glutathione. This thiol effect simply resulted from an interference with the chemical determination of nitrite. Preincubation of the enzyme with NAD⁺ and these thiols enhanced the inhibition of nitrate reductase activity. This effect was mediated by NADH production by the thiol reduction of NAD⁺. The inactivation by NAD⁺ in the presence of thiol compounds which was enhanced by cyanide ions could be reversed by ferricyanide, as has been observed previously for NADH-mediated inactivation of nitrate reductase.     

Deciphering the mode of action,structural and biochemical analysis of heparinase II/III (<Emphasis Type="Italic">Ps</Emphasis>PL12a) a new member of family 12 polysaccharide lyase from <Emphasis Type="Italic">Pseudopedobacter saltans</Emphasis>

Heparinases are widely used for production of clinically and therapeutically important bioactive oligosaccharides and in analyzing the polydisperse, heterogeneous, and complex structures of heparin/heparan sulfate. In the present study, the gene (1911 bp) encoding heparinase II/III of family 12 polysaccharide lyase (PsPL12a) from Pseudopedobacter saltans was cloned, expressed, and biochemically and functionally characterized. The purified enzyme PsPL12a of molecular size approximately 76 kDa exhibited maximum activity in the temperature range 45–50 °C and at pH 6.0. PsPL12a gave maximum activity at 1% (w/v) heparin under optimum conditions. The kinetic parameters, K _m and V_max, for PsPL12a were 4.6?±?0.5 mg/ml and 70?±?2 U/mg, respectively. Ten millimolars of each Mg²⁺ and Mn²⁺ ions enhanced PsPL12a activity by 80%, whereas Ni²⁺ inhibited by 75% and Co²⁺ by 10%, and EDTA completely inactivated the enzyme. Protein melting curve of PsPL12a gave a single peak at 55 °C and 10 mM Mg²⁺ ions and shifted the peak to 60 °C. The secondary structure analysis of PsPL12a by CD showed 65.12% α-helix, 11.84% β-strand, and 23.04% random coil. The degradation products of heparin by PsPL12a analyzed by ESI-MS spectra displayed peaks corresponding to heparin di-, tetra-, penta-, and hexa-saccharides revealing the endolytic mode of enzyme action. Heparinase II/III (PsPL12a) from P. saltans can be used for production of low molecular weight heparin oligosaccharides for their utilization as anticoagulants. This is the first report on heparinase cloned from P. saltans.     

Signaling role of nitric oxide in the induction of plant defense by exogenous application of abiotic inducers

The objective of this work was to search out the probable molecule behind the activation of broad spectrum resistance during abiotic elicitors such as arachidonic acid, cupric chloride, chitosan, isonicotinic acid and salicylic acid mediated induced systemic resistance (ISR) in Raphanus sativus L. The elicitor compounds were sprayed on the radish leaves of healthy plant and after 24 h incubation a significant increase of β-1,3 glucanase, peroxidase, polyphenol oxidase and phenolics as well as a remarkable increase of nitric oxide (NO), a probable potent defense-signaling molecule in plant, was observed. Furthermore, treatment of the host with NO donor, sodium nitroprusside, also induced the same defense molecules. The results suggests that NO might be the signaling molecule during abiotic elicitor mediated ISR induction in the host system.