Synthesis and Biodistribution Study of Biocompatible 198Au Nanoparticles by use of Arabinoxylan as Reducing and Stabilizing Agent

Biological Trace Element Research - Radioactive gold-198 is a useful diagnostic and therapeutic agent. Gold in the form of nanoparticles possesses even more exciting properties. This work aimed at...     

Molten globule state of human placental cystatin (HPC) at low pH conditions and the effects of trifluoroethanol (TFE) and methanol.

Acid-induced conformational changes were studied in human placental cystatin (HPC) in terms of circular dichroism (CD) spectroscopy, the binding of hydrophobic dye 1-anilinonapthalene-8-sulphonic acid (ANS), and intrinsic fluorescence measurements. Our results show the formation of an acid-induced molten globule state at pH 2.0, with significant secondary and tertiary interactions that resemble the native state, exposed hydrophobic regions and the effects of trifluoroethanol (TFE) and methanol in conversion of the acid-denatured state of HPC to the alcohol-induced state, which is characterized by increased helical content, disrupted tertiary structure, and the absence of hydrophobic clusters. Alcohol-induced formation of alpha-helical structures at pH 2.0 is evident from the increase in the ellipticity values at 222 nm, with native-like secondary structural features at 40% TFE. The increase in helical content was observed up to 80% TFE concentration. The ability of TFE (40%) to refold acid-denatured HPC to native-state conformation is also supported by intrinsic and ANS fluorescence measurements.     

Effect of polyols and salts on the acid-induced state of human placental cystatin

Polyols (glycerol and sorbitol) and salts (magnesium sulfate, sodium sulfate, and magnesium chloride) have been used to study the refolding of the acid-induced state of human placental cystatin (HPC), which is a low molecular weight (12,500 daltons) thiol proteinase inhibitor, in terms of CD spectroscopy, binding of hydrophobic dye 1-anilinonaphthalene-8-sulfonic acid (ANS), and intrinsic fluorescence measurements. The helical content of acid-denatured HPC increased with increase in glycerol concentration (0–80%). At 80% glycerol concentration, the secondary structural features observed in the far UV-CD region are similar to those of the native state (pH 6.0). The intrinsic fluorescence and near UV-CD studies showed that this 80% glycerol-induced state has a significant amount of tertiary structure with decreased ANS binding compared to the acid-denatured state. It was found that glycerol is more effective in stabilizing the acid-denatured state of HPC as compared to sorbitol. Among salts the stability effect was more for MgCl₂ (used up to concentration of 3 M) compared to MgSO₄ and Na₂SO₄ (used up to the concentration of 1.5 M due to restricted solubility of HPC at higher sulfate salt concentrations) as determined by CD studies and fluorescence measurements, which showed secondary and tertiary structural resemblance of this MgCl₂-induced state close to native state and showed overall spectral features in between the native state and the acid-denatured state. This MgCl₂ (3 M)-induced state showed decreased ANS fluorescence as compared to the acid-denatured state but more than that of the native state. The results taken together suggest that the acid-denatured state of HPC in the presence of 80% glycerol or 3 M MgCl₂ has a conformation in between that of the native state (pH 6.0) and the acid-induced state at pH 2.0. Published in Russian in Biokhimiya, 2006, Vol. 71, No. 6, pp. 768–777.     

Invited review nonmulberry silk biopolymers

The silk produced by silkworms are biopolymers and can be classified into two types--mulberry and nonmulberry. Mulberry silk of silkworm Bombyx mori has been extensively explored and used for century old textiles and sutures. But for the last few decades it is being extensively exploited for biomedical applications. However, the transformation of nonmulberry silk from being a textile commodity to biomaterials is relatively new. Within a very short period of time, the combination of load bearing capability and tensile strength of nonmulberry silk has been equally envisioned for bone, cartilage, adipose, and other tissue regeneration. Adding to its advantage is its diverse morphology, including macro to nano architectures with controllable degradation and biocompatibility yields novel natural material systems in vitro. Its follow on applications involve sustained release of model compounds and anticancer drugs. Its 3D cancer models provide compatible microenvironment systems for better understanding of the cancer progression mechanism and screening of anticancer compounds. Diversely designed nonmulberry matrices thus provide an array of new cutting age technologies, which is unattainable with the current synthetic materials that lack biodegradability and biocompatibility. Scientific exploration of nonmulberry silk in tissue engineering, regenerative medicine, and biotechnological applications promises advancement of sericulture industries in India and China, largest nonmulberry silk producers of the world. This review discusses the prospective biomedical applications of nonmulberry silk proteins as natural biomaterials.     

Purification and Characterization of High Molecular Mass and Low Molecular Mass Cystatin from Goat Brain

Cystatin are thiol proteinase inhibitors ubiquitously present in mammalian body and serve various important physiological functions. In the present study two cystatins were isolated from goat brain using alkaline treatment, ammonium sulphate fractionation, gel filtration and ion exchange chromatography. The high molecular mass cystatin of 70.8 kDa was named as HM-GBC (high molecular mass goat brain cystatin) and the low molecular mass cystatin of 12.72 kDa was named as LM-GBC (low molecular mass goat brain cystatin). The molecular mass determined by SDS-PAGE was found to be 70.8 and 12.88 kDa for HM-GBC and LM-GBC, respectively, however with gel filtration the masses were found to be 70.8 and 12.58 kDa. Both the cystatins were found to be stable in broad range of pH and temperature. HM-GBC was found to have 2% carbohydrate content while LM-GBC lacks any carbohydrate content. Both cystatins were found to be devoid of any sulphydryl content. Stoke's radii of 36 and 16 A, and diffusion coefficient of 6.189 x 10(-15) and 1.392 x 10(-14) cm(2)/s were calculated for HM-GBC and LM-GBC. K (i) values with papain were found to be 1.875 x 10(-8) and 3.125 x 10(-8) M for HM-GBC and LM-GBC, respectively. K (+1), K (-1) and half-life calculated along with K (i) values obtained showed that HM-GBC inhibited papain more specifically as compared to LM-GBC. The IC(50) values obtained for HM-GBC and LM-GBC also showed that HM-GBC binds more effectively to papain than LM-GBC. Ultraviolet and fluorescence spectra indicated that upon formation of papain-HM-GBC/LM-GBC complex there is significant conformational change after interaction in one or both the proteins of the complex.     

Physicochemical properties of thiol proteinase inhibitor isolated from goat pancreas

Thiol proteinase inhibitors are crucial to proper functioning of all living tissues consequent to their cathepsin regulatory and myriad important biologic properties. Equilibrium denaturation of dimeric goat pancreas thiol proteinase inhibitor (PTPI), a cystatin superfamily variant has been studied by monitoring changes in the protein's spectroscopic and functional characteristics. Denaturation of PTPI in guanidine hydrochloride and urea resulted in altered intrinsic fluorescence emission spectrum, diminished negative circular dichroism, and loss of its papain inhibitory potential. Native like spectroscopic properties and inhibitory activity are only partially restored when denaturant is diluted from guanidine hydrochloride unfolded samples demonstrating that process is partially reversible. Coincidence of transition curves and dependence of transition midpoint (3.2M) on protein concentration in guanidine hydrochloride‐induced denaturation are consistent with a two‐state model involving a native like dimer and denatured monomer. On the contrary, urea‐induced unfolding of PTPI is a multiphasic process with indiscernible intermediates. The studies demonstrate that functional conformation and stability are governed by both ionic and hydrophobic interactions. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 708–717, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Expression of multiple insecticidal genes confers broad resistance against a range of different rice pests

We report the simultaneous introduction of three insecticidal genes (the Bt genes cry1Ac and cry2A, and the snowdrop lectin gene gna) into commercially important indica rice varieties M7 and Basmati 370, by particle bombardment. Transgenic plants expressed Cry1Ac, Cry2A and GNA at different levels, either singly or in combination at 0.03–1%, 0.01–0.5% and 0.01–2.5% of total soluble protein, respectively. The transgenes showed stable transmission and expression, and R₁ transgenic plants provided significant (p<0.01) protection against three of the most important insect pests of rice: rice leaf folder (Cnaphalocrocis medinalis), yellow stemborer (Scirpophaga incertulas) and brown planthopper (Nilaparvata lugens). The triple transformants showed significantly (p<0.05) higher resistance to these insects than plants expressing single transgenes. Bioassays using the triple-transgenic plants showed 100% eradication of the rice leaf folder and yellow stem borer, and 25% reduction in the survival of the brown planthopper. The greatest reduction in insect survival, and the greatest reduction in plant damage, occurred in plants expressing all three transgenes. This approach maximises the utility of gene transfer technology to introduce combinations of genes whose products disrupt different biochemical or physiological processes in the same insect, providing a multi-mechanism defence.     

Screening and evaluation of antioxidant activity of some pyridazine derivatives

Antioxidants are compounds that can delay, inhibit, or prevent the oxidation of materials that can be oxidized by scavenging free radicals and help in diminishing oxidative stress. They belong to different chemical classes. Recently there are studies related to pyridazinone derivatives for their antioxidant activities. Since there are evidences implicates reactive oxygen species and nitric oxide as mediators of inflammation and/or tissue damage in inflammatory and arthritic disorders it was though that compounds that have both antioxidant and anti-inflammatory activities would have been essential for the inflammatory diseases. Based on these findings a series of 2H-pyridazine-3-one and 6-chloropyridazine analogues that have anti-inflammatory activity was tested in vitro on superoxide formation and effects on lipid peroxidation were determined against alpha-tocopherol. Most of the compounds have strong inhibitory effect on superoxide anion (between 84% - 99%) at 10(- 3) M concentration. In addition, these compounds showed similar activity to alpha-tocopherol at 10(- 3) M concentrations.