Biologically Synthesized Silver Nanoparticles and Their Diverse Applications.

Nanotechnology has become the most effective and rapidly developing field in the area of material science, and silver nanoparticles (AgNPs) are of leading interest because of their smaller size, larger surface area, and multiple applications. The use of plant sources as reducing agents in the fabrication of silver nanoparticles is most attractive due to the cheaper and less time-consuming process for synthesis. Furthermore, the tremendous attention of AgNPs in scientific fields is due to their multiple biomedical applications such as antibacterial, anticancer, and anti-inflammatory activities, and they could be used for clean environment applications. In this review, we briefly describe the types of nanoparticle syntheses and various applications of AgNPs, including antibacterial, anticancer, and larvicidal applications and photocatalytic dye degradation. It will be helpful to the extent of a better understanding of the studies of biological synthesis of AgNPs and their multiple uses.

Interaction of azadirachtin with the lipid-binding domain: Suppression of lipid transportation in the silkworm, Bombyx mori.

This study investigates the effects of the insect growth regulator azadirachtin on lipid transportation to the ovary of the silkworm, Bombyx mori. Lipids are hydrophobic in nature and require a carrier for circulation in the blood. Protein-lipid interactions play a vital role in lipid transport, thereby keeping the system balanced. In general, lipids bind to lipoproteins in a specific region called the lipid-binding domain (LBD). In this study, B. mori apolipophorin amino acid sequences were retrieved from NCBI and the LBD was identified. The LBD structure was predicted by (PS)2 and validated in ProSA. The LBD structure was docked with DMPC, POPC and sphingomyelin by SwissDock, each binding with GLN 171, ASN 162, and ASN 160 and 162, respectively. Interestingly, azadirachtin binds with ASN 160 and 162 and GLN 171, which shows that lipids and azadirachtin are binding with the same amino acid residues in the LBD. Later, this result was confirmed with wet lab work using a fluorescent phospholipid probe. Azadirachtin binding with the LBD was indirectly proportional to the fluorescent lipid binding. These results suggest that azadirachtin binds with the LBD instead of the lipids and interrupts the protein-lipid interaction, leading to the suppression of lipid transportation to the ovary.

Induction of HT-29 Colon Cancer Cells Apoptosis by Pyrogallol with Growth Inhibiting Efficacy Against Drug-Resistant Helicobacter pylori.

BACKGROUND: Colon cancer is the most aggressive form of cancers, that causes 0.5 million deaths per year around the globe. Targeting colon cancer by conventional therapeutic options elicits toxicity. Traditional medicines take a lead to alleviate the existing clinical challenges. OBJECTIVE: To investigate antibacterial activity against Helicobacter Pylori and in vitro anti-colon cancer activity by Acacia nilotica extract (ACE) and its active constituent pyrogallol. METHODS: Pyrogallol isolated from A. nilotica by column chromatography and HPLC and structure was elucidated by spectral analysis. Antibacterial activity was done by flow cytometry. Cytotoxicity was measured by MTT assay. Apoptotic morphology and nuclear fragmentation were assessed with AO/ethidium bromide and DAPI staining. DNA fragmentation was done by electrophoresis. Western blot used to analyze the molecular mechanism of apoptosis. Cell cycle arrest was determined using flow cytometry of propidium iodide stained cells. Cell migration was determined by wound healing assay. RESULTS: ACE (20 µg/ml) and pyrogallol (10 µg/ml) treatment reduced the survival of H.pylori at 61% and 62%, respectively. MTT results show that HT-29 cells are more sensitive to pyrogallol with an IC50 value of 35µg/ml compared to ACE. Pyrogallol treated HT-29 cells reached dead state i.e. late apoptotic state with severe nuclear fragmentation. Pyrogallol elicits dose dependent DNA fragmentation in HT-29 cells. Pyrogallol induced apoptosis by simultaneous down-regulation of Bcl-2 and up-regulation of BAX and cytochrome c. Pyrogallol arrested HT-29 cells in S and G2/M phase of cell cycle. Further pyrogallol exhibited marked antimetastatic potential by inhibiting the migration of HT-29 cells dose dependently. CONCLUSION: Both ACE and pyrogallol repressed the growth of H.pylori and as significant anti-colon cancer agent.