11 research outputs found
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Solvothermal synthesis of a new 3-D mixed-metal sulfide framework, (H1.33tren)[In2.67Sb1.33S8]∙tren
A new indium(III) antimony(V) sulfide, (H1.33tren)[In2.67Sb1.33S8]∙tren, has been prepared solvothermally at 433 K. The compound crystallises in the tetragonal space group I-42d (lattice parameters, a = 12.6248(5) and c = 19.4387(18) Å at 150 K) and contains adamantane-like T2 supertetrahedral units comprised of corner-sharing InS45- and SbS43- tetrahedra. The adamantane-like units are then linked through sulfur vertices to generate an open, 3-D framework structure containing large pores in which neutral, protonated tren (tris(2-aminoethylene)amine) molecules reside. The presence of the organic components was confirmed by solid-state 13C NMR (10 kHz), combustion and thermogravimetric analysis. The band gap, obtained from UV-vis diffuse reflectance measurements, is 2.7(2) eV. Stirring with either water or alkali-metal salt solution leads to removal of the neutral tren molecules and an ~9 % reduction in unit-cell volume on formation of (H1.33tren)[In2.67Sb1.33S8]∙(H2O)4
Synthetic Double-Stranded RNAs Are Adjuvants for the Induction of T Helper 1 and Humoral Immune Responses to Human Papillomavirus in Rhesus Macaques
Toll-like receptor (TLR) ligands are being considered as adjuvants for the induction of antigen-specific immune responses, as in the design of vaccines. Polyriboinosinic-polyribocytoidylic acid (poly I:C), a synthetic double-stranded RNA (dsRNA), is recognized by TLR3 and other intracellular receptors. Poly ICLC is a poly I:C analogue, which has been stabilized against the serum nucleases that are present in the plasma of primates. Poly I:C12U, another analogue, is less toxic but also less stable in vivo than poly I:C, and TLR3 is essential for its recognition. To study the effects of these compounds on the induction of protein-specific immune responses in an animal model relevant to humans, rhesus macaques were immunized subcutaneously (s.c.) with keyhole limpet hemocyanin (KLH) or human papillomavirus (HPV)16 capsomeres with or without dsRNA or a control adjuvant, the TLR9 ligand CpG-C. All dsRNA compounds served as adjuvants for KLH-specific cellular immune responses, with the highest proliferative responses being observed with 2 mg/animal poly ICLC (p = 0.002) or 6 mg/animal poly I:C12U (p = 0.001) when compared with immunization with KLH alone. Notably, poly ICLC—but not CpG-C given at the same dose—also helped to induce HPV16-specific Th1 immune responses while both adjuvants supported the induction of strong anti-HPV16 L1 antibody responses as determined by ELISA and neutralization assay. In contrast, control animals injected with HPV16 capsomeres alone did not develop substantial HPV16-specific immune responses. Injection of dsRNA led to increased numbers of cells producing the T cell–activating chemokines CXCL9 and CXCL10 as detected by in situ hybridization in draining lymph nodes 18 hours after injections, and to increased serum levels of CXCL10 (p = 0.01). This was paralleled by the reduced production of the homeostatic T cell–attracting chemokine CCL21. Thus, synthetic dsRNAs induce an innate chemokine response and act as adjuvants for virus-specific Th1 and humoral immune responses in nonhuman primates
Contribution of Microbe-Mediated Processes in Nitrogen Cycle to Attain Environmental Equilibrium
Nitrogen (N), the most important element, is required by all living organisms for
the synthesis of complex organic molecules like amino acids, proteins, lipids etc.
Nitrogen cycle is considered to be the most complex yet arguably important cycle
next to carbon cycle. Nitrogen cycle includes oxic and anoxic reactions like
organic N mineralization, ammonia assimilation, nitrification denitrification,
anaerobic ammonium oxidation (anammox), dissimilatory nitrate reduction to
ammonium (DNRA), comammox, codenitrification etc. Nitrogen cycling is one
of the most crucial processes required for the recycling of essential chemical
requirements on the planet. Soil microorganisms not only improve N-cycle
balance but also pave the way for sustainable agricultural practices, leading to
improved soil properties and crop productivity as most plants are opportunistic in
the uptake of soluble or available forms of N from soil. Microbial N
transformations are influenced by plants to improve their nutrition and vice
versa. Diverse microorganisms, versatile metabolic activities, and varied biotic and abiotic conditions may result in the shift in the equilibrium state of different
N-cycling processes. This chapter is an overview of the mechanisms and genes
involved in the diverse microorganisms associated in the operation of nitrogen
cycle and the roles of such microorganisms in different agroecosystems