Novel nanocomposites from spider silk–silica fusion (chimeric) proteins
Silica skeletal architectures in diatoms are characterized by remarkable morphological and nanostructural details. Silk proteins from spiders and silkworms form strong and intricate self-assembling fibrous biomaterials in nature. We combined the features of silk with biosilica through the design, synthesis, and characterization of a novel family of chimeric proteins for subsequent use in model materials forming reactions. The domains from the major ampullate spidroin 1 (MaSp1) protein of Nephila clavipes spider dragline silk provide control over structural and morphological details because it can be self-assembled through diverse processing methods including film casting and fiber electrospinning. Biosilica nanostructures in diatoms are formed in aqueous ambient conditions at neutral pH and low temperatures. The R5 peptide derived from the silaffin protein of Cylindrotheca fusiformis induces and regulates silica precipitation in the chimeric protein designs under similar ambient conditions. Whereas mineralization reactions performed in the presence of R5 peptide alone form silica particles with a size distribution of 0.5-10 m in diameter, reactions performed in the presence of the new fusion proteins generate nanocomposite materials containing silica particles with a narrower size distribution of 0.5-2 m in diameter. Furthermore, we demonstrate that composite morphology and structure could be regulated by controlling processing conditions to produce films and fibers. These results suggest that the chimeric protein provides new options for processing and control over silica particle sizes, important benefits for biomedical and specialty materials, particularly in light of the all aqueous processing and the nanocomposite features of these new materials.biomaterials ͉ nanostructures ͉ silaffin ͉ biomineralization ͉ ceramics C omplex mineralized composite systems in nature provide rich ground for insight into mechanisms of biomineralization and novel materials designs (1-4). Some of the more common sources of inspiration include seashells, insect exoskeletons, extracellular matrices involved in bone and other hard tissues, and biosilica skeletons. The formation of natural inorganic-organic composites is a multistep process, including the assembly of the extracellular matrix, the selective transportation of inorganic ions to discrete organized compartments with subsequent mineral nucleation, and growth delineated by preorganized cellular compartments. Silica skeletons found in nature are based on nanoscale composites wherein the organic components, usually proteins, are functional parts of the skeletal structures while also serving as silica-forming components (5, 6). As a result, materials' toughness is improved, strength is retained, and fine morphological control is achieved, all hallmark attributes of biological composites.Silica is widespread in biological systems and serves different functions, including support and protection in single-celled organisms, such as diatoms through to higher plants and animals (7,8...
The gp120 molecule of HIV-1 is a glycoprotein that is part of the outer layer of the virus. It presents itself as viral membrane spikes consisting of 3 molecules of gp120 linked together and anchored to the membrane by gp41 protein. Gp120 is essential for viral infection as it facilitates HIV entry into the host cell and this is its best-known and most researched role in HIV infection. However, it is becoming increasingly evident that gp120 might also be facilitating viral persistence and continuing HIV infection by influencing the T cell immune response to the virus. Several mechanisms might be involved in this process of which gp120 binding to the CD4 receptor of T cells is the best known and most important interaction as it facilitates viral entry into the CD4+ cells and their depletion, a hallmark of the HIV infection. Gp120 is shed from the viral membrane and accumulates in lymphoid tissues in significant amounts. Here, it can induce apoptosis and severely alter the immune response to the virus by dampening the antiviral CTL response thus impeding the clearance of HIV. The effects of gp120 and how it interacts and influences T cell immune response to the virus is an important topic and this review aims to summarize what has been published so far in hopes of providing guidance for future work in this area.
The gp160 complex of the envelope of the HIV virus and its component gp120 are essential for viral entry into the host cell. Gp120 binding to its receptor CD4 and co-receptor, CXCR4 or CCR5 is required for fusion of viral and cellular membranes. The presence of gp120 facilitates immune escape of the virus through its profound effect on the immune cells. It is a polyclonal activator of B cells, causing them to differentiate into immunoglobulin producing cells while activating the complement cascade. This results in the formation of immune complexes that are unable to kill the virus but instead shield it from the attack of other immune cells. Such HIV-1 virus that is trapped within immune complexes and is bound to the B cells via CD21 is more infectious than the free virion. In addition, HIV virions are trapped on the membrane of follicular dendritic cells (FDC) processes in immune complexes or through complement receptors. Thus, FDC can serve as a 'Trojan horse' and transmit the trapped virus to CD4+ T lymphocytes as they migrate through the germinal centre to the follicular mantle and paracortical areas. It was demonstrated that CXCR4-binding HIV-1 X4 gp120 causes the movement of T cells, including HIV-specific CTL, away from high concentrations of the viral protein and its expression by target cells reduces CTL efficacy in vitro. Therefore, apart from the essential role in viral attachment and infection of cells, gp120 possesses several properties that affect the behavior of immune cells and skew the immune response to the virus facilitating viral escape.
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