A peptide that antagonizes TCR-mediated reactions with both syngeneic and allogeneic agonists: functional and structural aspects

We identify and consider some characteristics of a peptide antagonist for the Ag-specific receptor on 2C cells (the 2C TCR). The peptide, GNYSFYAL (called GNY), binds to H-2K(b), and a very high-resolution crystal structure of the GNY-K(b) complex at 1.35 A is described. Although the GNY peptide does not bind to L(d), the potency of GNY-K(b) as an antagonist is evident from its ability to specifically inhibit 2C TCR-mediated reactions to an allogenic agonist complex (QLSPFPFDL-L(d)), as well as to a syngeneic agonist complex (SIYRYYGL-K(b)). The crystal structure and the activities of alanine-substituted peptide variants point to the properties of the peptide P4 side chain and the conformation of the Tyr-P6 side chain as the structural determinants of GNYSFYAL antagonist activity.     

Immune defects in 28-kDa proteasome activator gamma-deficient mice

Protein complexes of the 28-kDa proteasome activator (PA28) family activate the proteasome and may alter proteasome cleavage specificity. Initial investigations have demonstrated a role for the IFN-gamma-inducible PA28alpha/beta complex in Ag processing. Although the noninducible and predominantly nuclear PA28gamma complex has been implicated in affecting proteasome-dependent signaling pathways, such as control of the mitotic cell cycle, there is no previous evidence demonstrating a role for this structure in Ag processing. We therefore generated PA28gamma-deficient mice and investigated their immune function. PA28gamma(-/-) mice display a slight reduction in CD8+ T cell numbers and do not effectively clear a pulmonary fungal infection. However, T cell responses in two viral infection models appear normal in both magnitude and the hierarchy of antigenic epitopes recognized. We conclude that PA28gamma(-/-) mice, like PA28alpha(-/-)/beta(-/-) mice, are deficient in the processing of only specific Ags.     

Phosphate number and acyl chain length determine the subcellular location and lateral mobility of phosphoinositides

Phosphoinositides are critical regulators of ion channel and transporter activity. There are multiple isomers of biologically active phosphoinositides in the plasma membrane and the different lipid species are non-randomly distributed. However, the mechanism by which cells impose selectivity and directionality on lipid movements and so generate a non-random lipid distribution remains unclear. In the present study we investigated which structural elements of phosphoinositides are responsible for their subcellular location and movement. We incubated phosphatidylinositol (PI), phosphatidylinositol 4-monophosphate (PI(4)P) and phosphatidylinositol 4,5-bisphosphate (PI(4,5)P2) with short or long acyl chains in CHO and HEK cells. We show that phosphate number and acyl chain length determine cellular location and translocation movement. In CHO cells, PI(4,5)P2 with a long acyl chain was released into the cytosol easily because of a low partition coefficient whereas long chain PI was released more slowly because of a high partition coefficient. In HEK cells, the cellular location and translocation movement of PI were similar to those of PI in CHO cells, whereas those of PI(4,5)P2 were different; some mechanism restricted the translocation movement of PI(4,5)P2, and this is in good agreement with the extremely low lateral diffusion of PI(4,5)P2. In contrast to the dependence on the number of phosphates of the phospholipid head group of long acyl chain analogs, short acyl chain phospholipids easily undergo translocation movement regardless of cell type and number of phosphates in the lipid headgroup.     

PINOID positively regulates auxin efflux in Arabidopsis root hair cells and tobacco cells

Intercellular transport of auxin is mediated by influx and efflux carriers in the plasma membrane and subjected to developmental and environmental regulation. Here, using the auxin-sensitive Arabidopsis thaliana root hair cell system and the tobacco (Nicotiana tabacum) suspension cell system, we demonstrate that the protein kinase PINOID (PID) positively regulates auxin efflux. Overexpression of PID (PIDox) or the auxin efflux carrier component PINFORMED3 (PIN3, PIN3ox), specifically in the root hair cell, greatly suppressed root hair growth. In both PIDox and PIN3ox transformants, root hair growth was nearly restored to wild-type levels by the addition of auxin, protein kinase inhibitors, or auxin efflux inhibitors. Localization of PID or PIN3 at the cell boundary was disrupted by brefeldin A and staurosporine. A mutation in the kinase domain abrogated the ability of PID to localize at the cell boundary and to inhibit root hair growth. These results suggest that PIDox- or PIN3ox-enhanced auxin efflux results in a shortage of intracellular auxin and a subsequent inhibition of root hair growth. In an auxin efflux assay using transgenic tobacco suspension cells, PIDox or PIN3ox also enhanced auxin efflux. Collectively, these results suggest that PID positively regulates cellular auxin efflux, most likely by modulating the trafficking of PIN and/or some other molecular partners involved in auxin efflux.     

Thermosensitive and mucoadhesive delivery systems of mucosal vaccines

Mucosal vaccination is emerging as a potential administration route for eliciting antigen-specific mucosal and systemic immunogenicity. Most mucosal vaccines have been administered in a phosphate-buffered saline vehicle that may limit the exposure of antigens to the mucosal surfaces and result in poor immunogenicity. To improve the potency of the mucosal vaccines, we have developed mucosal vaccine delivery systems that might prevent leakage and increase retention of vaccines on mucosal surfaces. Thermosensitive polymers have been used to reduce the leakage problems of nasal or vaginal vaccines, while mucoadhesive polymers have been employed to increase the mucosal contact of the vaccines. Here, we describe the formulation and delivery methods of mucosal vaccines using thermosensitive and mucoadhesive polymers.     

Efficient high level expression of peptides and proteins as fusion proteins with the N-terminal domain of L9: application to the villin headpiece helical subdomain

The efficient expression of small to midsize polypeptides and small marginally stable proteins can be difficult. A new protein fusion system is developed to allow the expression of peptides and small proteins. The polypeptide of interest is linked via a Factor Xa cleavage sequence to the C-terminus of the N-terminal domain of the ribosomal protein L9 (NTL9). NTL9 is a small (56 residue) basic protein. The C-terminus of the protein is part of an alpha-helix which extends away from the globular structure thus additional domains can be fused without altering the fold of NTL9. NTL9 expresses at high levels, is extremely soluble, and remains fully folded over a wide temperature and pH range. The protein has a high net positive charge, facilitating purification of fusion proteins by ion exchange chromatography. NTL9 fusions can also be easily purified by reverse phase HPLC. As a test case we demonstrate the high level expression of a small, 36 residue, three helix bundle, the villin headpiece subdomain. This protein is widely used as a model system for folding studies and the development of a simple expression system should facilitate experimental studies of the subdomain. The yield of purified fusion protein is 70 mg/L of culture and the yield of purified villin headpiece subdomain is 24 mg/L of culture. We also demonstrate the use of the fusion system to express a smaller marginally folded peptide fragment of the villin headpiece domain.