SPOT synthesis permits parallel synthesis and screening of thousands of cellulose membrane-bound peptides to study protein-protein interactions in a proteomic context. Recognition of C-terminal residues is one of the most common binding features of PDZ domains. Unfortunately, most solid support-bound peptide libraries lack a free C terminus due to C-terminal fixation on the solid support. To overcome this restriction, we developed a robust methodology based on our previous strategy for generating peptides with authentic C termini. To validate this improved method, we screened a human peptide library of 6223 C termini with the syntrophin PDZ domain. Furthermore, using the same library, new peptide ligands derived from membrane proteins and receptors were found for the ERBIN PDZ domain. Finally, we identified the protein kinase breakpoint cluster region, which is known as a negative regulator of cell proliferation and oncogenic transformation, as an ERBIN ligand.
Transient macromolecular complexes are often formed by protein-protein interaction domains (e.g., PDZ, SH2, SH3, WW), which are often regulated (positively or negatively) by phosphorylation. To address the in vitro analysis of PDZ domain regulation by such phosphorylation, we improved the inverted peptide method. This method is based on standard SPOT synthesis, followed by inversion of the peptide under acidic conditions to generate the free C termini necessary for PDZ domain ligand recognition. The benefit of the newly introduced acidic conditions is the preservation of the incorporated phosphate group during peptide synthesis. Furthermore, the improved method is more robust and shows an increased signal-to-noise ratio. As representative examples, we used the AF6, ERBIN, and SNA1 (alpha-1-syntrophin) PDZ domains to analyze the influence of ligand-position-dependent phosphorylation. We could clearly demonstrate severe down-regulation by phosphorylation of the PDZ ligand position -2 (<50 %) and slightly less at position -1 ( approximately 50 %). These results are specific and reproducible for all three PDZ domains. Finally, we confirmed the influence of negative regulation by using the protein kinase BCR as the AF6 PDZ domain ligand. For the first time, this approach allows the SPOT synthesis technique to be used to screen large libraries of phosphorylated peptides in vitro. This should ultimately help in the identification of phosphorylation-dependent regulation mechanisms in vivo.
The malaria parasite invades the terminally differentiated erythrocytes, where it grows and multiplies surrounded by a parasitophorous vacuole. Plasmodium blood stages translocate newly synthesized proteins outside the parasitophorous vacuole and direct them to various erythrocyte compartments, including the cytoskeleton and the plasma membrane. Here, we show that the remodeling of the host cell directed by the parasite also includes the recruitment of dematin, an actin-binding protein of the erythrocyte membrane skeleton and its repositioning to the parasite. Internalized dematin was found associated with Plasmodium 14-3-3, which belongs to a family of conserved multitask molecules. We also show that, in vitro, the dematin-14-3-3 interaction is strictly dependent on phosphorylation of dematin at Ser 124 and Ser 333 , belonging to two 14-3-3 putative binding motifs. This study is the first report showing that a component of the erythrocyte spectrin-based membrane skeleton is recruited by the malaria parasite following erythrocyte infection.The Plasmodium parasite, the etiologic agent of malaria, invades the host red blood cell (RBC), 2 where it grows and multiplies within a parasitophorous vacuole (PV). The PV membrane (PVM) represents an interface between the parasite and the host erythrocyte. A subset of parasite proteins is exported beyond the PVM by a recently discovered secretory system directed by a pentameric amino acid sequence motif (PEXE(L/H)T) (1, 2). Additional pathways might flank this unusual export machinery because a number of parasite proteins that do not contain the PEXE(L/H)T motif are also exported to erythrocyte sites (3). The parasite generates novel membrane compartments to sustain protein trafficking. For example, in Plasmodium falciparum-infected RBCs (iRBCs), the so-called Maurer's clefts, organelles anchored to the RBC cytoskeleton, are responsible for the assembly and targeting of parasite adhesive proteins to the erythrocyte surface. Exported proteins are routed to different erythrocyte compartments, including the host membrane skeleton, leading to extensive remodeling of the host cell.The erythrocyte skeleton is anchored to the phospholipid bilayer through two major protein bridges; one connects the integral membrane protein band 3 to spectrin via ankyrin, whereas the other involves the junctional complex, which connects the C-terminal end of spectrin to short actin protofilaments (4, 5). Protein 4.1, dematin, and adducin are components of the junctional complex. Protein 4.1, p55, and the transmembrane glycophorin C form a well characterized ternary complex, which tethers the junctional complex to the plasma membrane (6). The membrane receptors glucose transporter-1 GLUT1 (7) and Band 3 (8) directly bind to dematin and/or adducin, providing alternative links to the erythrocyte plasma membrane.Several P. falciparum exported proteins bring about coordinated remodeling of the spectrin-based erythrocyte membrane skeleton (3, 9). One of the best characterized examples is the knob-associa...
BackgroundParvovirus B19 (B19V) is the most commonly detected virus in endomyocardial biopsies (EMBs) from patients with inflammatory cardiomyopathy (DCMi). Despite the importance of T-cells in antiviral defense, little is known about the role of B19V specific T-cells in this entity.Methodology and Principal FindingsAn exceptionally high B19V viral load in EMBs (115,091 viral copies/μg nucleic acids), peripheral blood mononuclear cells (PBMCs) and serum was measured in a DCMi patient at initial presentation, suggesting B19V viremia. The B19V viral load in EMBs had decreased substantially 6 and 12 months afterwards, and was not traceable in PBMCs and the serum at these times. Using pools of overlapping peptides spanning the whole B19V proteome, strong CD8+ T-cell responses were elicited to the 10-amico-acid peptides SALKLAIYKA (19.7% of all CD8+ cells) and QSALKLAIYK (10%) and additional weaker responses to GLCPHCINVG (0.71%) and LLHTDFEQVM (0.06%). Real-time RT-PCR of IFNγ secretion-assay-enriched T-cells responding to the peptides, SALKLAIYKA and GLCPHCINVG, revealed a disproportionately high T-cell receptor Vbeta (TRBV) 11 expression in this population. Furthermore, dominant expression of type-1 (IFNγ, IL2, IL27 and T-bet) and of cytotoxic T-cell markers (Perforin and Granzyme B) was found, whereas gene expression indicating type-2 (IL4, GATA3) and regulatory T-cells (FoxP3) was low.ConclusionsOur results indicate that B19V Ag-specific CD8+ T-cells with effector function are involved in B19V associated DCMi. In particular, a dominant role of TRBV11 and type-1/CTL effector cells in the T-cell mediated antiviral immune response is suggested. The persistence of B19V in the endomyocardium is a likely antigen source for the maintenance of CD8+ T-cell responses to the identified epitopes.
Human cytomegalovirus (CMV) is a major cause of morbidity in immunocompromised individuals. However, no efficient vaccine has been developed to date. Identification of T-cell target proteins and epitopes is crucial not only for developing a successful immunization strategy, but also for new approaches using adoptive transfer of antigen-specific T-cells. The CMV genome has more than 200 open reading frames potentially coding for as many proteins. Here, we describe a robust, fast, and simple SPOT synthesis strategy, which allowed us to micro-synthesize every possible CD8 T-cell epitope in the entire potential CMV proteome. So far, 9069 of these peptides have been tested in an ex vivo T-cell stimulation assay. As well as confirming a number of previously known epitopes, we identified several new ones.
A high demand of interest concerning binding assays to study the consequences of posttranscriptional phosphorylation may be addressed by peptide array-based methods. A crucial factor for de novo chemical approaches to generate such arrays is the possibility to rationally permutate phosphorylation events along a huge number of sequences. The simple principle behind this advantage is the stepwise synthesis of peptides, which allows the incorporation of either phosphorylated or nonphosphorylated derivates at serine, threonine, and tyrosine positions. In spite of several reported applications of phosphopeptide arrays, there is, to our best knowledge, no reported analysis of the efficiency of the involved techniques. Here, we analyze different coupling conditions to introduce phosphoamino acids in standard SPOT synthesis. Our results clearly indicate that EEDQ is the preferable activator and can also be used in fully automated SPOT synthesis.
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