Lymph node fibroblastic reticular cells directly present peripheral tissue antigen under steady-state and inflammatory conditions.

Lymph node stromal cells (LNSCs) can induce potent, antigen-specific T cell tolerance under steady-state conditions. Although expression of various peripheral tissue-restricted antigens (PTAs) and presentation to naive CD8+ T cells has been demonstrated, the stromal subsets responsible have not been identified. We report that fibroblastic reticular cells (FRCs), which reside in the T cell zone of the LN, ectopically express and directly present a model PTA to naive T cells, inducing their proliferation. However, we found that no single LNSC subset was responsible for PTA expression; rather, each subset had its own characteristic antigen display. Studies to date have concentrated on PTA presentation under steady-state conditions; however, because LNs are frequently inflammatory sites, we assessed whether inflammation altered stromal cell-T cell interactions. Strikingly, FRCs showed reduced stimulation of T cells after Toll-like receptor 3 ligation. We also characterize an LNSC subset expressing the highest levels of autoimmune regulator, which responds potently to bystander inflammation by up-regulating PTA expression. Collectively, these data show that diverse stromal cell types have evolved to constitutively express PTAs, and that exposure to viral products alters the interaction between T cells and LNSCs.

High-throughput microfluidic mixing and multiparametric cell sorting for bioactive compound screening.

HyperCyt, an automated sample handling system for flow cytometry that uses air bubbles to separate samples sequentially introduced from multiwell plates by an autosampler. In a previously documented HyperCyt configuration, air bubble separated compounds in one sample line and a continuous stream of cells in another are mixed in-line for serial flow cytometric cell response analysis. To expand capabilities for high-throughput bioactive compound screening, the authors investigated using this system configuration in combination with automated cell sorting. Peptide ligands were sampled from a 96-well plate, mixed in-line with fluo-4-loaded, formyl peptide receptor-transfected U937 cells, and screened at a rate of 3 peptide reactions per minute with approximately 10,000 cells analyzed per reaction. Cell Ca(2+) responses were detected to as little as 10(-11) M peptide with no detectable carryover between samples at up to 10(-7) M peptide. After expansion in culture, cells sort-purified from the 10% highest responders exhibited enhanced sensitivity and more sustained responses to peptide. Thus, a highly responsive cell subset was isolated under high-throughput mixing and sorting conditions in which response detection capability spanned a 1000-fold range of peptide concentration. With single-cell readout systems for protein expression libraries, this technology offers the promise of screening millions of discrete compound interactions per day.

Surface passivation of a microfluidic device to glial cell adhesion: a comparison of hydrophobic and hydrophilic SAM coatings.

Cell adhesion in a microfluidic structure can lead to catastrophic flow problems due to the comparable size of the cell with the microfabricated device. Such issues are important in the growing research area involving the merging of biological materials and MEMS devices. We have examined the surface compatibility of uncoated and coated microfabricated glass and semiconductor surfaces under static solution (cell culture) and flow experiments (microfluidic device) using glial (astrocyte and glioblastoma) cells. Bare semiconductor and glass surfaces were most attractive to cell adhesion, promoting biofouling under both static and flow conditions. Passivation of the surfaces was performed with silane coupling agents octadecyltrimethoxysilane (OTMS) or N-(triethoxysilylpropyl)-O-polyethylene oxide urethane (TESP) on SiO2 surfaces via self-assembled monolayer (SAM) deposition. The hydrophilic TESP coating was effective at inhibiting biofouling of the microfluidic structure, allowing greater than several minutes of fluid flow. The hydrophobic OTMS coating, on the other hand, promoted cell adhesion leading to restricted flow within a few minutes. Interestingly, under cell culture conditions the TESP surface exhibited biocompatible properties for glial cell adhesion and proliferation, in contrast to the OTMS surface which resisted cell growth. These studies suggest that cell adhesion is dependent upon the time domain of the cell-surface interaction.