An approach to the focal presentation of chemical stimuli

An olfactometer is described that presents temporally-discretepulses of stimuli to individual chemosensory structures. Thedevice is based on standard pressure injection techniques inwhich pulses of compressed air eject nanoliter volumes of upto six stimulants from small diameter glass micropipettes. Thedevice should be readily adaptable to different chemoreceptorpreparations.     

Ihog proteins contribute to integrin-mediated focal adhesions

Integrin expression forms focal adhesions, but how this process is physiologically regulated is unclear. Ihog proteins are evolutionarily conserved, playing roles in Hedgehog signaling and serving as trans-homophilic adhesion molecules to mediate cell-cell interactions. Whether these proteins are also engaged in other cell adhesion processes remains unknown. Here, we report that Drosophila Ihog proteins function in the integrin-mediated adhesions. Removal of Ihog proteins causes blister and spheroidal muscle in wings and embryos, respectively. We demonstrate that Ihog proteins interact with integrin via the extracellular portion and that their removal perturbs integrin distribution. Finally, we show that Boc, a mammalian Ihog protein, rescues the embryonic defects caused by removing its Drosophila homologs. We thus propose that Ihog proteins contribute to integrin-mediated focal adhesions.

     

Diazo coupling method for covalent attachment of proteins to solid substrates

We describe a process for covalently linking proteins to glass microscope slides and microbeads in a manner that optimizes the reactivity of the immobilized proteins and that is suitable for high-throughput microarray and flow cytometry analysis. The method involves the diazo coupling of proteins onto activated self-assembled monolayers formed from p-aminophenyl trimethoxysilane. Proteins immobilized by this method maintained bioactivity and produced enhanced levels of protein-protein interaction, low background fluorescence, and high selectivity. The binding of immobilized proteins to their specific binding partner was analyzed quantitatively and successfully correlated with solution concentrations. Diazotized surfaces bound more efficiently to proteins containing a hexahistidine tag than those without a his-tag. Moreover, significantly higher reactivity of the immobilized his-tagged proteins was observed on diazotized surfaces than on amine-terminated surfaces. Results suggest that his-tagged proteins are immobilized by reaction of the his-tag with the diazotized surface, thus offering the possibility for preferential orientation of covalently bound proteins.     

Halothane affects focal adhesion proteins in the A 549 cells

Halothane is a volatile anaesthetic, which is known to induce alterations in cellular plasma membranes, modulating the physical state of the membrane lipids and/or interacting directly with membrane-bound proteins, such as integrin receptors. Integrin-mediated cell adhesion is a general property of eukaryotic cells, which is closely related to cell viability. Our previous investigations showed that halothane is toxic for A 549 lung carcinoma cells when applied at physiologically relevant concentrations and causes inhibition of adhesion to collagen IV. The present study is focused on the mechanisms underlying halothane toxicity. Our results imply that physiologically relevant concentrations of halothane disrupt focal adhesion contacts in A 549 cells, which is accompanied with suppression of focal adhesion kinase activity and paxillin phosphorylation, and not with proteolytic changes or inhibition of vinculin and paxillin expression. We suggest that at least one of the toxic effects of halothane is due to a decreased phosphorylation of the focal contact proteins.     

Automated docking of substrates to proteins by simulated annealing

The Metropolis technique of conformation searching is combined with rapid energy evaluation using molecular affinity potentials to give an efficient procedure for docking substrates to macromolecules of known structure. The procedure works well on a number of crystallographic test systems, functionally reproducing the observed binding modes of several substrates.     

Degradation of focal adhesion proteins during nocodazole-induced apoptosis in rat-1 cells

Nocodazole, a microtubule-disrupting agent, induced apoptosis in Rat-1 cells, as indicated by changes in cell morphology, DNA fragmentation, and eventual cell death. During nocodazole-induced apoptosis, normally flat cells became rounded in shape and detached from the extracellular matrix. These morphological changes appeared to be closely associated with degradation of focal adhesion proteins, including p130cas, p125(FAK) and paxillin. p130cas was also degraded in cells treated with staurosporine or etoposide, suggesting that degradation of focal adhesion proteins is a characteristic feature of apoptosis. Nocodazole-induced apoptosis was antagonized by Bcl-2: degradation of focal adhesion proteins was suppressed and cell viability was enhanced in bcl-2 over-expressing cells, even in the presence of nocodazole. Further study of the molecular mechanism of Bcl-2 activation should provide an understanding of the apoptosis induced by disruption of the microtubule network.     

Tightly bound to DNA proteins: possible universal substrates for intranuclear processes

Tightly bound to DNA proteins (TBPs) are a protein group that remains attached to DNA after its deproteinization by phenol, chloroform or salting-out. TBP are bound to DNA with covalent phosphotriester or non-covalent ion and hydrogen bonds. They appear to be a vast protein group involved in numerous intranuclear processes. The TBPs fraction co-purified with DNA deproteinized by mild procedures is extremely heterogeneous, tissue and species-specific. The protein fraction co-purified with DNA after harsh deproteinization procedures appears to be formed from few polypeptides common to different species and tissues. Interaction sites between DNA and TBPs depend on the physiological status of the cell. The binding sites of TBPs to DNA do not co-localize with the nuclear matrix attachment regions. We hypothesize that TBPs form a universal substrate for intranuclear processes.     

Chemically related antigens compete for presentation by accessory cells to T cells

Immune responsiveness of guinea pigs to dinitrophenyl-poly-L-lysine (DNP-PLL) and to the lysine-rich random copolymer of L-glutamic acid and L-lysine (GL) are both controlled by the "poly-L-lysine gene." We demonstrate that accessory cells of responder strains can be made incapable of presenting DNP-PLL to response T cells in assays for proliferation by in vitro exposure of the cells to GL before and during their exposure to DNP-PLL. The inhibition was not rapidly reversible, because GL preexposed accessory cells that were cultured for 2 hr in GL-free medium were still refractory to pulsing with DNP-PLL. In contrast, DNP-PLL had only a moderate inhibitory effect on accessory cell presentation of GL. Unconjugated poly- and oligo-lysines also inhibited the ability of accessory cells to present DNP-PLL, but inhibitory activity was displayed only by homopolymers containing eight to 12 or more residues in the chain. The homopolymers of D-lysine, L-arginine, and L-glutamic acid, and lysine-free glutamic acid-rich copolymers had little or no inhibitory effect. The results are interpreted to mean that antigens to which responsiveness is regulated by the same Ir gene compete for presentation by accessory cells. This may reflect a competition for the Ir gene product of the antigen-presenting cell.     

Molecular dynamics simulation of the docking of substrates to proteins

A simple method is described to perform docking of subtrates to proteins or probes to receptor molecules by a modification of molecular dynamics simulations. The method consists of a separation of the center-of-mass motion of the substrate from its internal and rotational motions, and a separate coupling to different thermal baths for both types of motion of the substrate and for the motion of the receptor. Thus the temperatures and the time constants of coupling to the baths can be arbitrarily varied for these three types of motion, allowing either a frozen or a flexible receptor and allowing control of search rate without disturbance of internal structure. In addition, an extra repulsive term between substrate and protein was applied to smooth the interaction. The method was applied to a model substrate docking onto a model surface, and to the docking of phosphocholine onto immunoglobulin McPC603, in both cases with a frozen receptor. Using transrational temperatures of the substrate in the range of 1300–1700 K and room temperature for the internal degrees of freedom of the substrate, an efficient nontrapping exploratory search (“helicopter view”) is obtained, which visits the correct binding sites. Low energy conformations can then be further investigated by separate search or by dynamic simulated annealing. In both cases the correct minima were identified. The possibility to work with flexible receptors is discussed. © 1994 Wiley-Liss, Inc.     

Novel polymer substrates for SFM investigations of living cells, biological membranes, and proteins.

Extended studies were performed to prepare substrates for scanning force microscopy of biological samples with a surface roughness below 1 nm rms over an area of 500 x 500 nm2. The substrate smoothness and the lack of tip obscuring material are indispensable in order to visualize detailed structures of membrane surfaces, particularly when scanning the lamellipodia of mechanically sensitive goldfish glial cells where peripheral lamellipodia are only 20-30 nm in thickness. Appropriate substrates are poly(vinyl phenyl ketone) or furan polymers with corrugations of 0.3 and 0.15 nm rms, respectively, to which the growth-promoting protein laminin adsorbs directly with an acceptably increased roughness. Cells show normal growth behavior on these substrates and stick to the substrates in a stable fashion during several scans. Thus details of the membrane's surface may be resolved and are not obscured by the substrate texture. The uncoated furan polymer substrates are suitable for immobilization of membrane preparations such as purified membrane fragments containing bacteriorhodopsin or Na, K-ATPase and protein preparations such as antibodies.     

Regulated folding of tyrosinase in the endoplasmic reticulum demonstrates that misfolded full-length proteins are efficient substrates for class I processing and presentation

Short-lived protein translation products have been proposed to be the principal substrates that enter the class I MHC processing and presentation pathway. However, the biochemical nature of these substrates is poorly defined. Whether the major processing substrates are misfolded full-length proteins, or alternatively, aberrantly initiated or truncated polypeptides still remains to be addressed. To examine this, we used melanoma in which one-third of wild-type tyrosinase molecules were correctly folded and localized beyond the Golgi, while the remainder were present in the endoplasmic reticulum in an unfolded/misfolded state. Increasing the efficiency of tyrosinase folding using chemical chaperones led to a reduction in the level of substrate available to the proteasome and decreased the expression of a tyrosinase-derived epitope. Conversely, in transfectants expressing tyrosinase mutants that are completely misfolded, both proteasome substrate and epitope presentation were significantly enhanced. Proteasome substrate availability was a consequence of misfolding and not simply due to retention in the endoplasmic reticulum. Thus, the extent of folding/misfolding of a full-length protein is an important determinant of the level of epitope presentation.     

Langerhans cells are required for efficient presentation of topically applied hapten to T cells

Dendritic cells (DC) play a pivotal role in the control of T cell immunity due to their ability to stimulate naive T cells and direct effector function. Murine and human DC are composed of a number of phenotypically, and probably developmentally, distinct subsets, which may play unique roles in the initiation and regulation of T cell responses. The skin is populated by at least two subsets of DC: Langerhans cells (LC), which form a contiguous network throughout the epidermis, and dermal DC. LC have classically been thought vital to initiate T cell responses to cutaneous Ags. However, recent data have highlighted the importance of dermal DC in cutaneous immunity, and the requirement for LC has become unclear. To define the relative roles of LC and dermal DC, we and others generated mouse models in which LC were specifically depleted in vivo. Unexpectedly, these studies yielded conflicting data as to the role of LC in cutaneous contact hypersensitivity (CHS). Extending our initial finding, we demonstrate that topical Ag is inefficiently transported to draining lymph nodes in the absence of LC, resulting in suboptimal priming of T cells and reduced CHS. However, dermal DC may also prime cutaneous T cell responses, suggesting redundancy between the two different skin DC subsets in this model.     

Evidence for MR1 antigen presentation to mucosal-associated invariant T cells

The novel class Ib molecule MR1 is highly conserved in mammals, particularly in its alpha1/alpha2 domains. Recent studies demonstrated that MR1 expression is required for development and expansion of a small population of T cells expressing an invariant T cell receptor (TCR) alpha chain called mucosal-associated invariant T (MAIT) cells. Despite these intriguing properties it has been difficult to determine whether MR1 expression and MAIT cell recognition is ligand-dependent. To address these outstanding questions, monoclonal antibodies were produced in MR1 knock-out mice immunized with recombinant MR1 protein, and a series of MR1 mutations were generated at sites previously shown to disrupt the ability of class Ia molecules to bind peptide or TCR. Here we show that 1) MR1 molecules are detected by monoclonal antibodies in either an open or folded conformation that correlates precisely with peptide-induced conformational changes in class Ia molecules, 2) only the folded MR1 conformer activated 2/2 MAIT hybridoma cells tested, 3) the pattern of MAIT cell activation by the MR1 mutants implies the MR1/TCR orientation is strikingly similar to published major histocompatibility complex/alphabetaTCR engagements, 4) all the MR1 mutations tested and found to severely reduce surface expression of folded molecules were located in the putative ligand binding groove, and 5) certain groove mutants of MR1 that are highly expressed on the cell surface disrupt MAIT cell activation. These combined data strongly support the conclusion that MR1 has an antigen presentation function.     

Muscle proteins related to microtubule associated protein-2 are substrates for an insulin-stimulatable kinase

High molecular weight muscle protein(s), present as a doublet (approximately 320 and approximately 290 kDa apparent molecular weight) in partially purified preparations of inhibitor-2 from rabbit skeletal muscle, and homogeneous bovine brain microtubule associated protein-2 are both in vitro substrates for a soluble insulin-stimulatable serine/threonine kinase in 3T3-L1 adipocytes. The high molecular weight muscle substrate doublet was specifically immunoprecipitated by affinity-purified anti-microtubule associated protein-2 antibody.     

Antigen processing for presentation to CD4+ T cells.

The immune system surveys the organism for the presence of foreign or abnormal structures. An important role in the immune response is assumed by T lymphocytes that recognize foreign antigen while tolerating self-proteins. T lymphocytes can recognize only peptide fragments that are presented to them by molecules of the major histocompatibility complex (MHC). Antigen processing for presentation to T cells involves distinct cellular compartments where peptides and MHC molecules interact. Whereas class I MHC molecules (recognized by CD8+ cytotoxic T cells) acquire peptides in an early biosynthetic compartment, class II molecules (recognized by CD4+ helper T cells) acquire peptides most efficiently in an endocytic compartment. It has emerged recently that the class II processing compartment can be fed not only from the outside with exogenous antigen but also from endogenous sources, including membrane-associated and cytosolic proteins. The potential sources of proteins that can trigger a helper T cell response during viral infections and that can induce self-tolerance are thus much wider than previously anticipated.     

An intracellular pathway is required for ABA-tyrosine presentation to T cells

Although tyrosine-azobenzenearsonate (ABA-Tyr) is not degraded by proteolytic enzymes, its presentation by accessory cells is inhibited by lysosomotropic agents such as chloroquine. Presentation of ABA-poly-L-glutamic, alanine, tyrosine (ABA-GAT) is similarly inhibited by chloroquine, but in contrast to ABA-Tyr it is also inhibited by leupeptin. Finally formaldehyde fixation of accessory cells after pulsing with ABA-Tyr but not before permits successful stimulation of ABA-specific hybridoma cells. These results suggest that a lysosomal pathway but not digestion is necessary for the association of ABA-Tyr and la molecules for presentation.     

Impaired processing and presentation by MHC class II proteins in human diabetic cells

The biochemical processing of and Ag presentation by MHC class II molecules were examined in B cell lines derived from pairs of identical twins discordant for type 1 diabetes. MHC class II defects detected exclusively in cells derived from the twins with autoimmunity included increased rates of transport to and subsequent turnover at the cell surface, inadequate glycosylation, and a reduced display at the cell surface of antigenic peptides. These defects appeared to be secondary to a decreased abundance of the p35 isoform of the invariant chain (Ii), a human-specific chaperone protein for MHC class II normally generated by use of an alternative translation start site. Stable transfection of diabetic B cell lines with an Ii p35 expression vector corrected the defects in MHC class II processing and peptide presentation. A defect in the expression of Ii p35 may thus result in impairment of Ag presentation by MHC class II molecules and thereby contribute to the development of type 1 diabetes in at-risk genotypes.     

Dynamics of cellular focal adhesions on deformable substrates: consequences for cell force microscopy

Cell focal adhesions are micrometer-sized aggregates of proteins that anchor the cell to the extracellular matrix. Within the cell, these adhesions are connected to the contractile, actin cytoskeleton; this allows the adhesions to transmit forces to the surrounding matrix and makes the adhesion assembly sensitive to the rigidity of their environment. In this article, we predict the dynamics of focal adhesions as a function of the rigidity of the substrate. We generalize previous theories and include the fact that the dynamics of proteins that adsorb to adhesions are also driven by their coupling to cell contractility and the deformation of the matrix. We predict that adhesions reach a finite size that is proportional to the elastic compliance of the substrate, on a timescale that also scales with the compliance: focal adhesions quickly reach a relatively small, steady-state size on soft materials. However, their apparent sliding is not sensitive to the rigidity of the substrate. We also suggest some experimental probes of these ideas and discuss the nature of information that can be extracted from cell force microscopy on deformable substrates.