The FDA-approved compound, pramipexole and the clinical-stage investigational drug, dexpramipexole, reverse chronic allodynia from sciatic nerve damage in mice, and alter IL-1β and IL-10 expression from immune cell culture

During the onset of neuropathic pain from a variety of etiologies, nociceptors become hypersensitized, releasing neurotransmitters and other factors from centrally-projecting nerve terminals within the dorsal spinal cord. Consequently, glial cells (astrocytes and microglia) in the spinal cord are activated and mediate the release of proinflammatory cytokines that act to enhance pain transmission and sensitize mechanical non-nociceptive fibers which ultimately results in light touch hypersensitivity, clinically observed as allodynia. Pramipexole, a D2/D3 preferring agonist, is FDA-approved for the treatment of Parkinson's disease and demonstrates efficacy in animal models of inflammatory pain. The clinical-stage investigational drug, R(+) enantiomer of pramipexole, dexpramipexole, is virtually devoid of D2/D3 agonist actions and is efficacious in animal models of inflammatory and neuropathic pain. The current experiments focus on the application of a mouse model of sciatic nerve neuropathy, chronic constriction injury (CCI), that leads to allodynia and is previously characterized to generate spinal glial activation with consequent release IL-1β. We hypothesized that both pramipexole and dexpramipexole reverse CCI-induced chronic neuropathy in mice, and in human monocyte cell culture studies (THP-1 cells), pramipexole prevents IL-1β production. Additionally, we hypothesized that in rat primary splenocyte culture, dexpramixole increases mRNA for the anti-inflammatory and pleiotropic cytokine, interleukin-10 (IL-10). Results show that following intravenous pramipexole or dexpramipexole, a profound decrease in allodynia was observed by 1 hr, with allodynia returning 24 hr post-injection. Pramipexole significantly blunted IL-1β protein production from stimulated human monocytes and dexpramipexole induced elevated IL-10 mRNA expression from rat splenocytes. The data support that clinically-approved compounds like pramipexole and dexpramipexole support their application as anti-inflammatory agents to mitigate chronic neuropathy, and provide a blueprint for future, multifaceted approaches for opioid-independent neuropathic pain treatment.

Modulation of GPCR conformations by ligands, G-proteins, and arrestins

G-protein-coupled receptors (GPCRs) have traditionally been thought to adopt two conformations: the inactive unliganded conformation and the active ligand-bound conformation. Interactions with G-proteins in cells and membranes are known to modulate the affinity of the receptor for ligand and therefore the conformation of the receptor. Such observations led to the proposal of the ternary complex model. However, subsequent studies of constitutively active GPCRs led to the development of an extended version of this model to account for active conformations of the receptor in the absence of agonist. A significant difficulty with many of the studies, upon which this latter model was based, is the lack of knowledge of receptor and G-protein concentrations due to the two-dimensional nature of the membranes used to perform the measurements. Over the past decade, we have studied the interaction of GPCRs, G-proteins, arrestins, and ligands in solubilized systems, where the concentration of each component can be defined. Here we summarize results of these studies as they pertain to the regulation of GPCR conformations and affinities for interacting species.

Eosinophil traffic in the circulation following allergen challenge

BACKGROUND

Eosinophils contribute to the pathogenesis of asthma and localize to the lung after allergen exposure by uncertain mechanisms.

METHODS

We used intrabronchial instillation of allergen to model the interaction between inhaled allergen and the lung. We measured the number of peripheral blood leukocytes and the expression of VLA-4 (CD49d), Mac-1 (CD11b) and PSGL-1 (CD162) up to 4 h after instillation of allergen into a bronchus of eight atopic asthmatics. For controls, we instilled normal saline into a subset of the asthmatic subjects, and allergen into nonatopic, nonasthmatic subjects.

RESULTS

There were changes of total leukocyte number, number of polymorphonuclear leukocytes, lymphocytes, monocytes and eosinophils in all three groups (atopic asthmatics instilled with allergen, atopic asthmatics instilled with saline, nonatopic nonasthmatic subjects instilled with allergen), which were likely related to bronchoscopy. However, the decrease of eosinophils was significant only in the atopic asthmatics instilled with allergen. The remaining eosinophils in the allergen challenged asthmatics were not activated as defined by cell density or change of expression of VLA-4, Mac-1 and PSGL-1.

CONCLUSIONS

While eosinophils rapidly and specifically leave the circulation after allergen challenge of atopic asthmatics, the remaining circulating eosinophils are not activated.

Mixing of a continuous flow of two fluids due to unsteady flow

In many low-Reynolds number mixing applications, the absence of turbulence makes it difficult to achieve proper mixing of two fluids. In this paper, flow visualization is used to obtain quantitative measurements of mixing that occurs when combining two pulsatile fluid streams at a Y-connection. Mixing results from the interface distortion created by the pulsatile flow. This is generated by combining the action a peristaltic pump, which provides the mean flow, with the action of two pinch valves, one on each arm of the Y-connection, to generate strong pulsations. The action of the pinch valves is be controlled via pulse generators. Apparently chaotic conditions were realized in the confluence region, superimposed with the mean flow. The valve action was optimized to maximize mixing, the latter quantified via image analysis. This work demonstrates a low cost, efficient mixing device for low-Reynolds number conditions, which is therefore suitable for miniaturization.

High throughput screening of G-protein coupled receptors via flow cytometry

The molecular assemblies of signal transduction components, for example kinases and their target proteins or receptor-ligand complexes and intracellular signaling molecules, are critical for biological functions in cells. To better understand the interactions of these molecular assemblies and to screen for new pharmaceutics that could control and modulate these types of interactions, we have focused on developing high throughput approaches for the analysis of G-protein coupled receptors via flow cytometry. Flow cytometry offers a number of advantages including real-time collection of multicomponent data, and together with improvements in sample handling, the high throughput sampling rate is up to 100 samples per minute. For our targets, assemblies of solubilized GPCRs, a screening platform of a dextran bead has proven to be flexible, allowing different surface chemistries on the beads. The bead can be either ligand-labeled or have epitope-linked proteins attached to the bead surface, enabling several molecular assemblies to be constructed and analyzed. A major improvement with this system is that for screening ligands for GPCRs the underlying mechanism of action for these compounds can be investigated and incorporated into the definition of a 'hit'. Our current screening system is capable of simultaneously distinguishing GPCR agonists and antagonists.

Performance of in-line microfluidic mixers in laminar flow for high-throughput flow cytometry

We describe a micromixing approach that is compatible with commercial autosamplers, flow cytometry, and other detection schemes that require the mixing of components that have been introduced into laminarflow. The scheme is based on high-throughput flow cytometry (HyperCyt) where samples from multi-well plates that have been picked up by an autosampler can be separated during delivery by the small air bubbles introduced during the transit of the autosampler probe from well to well. Here, either cell or particle samplesflowing continuously and driven by a syringe are brought together in a Y with reagent samples from wells driven by a peristaltic pump. The mixing is driven by a magnetic microstirrer contained within the sample line. The mixing is assessed using fluorescence of both cell calcium responses and bead-based fluorescence unquenching. In the analysis stream, the particles and reagents are mixed with eithera "wire" or "bar". The bar is more efficient than the wire, and the efficiency of either depends on the spinning action. The high-throughput approach and mixing in HyperCyt integrate autosamplers with submicroliter detection volumes for analysis in flow cytometry or in microfluidic channels.

Mixing small volumes for continuous high-throughput flow cytometry: performance of a mixing Y and peristaltic sample delivery

BACKGROUND

Online mixing for continuous high-throughput flow cytometry has not been previously described. A simple, general high-throughput method for mixing and delivery of submicroliter volumes in laminar flow at low Reynolds numbers would be widely useful.

MATERIALS AND METHODS

We describe a micromixing approach that is compatible with commercial autosamplers, flow cytometry, and other detection schemes that require mixing of components that have been introduced into laminar flow. The scheme is based on a previous approach to high-throughput flow cytometry (HyperCyt, Kuckuck et al.: Cytometry 44:83-90, 2001). We showed that samples from multiwell plates that have been picked up by an autosampler can be separated during delivery by the small air bubbles introduced during the transit of the autosampler probe from well to well. Here, a particle sample flowing continuously is brought together in a Y with reagent samples from wells, which have been separated by bubbles.

RESULTS

In the effluent stream, the particles and reagents are mixed, most likely as a result of peristaltic action, and reagents from individual wells can be resolved. The sample volumes that can be mixed with this technology are submicroliter in volume, and samples can be mixed at rates up to at least 100/samples per minute. With the current device, carryover between samples can be eliminated if the mixing system is flushed with several volumes of buffer. The anticipated throughput for screening is expected to be at least 20 samples per minute.

CONCLUSIONS

The high-throughput approach and peristaltic mixing in HyperCytTM serve to integrate autosamplers with submicroliter detection volumes for analysis in flow cytometry or in microfluidic channels.

Real time analysis of the affinity regulation of alpha 4-integrin. The physiologically activated receptor is intermediate in affinity between resting and Mn(2+) or antibody activation

This work examines the affinity of alpha(4)beta(1)-integrin and whether affinity regulation by G protein-coupled receptor (GPCR) and chemokines receptors is compatible with cell adhesion mediated between alpha(4)-integrin and vascular cell adhesion molecule-1. We used flow cytometry to examine the binding of a fluorescent derivative of an LDV peptide (Chen, L. L., Whitty, A., Lobb, R. R., Adams, S. P., and Pepinsky, R. B. (1999) J. Biol. Chem. 274, 13167-13175) to several cell lines and leukocytes with alpha(4)-integrin ranging from about 2,000 to 100,000 sites/cell. The results support the idea that alpha(4)-integrins exhibit multiple affinities and that affinity changes are regulated by the dissociation rate and conformation. The affinity varies by 3 orders of magnitude with the affinity induced by binding mAb TS2/16 plus Mn(2+) > Mn(2+) ' TS2/16 > activation because of occupancy of GPCR or chemokines receptor > resting receptors. A significant fraction of the receptors respond to the activating process. The change in alpha(4)-integrin affinity and the corresponding change in off rates mediated by GPCR receptor activation are rapid and transient, and their duration depends on GPCR desensitization. The affinity changes mediated by IgE receptor or interleukin-5 receptor persist longer. It appears that the physiologically active state of the alpha(4)-integrin, determined by inside-out signaling, has similar affinity in several cell types.

Regulation of formyl peptide receptor agonist affinity by reconstitution with arrestins and heterotrimeric G proteins

Although heptahelical chemoattractant and chemokine receptors are known to play a significant role in the host immune response and the pathophysiology of disease, the molecular mechanisms and transient macroassemblies underlying their activation and regulation remain largely uncharacterized. We report herein real time analyses of molecular assemblies involving the formyl peptide receptor (FPR), a well described member of the chemoattractant subfamily of G protein-coupled receptors (GPCRs), with both arrestins and heterotrimeric G proteins. In our system, the ability to define and discriminate distinct, in vitro receptor complexes relies on quantitative differences in the dissociation rate of a fluorescent agonist as well as the guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) sensitivity of the complex, as recently described for FPR-G protein interactions. In the current study, we demonstrate a concentration- and time-dependent reconstitution of liganded, phosphorylated FPR with exogenous arrestin-2 and -3 to form a high agonist affinity, nucleotide-insensitive complex with EC(50) values of 0.5 and 0.9 microm, respectively. In contrast, neither arrestin-2 nor arrestin-3 altered the ligand dissociation kinetics of activated, nonphosphorylated FPR. Moreover, we demonstrated that the addition of G proteins was unable to alter the ligand dissociation kinetics or induce a GTP gamma S-sensitive state of the phosphorylated FPR. The properties of the phosphorylated FPR were entirely reversible upon treatment of the receptor preparation with phosphatase. These results represent to our knowledge the first report of the reconstitution of a detergent-solubilized, phosphorylated GPCR with arrestins and, furthermore, the first demonstration that phosphorylation of a nonvisual GPCR is capable of efficiently blocking G protein binding in the absence of arrestin. The significance of these results with respect to receptor desensitization and internalization are discussed.

Partial phosphorylation of the N-formyl peptide receptor inhibits G protein association independent of arrestin binding

It is now well accepted that G protein-coupled receptors activated by agonist binding become targets for phosphorylation, leading to desensitization of the receptor. Using a series of phosphorylation deficient mutants of the N-formyl peptide receptor (FPR), we have explored the role of phosphorylation on the ability of the receptor to interact with G proteins and arrestins. Using a fluorometric assay in conjunction with solubilized receptors, we demonstrate that phosphorylation of the wild type FPR lowers its affinity for G protein, whereas mutant receptors lacking four potential phosphorylation sites retain their ability to couple to G protein. Phosphorylated mutant receptors lacking only two potential phosphorylation sites are again unable to couple to G protein. Furthermore, whereas stimulated wild type FPR in whole cells colocalizes with arrestin-2, and the solubilized, phosphorylated FPR binds arrestin-2, the stimulated receptors lacking four potential phosphorylation sites display no interaction with arrestin-2. However, the mutant receptors lacking only two potential phosphorylation sites are restored in their ability to bind and colocalize with arrestin-2. Thus, there is a submaximal threshold of FPR phosphorylation that simultaneously results in an inhibition of G protein binding and an induction of arrestin binding. These results are the first to demonstrate that less than maximal levels of receptor phosphorylation can block G protein binding, independent of arrestin binding. We therefore propose that phosphorylation alone may be sufficient to desensitize the FPR in vivo, raising the possibility that for certain G protein-coupled receptors, desensitization may not be the primary function of arrestin.

Detection of epitope-tagged proteins in flow cytometry: fluorescence resonance energy transfer-based assays on beads with femtomole resolution

Epitope tagging of expressed proteins is a versatile tool for the detection and purification of the proteins. This approach has been used in protein-protein interaction studies, protein localization, and immunoprecipitation. Among the most popular tag systems is the FLAG epitope tag, which is recognized by three monoclonal antibodies M1, M2, and M5. We describe novel approaches to the detection of epitope-tagged proteins via fluorescence resonance energy transfer on beads. We have synthesized and characterized biotinylated and fluorescein-labeled FLAG peptides and examined the binding of FLAG peptides to commercial streptavidin beads using flow cytometric analysis. A requirement of assay development is the elucidation of parameters that characterize the binding interactions between component systems. We have thus compiled a set of Kd values determined from a series of equilibrium binding experiments with beads, peptides, and antibodies. We have defined conditions for binding biotinylated and fluoresceinated FLAG peptides to beads. Site occupancies of the peptides were determined to be on the order of several million sites per bead and Kd values in the 0.3-2.0 nM range. The affinity for antibody attachment to peptides was determined to be in the low nanomolar range (less than 10 nM) for measurements on beads and solution. We demonstrate the applicability of this methodology to assay development, by detecting femtomole amounts of N-terminal FLAG-bacteria alkaline phosphatase fusion protein. These characterizations form the basis of generalizable and high throughput assays for proteins with known epitopes, for research, proteomic, or clinical applications.

Real-time analysis of G protein-coupled receptor reconstitution in a solubilized system

Receptor based signaling mechanisms are the primary source of cellular regulation. The superfamily of G protein-coupled receptors is the largest and most ubiquitous of the receptor mediated processes. We describe here the analysis in real-time of the assembly and disassembly of soluble G protein-coupled receptor-G protein complexes. A fluorometric method was utilized to determine the dissociation of a fluorescent ligand from the receptor solubilized in detergent. The ligand dissociation rate differs between a receptor coupled to a G protein and the receptor alone. By observing the sensitivity of the dissociation of a fluorescent ligand to the presence of guanine nucleotide, we have shown a time- and concentration-dependent reconstitution of the N-formyl peptide receptor with endogenous G proteins. Furthermore, after the clearing of endogenous G proteins, purified Galpha subunits premixed with bovine brain Gbetagamma subunits were also able to reconstitute with the solubilized receptors. The solubilized N-formyl peptide receptor and Galpha(i3) protein interacted with an affinity of approximately 10(-6) m with other alpha subunits exhibiting lower affinities (Galpha(i3) > Galpha(i2) > Galpha(i1) Galpha(o)). The N-formyl peptide receptor-G protein interactions were inhibited by peptides corresponding to the Galpha(i) C-terminal regions, by Galpha(i) mAbs, and by a truncated form of arrestin-3. This system should prove useful for the analysis of the specificity of receptor-G protein interactions, as well as for the elucidation and characterization of receptor molecular assemblies and signal transduction complexes.

High throughput flow cytometry

BACKGROUND

Conventional flow cytometry does not allow the rapid analysis of multiple samples. This has limited its uses in drug discovery, for which the standard for throughput is 100,000 samples per day.

METHODS

We describe a simple method in which commercial peristaltic tubing is connected from a commercial autosampler to a flow cytometer. The samples are delivered via a peristaltic pump from source wells in a multiwell plate. The samples are separated by air bubbles.

RESULTS

Throughput rates approach the limit of the autosampler (up to 100 wells per minute). Using optimal tubing and flow rates, particles remain within appropriate light scatter and fluorescence gates. The carryover between wells is typically less than 5% without and 1% with a wash step. The volumes of sample delivered are in the microliter scale. The approach has been validated with instruments from three manufacturers.

CONCLUSIONS

Flow cytometry has potential throughput of 100,000 samples or more per day starting with the method described. The method is currently best suited to end-point assays. However, combined with high-speed sorting and single- cell assays, the number of assays could approach 1 billion per day.

HTPS flow cytometry: a novel platform for automated high throughput drug discovery and characterization

The flow cytometer is unique among biomedical analysis instruments because it makes simultaneous and multiple optical measurements on individual cells or particles at high rates. High throughput flow cytometry represents a potentially important multifactorial approach for screening large combinatorial libraries of compounds. Limiting this approach has been the availability of instrumentation and methods in flow cytometry for automated sample handling on the scale required for drug discovery applications. Here, we describe an automated system in which a novel patented fluidics-based pharmacology platform, the HTPS (High Throughput Pharmacological System), is coupled to a flow cytometer using a recently described plug flow-coupling valve technology. Individual samples are aspirated sequentially from microplate wells and delivered to a flow cytometer for rapid multiparametric analysis. For primary screening to detect and quantify cell fluorescence in endpoint assays, a high-speed no-wash protocol enabled processing of 9-10 cell samples/min from 96-well microplates. In an alternate primary screening format, soluble receptor ligands were sampled from microplate wells at rates of 3-4 samples/minute and successfully assessed for the ability to elicit intracellular calcium responses. Experiments with fluorescent beads validated the accurate automated production by the HTPS of exponential and linear gradients of soluble compounds. This feature enabled rapid (2- to 3-min) characterization of the intracellular calcium dose response of myeloid cells to formyl peptide as well as the quantitative relationship between formyl peptide receptor occupancy and cell response. HTPS flow cytometry thus represents a powerful high throughput multifactorial approach to increase the efficiency with which novel bioresponse-modifying drugs may be identified and characterized.

Plug flow cytometry extends analytical capabilities in cell adhesion and receptor pharmacology

BACKGROUND

Plug flow cytometry is a recently developed system for the automated delivery of multiple small boluses or "plugs" of cells or particles to the flow cytometer for analysis. Important system features are that sample plugs are of precisely defined volume and that the sample vessel need not be pressurized. We describe how these features enable direct cell concentration determinations and novel ways to integrate flow cytometers with other analytical instruments.

METHODS

Adhesion assays employed human polymorphonuclear neutrophils (PMNs) loaded with Fura Red and Chinese hamster ovary (CHO) cells cotransfected with genes for green fluorescent protein (GFP) and human P-selectin. U937 cells expressing the human 7-transmembrane formyl peptide receptor were loaded with the fluorescent probe indo-1 for intracellular ionized calcium determinations. A computer-controlled syringe or peristaltic pump loaded the sample into a sample loop of the plug flow coupler, a reciprocating eight-port valve. When the valve position was switched, the plug of sample in the sample loop was transported to the flow cytometer by a pressure-driven fluid line.

RESULTS

In stirred mixtures of PMNs and CHO cells, we used plug flow cytometry to directly quantify changes in concentrations of nonadherent singlet PMNs. This approach enabled accurate quantification of adherent PMNs in multicell aggregates. We constructed a novel plug flow interface between the flow cytometer and a cone-plate viscometer to enable real-time flow cytometric analysis of cell-cell adhesion under conditions of uniform shear. The High Throughput Pharmacology System (HTPS) is an instrument used for automated programming of complex pharmacological cell treatment protocols. It was interfaced via the plug flow coupling device to enable rapid (< 5 min) flow cytometric characterization of the intracellular calcium dose-response profile of U937 cells to formyl peptide.

CONCLUSIONS

By facilitating the coupling of flow cytometers to other fluidics-based analytical instruments, plug flow cytometry has extended analytical capabilities in cell adhesion and pharmacological characterization of receptor-ligand interactions.

Analysis of free intracellular calcium by flow cytometry: multiparameter and pharmacologic applications

Flow cytometry offers numerous advantages over traditional techniques for measuring intracellular Ca(2+) in lymphoid and nonlymphoid cells. In particular, the heterogeneity of cell responses can be defined by flow cytometry, and multiparameter analyses permit the determination of intracellular Ca(2+) in surface-marker-defined target cells as well as correlation of changes in Ca(2+) with other biochemical markers, including ligand binding. This article presents several established methods for measuring intracellular Ca(2+) by flow cytometry in lymphoid and nonlymphoid cells. Examples are provided for determination of Ca(2+) in human peripheral blood leukocytes and two human epithelial cell lines grown in monolayer. In addition, applications are reviewed or presented for correlating changes in intracellular Ca(2+) with other cell parameters, including cell cycle analysis, changes in cell membrane integrity, and the induction of apoptosis markers. Finally, a number of novel sample handling capabilities useful for performing kinetic analyses of Ca(2+) changes by flow cytometry are now available and one application is presented which is finding utility in pharmacologic studies.

Expression of P-selectin at low site density promotes selective attachment of eosinophils over neutrophils

The selective interaction of neutrophils with E-selectin and eosinophils with P-selectin has been previously reported, but the relevance of selectin site density and fluid shear has not been studied in detail. We have developed a new approach to examine these interactions in cell suspensions that integrates an on-line cone-plate viscometer with a flow cytometer. We find that eosinophils and neutrophils both use P-selectin glycoprotein ligand-1 to form stable conjugates with P-selectin Chinese hamster ovary cell transfectants, with a preferential adhesion of eosinophils. Further, the difference in cell adhesion between neutrophils and eosinophils is magnified at P-selectin expression levels below approximately 20 sites/microm2, a range likely to be relevant to endothelial cell expression levels in conditions associated with eosinophilia. The unique behavior is retained over shear rates ranging from 100 to 1500/s but is magnified at low shear. Results from parallel-plate flow chamber assays suggest that preferential eosinophil adhesion reflects an enhanced efficiency of initial PSGL-1 bond formation with P-selectin rather than a unique ability of eosinophils to mediate rolling interactions of longer duration on low-density P-selectin substrates. These differences may account in part for the increase in eosinophil accumulation in allergic diseases.

Solubilization and display of G protein-coupled receptors on beads for real-time fluorescence and flow cytometric analysis

G protein-coupled receptors (GPCR) and cellular signaling elements are prime targets for drug discovery. Sensitive real-time methods that expand the analytical capabilities for these elements can play significant roles in basic research and drug discovery. Here, we describe novel approaches for the real-time fluorescence analysis of GPCRs. Using the G protein-coupled N-formyl peptide receptor (FPR) as a model system in concert with a fluorescent ligand, we showed the quantitative solubilization of his-tagged FPRs in 1% dodecyl maltoside. Solubilized receptors reconstitute in dodecyl maltoside with a mixture of bovine brain Gi/Go showing an apparent Kd of 100 nM. Solubilized receptors were also bound to Ni(2+)-silica particles and were detected in a flow cytometer by the binding of fluorescent ligand. The efficiency of receptor uptake by the particles was in excess of 80% with an apparent affinity for the bead in the nM range. The receptors had largely homogeneous dissociation characteristics, an appropriate Kd for the ligand in the low nM range and a high site number, with several million receptor molecules per particle. However, the G protein reconstitution was not detected on the beads, apparently for steric reasons. These approaches for displaying receptors could prove useful in drug discovery and in the analysis of the molecular assemblies in signal transduction.

Sulfhydryl regulation of L-selectin shedding: phenylarsine oxide promotes activation-independent L-selectin shedding from leukocytes

The L-selectin adhesion molecule mediates leukocyte recruitment to inflammatory sites and lymphocyte trafficking through the peripheral lymph nodes. In response to leukocyte activation, L-selectin is proteolytically released from the cell surface, disabling leukocytes from the subsequent L-selectin-dependent interactions. We have found that L-selectin shedding is sensitive to sulfhydryl chemistry; it is promoted by thiol-oxidizing or -blocking reagents and inhibited by reducing reagents. Phenylarsine oxide (PAO), a trivalent arsenical that interacts with vicinal dithiols, is most potent in inducing rapid shedding of L-selectin from isolated neutrophils, eosinophils, and lymphocytes as well as from neutrophils in whole blood. PAO does not cause cell activation, nor does it interfere with integrin function or alter the expression of several other cell surface molecules at the low concentrations that induce L-selectin shedding. PAO is not required to enter the cell to induce L-selectin shedding. TAPI-2 ((N-(D,L-[2-(hydroxyaminocarbonyl)-methyl]-4-methylpentanoyl)-L-3-(tert-butyl)-alanyl-l -alanine, 2-aminoethyl amide), which has previously been shown to inhibit the activation-dependent L-selectin shedding, is also capable of inhibiting PAO-induced L-selectin shedding. We hypothesize that PAO-induced L-selectin shedding involves a regulatory molecule, such as protein disulfide isomerase (PDI), an enzyme that plays a role in the formation and rearrangement of disulfide bonds, contains PAO-binding, vicinal dithiol-active sites, and is expressed on the neutrophil surface. Cell surface expression of PDI, L-selectin shedding induced by PDI-blocking Abs and by bacitracin, a known inhibitor of PDI activity, and direct binding of PDI to PAO, provide supporting evidence for this hypothesis.

Plug flow cytometry: An automated coupling device for rapid sequential flow cytometric sample analysis

BACKGROUND

The tools for high throughput flow cytometry have been limited in part because of the requirement that the samples must flow under pressure. We describe a simple system for sampling repetitively from an open vessel.

METHODS

Under computer control, the sample is loaded into a sample loop in a reciprocating eight-way valve by the action of a syringe. When the valve position is switched, the plug of sample in the sample loop is transported to the flow cytometer by a pressure-driven fluid line. By coupling the plug-forming capability to a second multi-port valve, samples can be delivered sequentially from separate vessels.

RESULTS

The valve is able to deliver samples at rates ranging up to about 9 samples per minute. Each plug of sample has uniform delivery characteristics with a reproducible coefficient of variation (CV). Even at the highest sampling rate, carryover between samples is limited.

CONCLUSIONS

Plug-flow flow cytometry has the potential to automate the delivery of small samples from unpressurized sources at rates compatible with many screening and assay applications.

Peptides, antibodies, and FRET on beads in flow cytometry: A model system using fluoresceinated and biotinylated beta-endorphin

BACKGROUND

Particulate surfaces such as beads are routinely used as platforms for molecular assembly for fundamental and practical applications in flow cytometry. Molecular assembly is transduced as the direct analysis of fluorescence, or as a result of fluorescence resonance energy transfer. Binding of fluorescent ligands to beads sometimes alters their emission yield relative to the unbound ligands. Characterizing the physical basis of factors that regulate the fluorescence yield of bound fluorophores (on beads) is a necessary step toward their rational use as mediators of numerous fluorescence based applications.

METHODS

We have examined the binding between two biotinylated and fluoresceinated beta-endorphin peptides and commercial streptavidin beads using flow cytometric analysis. We have analyzed the assembly between a specific monoclonal antibody and an endorphin peptide in solution using resonance energy transfer and compared the results on beads in flow cytometry using steady-state and time-resolved fluorescence.

RESULTS

We have defined conditions for binding biotinylated and fluoresceinated endorphin peptides to beads. These measurements suggest that the peptide structure can influence both the intensity of fluorescence and the mode of peptide binding on the bead surface. We have defined conditions for binding antibody to the bead using biotinylated protein A. We compared and contrasted the interactions between the fluoresceinated endorphin peptide and the rhodamine- labeled antibody. In solution we measure a K(d) of <38 nM by resonance energy transfer and on beads 22 nM.

DISCUSSION

Some issues important to the modular assembly of a fluorescence resonance energy transfer (FRET) based sensing scheme have been resolved. The affinity of peptides used herein is a function of their solubility in water, and the emission intensity of the bound species depends on the separation distance between the fluorescein and the biotin moiety. This is due to the quasi-specific quenching interaction between the fluorescein and a proximal binding pocket of streptavidin. Detection of antibodies in solution and on beads either by FRET or capture of fluorescent ligands by dark antibodies subsequently enables the determination of K(d) values, which indicate agreement between solution and flow cytometric determinations.

Flow cytometry: a versatile tool for all phases of drug discovery

The applications of flow cytometry are being extended beyond cells into molecular interactions and genomic analyses. The authors explain how instrumentation and reagent development are combining to improve flow cytometric throughput by orders of magnitude beyond that possible just a few years ago, such that the combination of sensitivity, throughput and versatility makes flow cytometry an analytical platform with applications at all stages of drug discovery.

Multiple activation steps of the N-formyl peptide receptor

The human N-formyl peptide receptor (FPR) is representative of a growing family of G protein-coupled receptors (GPCR) that respond to chemokines and chemoattractants. Despite the importance of this receptor class to immune function, relatively little is known about the molecular mechanisms involved in their activation. To reveal steps required for the activation of GPCR receptors, we utilized mutants of the FPR which have previously been shown to be incapable of binding and activating G proteins. For this study, the FPR mutants were expressed in human myeloid U937 cells and characterized for functions in addition to G protein coupling, such as receptor phosphorylation and ligand-induced receptor internalization. The results demonstrated that one of the mutants, R123G, though being unable to activate G protein, was capable of undergoing ligand-induced phosphorylation as well as internalization. Receptor internalization was monitored by following the fate of the ligand as well as by directly monitoring the fate of the receptor. The results with the R123G mutant were in contrast to those obtained for mutants D71A and R309G/E310A/R311G which, though being expressed at the cell surface and binding ligand, were incapable of being phosphorylated or internalized upon agonist stimulation. These results suggest that following ligand binding at least two "steps" are required for full activation of the wild-type FPR. That these observations may be of more general importance in GPCR-mediated signaling is suggested by the highly conserved nature of the mutants studied: D71, R123, and the site represented by amino acids 309-311 are very highly conserved throughout the entire superfamily of G protein-coupled receptors. Models of receptor activation based on the observed results are discussed.

The uncoupled state of the human formyl peptide receptor

The formyl peptide receptor (FPR) has been widely used to study the kinetics of the interaction between ligand, receptor and G protein with real-time fluorescence methods. Because the wild type receptor rapidly signals, and is then desensitized and internalized once occupied by ligand, it has been difficult to study the uncoupled receptor form. We have examined a mutant form of the FPR expressed in U937 cells that does not bind G protein and is thus ideal to study the uncoupled form of the FPR in the intact cell. Using kinetic flow cytometry, we have measured the dissociation kinetics of a fluorescent ligand from this mutant in intact, permeabilized and fixed cells. We observed a novel uncoupled receptor form in the intact cell with a dramatically reduced off-rate (approximately 0.02 s-1) from LR in a broken cell preparation (approximately 0.2 s-1). Both receptor forms are retained in the presence of formaldehyde. We also observed this novel receptor form coexisting with the LRG complex when the wild type receptor is fixed in neutrophils or transfectants. These results complex when the wild type receptor is fixed in neutrophils o transfectants. These results lead us to suggest that there are distinct receptor structures in cells and membranes and that only a fraction of receptors in intact cells exist in the uncoupled form.

Analysis of vertical fluorescence resonance energy transfer from the surface of a small-diameter sphere

Fluorescence resonance energy transfer (FRET) measurements have been used to analyze fluorophore separations in a number of varying geometries, including small particles and extended surfaces. This study focuses on the geometry created by a donor extended above the surface of a small sphere (radius < R0), where the acceptors are integrated into the sphere surface. The model of this geometry was based on an amphipathic molecule with its lipophilic region integrated into a detergent micelle and its hydrophilic region extending outward from the micelle surface, where the donor fluorophore is attached to the hydrophilic region of the molecule. Based on random acceptor incorporation into the micelle, a Poisson distribution was used to calculate the distribution of acceptor probes across the micelle population. The model converges to RET on a flat surface when the radius of the micelle exceeds 0.8 R0. The model was also used to simulate FRET data showing that the positions of donors above the micelle surface could be uniquely resolved. Experimental verification of the model was achieved in a sulfobetaine palmitate micelle with fluorescein isothiocyanate donors attached to detergent-solubilized lipopolysaccharide (LPS) and lipophilic Fast-DiI acceptors. The use of steady-state analysis allowed resolution of cases in which donors were located at different distances from the surface. Combining steady-state with excited-state lifetime analysis allowed resolution of cases where there was a combination of distances. Given the large number of biomolecules that interact with lipids, this approach may prove generally useful for defining molecular conformation.

Sheath fluid control to permit stable flow in rapid mix flow cytometry

BACKGROUND

Flow cytometry is a potentially powerful tool to analyze the kinetics of ligand binding, cell response and molecular assembly. The difficulty in adding reactant to cells, achieving adequate mixing, delivering those cells to the laser focal point and establishing stable flow, has historically limited flow cytometry to systems with reactions times longer than 5 s. With the advent of automated syringes and flow injection methods, sample injection times shorter than 1 s have become routine. However, an inherent problem in acquiring time courses starting under 1 s is that rapid sample introduction through the flow tip to the detection point perturbs laminar flow. The purpose of this work was to determine if stable flow could be reestablished more quickly if the sheath flow was reduced during sample introduction, returning to normal sheath and sample rates afterward.

METHODS

We used programmable syringes and valves to control sample mixing as well as sheath and sample delivery through the flow tip to the detection point for stream-in-air detection. Stable flow was monitored by mean particle fluorescence during sample introduction.

RESULTS

With no sheath reduction, stable flow recovered after more than 1 s. By reducing sheath flow during the short period (300 msec) of sample mixing and delivery, stable laminar flow recovered within 200 msec.

CONCLUSIONS

This use of automated syringes to control both sheath and sample flow provides a potential for robust sample handling applicable to kinetic as well as high throughput flow cytometric analysis.

Beta2-integrins mediate stable adhesion in collisional interactions between neutrophils and ICAM-1-expressing cells

The aggregation of human neutrophils in suspension has features that are analogous to their attachment to activated endothelium in that both involve selectin and beta2-integrin adhesion receptors. For the collisional interaction that forms neutrophil aggregates in suspension, there is a tethering step in which L-selectin on neutrophils binds PSGL-1. At relatively low shear rates (100-200 s(-1)) firm adhesion is mediated in equal measure by LFA-1 binding to ICAM-3, and Mac-1 binding to an as yet undefined ligand. In this report we used a mouse melanoma cell line expressing an estimated 700,000 ICAM-1 (CD54) to examine the relative roles of LFA-1 and Mac-1 over the kinetics of heterotypic cell adhesion in shear mixed suspensions. Neither heterotypic nor homotypic neutrophil aggregates formed with application of shear alone. However, the rate of aggregation peaked within seconds of chemotactic stimulation. In contrast to homotypic aggregation, neither L-selectin nor its O-glycoprotein ligands on neutrophils contributed to heterotypic adhesion. Adhesion was inhibited in a dose-dependent manner as ICAM-1 was titrated with blocking mAb. A direct interaction between LFA-1 and ICAM-1 was preferred over the first minute of stimulation, whereas at later times adhesion was supported equally by Mac-1. Activation with MnCl2 also favored participation of the constitutively expressed LFA-1. Application of defined shear in a cone and plate viscometer showed that adhesion to the ICAM-1 cells decreased from a maximum level to baseline as shear rate increased up to 400 s(-1) in a manner typical of integrin adhesion alone. In contrast, homotypic aggregation supported by the transition from selectin to integrin binding exhibited an increase in efficiency up to 800 s(-1). The pathophysiological significance of receptor site density and duration of contact in collisional interactions relevant to leukocyte recruitment compared to leukocyte-endothelial cell interactions on surfaces is discussed.

The emergence of flow cytometry for sensitive, real-time measurements of molecular interactions

The analysis of macromolecular interactions is an essential element of biomedical research. Flow cytometry is uniquely capable of making sensitive and quantitative measurements of molecular interactions. These measurements can be made in real time with subsecond kinetic resolution using purified biomolecules or living cells. Combined with automated sample handling, these features make flow cytometry a versatile and robust technology for the analysis of molecular interactions.

Strategies for positioning fluorescent probes and crosslinkers on formyl peptide ligands

Chemoattractant receptors represent a major subset of the G-protein coupled receptor (GPCR) family. One of the best characterized, the N-formyl peptide receptor (FPR), participates in host defense responses of neutrophils. The features of the ligand which regulate its interaction with the FPR are well-known. By manipulating these features we have developed new ligands to probe structural and mechanistic aspects of the peptide-receptor interaction. Three ligand groups have been developed: 1) ligands containing a Lys residue located in positions 2 through 7 that can be conjugated to FITC (N-formyl-Met1-Lys2-Phe3-Phe4, N-formyl-Met1-Leu2-Lys3-Phe4, N-formyl-Met1-Leu2-Phe3-Lys4, N-formyl-Met1-Leu2-Phe3-Phe4-Lys5, N-formyl-nLeu1-Leu2-Phe3-nLeu4-Tyr5-Lys6 and N-formyl-Met1-Leu2-Phe3-Phe4-Gly5-Gly6-Lys7; 2) fluorescent pentapeptide ligands (N-formyl-Met-X-Phe-Phe-Lys(FITC) where X = Leu, Ala, Val or Gly); and 3) small crosslinking ligands where the photoaffinity crosslinker 4-azidosalicylic acid (ASA) was conjugated to Lys in positions 3 and 4 and p-benzoyl-phenylalanine (Bpa) was located in position 2 in N-formyl-Met1-Bpa2-Phe3-Tyr4. The peptides were characterized according to activity and affinity in human neutrophils and cell lines transfected with FPR. All of the peptides were agonists, with parallel affinity and activity. In the first group, the peptide activity decreases as Lys is placed closer to the N-formyl group and the activity is improved by 1-3 orders of magnitude by conjugation with FITC. In the second group, the dissociation rate of the peptide from the receptor increases as position 2 is replaced by aliphatic amino acids with smaller alkyl groups. In the third group, crosslinking ligands remain biologically active, display nM affinity and covalently label the FPR.

Retinoic acid induces aggregation of the acute promyelocytic leukemia cell line NB-4 by utilization of LFA-1 and ICAM-2

All-trans retinoic acid (tRA) is a potent differentiation agent that is effective therapy for acute promyelocytic leukemia (APL). However, 5% to 25% of patients develop retinoic acid syndrome, a potentially life-threatening complication in which the pathogenesis relates to adhesive alterations of APL cells. Therefore, we investigated the relationship between tRA-induced differentiation and the adhesive properties of APL cells. After confirming differentiation-related morphological changes of NB-4 cells in response to tRA, we showed that homotypic aggregation of NB-4 cells grown in tRA for 72 hours is dose-dependent with a median effective dose of approximately 50 nmol/L. Maximal aggregation occurred at mean and peak therapeutic serum concentrations (100 and 1,000 nmol/L, respectively). Aggregation also increased with the length of tRA exposure over 168 hours. Aggregation was inhibited by neutralizing antibodies against LFA-1 and ICAM-2. Notably, antibodies directed against VLA-4, other beta2 integrins (Mac-1 and p150), or other potential LFA-1 counterstructures that were expressed on the cell surface (ICAM-1 and ICAM-3) did not block aggregation. Aggregation occurred with similar kinetics regardless of the presence of phorbol ester or the "activating" monoclonal antibody (MoAb) KIM 185, suggesting that the avidity of LFA-1 is not modulated on NB-4 cells in a manner similar to other leukocytes. Consistent with the prompt clinical effectiveness of methyl prednisolone sodium succinate (MPSS) in retinoic acid syndrome, MPSS rapidly inhibited homotypic aggregation in a dose-dependent manner. Thus, tRA alters the adhesive properties of APL cells by inducing the expression of high-avidity beta2 integrins, aggregation is inhibited by LFA-1 and ICAM-2 MoAb, and tRA effects are rapidly reversible by MPSS. Taken together, our findings provide a clinically relevant system for study of LFA-1/ICAM-2 interaction and suggest a mechanism in part for retinoic acid syndrome and the effectiveness of MPSS in ameliorating retinoic acid syndrome.

Relationship of ligand-receptor dynamics to actin polymerization in RBL-2H3 cells transfected with the human formyl peptide receptor

The human formyl peptide receptor (FPR) expressed in RBL-2H3 transfectants (RBL[FPR]) behaves qualitatively like the FPR expressed by neutrophils except that it causes sustained F-actin accumulation and cell shape change responses on formyl peptide stimulation. These sustained responses were not accounted for by changes in the transfected receptor's ability to interact with ligand or by receptor density. Signal transduction pathways of transfected and neutrophil FPRs are apparently similar. In transfected cells, dissociation of ligand is sensitive to guanine nucleotide, the G protein is pertussis toxin-sensitive, FPR and G protein appear to be precoupled, the F-actin response is stimulated with the same dose-response profile as in neutrophils, and the F-actin accumulation response is directly regulated by the FPR, even long after initial stimulation. Potentially significant differences between neutrophil and transfected FPR were found when receptor processing was measured. In neutrophils, practically 100% of the FPR is converted to forms that dissociate slowly from ligand and are inactive in signal transduction within 2 min of ligand stimulation. By contrast, 20% or more of transfected FPR remains rapidly dissociating even 5 min after stimulation. Although 80% of neutrophil FPR is internalized by 5 min after stimulation, transfected FPR appears to plateau at 50-60% internalized. Because actin responses in neutrophils are regulated by a small number of active receptors, the inefficiency of receptor inactivation in RBL(FPR) transfectants may account for the prolonged F-actin accumulation response.

Functional analysis of point mutations in human flap endonuclease-1 active site

Human flap endonuclease-1 (hFEN-1) is highly homologous to human XPG, Saccharomyces cerevisiae RAD2 and S.cerevisiae RTH1 and shares structural and functional similarity with viral exonucleases such as T4 RNase H, T5 exonuclease and prokaryotic DNA polymerase 5'nucleases. Sequence alignment of 18 structure-specific nucleases revealed two conserved nuclease domains with seven conserved carboxyl residues and one positively charged residue. In a previous report, we showed that removal of the side chain of each individual acidic residue results in complete loss of flap endonuclease activity. Here we report a detailed analysis of substrate cleavage and binding of these mutant enzymes as well as of an additional site-directed mutation of a conserved acidic residue (E160). We found that the active mutant (R103A) has substrate binding and cleavage activity indistinguishable from the wild type enzyme. Of the inactive mutants, one (D181A) has substrate binding properties comparable to the wild type, while three others (D34A, D86A and E160A) bind with lower apparent affinity (2-, 9- and 18-fold reduced, respectively). The other mutants (D158A, D179A and D233A) have no detectable binding activity. We interpret the structural implications of these findings using the crystal structures of related enzymes with the flap endonuclease activity and propose that there are two metal ions (Mg2+or Mn2+) in hFEN enzyme. These two metal coordinated active sites are distinguishable but interrelated. One metal site is directly involved in nucleophile attack to the substrate phosphodiester bonds while the other may stabilize the structure for the DNA substrate binding. These two sites may be relatively close since some of carboxyl residues can serve as ligands for both sites.

Cooperation between the Fc epsilonR1 and formyl peptide receptor signaling pathways in RBL(FPR) cells: the contribution of receptor-specific Ca2+ mobilization responses

RBL(FPR) mast cells express the tyrosine kinase-coupled IgE receptor, Fc epsilonR1, and the G-protein-coupled formyl peptide receptor, FPR. Fc epsilonR1 crosslinking causes Ca2+ stores release, Ca2+ influx, Ins(1,4,5)P3 production and secretion. FPR ligation also mobilizes Ca2+, but without measurable Ins(1,4,5)P3 production or secretion. Co-stimulating the FPR and Fc epsilonR1 induces more Ins(1,4,5)P3 production and secretion than Fc epsilonR1 cross-linking alone. Costimulation also produces more rapid and sustained Ca2+ responses than are generated by Fc epsilonR1 activation alone. We identified multiple differences between the FPR- and Fc epsilonR1-coupled Ca2+ responses, including a more rapid Ca2+ spike response to FPR ligation; intracellular Ca2+ stores that are empty following Fc epsilonR1 crosslinking but partially full following FPR activation; a more sustained Ca2+ influx response to Fc epsilonR1 crosslinking; and the immediate inhibition of stimulated Ca2+ influx by FPR antagonists but not by monovalent ligand that terminates Fc epsilonR1 crosslinking. We hypothesize that the interaction of receptor-specific Ca2+ mobilization pathways contributes to the FPR-mediated potentiation of Fc epsilonR1-coupled secretion.

New flow cytometric technologies for the 21st century

The envelope that defines the limits within which flow cytometry was developed is being rapidly expanded. For example: detection sensitivity has been extended to single molecules, the size range of "particle" analysis now extends from DNA fragments to plankton (1,000.+ microns), cell and chromosome sorting rates are being increased dramatically by using inactivation procedures (50,000 per second versus 2,000 per second), rapid kinetic flow cytometry enables real-time analysis of molecular assembly and cell function in the sub-second time domain, the lifetime of a fluorochrome bound to a single cell can be measured with nsec precision, and classical karyotype information (cell to cell heterogeneity) can be determined in a flow based system. These frontiers have greatly expanded the range of new and exciting flow cytometric based biomedical applications. New enabling technologies have provided the means to measure DNA cleavage by the structure-specific nuclease, human Flap Endonuclease (FEN-1), in the 300 msec time frame. Phase sensitive measurements and fluorescence lifetime are proving to be major advances for understanding molecular environments that change with, for example, the process of apoptosis. The ability to detect single fluorescent molecules has been applied to the analysis of DNA fragments obtained from enzymatic digestion of lambda DNA. This technology is being used to rapidly and very accurately size DNA fragments for the human genome project. Optical chromosome selection is a faster, better, less complex approach to chromosome sorting. This method is based on the induction of specific damage to the DNA of selected chromosomes. Lastly, the miniaturization of a single cell fractionator has made it possible to perform single cell flow cytogenetics.

Analysis of fluorescence lifetime and quenching of FITC-conjugated antibodies on cells by phase-sensitive flow cytometry

Fluorescent antibodies are often used to measure the number of receptor sites on cells. The quantitative estimate of the number of receptor sites using this procedure assumes that the fluorescence intensity on a cell is proportional to the number of bound antibodies. Quenching may invalidate this assumption. For many fluorophores, intermolecular interactions and energy transfer between molecules in close proximity to one another results in self-quenching. This effect can occur in antibody probes with a high fluorochrome to protein (F/P) ratio. It can also occur due to close proximity antibodies relative to one another on a highly labeled cell surface. Since self-quenching is accompanied by a change in the fluorescence decay and a decrease in the fluorescence lifetime, it may be conveniently identified using fluorescence lifetime spectroscopy. In this paper we apply the phase-sensitive detection method to investigate the impact of self-quenching on fluorescence lifetimes by flow cytometry, using a model system consisting of FITC conjugated anti-mouse Thy1.2 antibodies bound to murine thymus cells. We show that in addition to the expected variation of lifetimes as a function of F/P ratio of the probes, the fluorescence lifetime diminishes also as a function of antibody labeling concentration on the cell surface. This is consistent with self-quenching effects expected at high densities of FITC molecules.

P-selectin glycoprotein ligand-1 (PSGL-1) is a ligand for L-selectin in neutrophil aggregation

In inflammation, activated neutrophils adhere to endothelial cells and aggregate with one another. While beta 2-integrin and L-selectin are essential for aggregation, their ligands remain to be identified. We have previously shown that L-selectin mediates a carbohydrate-dependent interaction in aggregation (Simon et al: J Immunol 149:2765, 1992; Rochon et al: J Immunol 152:1385, 1994). We have suggested that the L-selectin counter-structure is a mucinlike protein and proposed that aggregation occurs through a two-step process involving L-selectin, beta 2-integrin, and their distinct counter-structures (Bennett et al: J Leuk Biol 58:510, 1995). A candidate ligand for L-selectin is P-selectin glycoprotein ligand-1 (PSGL-1), a mucinlike protein on neutrophils that binds P-and E-selectin. Using flow cytometry we show that the number and size of neutrophil aggregates is reduced with Fab fragments of PL1, an anti-PSGL-1 monoclonal antibody that blocks the interaction between P-selectin and PSGL-1 (Moore et al: J Cell Biol 128:661, 1995). In addition, monoclonal antibodies to L-selectin and PSGL-1 were used simultaneously to modulate the availability of these adhesion molecules on individual cell populations. The inhibition of aggregation by these antibodies is consistent with L-selectin and PSGL-1 being counter-structures. We suggest that L-selectin and PSGL-1 support a collisional cell-cell interaction that represents the first step in neutrophil aggregation.

Kinetic analysis of human flap endonuclease-1 by flow cytometry

Human flap endonuclease-1 (FEN-1) is a structure-specific endonuclease and exonuclease which is essential for DNA replication and repair. We have cloned a human FEN-1 gene, overexpressed it in Escherichia coli, purified the recombinant protein to near homogeneity, and characterized its cleavage of a flap DNA structure using a novel analytical approach based on flow cytometry. With this approach, we were able to measure continuously the kinetics of DNA cleavage by FEN-1 and to separate experimentally the binding and catalysis functions of the enzyme. When the reaction was initiated by the addition of FEN-1, the cleavage kinetics were dependent on enzyme concentration and appeared to saturate at high concentrations. When enzyme and substrate were preincubated in the presence of EDTA and the reaction initiated by the addition of Mg2+, rapid kinetic flow cytometry measurements showed that cleavage is fast (t1/2 approximately 6 s, k = 0.10 s-1). Using the single-turnover kinetics as a measure of the amount of enzyme-substrate complex present, we estimated the Kd for the FEN-1-flap DNA substrate to be 7.5 nM in the absence of Mg2+ and the rate constant for dissociation of the enzyme-substrate complex to be 0.07 s-1. Computer fitting of the experimental data to a kinetic model confirms these estimates for the individual steps and suggests some interesting features of enzymology using a surface-bound substrate.

Enhanced aggregation of human neutrophils by MnCl2 or DTT differentiates the roles of L-selectin and beta 2-integrins

MnCl2 and dithiothreitol (DTT) enhance the adhesive functions of beta 2 -integrins. We have used these agents and flow cytometry to distinguish the contributions of beta 2-integrins and L-selectin to neutrophil aggregation. Although neither compound induced aggregation, they prolonged N-formyl-methionyl-leucyl-phenylalanine-induced aggregation and produced larger aggregates. Because activated polymorphonuclear granulocytes (PMN) shed L-selectin in the presence of MnCl2, but not DTT, we could evaluate the role of L-selectin in the early and late stages of aggregation. Blocking L-selectin sites with DREG200 Fab and/or beta 2-integrin sites with IB4 Fab indicated that aggregation under all conditions remained beta 2-integrin- and L-selectin-dependent. Disaggregation was integrin-dependent whether L-selectin was present or shed. The disaggregation kinetics suggested that integrin bonds turned over at a slower rate in MnCl2-treated cells. Enhanced aggregation due to DTT and MnCl2 required sustained energy output, suggesting intracellular rather than strictly conformational control. These results provide evidence that PMN aggregation, like leukocyte-endothelial cell adhesion, utilizes L-selectin to form intercellular contacts that are maintained through activated integrins.

Hydroxamate-based metalloprotease inhibitor blocks shedding of L-selectin adhesion molecule from leukocytes: functional consequences for neutrophil aggregation

L-selectin is an adhesion molecule that mediates the recruitment of neutrophils to inflammatory sites and initiates the migration of lymphocytes into the peripheral lymph nodes. In response to cell activation, L-selectin is shed from the cell surface, and altered levels of functional soluble L-selectin are detected in the plasma of patients suffering from numerous inflammatory diseases as well as AIDS. The mechanism that regulates L-selectin shedding is poorly understood. Here we show that a hydroxamate-based metalloprotease inhibitor, N-(D,L-[2-(hydroxyaminocarbonyl)- methyl]-4-methylpentano)-L-3-(tert-butyl)-alanyl-L-alanine, 2-aminoethyl amide, which blocks leukocyte TNF, TNF receptor, and IL-6 receptor release, also inhibits L-selectin shedding from neutrophils, eosinophils, and lymphocytes. Moreover, we show that such inhibition of L-selectin shedding profoundly affects neutrophil aggregation and permits reaggregation in the presence of a heterologous stimulus.

Hydroxamate-based metalloprotease inhibitor blocks shedding of L-selectin adhesion molecule from leukocytes: functional consequences for neutrophil aggregation

L-selectin is an adhesion molecule that mediates the recruitment of neutrophils to inflammatory sites and initiates the migration of lymphocytes into the peripheral lymph nodes. In response to cell activation, L-selectin is shed from the cell surface, and altered levels of functional soluble L-selectin are detected in the plasma of patients suffering from numerous inflammatory diseases as well as AIDS. The mechanism that regulates L-selectin shedding is poorly understood. Here we show that a hydroxamate-based metalloprotease inhibitor, N-(D,L-[2-(hydroxyaminocarbonyl)- methyl]-4-methylpentano)-L-3-(tert-butyl)-alanyl-L-alanine, 2-aminoethyl amide, which blocks leukocyte TNF, TNF receptor, and IL-6 receptor release, also inhibits L-selectin shedding from neutrophils, eosinophils, and lymphocytes. Moreover, we show that such inhibition of L-selectin shedding profoundly affects neutrophil aggregation and permits reaggregation in the presence of a heterologous stimulus.

Essential amino acids for substrate binding and catalysis of human flap endonuclease 1

Human flap endonuclease 1 (FEN-1) is a member of the structure-specific endonuclease family and is involved in DNA repair. Eight restrictively conserved amino acids in FEN-1 have been converted individually to an alanine to elucidate their roles in specific DNA substrate binding and catalysis. Flap endonuclease activity of the wild type and mutant enzymes was measured by kinetic flow cytometry. Mutants D34A, D86A, and D181A lost their cleavage activity completely but retained substrate binding ability, as measured by their ability to inhibit the wild type enzyme in a competition assay. This indicates that these amino acids contribute to integrity of the enzyme active site. Loss of both binding and cleavage competency for the flap substrate by mutants E156A, G231A, and D233A suggests that these amino acids are involved in substrate binding. Mutants R103A and D179A retained wild type-like enzyme activity.

Fluorescence resonance energy transfer analysis of lipopolysaccharide in detergent micelles

Bacterial endotoxins or lipopolysaccharides (LPS), cell wall components of gram-negative bacteria, are involved in septic shock. LPS consists of a lipid A tail attached to core and O-antigen polysaccharides, but little is known about the supramolecular structure of LPS in blood. We have developed an approach to locate donor and acceptor probes in sulfobetaine palmitate detergent micelles using steady-state and time-resolved fluorescence resonance energy transfer. C18-fluorescein and several LPS species of varying molecular weight labeled with fluorescein isothiocyanate (FITC-LPS) were the donor probes. Acceptor probes were 1,1-dilinoleyl-3,3,3',3'-tetramethyl indocarbocyanine perchlorate (Fast C18-Dil, Ro approximately 68 A), and octadecyl B rhodamine chloride (C18-Rhd, Ro approximately 58 A). With either acceptor, the transfer was of similar high efficiency when FITC-LPS Salmonella minnesota Re 595 (2,500 mol wt, lacking both core and O-antigen) or C18-fluorescein were the fluorescent donor probes. Thus, the donor FITC-LPS with short polysaccharide chain S. minnesota Re 595 and the control donor C18-fluorescein appear to be close to the micelle surface. The transfer efficiency decreased as the molecular weight of the LPS increased. Separation distances between the longest FITC-LPS, S. minnesota (20,000 mol wt, with a long O-antigen), and the micelle were estimated to be 1.5 Ro or more (approximately 100 A), consistent with an extended conformation for the longer O-antigen polysaccharide chain in the detergent.

Fixation traps formyl peptide receptors in high and low affinity forms that can be regulated by GTP[S] in the absence of ligand

The formyl peptide receptor on human neutrophils recognizes bacterial, N-formylated peptides and initiates a cascade of intracellular signals via a pertussis toxin sensitive Gi protein. We used fluorescence techniques to investigate the interactions of ligand (L), receptor (R), and G proteins (G), the ternary complex, in both live and fixed human neutrophils. By lightly fixing permeabilized neutrophils with a procedure that retained ligand binding, we were able to "capture' R and G in different configurations in the absence of ligand. Fixed receptors were trapped in a high affinity form (attributed to LRG) that could not be rapidly converted to low affinity by the addition of GTP[S]. Adding saturating nucleotide prior to fixation trapped receptors in a low affinity form (attributed to LR). The low affinity receptors retained the sensitivity of the native receptors to the presence of NA+. The distribution between high and low affinity receptors was modulated by GTP[S] in a dose dependent manner. The ability to redistribute low and high affinity receptor forms prior to fixation was unique to GTP[S], as compared to other non-activating nucleotides, suggesting that GTP[S] can regulate the distribution between R and RG. We suggest that precoupled receptors that give rise to high affinity ligand binding are likely to exist in native membranes in human neutrophils.

Simultaneous dual-frequency phase-sensitive flow cytometric measurements for rapid identification of heterogeneous fluorescence decays in fluorochrome-labeled cells and particles

In frequency-domain lifetime spectroscopy, the apparent fluorescence lifetimes obtained from phase-shift measurements are independent of modulation frequency only in the special case of a single exponential fluorescence decay. For heterogeneous fluorescence decay, the apparent fluorescence lifetimes measured by the phase-shift methods are functions of the modulation frequency. This modulation-frequency dependent property of apparent fluorescence lifetimes may be used to identify heterogeneous fluorescence decays by measuring lifetimes at multiple frequencies. In this article we explore the requirements and experimental design considerations for making such measurements in flow. We report a phase-sensitive flow cytometric method that allows one to probe the excited state-lifetimes of labeled cells by using multiple simultaneous modulation frequencies. Application of this method is demonstrated by measuring fluorescence lifetimes of labeled cells at two frequencies simultaneously, using a continuous-wave, dual-frequency modulated excitation in flow. The dual-frequency method presented herein can be used to rapidly identify heterogeneity in the fluorescence decay on a cell-by-cell basis in real time. Information on the nature of the fluorescence decay is important in biological measurements because it can provide insight into intermolecular interactions at the subcellular level.

A rapid mix flow cytometer with subsecond kinetic resolution

Kinetic approaches are valuable tools for mechanistic studies of cell function. Flow cytometry is well suited to make sensitive kinetic measurements, but the time required to deliver mixed samples to the point of measurement (10-20 s in a conventional cytometer) limits analysis of rapidly occurring events. To address this limitation, we adapted a syringe-based stopped-flow rapid mixing device to a modified commercial flow cytometer to achieve mixing and measurement of sample in under 1 s. Because such screw-driven mixers are designed to deliver fluid at rates of microliters per millisecond and cytometers accept samples at microliters per second, the syringe mixer was modified with a screw to allow sample delivery at rates as low as 1.8 microliters/s. A custom-made nozzle holder featuring a fast-acting three-way sample delivery valve and a 1.5- microliters dead volume was designed for a Becton Dickinson FACS stream-in-air flow nozzle. Syringe motors and valves are computer controlled, as is the start signal for an adjustable time ramp. A stable sample stream can be established within the sheath stream in less than 1 s, enabling fluorescence measurements of microspheres with coefficients of variation of approximately 5%. Light scatter gating to select particles in the center of the laser beam enables fluorescence measurements at times of under 300 ms. Efficient mixing of reagents is demonstrated by the iodide quenching of microspheres surface labeled with fluorescein isothiocyanate (FITC). The instrument is capable of quantitatively proportioning cells and reagent, thereby allowing precise control of reagent concentration and dilution. Rapid kinetic measurements of intact cells are demonstrated by FITC-formyl peptide binding to cell surface receptors.

Evidence for a third component in neutrophil aggregation: potential roles of O-linked glycoproteins as L-selectin counter-structures

The homotypic aggregation of neutrophils requires the participation of L-selectin and the beta 2-integrins, but it has not been clear whether the two receptors recognize one another as counter-structures or whether other adhesion molecules are involved. We have examined aggregation of live neutrophils with target populations, manipulated to alter expression of adhesive epitopes, using flow cytometry. A target population depleted of both L-selectin and activatable beta 2-integrin displayed an ability to aggregate with live neutrophils, suggesting that these two molecules are not counter-structures. We also found that an O-sialoglycoprotease (GCP) from Pasteurella haemolytica is capable of inhibiting homotypic aggregation. Neutrophils treated with GCP lose O-glycosylated proteins but retain L-selectin and activatable beta 2-integrin. One or more of the GCP substrates appears to function in L-selectin-dependent binding but not in beta 2-integrin-dependent binding. Together the data suggest a mechanism of aggregation that is analogous to leukocyte-endothelial cell adhesion in which a low-affinity carbohydrate-dependent interaction precedes a high-affinity integrin-dependent adhesion.

L-selectin (CD62L) cross-linking signals neutrophil adhesive functions via the Mac-1 (CD11b/CD18) beta 2-integrin

Emigration of leukocytes at sites of inflammation is initiated by the selectin family of carbohydrate-binding adhesion molecules. Molecular crossbridges initiate rolling of cells along the vascular endothelium where chemokines such as IL-8 and platelet activating factor (PAF) may be presented to their receptors on the leukocyte surface resulting in cell stimulation. Integrin activation appears to be a requirement for subsequent cell localization and diapedesis into the tissue. Several recent reports have demonstrated that ligation and cross-linking of neutrophil L-selectin results in neutrophil activation, including intracellular calcium release, superoxide production, and induction of mRNA for production of IL-8 and TNF-alpha. The purpose of this study was to examine whether ligation and cross-linking of L-selectin would specifically result in activation of beta 2-integrin-dependent adhesion. A fluorescence flow cytometric assay was developed that directly measures Mac-1-dependent cell adhesion. Fluorescent latex beads (2-microns diameter) were adsorbed with albumin or fibrinogen and added in excess to human neutrophils in a shear-stirred suspension. Following stimulation the kinetics of bead capture by neutrophils was continuously measured in real time on the flow cytometer. The onset of bead binding was detected in the presence of extremely low concentrations of PAF (10 pM) or formyl peptide (0.2 nM) stimulation. Ligation of L-selectin with whole IgG DREG200 or DREG56 Ab, but not controls (anti-CD44, -CD45, -CD11a), resulted in a significant potentiation of bead binding. Cross-linking F(ab')2 fragments of DREG200 with a goat anti-mouse F(ab')2 secondary Ab also stimulated beta 2-integrin-dependent adhesion in a dose-dependent fashion. A chimeric form of DREG200 expressing gamma 4 or gamma 1 isotypes of human Fc domain also stimulated cell adhesion when cross-linked. Surface expression of CD18 and an activation-dependent epitope, as detected with mAb24, also increased in response to L-selectin cross-linking. Cross-linking L-selectin induced significant adhesion and transmigration of neutrophils across human umbilical vein endothelial cells. We propose that cross-linking of L-selectin results in a cell signal that directly stimulates beta 2-integrin adhesive responses.

L-selectin (CD62L) cross-linking signals neutrophil adhesive functions via the Mac-1 (CD11b/CD18) beta 2-integrin

Emigration of leukocytes at sites of inflammation is initiated by the selectin family of carbohydrate-binding adhesion molecules. Molecular crossbridges initiate rolling of cells along the vascular endothelium where chemokines such as IL-8 and platelet activating factor (PAF) may be presented to their receptors on the leukocyte surface resulting in cell stimulation. Integrin activation appears to be a requirement for subsequent cell localization and diapedesis into the tissue. Several recent reports have demonstrated that ligation and cross-linking of neutrophil L-selectin results in neutrophil activation, including intracellular calcium release, superoxide production, and induction of mRNA for production of IL-8 and TNF-alpha. The purpose of this study was to examine whether ligation and cross-linking of L-selectin would specifically result in activation of beta 2-integrin-dependent adhesion. A fluorescence flow cytometric assay was developed that directly measures Mac-1-dependent cell adhesion. Fluorescent latex beads (2-microns diameter) were adsorbed with albumin or fibrinogen and added in excess to human neutrophils in a shear-stirred suspension. Following stimulation the kinetics of bead capture by neutrophils was continuously measured in real time on the flow cytometer. The onset of bead binding was detected in the presence of extremely low concentrations of PAF (10 pM) or formyl peptide (0.2 nM) stimulation. Ligation of L-selectin with whole IgG DREG200 or DREG56 Ab, but not controls (anti-CD44, -CD45, -CD11a), resulted in a significant potentiation of bead binding. Cross-linking F(ab')2 fragments of DREG200 with a goat anti-mouse F(ab')2 secondary Ab also stimulated beta 2-integrin-dependent adhesion in a dose-dependent fashion. A chimeric form of DREG200 expressing gamma 4 or gamma 1 isotypes of human Fc domain also stimulated cell adhesion when cross-linked. Surface expression of CD18 and an activation-dependent epitope, as detected with mAb24, also increased in response to L-selectin cross-linking. Cross-linking L-selectin induced significant adhesion and transmigration of neutrophils across human umbilical vein endothelial cells. We propose that cross-linking of L-selectin results in a cell signal that directly stimulates beta 2-integrin adhesive responses.

Fluorescence lifetime measurements in a flow cytometer by amplitude demodulation using digital data acquisition technique

We have developed a method for fluorescence lifetime measurements in a flow cytometer based upon the amplitude demodulation of the fluorescence signals using digital data acquisition techniques. Amplitude demodulation is one of the two methods by which excited state lifetimes may be investigated in the frequency domain. The other method involves the phase-shift measurements. In frequency-domain measurement techniques, the amplitude-demodulation and phase-shift data serve mutually complementary roles to enhance the analytical capabilities of the measurements. The purpose of having amplitude demodulation measurement capability is to obtain information that supplements, rather than replaces, that obtained by the phase-shift method alone. Application of amplitude demodulation measurements has been widely explored in static, cuvette-based, frequency domain systems. However, due to time dependence of the amplitude of the modulated fluorescence signal in a flow cytometer, the amplitude demodulation measurements in flow turns out to be more complicated than similar measurements in a static system. The goal of the present work is to explore the problems involved in amplitude demodulation measurements in flow (using digital method), through detailed theoretical modeling and use the model to develop a practical method that can be incorporated into a flow cytometer to measure amplitude modulation lifetimes. We experimentally verify the amplitude demodulation measurement capability of this method using fluorescent microspheres. The experimental measurements show good agreement with static frequency-domain measurements on microspheres in bulk suspensions.