A microfluidic device for measuring cellular membrane potential.

Recent developments in microfluidics have enabled the design of a lab-on-a-chip system capable of measuring cellular membrane potential. The chip accesses liquid samples sequentially by sipping from a microplate through a capillary, mixes the samples with cells flowing through a microchannel, contacts the cells with potential-sensitive dyes, and reads out cellular responses using fluorescence detection. The rate of cellular uptake of membrane-permeable, ionic fluorophores by THP-1 cells was found to depend strongly on membrane potential. The ratio of the fluorescence of the anionic dye DiBAC(4)(3) and the cationic dye Syto 62 taken up by cells was found to double for every 33 mV change in membrane potential. The utility of this approach was demonstrated by assaying ion channel activity in human T lymphocytes. Because of the high sensitivity, low cellular and reagent consumption, and high data quality obtained with the microfluidic device, the lab-on-a-chip system should be widely applicable in high-throughput screening and functional genomics studies.

Microchip-based systems for target validation and HTS.

Microarray and microfluidic device technologies for performing genetic and biochemical analyses are revolutionizing biological research. These technologies are now being applied to gene expression profiling and to primary screening for target validation and lead discovery in the pharmaceutical industry. In this article, we briefly review microchip technology and discuss future development trends.

Chimeric G proteins allow a high-throughput signaling assay of Gi-coupled receptors.

G-protein-coupled receptors are a major target for potential therapeutics; yet, a large number of these receptors couple to the Gi pathway, generating signals that are difficult to detect. We have combined chimeric G proteins, automated sample handling, and simultaneous 96-well fluorometric imaging to develop a high-throughput assay system for Gi signaling. The chimeric G proteins alter receptor coupling so that signaling can occur through Gq and result in mobilization of intracellular calcium stores. An automated signaling assay device, the fluorometric imaging plate reader (FLIPR), can simultaneously measure this response in real time in 96-well microplates, allowing two people to process more than 10,000 points per day. We used the chimeric G protein/FLIPR system to characterize signaling by the Gi-coupled human opioid receptors. We show that the mu, delta, and kappa opioid receptors and the related nociceptin receptor, ORL1, each couple to Galphaqi5, Galphaqo5, and Galpha16 (Galphaqi5 and Galphaqo5 refer to Galphaq proteins containing the five carboxyl-terminal amino acids from Galphai and Galphao, respectively) and that different receptor/G protein combinations show different levels of maximal activation. We tested 31 opioid ligands for agonist activity at the opioid receptors (124 ligand-receptor combinations); all 31 activated at least one receptor type, and several activated multiple receptors with differing potencies. This high-throughput assay could be useful for dissecting the complex ligand-receptor relationships that are common in nature.

Duration and magnitude of nerve growth factor signaling depend on the ratio of p75LNTR to TrkA.

The role of the low affinity neurotrophin receptor p75LNTR in neurotrophin signal transduction remains open. Recent reports show that this receptor generates intracellular signals independent of Trk activity, and others imply that it collaborates with Trk(s) to enhance cellular responses to low neurotrophin concentrations. We have used the Cytosensor microphysiometer as a direct marker of intracellular metabolic activity to address the physiologic role of p75LNTR in nerve growth factor (NGF) signal transduction. NGF treatment of PC12 or TrkA-transfected Chinese hamster ovary (CHO) cells results in a rapid, transient increase in the extracellular acidification rate as measured by the Cytosensor; in both cell types, p75LNTR enhances this response. p75LNTR affects both the magnitude of and the duration of the extracellular acidification response to NGF. Moreover, it is not merely the presence of p75LNTR, but also the ratio of p75LNTR:TrkA which determines cellular responsiveness to NGF. In transiently transfected CHO cells, a 5:1 ratio of p75LNTR:trkA cDNAs produced the greatest change in NGF-induced acid secretion. Pretreatment of PC12 cells with anti-p75LNTR antibodies decreased the responsiveness to NGF. However, long-term NGF exposure to PC12 cells in which p75LNTR expression was decreased to approximately 10% of wild-type levels showed a longer duration of acid secretion compared to wild-type PC12 cells. Together, these data suggest that p75LNTR may play a dual role in modulating NGF signal transduction by enhancing and extending cellular responses to short-term ligand exposures while attenuating the metabolic response to long-term ligand exposures. With regard to potential Trk-independent p75LNTR signal transduction mechanisms, we detected no change in extracellular acidification response in 75LNTR-transfected CHO cells, PCNA-15 fibroblasts, or Schwann cells, all of which express large amounts of p75LNTR and no Trk. Thus, p75LNTR cannot produce any signal detected by microphysiometry in the absence of TrkA.

Controlling signaling with a specifically designed Gi-coupled receptor.

We are developing a system to control G protein signaling in vivo to regulate a broad range of physiologic responses. Our system utilizes G protein-coupled peptide receptors engineered to respond exclusively to synthetic small molecule ligands and not to their natural ligand(s). These engineered receptors are designated RASSLs (receptor activated solely by a synthetic ligand). We have made two prototype RASSLs that are based on the human kappa opioid receptor. Small molecule drugs that activate the kappa receptor are nonaddictive and safe to administer in vivo. Binding and signaling assays reveal 200-2000-fold reductions in the ability of our RASSLs to bind or be activated by dynorphin, an endogenous peptide ligand of the kappa opioid receptor. In a high-throughput signaling assay, these prototype RASSLs expressed in Chinese hamster ovary K1 cells showed little or no response to a panel of 21 opioid peptides but still signaled normally in response to small molecule drugs such as spiradoline. Activation of a RASSL by spiradoline also caused proliferation of rat-1a tissue culture cells. These data provide evidence that G protein-coupled receptors can be made into RASSLs. The potential in vivo applications for RASSLs include the positive enrichment of transfected cells and the development of new animal models of disease.

Nonisotopic quantitation of mRNA using a novel RNase protection assay: measurement of erbB-2 mRNA in tumor cell lines.

We have developed a nonisotopic RNase protection assay using RNA probes that are dual-labeled with biotin and fluorescein for detection. This system utilizes capture of the protected RNA probe hybrids to streptavidin-coated membranes attached to plastic dipsticks, complexing of anti-fluorescein-urease conjugate with the labeled RNA probe, and quantitative detection of the membrane-bound complex by a potentiometric silicon sensor. The dual-label RNase protection (RP) assay was capable of measuring beta-actin mRNA in cellular RNA samples at the 27- to 45-amol level (10-17 pg) with high precision (%CV < 7). We have used this method to quantitate the levels of erbB-2 mRNA in the human tumor cell lines SKBR-3, SKOV-3, and MCF-7. The levels of erbB-2 mRNA in these cells were 105, 190, and 0.9 amol per microgram of cellular RNA, respectively. The dual-label RP method should be useful for measuring the mRNA expression for other erbB-2 homologs such as erbB-3 and erbB-4 in tumor cells and tissues and can be a generally useful mRNA quantitative method for laboratories wishing to minimize radioisotope use.

B-lymphoma cells are activated by peptide ligands of the antigen binding receptor or by anti-idiotypic antibody to induce extracellular acidification.

Synthetic peptide ligands specific for the surface immunoglobulin receptor of the human Burkitt's lymphoma cell line SUP-B8, previously identified using phage display libraries, induced apoptosis of the SUP-B8 cells in vitro when administered as dimers or tetramers. The use of synthetic peptide ligands is being explored for immunotherapy of B-cell lymphoma. It will be critical to identify which of the peptide ligands identified are the most active functionally. Using the Cytosensor microphysiometer, SUP-B8 cells and B-lymphoma cells obtained from patients were found to acidify their extracellular environment within minutes of specific activation by surrogate peptide ligands or by anti-idiotype antibodies. This signal was blocked by pretreatment of the lymphoma cells with the tyrosine kinase inhibitor genistein. Treatment of SUP-B8 cells with dimeric and tetrameric specific peptide ligands caused a rapid increase in extracellular acidification rate, which peaked after 10 min at approximately 15 and 20% above basal rates, respectively. These responses were blocked by excess monomeric peptide. To evaluate the ability of different peptide ligands to induce a signal directly on lymphoma cells, thereby establishing their relative affinity to the surface immunoglobulin receptor, acidification rate changes were measured at varying peptide concentrations. The microphysiometer signal correlated with the known relative affinities and antiproliferative potencies of the peptides. This approach is particularly useful for primary tumor cells that cannot be cultured. The signal may be predictive of the efficacy of treatment with synthetic peptide ligands and may be useful in the evaluation of ligands for other cell surface receptors with biological effects on B-lymphoma cells.

Heregulin activation of extracellular acidification in mammary carcinoma cells is associated with expression of HER2 and HER3.

HER2, the erbB-2/neu proto-oncogene product, is a 185-kDa transmembrane glycoprotein related to the epidermal growth factor receptor. Overexpression of HER2 was reported in several human adenocarcinomas, including mammary and ovarian carcinomas. A family of glycoproteins, the heregulin/neu differentiation factors, was characterized and implicated as the ligands for HER2. Recently, it has been shown that HER2 alone is not sufficient to reconstitute high affinity heregulin receptors and that HER3 or HER4 may be the required components of the heregulin receptors on mammary carcinoma cells (Sliwkowski, M.X., Schaefer, G., Akita, R.W., Lofgren, J.A., Fitzpatrick, V.D., Nuijens, A., Fendly, B.M., Cerione, R.A., Vandlen, R.L., and Carraway, K.L., III (1994) J. Biol. Chem. 269, 14661-14665; Plowman, G.D., Green, J.M., Culouscou, J.-M., Carlton, G.W., Rothwell, V.M., and Buckley, W. (1993) Nature 366, 473-475). Using the Cytosensor to measure the extracellular acidification rate, we have examined the effects of recombinant human heregulin-alpha on three mammary carcinoma cell lines expressing HER2 (MDA-MB-453, SK-BR-3, and MCF-7), an ovarian carcinoma cell line expressing HER2 (SK-OV-3), and CHO-K1 and 293-EBNA cells stably transfected with HER2. By reverse transcription polymerase chain reaction and Western blotting, we found that the breast cells also express HER3 and that the ovarian line co-expresses the HER4 message. A dramatic increase in the acidification rate was observed for the mammary carcinoma cells co-expressing high levels of HER2 and HER3. In contrast, the ovarian cells expressing high levels of HER2 and low levels of HER4 or CHO-K1 and 293-EBNA cells expressing HER2 alone were not responsive to heregulin. When these same transfected cells were exposed to monoclonal anti-HER2 antibody followed by anti-IgG to cause aggregation of the HER2 molecules, an increase in the acidification rate was observed, indicating coupling of transfected HER2 to the signal transduction pathway. Transfection of HER2 into MCF-7 cells, on the other hand, gave 4-fold enhanced acidification responses. These data, together with the previously reported high affinity heregulin binding and activation of tyrosine phosphorylation in HER2 and HER3 co-transfected cells support the role of HER2 and HER3 as components of the heregulin receptor in breast cells.

Stimulation of T cells by antigen-presenting cells is kinetically controlled by antigenic peptide binding to major histocompatibility complex class II molecules.

Activation of CD4+ T cells by antigenic peptide involves the interaction of major histocompatibility complex (MHC) class II-peptide complexes on the surface of antigen-presenting cells (APCs) with T-cell receptors. This report describes the kinetics of T-cell triggering by exogenous antigenic peptides in the presence of APCs. A rapid specific increase in extracellular acidification rate is observed within minutes upon exposure of A.E7 T cells (restricted for IEk and moth cytochrome c peptide containing residues 88-103) and 4R3.9 T cells (restricted for IAk and myelin basic protein peptide containing residues 1-14 [AcMBP-(1-14)]) to their cognate peptides in the presence of CH27 cells bearing both IAk and IEk MHC class II molecules. Pretreatment of cloned T cells, but not APCs, with herbimycin A resulted in complete inhibition of triggering events, indicating that the acidification response is mediated by T-cell second messenger pathways. This rapid assay for 4R3.9 T-cell stimulation showed increased T-cell triggering activity for AcMBP-(1-14)-A4 and MBP-(1-14)-M4 peptides compared to the native AcMBP-(1-14)-K4. By using the previously determined kinetic constants for MBP-(1-14)-A4 reactions with IAk, it is possible to show that at the lowest peptide concentrations the kinetics of T-cell triggering are limited by the kinetics of the peptide binding to MHC class II molecules.

Activation of TNF-R1 receptor in the presence of copper kills TNF resistant CEM leukemic T cells.

The cytotoxic effects of TNF on malignant cells are known to be mediated through high affinity surface receptors. The precise mechanism by which transformed cells are selectively killed by the activation of these receptors is yet unknown, but several intracellular signaling pathways are known to be involved. Phospholipase A2 activation by TNF-alpha has been shown to be important in the transduction of signals leading to cell death. We have used monitoring of extracellular acidification rate as a measure of cellular metabolism to follow the early time course of TNF effects on a human leukemic T cell line (CEM-SS cells). CEM-SS cells were relatively resistant to TNF cell killing but TNF caused an early stimulation of metabolism within 2-4 hr, followed by a suppression of metabolic activity occurring over 20 hr. In contrast, a TNF sensitive subclone of CEM cells (C1Ca) showed a rapid and dramatic decrease in metabolic activity corresponding to cytotoxicity within 18 hr. It was discovered that cupric o-phenanthroline markedly potentiated the effects of TNF on the resistant CEM-SS cells leading to cell death. This observation was specific for copper because ferric o-phenanthroline was without effect at the same concentration. The copper cytotoxic effect was shown to be mediated through the TNF-R1 receptor and independent of phospholipase A2 signaling.

The role of N-linked oligosaccharides of MHC class II antigens in T cell stimulation.

A specific increase in T cell extracellular acidification rate has been demonstrated recently when complexes of purified MHC class II molecules and antigenic peptides interact with T cell receptors (TCRs) on cloned T cells. The present study shows that such measurements of an increase in extracellular acidification rate can be used to evaluate the functional role of various N-linked oligosaccharides of MHC class II antigens. Affinity-purified murine IAk and IAs were deglycosylated in the presence of aspargine-amidase enzyme and were characterized by SDS-polyacrylamide gel electrophoresis. The complete removal of all three N-linked oligosaccharides from the alpha/beta heterodimer was confirmed by four different lectin-linked Western blot analyses. Similar to the native heterodimer, both deglycosylated IAk and deglycosylated IAs were fully capable of binding synthetic antigenic peptides derived from myelin basic protein (MBP). When equivalent amount of glycosylated and deglycosylated class II-peptide complexes were exposed to restricted cloned T cells, identical increases in T cell extracellular acidification rates were observed. The specificity of such increases in extracellular acidification rate was demonstrated by exposing cloned T cells to irrelevant complexes of glycosylated and deglycosylated class II and antigenic peptides. These results show how measurement of extracellular acidification rate can be used to study structure-function correlations of ligand-receptor interactions, and support an earlier observation that N-linked oligosaccharides of murine MHC class II molecules are not involved in either antigenic peptide binding or T cell recognition.

Stimulation of T cells by antigenic peptide complexed with isolated chains of major histocompatibility complex class II molecules.

Major histocompatibility complex (MHC) class II molecules are heterodimeric glycoproteins with one alpha and one beta polypeptide chain of similar molecular size. In this report, we describe the binding of an acetylated N-terminal peptide of myelin basic protein, [Ala4]MBP-(1-14), to purified individual alpha and beta chains of murine I-Ak molecules. Purified complexes of isolated single chains and antigenic peptide bind to cloned T cells restricted by I-Ak and [Ala4]MBP-(1-14) tetradecapeptide. The binding is blocked by alpha/beta anti-T-cell receptor (TCR) monoclonal antibody. Cell triggering as measured by an increase in extracellular acidification rate is observed when cloned T cells are exposed to purified complexes of isolated chains and antigenic peptide. This increase in the extracellular acidification rate is antigen specific and MHC-restricted, as chains alone or irrelevant chain-peptide complexes do not trigger an increase in the metabolic acidification rate. These results together demonstrate that in vitro cloned T cells are triggered by complexes of specific antigenic peptides and isolated individual chains of their cognate MHC proteins.

Purified beta-chain of MHC class II binds to CD4 molecules on transfected HeLa cells.

The initial event triggering the activation of Th cells occurs when the TCR interacts with antigenic peptide in the context of the MHC II on APC. Various T cell accessory molecules including CD4, CD28, and LFA-1 participate and facilitate the activation event. Although some evidence for the interaction of MHC II and CD4 is available, the site of MHC class II (alpha-chain, beta-chain, or both chains) for CD4 interaction has not yet been clearly defined. Results from different laboratories had indicated the involvement of alpha 1, beta 1, and beta 2 domains of MHC class II molecules in CD4 interaction. Recently, a conserved site of DR beta 2 domain has been identified that involves CD4 interaction that is analogous to MHC class I binding site for CD8 molecule. In this report, direct binding of affinity-purified HLA-DR2 dimer and its isolated alpha- and beta-chains to CD4 was studied using a CD4-transfected HeLa cell line. Preferential binding of the beta-chain and intact MHC II dimer to the CD4-transfected cells was observed and found to be specifically inhibited by anti-CD4 mAb. In contrast, the isolated alpha-chain of HLA DR2 did not show significant binding to CD4-transfected cells. Complexes of radiolabeled DR2 dimer or beta-chain alone with an immunodominant epitope from myelin basic protein (83-102) did not show any further increase in binding of these molecules. Binding of the beta-chain to CD4+ cells was markedly inhibited by a DR beta 1 peptide (35-46) and was partially inhibited by a DR beta 2 peptide (134-148) of MHC class II molecule. These results suggest the involvement of at least two conserved regions of the beta polypeptide chain of MHC class II in CD4 interaction. Because in our experiments transfected cells lack TCR molecules and the binding of DR2 to the CD4-transfected cells was unaffected by added antigenic peptide, it is possible that the interaction of MHC class II to CD4 is independent of TCR occupancy.

GM-CSF triggers a rapid, glucose dependent extracellular acidification by TF-1 cells: evidence for sodium/proton antiporter and PKC mediated activation of acid production.

The extracellular acidification rate of the human bone marrow cell line, TF-1, increases rapidly in response to a bolus of recombinant granulocyte-macrophage colony stimulating factor (GM-CSF). Extracellular acidification rates were measured using a silicon microphysiometer. This instrument contains micro-flow chambers equipped with potentiometric sensors to monitor pH. The cells are immobilized in a fibrin clot sandwiched between two porous polycarbonate membranes. The membranes are part of a disposable plastic "cell capsule" that fits into the microphysiometer flow chamber. The GM-CSF activated acidification burst is dose dependent and can be neutralized by pretreating the cytokine with anti-GM-CSF antibody. The acidification burst can be resolved kinetically into at least two components. A rapid component of the burst is due to activation of the sodium/proton antiporter as evidenced by its elimination in sodium-free medium and in the presence of amiloride. A slower component of the GM-CSF response is a consequence of increased glycolytic metabolism as demonstrated by its dependence on D-glucose as a medium nutrient. Okadaic acid (a phospho-serine/threonine phosphatase inhibitor), phorbol 12-myristate 13-acetate (PMA, a protein kinase C (PKC) activator), and ionomycin (a calcium ionophore) all produce metabolic bursts in TF-1 cells similar to the GM-CSF response. Pretreatment of TF-1 cells with PMA for 18 h resulted in loss of the GM-CSF acidification response. Although this treatment is reported to destroy protein kinase activity, we demonstrate here that it also down-regulates expression of high-affinity GM-CSF receptors on the surface of TF-1 cells. In addition, GM-CSF driven TF-1 cell proliferation was decreased after the 18 h PMA treatment. Short-term treatment with PMA (1-2 h) again resulted in loss of the GM-CSF acidification response, but without a decrease in expression of high-affinity GM-CSF receptors. Evidence for involvement of PKC in GM-CSF signal transduction was obtained using calphostin C, a specific inhibitor of PKC, which inhibited the GM-CSF metabolic burst at a subtoxic concentration. Genistein and herbimycin A, tyrosine kinase inhibitors, both inhibited the GM-CSF response of TF-1 cells, but only at levels high enough to also inhibit stimulation by PMA. These results indicate that GM-CSF activated extracellular acidification of TF-1 cells is caused by increases in sodium/proton antiporter activity and glycolysis, through protein kinase signalling pathways which can be both activated and down-regulated by PMA.

PKC epsilon is involved in granulocyte-macrophage colony-stimulating factor signal transduction: evidence from microphysiometry and antisense oligonucleotide experiments.

We have used microphysiometry and antisense methodology to show that the epsilon isoenzyme of protein kinase C (PKC) is involved in the signal transduction pathway of granulocyte-macrophage colony-stimulating factor (GM-CSF) in a human bone marrow cell line, TF-1. These cells require GM-CSF or a related cytokine for proliferation. When the cells are appropriately exposed to GM-CSF, they exhibit a burst of metabolic activity that can be detected on the time scale of minutes in the microphysiometer, a biosensor-based instrument that measures the rate at which cells excrete protons. These cells express PKC alpha and -epsilon, as determined by Western blot analysis. Treatment with isoenzyme-specific antisense oligonucleotides inhibits expression appropriately, but only inhibition of PKC epsilon appreciably diminishes the burst of metabolic activity induced by GM-CSF. Consistent with the involvement of PKC epsilon, GM-CSF appears to activate phospholipase D and does not cause a detectable increase in cytosolic [Ca2+].

The cytosensor microphysiometer: biological applications of silicon technology.

A silicon-based device, dubbed a microphysiometer, can be used to detect and monitor the response of cells to a variety of chemical substances, especially ligands for specific plasma membrane receptors. The microphysiometer measures the rate of proton excretion from 10(4) to 10(6) cells. This article gives an overview of experiments currently being carried out with this instrument with emphasis on receptors with seven transmembrane helices and tyrosine kinase receptors. As a scientific instrument, the microphysiometer can be thought of as serving two distinct functions. In terms of detecting specific molecules, selected biological cells in this instrument serve as detectors and amplifiers. The microphysiometer can also investigate cell function and biochemistry. A major application of this instrument may prove to be screening for new receptor ligands. In this respect, the microphysiometer appears to offer significant advantages over other techniques.

Antigen-specific stimulation of T cell extracellular acidification by MHC class II-peptide complexes.

A specific T cell response to a preformed complex of detergent-solubilized MHC class II molecule and cognate antigenic peptide was observed by monitoring the extracellular acidification. An increase in this rate was observed when the resting 4R3.9 T cell clone specific for the peptide fragment MBP(1-14) of myelin basic protein was exposed to preformed detergent-solubilized IAk-MBP(1-14)A4 complexes. MBP peptide alone, IAk alone, or complexes of IAs-proteolipid protein(139-151) and IAd-OVA(323-339), did not cause significant increases in the acidification rates of the MBP(1-14)-restricted 4R3.9 T cell clone. In addition, BW 5147 T lymphoma cells, which lack TCR, did not show any increase in rate when exposed to IAk-MBP(1-14)A4 complexes. Similar increases in acidification rate were observed in the presence of IL-2, anti-CD3 and anti-TCR antibodies. The enhanced acidification responses were blocked by genistein, a tyrosine kinase inhibitor.

Detection of cell-affecting agents with a silicon biosensor.

Cellular metabolism is affected by many factors in a cell's environment. Given a sufficiently sensitive method for measuring cellular metabolic rates, it should be possible to detect a wide variety of chemical and physical stimuli. A biosensor has been constructed in which living cells are confined to a flow chamber in which a potentiometric sensor continually measures the rate of production of acidic metabolites. Exploratory studies demonstrate several applications of the device in basic science and technology.