General purpose, field-portable cell-based biosensor platform.

There are several groups of researchers developing cell-based biosensors for chemical and biological warfare agents based on electrophysiologic monitoring of cells. In order to transition such sensors from the laboratory to the field, a general-purpose hardware and software platform is required. This paper describes the design, implementation, and field-testing of such a system, consisting of cell-transport and data acquisition instruments. The cell-transport module is a self-contained, battery-powered instrument that allows various types of cell-based modules to be maintained at a preset temperature and ambient CO(2) level while in transit or in the field. The data acquisition module provides 32 channels of action potential amplification, filtering, and real-time data streaming to a laptop computer. At present, detailed analysis of the data acquired is carried out off-line, but sufficient computing power is available in the data acquisition module to enable the most useful algorithms to eventually be run real-time in the field. Both modules have sufficient internal power to permit realistic field-testing, such as the example presented in this paper.

Single-molecule spectroscopy of the beta(2) adrenergic receptor: observation of conformational substates in a membrane protein.

Single-molecule studies of the conformations of the intact beta(2) adrenergic receptor were performed in solution. Photon bursts from the fluorescently tagged adrenergic receptor in a micelle were recorded. A photon-burst algorithm and a Poisson time filter were implemented to characterize single molecules diffusing across the probe volume of a confocal microscope. The effects of molecular diffusion and photon number fluctuations were deconvoluted by assuming that Poisson distributions characterize the molecular occupation and photon numbers. Photon-burst size histograms were constructed, from which the source intensity distributions were extracted. Different conformations of the beta(2) adrenergic receptor cause quenching of the bound fluorophore to different extents and hence produce different photon-burst sizes. An analysis of the photon-burst histograms shows that there are at least two distinct substates for the native adrenergic membrane receptor. This behavior is in contrast to one peak observed for the dye molecule, rhodamine 6G. We test the reliability and robustness of the substate number determination by investigating the application of different binning criteria. Conformational changes associated with agonist binding result in a marked change in the distribution of photon-burst sizes. These studies provide insight into the conformational heterogeneity of G protein-coupled receptors in the presence and absence of a bound agonist.

Agonist-induced conformational changes in the G-protein-coupling domain of the beta 2 adrenergic receptor.

The majority of extracellular physiologic signaling molecules act by stimulating GTP-binding protein (G-protein)-coupled receptors (GPCRs). To monitor directly the formation of the active state of a prototypical GPCR, we devised a method to site specifically attach fluorescein to an endogenous cysteine (Cys-265) at the cytoplasmic end of transmembrane 6 (TM6) of the beta(2) adrenergic receptor (beta(2)AR), adjacent to the G-protein-coupling domain. We demonstrate that this tag reports agonist-induced conformational changes in the receptor, with agonists causing a decline in the fluorescence intensity of fluorescein-beta(2)AR that is proportional to the biological efficacy of the agonist. We also find that agonists alter the interaction between the fluorescein at Cys-265 and fluorescence-quenching reagents localized to different molecular environments of the receptor. These observations are consistent with a rotation and/or tilting of TM6 on agonist activation. Our studies, when compared with studies of activation in rhodopsin, indicate a general mechanism for GPCR activation; however, a notable difference is the relatively slow kinetics of the conformational changes in the beta(2)AR, which may reflect the different energetics of activation by diffusible ligands.

Functionally different agonists induce distinct conformations in the G protein coupling domain of the beta 2 adrenergic receptor.

G protein-coupled receptors represent the largest class of drug discovery targets. Drugs that activate G protein-coupled receptors are classified as either agonists or partial agonists. To study the mechanism whereby these different classes of activating ligands modulate receptor function, we directly monitored ligand-induced conformational changes in the G protein-coupling domain of the beta(2) adrenergic receptor. Fluorescence lifetime analysis of a reporter fluorophore covalently attached to this domain revealed that, in the absence of ligands, this domain oscillates around a single detectable conformation. Binding to an antagonist does not change this conformation but does reduce the flexibility of the domain. However, when the beta(2) adrenergic receptor is bound to a full agonist, the G protein coupling domain exists in two distinct conformations. Moreover, the conformations induced by a full agonist can be distinguished from those induced by partial agonists. These results provide new insight into the structural consequence of antagonist binding and the basis of agonism and partial agonism.

The effect of pH on beta(2) adrenoceptor function. Evidence for protonation-dependent activation.

The transition of rhodopsin from the inactive to the active state is associated with proton uptake at Glu(134) (1), and recent mutagenesis studies suggest that protonation of the homologous amino acid in the alpha(1B) adrenergic receptor (Asp(142)) may be involved in its mechanism of activation (2). To further explore the role of protonation in G protein-coupled receptor activation, we examined the effects of pH on the rate of ligand-induced conformational change and on receptor-mediated G protein activation for the beta(2) adrenergic receptor (beta(2)AR). The rate of agonist-induced change in the fluorescence of NBD-labeled, purified beta(2)AR was 2-fold greater at pH 6.5 than at pH 8, even though agonist affinity was lower at pH 6.5. This biophysical analysis was corroborated by functional studies; basal (agonist-independent) activation of Galpha(s) by the beta(2)AR was greater at pH 6.5 compared with pH 8.0. Taken together, these results provide evidence that protonation increases basal activity by destabilizing the inactive state of the receptor. In addition, we found that the pH sensitivity of beta(2)AR activation is not abrogated by mutation of Asp(130), which is homologous to the highly conserved acidic amino acids that link protonation to activation of rhodopsin (Glu(134)) and the alpha(1B) adrenergic receptor (Asp(142)).

Mutation of a highly conserved aspartic acid in the beta2 adrenergic receptor: constitutive activation, structural instability, and conformational rearrangement of transmembrane segment 6.

Movements of transmembrane segments (TMs) 3 and 6 play a key role in activation of G protein-coupled receptors. However, the underlying molecular processes that govern these movements, and accordingly control receptor activation, remain unclear. To elucidate the importance of the conserved aspartic acid (Asp-130) in the Asp-Arg-Tyr motif of the beta2 adrenergic receptor (beta2AR), we mutated this residue to asparagine (D130N) to mimic its protonated state, and to alanine (D130A) to fully remove the functionality of the side chain. Both mutants displayed evidence of constitutive receptor activation. In COS-7 cells expressing either D130N or D130A, basal levels of cAMP accumulation were clearly elevated compared with cells expressing the wild-type beta2AR. Incubation of COS-7 cell membranes or purified receptor at 37 degrees C revealed also a marked structural instability of both mutant receptors, suggesting that stabilizing intramolecular constraints had been disrupted. Moreover, we obtained evidence for a conformational rearrangement by mutation of Asp-130. In D130N, a cysteine in TM 6, Cys-285, which is not accessible in the wild-type beta2AR, became accessible to methanethiosulfonate ethylammonium, a charged, sulfhydryl-reactive reagent. This is consistent with a counterclockwise rotation or tilting of TM 6 and provides for the first time structural evidence linking charge-neutralizing mutations of the aspartic acid in the DRY motif to the overall conformational state of the receptor. We propose that protonation of the aspartic acid leads to release of constraining intramolecular interactions, resulting in movements of TM 6 and, thus, conversion of the receptor to the active state.

Characterization of ligand-induced conformational states in the beta 2 adrenergic receptor.

Drugs acting at G protein coupled receptors can be classified in biological assays as either agonists, partial agonists, neutral antagonists, or as inverse agonists. Very little is known about the actual molecular events and structural changes that occur in the receptor following ligand binding and during transmission of a signal across the membrane. Therefore, the structural basis for the biological classification of drug action remains unknown. To date, the conformational state of G protein coupled receptors has been inferred from the activity of the effector enzyme modulated by the G protein. We have used two different approaches to monitor conformational changes in beta 2 adrenergic receptor. Fluorescence spectroscopy can be used to directly monitor structural changes in purified beta 2 adrenergic receptor in real-time. The emission from many fluorescent molecules is strongly dependent on the polarity of the environment in which they are located. Thus, fluorescent probes covalently bound to proteins can be used as sensitive indicators of conformational changes and protein-protein interactions. In addition, we examined functional differences between agonists and partial agonists using fusion proteins between wild-type beta 2 receptor or a constitutively active beta 2 receptor mutant and Gs alpha. These receptor-G protein fusion proteins guarantee highly efficient coupling with a defined stoichiometry. The results of these experiments will be discussed in the context of current models of G protein coupled receptor activation.

Examination of ligand-induced conformational changes in the beta2 adrenergic receptor.

The environmentally sensitive and cysteine reactive fluorescent probe, IANBD, was used to monitor ligand-induced structural changes in the beta2 adrenergic receptor (beta2AR) by fluorescent spectroscopy. We found that agonists caused a dose-dependent and reversible decrease in fluorescence from the purified IANBD-labeled beta2AR. This suggested that agonists promote a conformational change in the receptor that leads to an increase in the polarity of the environment around one or more IANBD labeled cysteines. The wildtype receptor contains eight free cysteines and mutagenesis and peptide mapping experiments have indicated that several of these sites are accessible for chemical derivatization. Thus, to identify the cysteine(s) involved in the agonist-induced change in fluorescence and thereby map agonist-induced conformational changes in the beta2AR, we generated a series of mutant receptors having limited numbers of cysteines available for fluorescent labeling. Fluorescence spectroscopy analysis of the purified and site-selectively IANBD-labeled mutants showed that IANBD labeled 125Cys and 285Cys are responsible for the observed changes in fluorescence consistent with movements of TM III and VI in response to agonist binding.

Agonists induce conformational changes in transmembrane domains III and VI of the beta2 adrenoceptor.

Agonist binding to G protein-coupled receptors is believed to promote a conformational change that leads to the formation of the active receptor state. However, the character of this conformational change which provides the important link between agonist binding and G protein coupling is not known. Here we report evidence that agonist binding to the beta2 adrenoceptor induces a conformational change around 125Cys in transmembrane domain (TM) III and around 285Cys in TM VI. A series of mutant beta2 adrenoceptors with a limited number of cysteines available for chemical derivatization were purified, site-selectively labeled with the conformationally sensitive, cysteine-reactive fluorophore IANBD and analyzed by fluorescence spectroscopy. Like the wild-type receptor, mutant receptors containing 125Cys and/or 285Cys showed an agonist-induced decrease in fluorescence, while no agonist-induced response was observed in a receptor where these two cysteines were mutated. These data suggest that IANBD bound to 125Cys and 285Cys are exposed to a more polar environment upon agonist binding, and indicate that movements of transmembrane segments III and VI are involved in activation of G protein-coupled receptors.

A DNA minor groove-binding ligand both potentiates and arrests transcription by RNA polymerase II. Elongation factor SII enables readthrough at arrest sites.

RNA polymerase II encounters various obstacles to transcript elongation both in vivo and in vitro. These include DNA sequence elements and protein bound to the major groove of DNA. Elongation factor SII binds to RNA polymerase II and enables the enzyme to bypass these impediments. SII also activates nascent RNA cleavage by the arrested transcription elongation complex, an activity intimately involved in the readthrough process. Here we identify another type of reversible blockage to RNA polymerase II transcription, the antitumor antibiotic distamycin, which binds in the minor groove of A + T-rich DNA. SII facilitates readthrough of arrest sites resulting from DNA-binding of the drug. In response to SII, these complexes cleave their nascent RNA chains. These findings confirm that SII is a general elongation factor that potentiates transcription through a variety of impediments. They also strengthen the idea that SII stimulates transcription by activating nascent RNA cleavage. In some cases, distamycin can potentiate transcription through a naturally occurring pause site. We also show that the template undergoes a conformational change in the presence of distamycin. This suggests that distamycin can transform DNA from an elongation-non-permissive configuration into an elongation-permissive form and we take this as independent evidence confirming that DNA structure influences transcription elongation by RNA polymerase II.

Transcription elongation by RNA polymerase II: mechanism of SII activation.

RNA chain elongation by RNA polymerase is a dynamic process. Techniques that allow the isolation of active elongation complexes have enabled investigators to describe individual steps in the polymerization of RNA chains. This article will describe recent studies of elongation by RNA polymerase II (pol II). At least four types of blockage to chain elongation can be overcome by elongation factor SII: (a) naturally occurring "arrest" sequences, (b) DNA-bound protein, (c) drugs bound in the DNA minor groove, and (d) chain-terminating substrates incorporated into the RNA chain. SII binds to RNA polymerase II and stimulates a ribonuclease activity that shortens nascent transcripts from their 3' ends. This RNA cleavage is required for chain elongation from some template positions. As a result, the pol II elongation complex can repeatedly shorten and reextend the nascent RNA chain in a process we refer to as cleavage-resynthesis. Hence, assembly of large RNAs does not necessarily proceed in a direct manner. The ability to shorten and reextend nascent RNAs means that a transcription impediment through which only half the enzyme molecules can proceed per encounter, can be overcome by 99% of the molecules after six iterations of cleavage-resynthesis. Surprisingly, the boundaries of the elongation complex do not move upstream after RNA cleavage. The physico-chemical alterations in the elongation complex that accompany RNA cleavage and permit renewed chain elongation are not yet understood.

The RNA polymerase II elongation complex. Factor-dependent transcription elongation involves nascent RNA cleavage.

Regulation of transcription elongation is an important mechanism in controlling eukaryotic gene expression. SII is an RNA polymerase II-binding protein that stimulates transcription elongation and also activates nascent transcript cleavage by RNA polymerase II in elongation complexes in vitro (Reines, D. (1992) J. Biol. Chem. 267, 3795-3800). Here we show that SII-dependent in vitro transcription through an arrest site in a human gene is preceded by nascent transcript cleavage. RNA cleavage appeared to be an obligatory step in the SII activation process. Recombinant SII activated cleavage while a truncated derivative lacking polymerase binding activity did not. Cleavage was not restricted to an elongation complex arrested at this particular site, showing that nascent RNA hydrolysis is a general property of RNA polymerase II elongation complexes. These data support a model whereby SII stimulates elongation via a ribonuclease activity of the elongation complex.