Fluorescein monophosphates as fluorogenic substrates for protein tyrosine phosphatases

Colorimetric sensing of alkaline phosphatase and α-fetoprotein based on the photoinduced oxidase activity of fluorescein

A simple and inexpensive colorimetric assay for alkaline phosphatase (ALP) and α-fetoprotein (AFP) has been established by the hydrolysis of fluorescein diphosphate (FDP).

Interrogating Protein Phosphatases with Chemical Activity Probes

Protein phosphatases, while long overlooked, have recently become appreciated as drivers of both normal- and disease-associated signaling events. As a result, the spotlight is now turning torwards this enzyme family and efforts geared towards the development of modern chemical tools for studying these enzymes are well underway. This Minireview focuses on the evolution of chemical activity probes, both optical and covalent, for the study of protein phosphatases. Small-molecule probes, global monitoring of phosphatase activity through the use of covalent modifiers, and targeted fluorescence-based activity probes are discussed. We conclude with an overview of open questions in the field and highlight the potential impact of chemical tools for studying protein phosphatases.

Design, synthesis, and biological application of fluorescent sensor molecules for cellular imaging

Cellular imaging has achieved many new biological findings, among them GFP and other fluorescent proteins and small molecule based fluorescent sensors have been widely used, especially in the last decade. The design concept and application of chemical sensors are described, these being FRET based sensors and Zn(2+) sensors.Fluorescence resonance energy transfer (FRET) has been used extensively as the designing principle for fluorescent sensor molecules. One of the most significant advantages of designing sensor molecules with FRET modulation is that it can enable ratiometric measurement in living cells, which reduces the artifact from microscopic imaging systems. The design strategy for the development of small molecular FRET sensors is described in terms of avoiding close contact of donor fluorophore and acceptor fluorophore in aqueous solution. Furthermore, a strategy to design FRET sensors with modulating overlap integrals of donor and acceptor is introduced.Numerous tools for Zn(2+) sensing in living cells have become available in the last 8 years. Among them, fluorescence imaging using fluorescent sensor molecules has been the most popular approach. Some of these sensor molecules can be used to visualize Zn(2+) in living cells. Some of the biological functions of Zn(2+) were clarified using these sensor molecules, especially in neuronal cells, which contain a high concentration of free Zn(2) (+).

An expanded set of fluorogenic sulfatase activity probes

Fluorogenic probes that are activated by an enzymatic transformation are ideally suited for profiling enzyme activities in biological systems. Here, we describe two fluorogenic enzyme probes, 3-O-methylfluorescein-sulfate and resorufin-sulfate, that can be used to detect sulfatases in mycobacterial lysates. Both probes were validated with a set of commercial sulfatases and used to reveal species-specific sulfatase banding patterns in a gel-resolved assay of mycobacterial lysates. The fluorogenic probes described here are suitable for various assays and provide a starting point for creating new sulfatase probes with improved selectivity for mycobacterial sulfatases.

Activatable Optical Probes for the Detection of Enzymes

The early detection of many human diseases is crucial if they are to be treated successfully. Therefore, the development of imaging techniques that can facilitate early detection of disease is of high importance. Changes in the levels of enzyme expression are known to occur in many diseases, making their accurate detection at low concentrations an area of considerable active research. Activatable fluorescent probes show immense promise in this area. If properly designed they should exhibit no signal until they interact with their target enzyme, reducing the level of background fluorescence and potentially endowing them with greater sensitivity. The mechanisms of fluorescence changes in activatable probes vary. This review aims to survey the field of activatable probes, focusing on their mechanisms of action as well as illustrating some of the in vitro and in vivo settings in which they have been employed.

Sts-2 is a phosphatase that negatively regulates zeta-associated protein (ZAP)-70 and T cell receptor signaling pathways

T cell activity is controlled in large part by the T cell receptor (TCR). The TCR detects the presence of foreign pathogens and activates the T cell-mediated immune reaction. Numerous intracellular signaling pathways downstream of the TCR are involved in the process of T cell activation. Negative regulation of these pathways helps prevent excessive and deleterious T cell responses. Two homologous proteins, Sts-1 and Sts-2, have been shown to function as critical negative regulators of TCR signaling. The phosphoglycerate mutase-like domain of Sts-1 (Sts-1(PGM)) has a potent phosphatase activity that contributes to the suppression of TCR signaling. The function of Sts-2(PGM) as a phosphatase has been less clear, principally because its intrinsic enzyme activity has been difficult to detect. Here, we demonstrate that Sts-2 regulates the level of tyrosine phosphorylation on targets within T cells, among them the critical T cell tyrosine kinase Zap-70. Utilizing new phosphorylated substrates, we demonstrate that Sts-2(PGM) has clear, albeit weak, phosphatase activity. We further pinpoint Sts-2 residues Glu-481, Ser-552, and Ser-582 as specificity determinants, in that an Sts-2(PGM) triple mutant in which these three amino acids are altered to their counterparts in Sts-1(PGM) has substantially increased activity. Our results suggest that the phosphatase activities of both suppressor of TCR signaling homologues cooperate in a similar but independent fashion to help set the threshold for TCR-induced T cell activation.

Unexpected phosphoryl transfer from Asp351 to fluorescein attached to Lys515 in sarcoplasmic reticulum Ca2+-ATPase

Sarcoplasmic reticulum Ca(2+)-ATPase is an ion pump whose catalytic cycle includes the transient formation of an acyl phosphate at Asp(351), and fluorescein isothiocyanate is a covalent inhibitor of ATP binding to this pump, known to specifically derivatize Lys(515) in the nucleotide-binding site. It was previously found that an unusually stable, phosphorylated form of fluorescein-ATPase, with low fluorescence, is obtained following Ca (2+) loading with acetyl phosphate as energy source and then chelation with EGTA of Ca(2+) on the cytosolic side. Here we show that the phospho-linkage in this low fluorescent species is stable at alkaline pH, unlike the acyl phosphate at Asp(351). Moreover, the low fluorescence and stable phosphoryl group track together in primary and secondary tryptic subfragments, separated by SDS-PAGE after denaturation. Finally, normal fluorescence and absorbance are recovered upon treatment with alkaline phosphatase after extensive trypsinolysis. We conclude that the low fluorescent species is the result of the phosphoryl group being transferred from Asp (351) to the fluorescein moiety during pump reversal, yielding fluorescein monophosphate tethered to Ca(2+)-ATPase.

High-throughput assays for yeast RNA 5' triphosphatase (Cet1p)

The 5' cap on eukaryotic messenger RNA (mRNA) is critical for the stabilization, processing, nuclear transport, and translation of the transcript. Before capping can occur, the gamma-phosphate from the 5' end of newly synthesized RNA must be removed. In Saccharomyces cerevisiae, this reaction is catalyzed by Cet1p, an RNA triphosphatase. Because Cet1p is both essential for fungal growth and sufficiently different from its human counterpart in terms of three-dimensional structure and catalytic mechanism, it represents an unexplored target for antifungal drug discovery. To this end, we characterized the steady-state kinetics of Cet1p using both synthetic RNA oligos and nucleoside triphosphates. Nucleotide triphosphatase activity was measured in a scintillation proximity assay (SPA)-based high-throughput screen using [gamma-(33)P]biotin-11 GTP as substrate (GTP-SPA); the format is sensitive, accurate, robust, and compatible with automation. A charcoal absorption method was used to measure the release of free inorganic phosphate from an RNA substrate; the method was adapted to fit a 96-well plate format. The performance of the GTP-SPA and RNA assays was tested against a panel of commercially available compounds and found to be comparable. The charcoal absorption method run in the 96-well plate format has general utility for any phosphatase using nucleotides, nucleic acids, or proteins as substrate.

Enzyme occupancy measurement of intracellular protein tyrosine phosphatase 1B using photoaffinity probes

Protein tyrosine phosphatase 1B (PTP1B) is believed to be one of the enzymes involved in down-regulating the insulin receptor and is a drug target for the treatment of type II diabetes. To better understand the in vitro and in vivo behavior of PTP1B inhibitors, a cell-based assay to directly measure enzyme occupancy of PTP1B by inhibitors using photoaffinity labeling was developed. Two photoaffinity probes were synthesized containing the photolabile diazirine moiety. These photoprobes were specific for PTP1B and T-cell protein tyrosine phosphatase over CD45, with the most potent photoprobe having an IC(50) value of 0.2nM for PTP1B. Activation of the photoprobes with a 40-W UV lamp in the presence of purified AspTyrLysAspAspAspAspLys (Flag)-PTP1B formed a 1:1 irreversible adduct with the enzyme. The photolabeling was competed by known PTP1B inhibitors, vanadate, and the peptide inhibitor N-benzoyl-l-glutamyl-[4-phosphono(difluoromethyl)]-l-phenylalanyl-[4-phosphono(difluoromethyl)]l-phenylalanineamide (BzN-EJJ-amide). In HepG2 (human hepatoma cell line) cells, endogenous PTP1B was labeled by the UV-activated photoprobes in both lysed and intact cells. Enzyme occupancy measurements were conducted with a series of PTP1B inhibitors using the photoprobe affinity assay. Several compounds were shown to bind to endogenous PTP1B in the HepG2 intact cells.

Organization and expression of thirteen alternatively spliced exons in catfish CD45 homologs

CD45, also known as LCA, is a transmembrane protein tyrosine phosphatase encoded by the PTPRC gene. In mammals, it plays an important role in T and B cell receptor and cytokine signaling by maintaining receptor associated kinases in an active state. A prominent CD45 feature is alternative splicing of exons encoding the N-terminus, resulting in the generation of several isoforms. The expression of isoforms is tightly regulated and dependent on the developmental/activation state of the lymphocyte. Nevertheless, the significance of these multiple isoforms in mammals is poorly understood. In this study, the channel catfish CD45 homolog was sequenced and found to be similar to CD45 of other species. However, unlike mammalian CD45, it appears that up to 13 exons are used in producing multiple alternatively spliced CD45 variants in catfish cells. These 13 alternatively spliced exons variably encode for O-linked glycosylation sites. Several of the exons are identical or very similar, suggesting gene duplication of a block of four exons. As demonstrated by RT-PCR, many of the alternatively spliced forms of catfish CD45 are differentially expressed in lymphoid cell lines with B cells expressing larger isoforms than do T cells. Furthermore, immunoprecipitation experiments utilizing anti-catfish CD45 mAbs substantiated that different size CD45 isoforms are expressed at the protein level on catfish T and B cells.

Directed evolution of a yeast arsenate reductase into a protein-tyrosine phosphatase

Arsenic, which is ubiquitous in the environment and comes from both geochemical and anthropogenic sources, has become a worldwide public health problem. Every organism studied has intrinsic or acquired mechanisms for arsenic detoxification. In Saccharomyces cerevisiae arsenate is detoxified by Acr2p, an arsenate reductase. Acr2p is not a phosphatase but is a homologue of CDC25 phosphatases. It has the HCX5R phosphatase motif but not the glycine-rich phosphate binding motif (GXGXXG) that is found in protein-tyrosine phosphatases. Here we show that creation of a phosphate binding motif through the introduction of glycines at positions 79, 81, and 84 in Acr2p resulted in a gain of phosphotyrosine phosphatase activity and a loss of arsenate reductase activity. Arsenate likely achieved geochemical abundance only after the atmosphere became oxidizing, creating pressure for the evolution of an arsenate reductase from a protein-tyrosine phosphatase. The ease by which an arsenate reductase can be converted into a protein-tyrosine phosphatase supports this hypothesis.

Measuring the specific activity of the CD45 protein tyrosine phosphatase

Many assays for protein tyrosine phosphatases (PTPs) rely on colorimetric substrates or more recently developed fluorescent substrates. Enzyme activity is measured but no assessment of specific activity is made, which is important since these enzymes can exist in an enzymatically inactive form. In this study, we have directly compared the relative sensitivity of assays using either colorimetric or fluorescent substrates and show the latter to be considerably more sensitive with as few as 0.2 x 10(6) cells required compared to 3 x 10(6) cells for the colorimetric method. We then describe a quick and sensitive protocol that measures both the phosphatase activity and amount of CD45, allowing the calculation of the specific activity. CD45 is captured from cell lysates using anti-CD45 monoclonal antibody coated onto a 96-well plate, and the phosphatase activity is measured using the substrate fluorescein diphosphate (FDP). The amount of CD45 protein bound in the wells is measured against a standard curve using an anti-CD45-HRP conjugate, and this value is used to derive the specific activity. We used this assay to demonstrate that exposure of Jurkat T cells, and primary CD4(+) T cells to H(2)O(2) decreases the specific activity of their CD45, mimicking the changes seen in some diseases. The assay is applicable to other cell types and phosphatases, and so its use may help to identify the presence of inactive but intact enzyme in cells, which may play an important regulatory role in vivo.

Structure of protein tyrosine phosphatase 1B in complex with inhibitors bearing two phosphotyrosine mimetics

Protein tyrosine phosphatases (PTPases) are signal-transducing enzymes that dephosphorylate intracellular proteins that have phosphorylated tyrosine residues. It has been demonstrated that protein tyrosine phosphatase 1B (PTP1B) is an attractive therapeutic target because of its involvement in regulating insulin sensitivity (Elcheby et al. Science 1999, 283, 1544-1548). The identification of a second binding site in PTP1B (Puius et al., Proc. Natl. Acad. Sci. U.S.A.1997, 94, 13420-13425) suggests a new strategy for inhibitor design, where appropriate compounds may be made to simultaneously occupy both binding sites to gain much higher affinity and selectivity. To test this hypothesis and gain further insights into the structural basis of inhibitor binding, we have determined the crystal structure of PTP1B complexed with two non-peptidyl inhibitors, 4 and 5, both of which contain two aryl difluoromethylenephosphonic acid groups, a nonhydrolyzable phosphate mimetic. The structures were determined and refined to 2.35 and 2.50 A resolution, respectively. Although one of the inhibitors seems to have satisfied the perceived requirement for dual binding, it did not bind both the active site and the adjacent noncatalytic binding site as expected. The second or distal phosphonate group instead extends into the solvent and makes water-mediated interactions with Arg-47. The selectivity of the more potent of these two inhibitors, as well as four other inhibitors bearing two such phosphate mimetics for PTP1B versus seven other PTPases, was examined. In general, selectivity was modest to good when compared to PTPases Cdc25a, PTPmeg-1, PTPbeta, and CD45. However, selectivity was generally poor when compared to other PTPases such as SHP-1, SHP-2, and especially TCPTP, for which almost no selectivity was found. The implications these results have concerning the utility of dual-binding inhibitors are discussed.

Development of a method for evaluating protein tyrosine phosphatase CD45 inhibitors using Jurkat cell membrane

A simple, high-throughput fluorescent assay was developed to measure the inhibition of membrane-bound CD45 from Jurkat cells. This assay is based on the fact that approximately 64% of PTP activity from Jurkat cell membrane is contributed by CD45. This has been proven by comparing the activity in membrane protein from wild-type Jurkat cells and CD45-negative mutant cells, and also by measuring the residual activity after depleting CD45 from Jurkat cell membrane. We have demonstrated that fluorescein diphosphate can be used as a substrate to monitor CD45 activity from Jurkat cell membrane, which allows us to easily follow CD45 activity in both fluorescent and absorbance modes in a 96-well format. Some common protein tyrosine phosphatase inhibitors have been evaluated with this assay.