Team:Bielefeld-Germany/Project/Background/NAD
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==NAD<sup>+</sup> in general== | ==NAD<sup>+</sup> in general== | ||
- | Nicotinamide adenine dinucleotide, abbreviated NAD<sup>+</sup>, is an ubiquitous and indispensable cofactor for all living organisms ([http://onlinelibrary.wiley.com/doi/10.1002/jcp.22419/full Bi ''et al.'', 2011]). The molecule has a wide range of physiological functions in cellular processes and a great impact on the cell integrity ([http://ini.sagepub.com/content/17/2/212.abstract Grahnert ''et al.'', 2011]). | + | [[Image:Bielefeld-Germany-2011_NAD-NADH.png|300px|thumb|right| '''Figure 1: Reduced (right) and oxidized (left) form of NAD.''']] |
- | + | [[Image:Bielefeld-Germany-2011_NAD-metabolism.png|300px|thumb|right| '''Figure 2: NAD as a key metabolite embedded in the cellular metabolism.''']] | |
- | NAD<sup>+</sup> is embedded in the cellular metabolism and has a great impact on essential cellular processes. The biosynthesis in most bacteria and plants starts with the anaerobic conversion of the amino acid aspartate to | + | Nicotinamide adenine dinucleotide, abbreviated NAD<sup>+</sup>, is an ubiquitous and indispensable cofactor for all living organisms ([http://onlinelibrary.wiley.com/doi/10.1002/jcp.22419/full Bi ''et al.'', 2011]). The molecule has a wide range of physiological functions in cellular processes and a great impact on the cell integrity ([http://ini.sagepub.com/content/17/2/212.abstract Grahnert ''et al.'', 2011]). [http://onlinelibrary.wiley.com/doi/10.1002/jcp.22419/full Bi ''et al.'' (2011)] announced the following physiological functions for NAD(P): cellular metabolism, energy metabolism, cofactor, DNA repair, redox reaction, precursor for vitamine B<sub>12</sub>, telomere maintenance, gene silencing, cell longevity, immune response, Ca<sup>2+</sup> signaling and regulation of incretion. Thus, NAD is integrated into the energy metabolism and determines the redox status of the cell due to its purpose as a reduction equivalent (see Figures 1 and 2). This is strongly linked to the control of signaling and transcriptional events. For instance, NAD<sup>+</sup> has been recently described as a modulator of immune functions ([http://ini.sagepub.com/content/17/2/212.abstract Grahnert ''et al.'', 2011]) and a master regulator of transcription ([http://www.sciencedirect.com/science/article/pii/S1874939910001057 Ghosh ''et al.'', 2010]). Several enzymes are tightly regulated by the cellular balance between the oxidized and reduced form of NAD<sup>+</sup> and are therefore regarded as a potential target for therapeutics ([http://jpet.aspetjournals.org/content/324/3/883.abstract Sauve, 2008]). Indeed, NAD<sup>+</sup> acts as a substrate for a wide range of proteins including NAD<sup>+</sup>-dependent protein deacetylases, poly(ADP-ribose) polymerases and several transcription factors ([http://edrv.endojournals.org/content/31/2/194.abstract Houtcooper ''et al.'', 2010]). An imbalance of the cellular NAD<sup>+</sup> level has usually relevance in symptoms and diseases like stroke, cardiac ischemia, epilepsy, huntington disease, wallerian degeneration, cancer, type two diabetes mellitus (T2DM), neutrophil survival, longevity, obesity as well as cardiovascular and neurodegenerative disease ([http://jpet.aspetjournals.org/content/324/3/883.abstract Sauve, 2008]; [http://edrv.endojournals.org/content/31/2/194.abstract Houtcooper ''et al.'', 2010]). Additionally, the regulation of NAD<sup>+</sup>-dependent pathways may have an influence on oxidative metabolism and life span extension ([http://edrv.endojournals.org/content/31/2/194.abstract Houtcooper ''et al.'', 2010]). Because of the essentialities of DNA ligases for fundamental processes in bacterial cells, the biosynthetic pathways for NAD<sup>+</sup> are proposed as promising novel antibiotics targets against pathogens ([http://onlinelibrary.wiley.com/doi/10.1002/jcp.22419/full Bi ''et al.'', 2011]).<br> |
+ | NAD<sup>+</sup> is embedded in the cellular metabolism and has a great impact on essential cellular processes. | ||
+ | The biosynthesis in most bacteria and plants starts with the anaerobic conversion of the amino acid aspartate to quinolinic acid (QA). As indicated in Figure 3, in yeast, humans and some bacterial microbes the quinolinic acid (QA) derives from tryptophan in an aerobic manner. This is a crucial step that leads under consumption of nicotinic acid (Na) to the nicotinate ring system via formation of nicotinic acid monoculeotide (NaMN), respectively ([http://jpet.aspetjournals.org/content/324/3/883.abstract Sauve, 2008]). After conjugation of adenosine mononucleotide (AMP) the NAD synthetase forms nicotinamide adenine dinucleotide (NAD). Additionally, it has been reported recently that in humans exists an nicotinic acid-independent reaction catalysed by the enzyme nampt/PBEF, which uses nicotinamide (Nam) directly as a substrate ([http://www.ncbi.nlm.nih.gov/pubmed/12555668 Rongvaux, 2002]). Diet or pharmalogical agents can thereby serve as a source for nicotinamide or nicotinic acid ([http://jpet.aspetjournals.org/content/324/3/883.abstract Sauve, 2008]). Fundamental processes as the cellular energy metabolism determine the balance between the oxidized (NAD<sup>+</sup>) and reduced (NADH) form of NAD (see Figures 1 and 2).<br> | ||
+ | <br style="clear: both" /> | ||
+ | [[Image:Bielefeld-Germany-2011_NAD-salvage.png|500px|thumb|centre| '''Figure 3: NAD salvage: for synthesis and recycling of NAD vertebrates use tryptophan (Trp), nicotinic acid (Na), nicotinamide (Nam) and/or nicotinamide riboside (NR).''']] | ||
<br style="clear: both" /> | <br style="clear: both" /> | ||
==Bacterial DNA ligases== | ==Bacterial DNA ligases== | ||
- | Bacterial DNA ligases are important enzymes for DNA repair and replication. The big difference between bacterial and eukaryotic DNA ligases is their specifity for cofactors. While eukaryotic DNA ligases use ATP as a source for building a phosphodiester bond in the DNAs phosphate backbone the bacterial ones display a NAD<sup>+</sup>-dependent biochemical catalysis. These enzymes are | + | Bacterial DNA ligases are important enzymes for DNA repair and replication. The big difference between bacterial and eukaryotic DNA ligases is their specifity for cofactors. While eukaryotic DNA ligases use ATP as a source for building a phosphodiester bond in the DNAs phosphate backbone, the bacterial ones display a NAD<sup>+</sup>-dependent biochemical catalysis. These enzymes are essential for bacterial survival and are therefore in focus for designing highly specific antiinfectives ([http://www.cell.com/structure/abstract/S0969-2126%2804%2900235-7 Gajiwala & Pinko, 2004]). All bacterial DNA ligases possess highly conserved functional domains. Generally, they can be devided into four functionally distinguishable domains, each with characteristic motifs: |
+ | [[Image:Bielefeld-Germany-2011_LigA_reactionmechanism.png|325px|right]] | ||
* Domain 1: Ia, Ib (NTase) | * Domain 1: Ia, Ib (NTase) | ||
* Domain 2: Oligomer-binding (OB) beta-barrel | * Domain 2: Oligomer-binding (OB) beta-barrel | ||
* Domain 3: Zinc (Zn)-finger, helix-hairpin-helix motif (HhH) | * Domain 3: Zinc (Zn)-finger, helix-hairpin-helix motif (HhH) | ||
* Domain 4: BRCT domain | * Domain 4: BRCT domain | ||
- | All bacterial DNA ligases share three fundamental steps during reaction mechanism ([http://www.cell.com/molecular-cell/abstract/S1097-2765%2807%2900144-X Nandakumar ''et al.'', 2007]): | + | All bacterial DNA ligases share three fundamental steps during their reaction mechanism ([http://www.cell.com/molecular-cell/abstract/S1097-2765%2807%2900144-X Nandakumar ''et al.'', 2007]): |
* Adenylation of DNA ligase by transferring hydrolysed AMP from NAD<sup>+</sup> to the active site lysine and release of NMN | * Adenylation of DNA ligase by transferring hydrolysed AMP from NAD<sup>+</sup> to the active site lysine and release of NMN | ||
* Tranfer of the AMP from DNA ligase to the 5'-phosphate group of nicked DNA | * Tranfer of the AMP from DNA ligase to the 5'-phosphate group of nicked DNA | ||
* Formation of a phosphodiester bond by attack of the nick 3'-OH on the 5'-phosphoanhydride linkage and release of free AMP | * Formation of a phosphodiester bond by attack of the nick 3'-OH on the 5'-phosphoanhydride linkage and release of free AMP | ||
- | |||
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<br style="clear: both" /> | <br style="clear: both" /> | ||
==Applications of molecular beacons== | ==Applications of molecular beacons== | ||
- | Molecular beacons can be applied to a wide range of biological and diagnostical studies. Whenever there is a specific nucleic acid which is supposed to be detected they can be utilized. Molecular beacons are used for the detection and distinction of retroviral DNA from different types of HIV, for instance ([http://www.sciencedirect.com/science/article/pii/S0009898105004249 Marras ''et al.'', 2006]). Even for identification of proteins which interact with DNA or RNA they are useful. In sum, there are a lot of opportunities to apply molecular beacons ([http://www.jbsdonline.com/c3008/c4017/Molecular-Beacons-Nucleic-Acid-Hybridization-and-Emerging-Applications-p-497-504-p10542.html Antony & Subramaniam, 2001]): | + | [https://2011.igem.org/Team:Bielefeld-Germany/Project/Description#NAD.2B_detection Molecular beacons] can be applied to a wide range of biological and diagnostical studies. Some examples for applying molecular beacons in different biological fields are described in Figures 4, 5 and 6. Whenever there is a specific nucleic acid which is supposed to be detected they can be utilized. Molecular beacons are used for the detection and distinction of retroviral DNA from different types of HIV, for instance ([http://www.sciencedirect.com/science/article/pii/S0009898105004249 Marras ''et al.'', 2006]). Even for identification of proteins which interact with DNA or RNA they are useful. In sum, there are a lot of opportunities to apply molecular beacons ([http://www.jbsdonline.com/c3008/c4017/Molecular-Beacons-Nucleic-Acid-Hybridization-and-Emerging-Applications-p-497-504-p10542.html Antony & Subramaniam, 2001]): |
* Detection of PCR amplification products | * Detection of PCR amplification products | ||
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* Biosensors | * Biosensors | ||
- | |||
{| align="center" | {| align="center" | ||
- | || [[Image:Bielefeld-Germany-2011 MolecularBeacon surface.png|300px|thumb|center| '''Figure | + | || [[Image:Bielefeld-Germany-2011 MolecularBeacon surface.png|300px|thumb|center| '''Figure 4: Hybridization of the molecular beacon and a complementary target forms the molecular beacons open state which leads to an increase of the fluorescence intensity. The molecular beacon can be immmobilized using specific biomolecular interaction, e.g. streptavidin/biotin or covalent cross-linking (taken from [http://www.ijcep.com/708009A.html Kim ''et al.'', 2008]).''']] |
- | || [[Image:Bielefeld-Germany-2011 MolecularBeacon SNP2.png|311px|thumb|center| '''Figure | + | || [[Image:Bielefeld-Germany-2011 MolecularBeacon SNP2.png|311px|thumb|center| '''Figure 5: Single nucleotide polymorphism of nucleic acids, including different alleles as indicated, can be detected by differently designed and labeled molecular beacons (taken from [http://www.ijcep.com/708009A.html Kim ''et al.'', 2008]).''']] |
- | || [[Image:Bielefeld-Germany-2011 MolecularBeacon mRNA.png|275px|thumb|center| '''Figure | + | || [[Image:Bielefeld-Germany-2011 MolecularBeacon mRNA.png|275px|thumb|center| '''Figure 6: Realtime ''in vivo'' imaging of specific mRNAs utilizing two molecular beacons that target adjacent positions on the mRNA allowing FRET to take place (taken from [http://www.ijcep.com/708009A.html Kim ''et al.'', 2008]).''']] |
|} | |} | ||
<br style="clear: both" /> | <br style="clear: both" /> | ||
- | ==Further applications | + | ==Further applications of the NAD<sup>+</sup> bioassay== |
- | The reviewed molecular beacon based [ | + | The reviewed molecular beacon based [https://2011.igem.org/Team:Bielefeld-Germany/Project/Description#NAD.2B_detection NAD<sup>+</sup> bioassay] can be applied to biochemical and biomedical studies ([http://pubs.acs.org/doi/abs/10.1021/ac102742k Tang ''et al.'', 2011]). Accordingly, it can be utilized to detect NAD<sup>+</sup>/NADH-dependent enzymatic processes. The low limit of detection, its reliability and manageability provides a practical alternative to present colorimetric, fluorometric, chemiluminescent, electrochemical or mass spectrometric methods detecting NAD<sup>+</sup> or NADH. In context of clinical applications and therapeutics the NAD<sup>+</sup> bioassay can be useful to monitor cellular NAD<sup>+</sup> levels during treatments of tissues or cell cultures for identification of drug targets, for instance. It may also be applied in the field of diagnostics. Finally, the principle of the proposed NAD<sup>+</sup> bioassay can be used for cell-free optical biosensors by taking molecular beacons either immobilized on the sensor surface or being present in the reaction medium. |
+ | |||
<br style="clear: both" /> | <br style="clear: both" /> | ||
Latest revision as of 21:28, 28 October 2011
Contents |
NAD+ detection
NAD+ in general
Nicotinamide adenine dinucleotide, abbreviated NAD+, is an ubiquitous and indispensable cofactor for all living organisms ([http://onlinelibrary.wiley.com/doi/10.1002/jcp.22419/full Bi et al., 2011]). The molecule has a wide range of physiological functions in cellular processes and a great impact on the cell integrity ([http://ini.sagepub.com/content/17/2/212.abstract Grahnert et al., 2011]). [http://onlinelibrary.wiley.com/doi/10.1002/jcp.22419/full Bi et al. (2011)] announced the following physiological functions for NAD(P): cellular metabolism, energy metabolism, cofactor, DNA repair, redox reaction, precursor for vitamine B12, telomere maintenance, gene silencing, cell longevity, immune response, Ca2+ signaling and regulation of incretion. Thus, NAD is integrated into the energy metabolism and determines the redox status of the cell due to its purpose as a reduction equivalent (see Figures 1 and 2). This is strongly linked to the control of signaling and transcriptional events. For instance, NAD+ has been recently described as a modulator of immune functions ([http://ini.sagepub.com/content/17/2/212.abstract Grahnert et al., 2011]) and a master regulator of transcription ([http://www.sciencedirect.com/science/article/pii/S1874939910001057 Ghosh et al., 2010]). Several enzymes are tightly regulated by the cellular balance between the oxidized and reduced form of NAD+ and are therefore regarded as a potential target for therapeutics ([http://jpet.aspetjournals.org/content/324/3/883.abstract Sauve, 2008]). Indeed, NAD+ acts as a substrate for a wide range of proteins including NAD+-dependent protein deacetylases, poly(ADP-ribose) polymerases and several transcription factors ([http://edrv.endojournals.org/content/31/2/194.abstract Houtcooper et al., 2010]). An imbalance of the cellular NAD+ level has usually relevance in symptoms and diseases like stroke, cardiac ischemia, epilepsy, huntington disease, wallerian degeneration, cancer, type two diabetes mellitus (T2DM), neutrophil survival, longevity, obesity as well as cardiovascular and neurodegenerative disease ([http://jpet.aspetjournals.org/content/324/3/883.abstract Sauve, 2008]; [http://edrv.endojournals.org/content/31/2/194.abstract Houtcooper et al., 2010]). Additionally, the regulation of NAD+-dependent pathways may have an influence on oxidative metabolism and life span extension ([http://edrv.endojournals.org/content/31/2/194.abstract Houtcooper et al., 2010]). Because of the essentialities of DNA ligases for fundamental processes in bacterial cells, the biosynthetic pathways for NAD+ are proposed as promising novel antibiotics targets against pathogens ([http://onlinelibrary.wiley.com/doi/10.1002/jcp.22419/full Bi et al., 2011]).
NAD+ is embedded in the cellular metabolism and has a great impact on essential cellular processes.
The biosynthesis in most bacteria and plants starts with the anaerobic conversion of the amino acid aspartate to quinolinic acid (QA). As indicated in Figure 3, in yeast, humans and some bacterial microbes the quinolinic acid (QA) derives from tryptophan in an aerobic manner. This is a crucial step that leads under consumption of nicotinic acid (Na) to the nicotinate ring system via formation of nicotinic acid monoculeotide (NaMN), respectively ([http://jpet.aspetjournals.org/content/324/3/883.abstract Sauve, 2008]). After conjugation of adenosine mononucleotide (AMP) the NAD synthetase forms nicotinamide adenine dinucleotide (NAD). Additionally, it has been reported recently that in humans exists an nicotinic acid-independent reaction catalysed by the enzyme nampt/PBEF, which uses nicotinamide (Nam) directly as a substrate ([http://www.ncbi.nlm.nih.gov/pubmed/12555668 Rongvaux, 2002]). Diet or pharmalogical agents can thereby serve as a source for nicotinamide or nicotinic acid ([http://jpet.aspetjournals.org/content/324/3/883.abstract Sauve, 2008]). Fundamental processes as the cellular energy metabolism determine the balance between the oxidized (NAD+) and reduced (NADH) form of NAD (see Figures 1 and 2).
Bacterial DNA ligases
Bacterial DNA ligases are important enzymes for DNA repair and replication. The big difference between bacterial and eukaryotic DNA ligases is their specifity for cofactors. While eukaryotic DNA ligases use ATP as a source for building a phosphodiester bond in the DNAs phosphate backbone, the bacterial ones display a NAD+-dependent biochemical catalysis. These enzymes are essential for bacterial survival and are therefore in focus for designing highly specific antiinfectives ([http://www.cell.com/structure/abstract/S0969-2126%2804%2900235-7 Gajiwala & Pinko, 2004]). All bacterial DNA ligases possess highly conserved functional domains. Generally, they can be devided into four functionally distinguishable domains, each with characteristic motifs:
- Domain 1: Ia, Ib (NTase)
- Domain 2: Oligomer-binding (OB) beta-barrel
- Domain 3: Zinc (Zn)-finger, helix-hairpin-helix motif (HhH)
- Domain 4: BRCT domain
All bacterial DNA ligases share three fundamental steps during their reaction mechanism ([http://www.cell.com/molecular-cell/abstract/S1097-2765%2807%2900144-X Nandakumar et al., 2007]):
- Adenylation of DNA ligase by transferring hydrolysed AMP from NAD+ to the active site lysine and release of NMN
- Tranfer of the AMP from DNA ligase to the 5'-phosphate group of nicked DNA
- Formation of a phosphodiester bond by attack of the nick 3'-OH on the 5'-phosphoanhydride linkage and release of free AMP
Applications of molecular beacons
Molecular beacons can be applied to a wide range of biological and diagnostical studies. Some examples for applying molecular beacons in different biological fields are described in Figures 4, 5 and 6. Whenever there is a specific nucleic acid which is supposed to be detected they can be utilized. Molecular beacons are used for the detection and distinction of retroviral DNA from different types of HIV, for instance ([http://www.sciencedirect.com/science/article/pii/S0009898105004249 Marras et al., 2006]). Even for identification of proteins which interact with DNA or RNA they are useful. In sum, there are a lot of opportunities to apply molecular beacons ([http://www.jbsdonline.com/c3008/c4017/Molecular-Beacons-Nucleic-Acid-Hybridization-and-Emerging-Applications-p-497-504-p10542.html Antony & Subramaniam, 2001]):
- Detection of PCR amplification products
- Mutational analysis
- Genotyping and allele discrimination
- Clinical diagnosis
- Oligonucleotide degradation studies
- Analysis of DNA/RNA hybridization
- Realtime visualization of hybridization in cells
- Analysis of triplex DNA formation
- Protein/DNA interaction
- Enzymatic assays
- Biosensors
Further applications of the NAD+ bioassay
The reviewed molecular beacon based NAD+ bioassay can be applied to biochemical and biomedical studies ([http://pubs.acs.org/doi/abs/10.1021/ac102742k Tang et al., 2011]). Accordingly, it can be utilized to detect NAD+/NADH-dependent enzymatic processes. The low limit of detection, its reliability and manageability provides a practical alternative to present colorimetric, fluorometric, chemiluminescent, electrochemical or mass spectrometric methods detecting NAD+ or NADH. In context of clinical applications and therapeutics the NAD+ bioassay can be useful to monitor cellular NAD+ levels during treatments of tissues or cell cultures for identification of drug targets, for instance. It may also be applied in the field of diagnostics. Finally, the principle of the proposed NAD+ bioassay can be used for cell-free optical biosensors by taking molecular beacons either immobilized on the sensor surface or being present in the reaction medium.
References
Antony T, Subramaniam V (2001) Molecular Beacons: Nucleic Acid Hybridization and Emerging Applications, [http://www.jbsdonline.com/c3008/c4017/Molecular-Beacons-Nucleic-Acid-Hybridization-and-Emerging-Applications-p-497-504-p10542.html Journal of Biomolecular Structure & Dynamics 19(3):497-504].
Bi J, Wang H, Xiel J (2011) Comparative genomics of NAD(P) biosynthesis and novel antibiotic drug targets, [http://onlinelibrary.wiley.com/doi/10.1002/jcp.22419/full Journal of Cellular Physiology 226(2):331-340].
Gajiwala KS, Pinko C (2004) Structural Rearrangement Accompanying NAD+ Synthesis within a Bacterial DNA Ligase Crystal, [http://www.cell.com/structure/abstract/S0969-2126%2804%2900235-7 Structure 12(8):1449-1459].
Ghosh S, George S, Roy U, Ramachandran D, Kolthur-Seetharam U (2010) NAD: A master regulator of transcription, [http://www.sciencedirect.com/science/article/pii/S1874939910001057 Biochimica et Biophysica Acta 1799(10-12):681-693].
Grahnert And, Grahnert Anj, Klein C, Schilling E, Wehrhahn J, Hauschildt S (2011) NAD+: A modulator of immune functions, [http://ini.sagepub.com/content/17/2/212.abstract Innate Immunity 17(2):212-233].
Houtkooper RH, Cantó C, Wanders RJ, Auwerx J (2010) The Secret Life of NAD+: An Old Metabolite Controlling New Metabolic Signaling Pathways, [http://edrv.endojournals.org/content/31/2/194.abstract Endocrine Reviews 31(2):194-223].
Kim Y, Sohn D, Tan W (2008) Molecular Beacons in Biomedical Detection and Clinical Diagnosis, [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2480550/?tool=pmcentrez&rendertype=abstract International Journal of Clinical and Experimental Pathology 1:105-116].
Marras SA, Tyagi S, Kramer FR (2006) Real-time assays with molecular beacons and other fluorescent nucleic acid hybridization probes, [http://www.sciencedirect.com/science/article/pii/S0009898105004249 Clinica chimica acta 363(1-2):48-60].
Miesel L, Kravec C, Xin AT, McMonagle P, Ma S, Pichardo J, Feld B, Barrabee E, Palermo R (2007) High-throughput assay for the adenylation reaction of bacterial DNA ligase, [http://medical-journals.healia.com/doc/17493575/A-high-throughput-assay-for-the-adenylation-reaction-of-bacterial-DNA-ligase Analytical Biochemistry 366:9-17].
Nandakumar J, Nair PA, Shuman S (2007) Last Stop on the Road to Repair: Structure of E. coli DNA Ligase Bound to Nicked DNA-Adenylate, [http://www.cell.com/molecular-cell/abstract/S1097-2765%2807%2900144-X Molecular Cell 26(2):257-271].
Rongvaux A, Shea RJ, Mulks MH, Gigot D, Urbain J, Leo O, Andris F (2002) Pre-B-cell colony-enhancing factor, whose expression is up-regulated in activated lymphocytes, is a nicotinamide phosphoribosyltransferase, a cytosolic enzyme involved in NAD biosynthesis, [http://www.ncbi.nlm.nih.gov/pubmed/12555668 European Journal of Immunology 32(11):3225-3234].
Sauve AA (2008) NAD+ and Vitamin B3: From Metabolism to Therapies, [http://jpet.aspetjournals.org/content/324/3/883.abstract The Journal of Pharmacology and Experimental Therapeutics 324(3):883-893].