Large scale expression and purification of the rat 5-HT2c receptor.

5-HT2c G-protein coupled receptors located in the central nervous system bind the endogenous neurotransmitters serotonin and couple to G protein to mediate excitatory neurotransmission, which inhibits dopamine and norepinephrine release in the brain. Thus, 5-HT2c receptors play important roles in cognitive function and are potent drug targets. Structural information is needed to elucidate the molecular mechanism of ligand-binding and receptor-activation of the 5-HT2c receptor. Lacking of an efficient expression system that produces sufficient amounts of active and homogenous receptors hinders progress in the functional and structural characterization of the 5-HT2c receptor. We present here a protocol which can be used easily to obtain milligram amount of purified rat 5-HT2c receptors. We established this protocol by protein engineering and optimization of expression and purification based on radioligand-binding assay. The purified and well-characterized rat 5-HT2c receptors are active, stable, homogenous, and ready for 2-dimensional and 3-dimensional crystallization experiments.

Crystal structure of the GlnZ-DraG complex reveals a different form of PII-target interaction.

Nitrogen metabolism in bacteria and archaea is regulated by a ubiquitous class of proteins belonging to the P(II)family. P(II) proteins act as sensors of cellular nitrogen, carbon, and energy levels, and they control the activities of a wide range of target proteins by protein-protein interaction. The sensing mechanism relies on conformational changes induced by the binding of small molecules to P(II) and also by P(II) posttranslational modifications. In the diazotrophic bacterium Azospirillum brasilense, high levels of extracellular ammonium inactivate the nitrogenase regulatory enzyme DraG by relocalizing it from the cytoplasm to the cell membrane. Membrane localization of DraG occurs through the formation of a ternary complex in which the P(II) protein GlnZ interacts simultaneously with DraG and the ammonia channel AmtB. Here we describe the crystal structure of the GlnZ-DraG complex at 2.1 Å resolution, and confirm the physiological relevance of the structural data by site-directed mutagenesis. In contrast to other known P(II) complexes, the majority of contacts with the target protein do not involve the T-loop region of P(II). Hence this structure identifies a different mode of P(II) interaction with a target protein and demonstrates the potential for P(II) proteins to interact simultaneously with two different targets. A structural model of the AmtB-GlnZ-DraG ternary complex is presented. The results explain how the intracellular levels of ATP, ADP, and 2-oxoglutarate regulate the interaction between these three proteins and how DraG discriminates GlnZ from its close paralogue GlnB.

Crystal structure of dinitrogenase reductase-activating glycohydrolase (DraG) reveals conservation in the ADP-ribosylhydrolase fold and specific features in the ADP-ribose-binding pocket.

Protein-reversible ADP-ribosylation is emerging as an important post-translational modification used to control enzymatic and protein activity in different biological systems. This modification regulates nitrogenase activity in several nitrogen-fixing bacterial species. ADP-ribosylation is catalyzed by ADP-ribosyltransferases and is reversed by ADP-ribosylhydrolases. The structure of the ADP-ribosylhydrolase that acts on Azospirillum brasilense nitrogenase (dinitrogenase reductase-activating glycohydrolase, DraG) has been solved at a resolution of 2.5 A. This bacterial member of the ADP-ribosylhydrolase family acts specifically towards a mono-ADP-ribosylated substrate. The protein shows an all-alpha-helix structure with two magnesium ions located in the active site. Comparison of the DraG structure with orthologues deposited in the Protein Data Bank from Archaea and mammals indicates that the ADP-ribosylhydrolase fold is conserved in all domains of life. Modeling of the binding of the substrate ADP-ribosyl moiety to DraG is in excellent agreement with biochemical data.

High-resolution crystal structure of AKR11C1 from Bacillus halodurans: an NADPH-dependent 4-hydroxy-2,3-trans-nonenal reductase.

Aldo-keto reductase AKR11C1 from Bacillus halodurans, a new member of aldo-keto reductase (AKR) family 11, has been characterized structurally and biochemically. The structures of the apo and NADPH bound form of AKR11C1 have been solved to 1.25 A and 1.3 A resolution, respectively. AKR11C1 possesses a novel non-aromatic stacking interaction of an arginine residue with the cofactor, which may favor release of the oxidized cofactor. Our biochemical studies have revealed an NADPH-dependent activity of AKR11C1 with 4-hydroxy-2,3-trans-nonenal (HNE). HNE is a cytotoxic lipid peroxidation product, and detoxification in alkaliphilic bacteria, such as B.halodurans, plays a crucial role in survival. AKR11C1 could thus be part of the detoxification system, which ensures the well being of the microorganism. The very poor activity of AKR11C1 on standard, small substrates such as benzaldehyde or DL-glyeraldehyde is consistent with the observed, very open active site lacking a binding pocket for these substrates. In contrast, modeling of HNE with its aldehyde function suitably positioned in the active site suggests that its elongated hydrophobic tail occupies a groove defined by hydrophobic side-chains. Multiple sequence alignment of AKR11C1 with the highly homologous iolS and YqkF proteins shows a high level of conservation in this putative substrate-binding site. We suggest that AKR11C1 is the first structurally characterized member of a new class of AKRs with specificity for substrates with long aliphatic tails.