Fireflies communicate with each other by emitting yellow-green to yellow-orange brilliant light. The bioluminescence reaction, which uses luciferin, Mg-ATP and molecular oxygen to yield an electronically excited oxyluciferin species, is carried out by the enzyme luciferase. Visible light is emitted during relaxation of excited oxyluciferin to its ground state. The high quantum yield of the luciferin/luciferase reaction and the change in bioluminescence colour caused by subtle structural differences in luciferase have attracted much research interest. In fact, a single amino acid substitution in luciferase changes the emission colour from yellow-green to red. Although the crystal structure of luciferase from the North American firefly (Photinus pyralis) has been described, the detailed mechanism for the bioluminescence colour change is still unclear. Here we report the crystal structures of wild-type and red mutant (S286N) luciferases from the Japanese Genji-botaru (Luciola cruciata) in complex with a high-energy intermediate analogue, 5'-O-[N-(dehydroluciferyl)-sulfamoyl]adenosine (DLSA). Comparing these structures to those of the wild-type luciferase complexed with AMP plus oxyluciferin (products) reveals a significant conformational change in the wild-type enzyme but not in the red mutant. This conformational change involves movement of the hydrophobic side chain of Ile 288 towards the benzothiazole ring of DLSA. Our results indicate that the degree of molecular rigidity of the excited state of oxyluciferin, which is controlled by a transient movement of Ile 288, determines the colour of bioluminescence during the emission reaction.
Gibberellins (GAs) are phytohormones essential for many developmental processes in plants. A nuclear GA receptor, GIBBERELLIN INSENSITIVE DWARF1 (GID1), has a primary structure similar to that of the hormone-sensitive lipases (HSLs). Here we analyse the crystal structure of Oryza sativa GID1 (OsGID1) bound with GA(4) and GA(3) at 1.9 A resolution. The overall structure of both complexes shows an alpha/beta-hydrolase fold similar to that of HSLs except for an amino-terminal lid. The GA-binding pocket corresponds to the substrate-binding site of HSLs. On the basis of the OsGID1 structure, we mutagenized important residues for GA binding and examined their binding activities. Almost all of them showed very little or no activity, confirming that the residues revealed by structural analysis are important for GA binding. The replacement of Ile 133 with Leu or Val-residues corresponding to those of the lycophyte Selaginella moellendorffii GID1s-caused an increase in the binding affinity for GA(34), a 2beta-hydroxylated GA(4). These observations indicate that GID1 originated from HSL and was further modified to have higher affinity and more strict selectivity for bioactive GAs by adapting the amino acids involved in GA binding in the course of plant evolution.
P-glycoprotein is an ATP-binding cassette multidrug transporter that actively transports chemically diverse substrates across the lipid bilayer. The precise molecular mechanism underlying transport is not fully understood. Here, we present crystal structures of a eukaryotic P-glycoprotein homolog, CmABCB1 from Cyanidioschyzon merolae, in two forms: unbound at 2.6-Å resolution and bound to a unique allosteric inhibitor at 2.4-Å resolution. The inhibitor clamps the transmembrane helices from the outside, fixing the CmABCB1 structure in an inward-open conformation similar to the unbound structure, confirming that an outward-opening motion is required for ATP hydrolysis cycle. These structures, along with site-directed mutagenesis and transporter activity measurements, reveal the detailed architecture of the transporter, including a gate that opens to extracellular side and two gates that open to intramembranous region and the cytosolic side. We propose that the motion of the nucleotide-binding domain drives those gating apparatuses via two short intracellular helices, IH1 and IH2, and two transmembrane helices, TM2 and TM5. multidrug resistance | ABC transporter | membrane protein | X-ray crystallography | macrocyclic peptide M ultidrug transporters of the ATP-binding cassette (ABC) superfamily, such as P-glycoprotein (P-gp; MDR1; ABCB1), MRP1 (ABCC1), and ABCG2 (BCRP), transport a large number of structurally unrelated compounds with molecular weights ranging up to several thousand Daltons (1, 2). These transporters not only play important roles in normal physiology by protecting tissues from various toxic xenobiotics and endogenous metabolites but also contribute to multidrug resistance (MDR) in tumors, a major obstacle to effective chemotherapeutic treatment (1, 3-7). Their functional forms consist of a minimum of four core domains: two transmembrane domains (TMDs) that create the translocation pathway for substrates and two nucleotide-binding domains (NBDs) that bind and hydrolyze ATP to power the transport process (8, 9). These four domains can exist either as two separate polypeptides (half-size) or fused together in a single large polypeptide with an internal duplication (full-size). The crystal structures of mouse and nematode P-gps, as well as their bacterial homologs (10-14), have been determined, and they have provided important insights into the relationships between protein structure and the functional and biochemical characteristics of P-gp. However, the detailed architecture of the TMD machinery and the gating mechanism during the transition between the inward-and outward-open states are poorly understood.Here, we report the structures of a eukaryotic P-gp homolog, unlocked (at 2.6-Å resolution) and locked allosterically with a tailor-made peptide at 2.4-Å resolution. Although CmABCB1 is not a full-length ABC transporter but a half-sized ABC transporter adopting a homodimeric architecture, CmABCB1 showed quite similar functional properties to those of human P-gp (hP-gp). Based on these structures, we...
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