Thermostable red and green light-producing firefly luciferase mutants for bioluminescent reporter applications

Light emission from the North American firefly Photinus pyralis, which emits yellow-green (557-nm) light, is widely believed to be the most efficient bioluminescence system known, making this luciferase an excellent tool for monitoring gene expression. We present studies on the production of a set of thermostable red- and green-emitting luciferase mutants with bioluminescent properties suitable for dual-color reporter assays, biosensor measurements with internal controls, and imaging techniques. Starting with the luciferase variant Ser284Thr, we introduced the mutations Thr214Ala, Ala215Leu, Ile232Ala, Phe295Leu, and Glu354Lys to produce a new red-emitting enzyme with a bioluminescence maximum of 610 nm, narrow emission bandwidth, favorable kinetic properties, and excellent thermostability at 37 degrees C. By adding the same five changes to luciferase mutant Val241Ile/Gly246Ala/Phe250Ser, we produced a protein with an emission maximum of 546 nm, providing a set of thermostable enzymes whose bioluminescence maxima were separated by 64 nm. Model studies established that the luciferases could be detected at the attomole level and six orders of magnitude higher. In microplate luminometer format, mixtures containing 1.0 fmol total luciferase were quantified from measurements of simultaneously emitted red and green light. The results presented here provide evidence that it is feasible to monitor two distinct activities at 37 degrees C with these novel thermostable proteins.     

Synergistic mutations produce blue-shifted bioluminescence in firefly luciferase

Light emission from the North American firefly Photinus pyralis, which emits yellow-green (557 nm) light, is widely believed to be the most efficient bioluminescence system known, making this luciferase an excellent tool for monitoring gene expression. In a previous study designed to produce luciferases for simultaneously monitoring two gene expression events, we identified a very promising blue-shifted emitter (548 nm) that contained the mutations Val241Ile, Gly246Ala, and Phe250Ser [Branchini, B. R., Southworth, T. L., Khattak, N. F., Michelini, E., and Roda, A. (2005) Red- and green-emitting firefly luciferase mutants for bioluminescent reporter applications, Anal. Biochem. 345, 140-148]. To establish the basis of the unusual blue-shifted emission, we determined that a simple additive effect of the three individual mutations did not account for the spectral properties of the triple mutant. Instead, the bioluminescence emission spectra of two double mutants containing Phe250Ser and either Val241Ile or Gly246Ala very closely resembled that of the triple mutant. Additional mutagenesis results confirmed that the blue-shifted emission of the double mutants was determined by the synergistic behavior of active site residues. Molecular modeling studies of the Gly246Ala and Phe250Ser double mutant supported the notion that the blue-shifted emission was due to localized changes that increased the hydrophobicity at the emitter site as a result of the addition of a single methyl group at position 246. Moreover, the modeling data suggested that the Ala246 side chain remained close to the emitter through an additional H-bond between Ala246 and the hydroxyl group of Phe250, providing a possible structural basis for the synergistic behavior.     

BMPs regulate differentiation of a putative visceral endoderm layer within human embryonic stem-cell-derived embryoid bodies.

Human embryonic stem cells (HESCs), pluripotent cells derived from the inner cell mass (ICM) of human blastocysts, represent a novel tool for the study of early human developmental events. When cultured in suspension with serum, HESCs form spherical structures resembling embryoid bodies (EBs). We show that differentiation of HESCs within EBs occurs radially, with central cells then undergoing apoptosis in association with EB cavitation. Cells within the outer layer of cavitating EBs display stage-specific immunoreactivity to pan-keratin, cytokeratin-8, GATA6, alpha-fetoprotein, and transthyretin specific antibodies, and hybridization to disabled-2, GATA4, and GATA6 specific riboprobes. Transmission electron microscopy of these cells reveals clathrin-coated micropinocytotic vesicles, microvilli, and many vacuoles, a phenotype consistent with mouse visceral endoderm (VE) rather than mouse definitive or parietal endoderm. When cultured in media supplemented with the BMP inhibitor noggin, or in the absence of serum, HESC derivatives do not develop the mouse VE-like phenotype. The addition of BMP-4 to noggin-treated HESCs cultured in serum or in serum-free conditions reconstituted development of the VE-like phenotype. These data demonstrate that human EBs undergo developmental events similar to those of mouse EBs and that in vitro BMP signalling induces derivatives of the human ICM to express a phenotype similar to mouse VE.     

Calcium channel involvement in potassium depolarization-induced phosphoinositide hydrolysis in rat cortical slices

The stimulation of production of inositol phosphates in rat cortical slices by KCl depolarization and the effects of calcium channel active drugs were investigated. Elevation of K⁺ in the medium up to 48 mM KCl caused a linear concentration-dependent increase in [³H]inositol phosphate accumulation. The KCl stimulated response was not significantly inhibited in the presence of muscarinic or ₁-adrenergic antagonists. KCl stimulated the production of inositol trisphosphate at 60 min but not 10 min. Addition of peptidase inhibitors did not significantly affect KCl-stimulated PI hydrolysis. The KCl-stimulated response was still observed in the absence of extracellular calcium, although the net accumulation of inositol phosphates was greater in the presence of 0.1 or 0.5 mM calcium. KCl (48 mM) inhibited [³H]inositol uptake into phospholipids of cortical slices. The dihydropyridine calcium channel agonist BAY K 8644 stimulated PI hydrolysis in cortical slices in a concentration dependent manner in the presence of 19 mM KCl. The BAY K 8644-stimulated PI response was partially inhibited by 1M atropine but not by 1M prazosin. Calcium channel blockers nitrendipine, verapamil, flunarizine, and nifedipine slightly inhibited the PI response stimulated by 19 mM KCl in the presence or absence of BAY K 8644. The effects of the calcium channel antagonists were attenuated in the presence of 1 M atropine. The peptide calcium channel blocker -conotoxin did not affect KCl-stimulated PI hydrolysis. These results suggest that endogenous muscarinic or adrenergic neurotransmitters are not involved in KCl-stimulated PI hydrolysis in cortical slices. Although extracellular calcium is necessary for optimal KCl-stimulated PI hydrolysis, it is not required for the expression of the KCl-evoked response suggesting that depolarization is the primary trigger for this stimulant.