Hemoglycin visible fluorescence induced by x rays.

Hemoglycin, a 1494 Da polymer composed of iron and glycine, has been detected in several carbonaceous meteorites. Iron atoms close out the ends of a 5 nm anti-parallel glycine beta sheet and contribute visible and near infrared absorptions that are not present with glycine alone. The 483 nm absorption of hemoglycin was discovered in theory and then observed on beamline I24 at Diamond Light Source. Light absorption in a molecule involves a coupled lower set of states receiving light energy that causes a transition into an upper set of states. In the reverse process, some energy source, such as an x-ray beam, populates the upper set of molecular states, which then radiates light as it returns to the lower "ground" set of states. We report on visible light re-emission during x-ray irradiation of a hemoglycin crystal. The emission is dominated by bands centered at 489 and 551 nm.

Direct drive with the argon fluoride laser as a path to high fusion gain with sub-megajoule laser energy.

Argon fluoride (ArF) is currently the shortest wavelength laser that can credibly scale to the energy and power required for high gain inertial fusion. ArF's deep ultraviolet light and capability to provide much wider bandwidth than other contemporary inertial confinement fusion (ICF) laser drivers would drastically improve the laser target coupling efficiency and enable substantially higher pressures to drive an implosion. Our radiation hydrodynamics simulations indicate gains greater than 100 are feasible with a sub-megajoule ArF driver. Our laser kinetics simulations indicate that the electron beam-pumped ArF laser can have intrinsic efficiencies of more than 16%, versus about 12% for the next most efficient krypton fluoride excimer laser. We expect at least 10% 'wall plug' efficiency for delivering ArF light to target should be achievable using solid-state pulsed power and efficient electron beam transport to the laser gas that was demonstrated with the U.S. Naval Research Laboratory's Electra facility. These advantages could enable the development of modest size and lower cost fusion power plant modules. This would drastically change the present view on inertial fusion energy as being too expensive and the power plant size too large. This article is part of a discussion meeting issue 'Prospects for high gain inertial fusion energy (part 1)'.

Opposing actions of cGMP and calcium on the conductance of the F(0) subunit c pore.

Subunit c of ATP synthase can be purified from neuronal plasma membrane and from the inner mitochondrial membrane. In the latter location the hydrophobic 75 amino acid protein is one component of the F(1) F(0) ATP synthase complex but in the former it is alone as a pore that is capable of generating spontaneous electrical oscillations. Pure mammalian subunit c when reconstituted in lipid bilayers and voltage clamped, yields a voltage sensitive pore that conducts a cation current regulated by calcium. The current is here found to be activated by cGMP with a K(M) ranging from 14 nM to 19 microM depending on calcium and temperature. It is sensitively inhibited by a number of ligands. The K(I) for calcium ranges from 100 nM to 100 microM depending on cGMP and temperature. DCCD inhibits with a K(app) of 100 nM. The polyamine nicotine inhibits at 84 nM. The pore has properties that would allow it to deliver sodium or calcium through the cell membrane in a controlled manner while maintaining membrane polarization.

Biological-to-electronic interface with pores of ATP synthase subunit C in silicon nitride barrier.

An oscillator pore is identified that generates intermittent, large amplitude, ionic current in the plasma membrane. The pore is thought to be composed of 10-12 units of subunit c of ATP synthase. Pore opening and closing is a co-operative process, dependent on the release, or binding, of as many as six calcium ions. This mechanism suggests a more general method of co-operative threshold detection of chemical agents via protein modification, the output being directly amplified in a circuit. Here the authors describe steps in the development of a sensor of chemical agents. The subunit c pore in a lipid bilayer spans a nanometer-scale hole in a silicon nitride barrier. Either side of the barrier are electrolyte solutions and current through the pore is amplified by circuitry. The techniques of laser ablation, electron beam lithography and ion beam milling are used to make successively smaller holes to carry the lipid patch. Holes of diameter as small as 20 nm are engineered in a silicon nitride barrier and protein activity in lipid membranes spanning holes as small as 30 nm in diameter is measured. The signal-to-noise ratio of the ionic current is improved by various measures that reduce the effective capacitance of the barrier. Some limits to scale reduction are discussed.

Eye CNG channel is modulated by nicotine.

The cyclic-nucleotide gated channel (CNG channel) of the rod outer segment of the retina (ROS) has its closed conformation stabilized by nicotine. Calcium and cGMP influence the Ki of the channel current to nicotine. Calcium lowers the Ki and cGMP increases it, giving a range of Ki between 10(-11) and 10(-8) M.

Power spectra and cooperativity of a calcium-regulated cation channel.

In this article we show that a channel complex of cooperatively interacting subunits can produce a power law spectrum with the slope of the spectrum depending on the strength of the cooperative interaction. The effects of cooperativity are explored via a computational model of a calcium-regulated cation channel for which new data is presented. The results, which concern "flickering" conductances, are correlated with prior work on critical fluctuations in the Ising model of ferromagnetism.