Numerical simulation of local calcium movements during L-type calcium channel gating in the cardiac diad.

Computer simulation was used to investigate the calcium levels after sarcolemmal calcium influx through L-type calcium channels (DHPRs) into the narrow diadic space of cardiac muscle. The effect of various cytosolic and membranebound buffers, diad geometry, DHPR properties (open time and current), and surface charge were examined. The simulations showed that phospholipid binding sites on the sarcolemmal membrane are the major buffer affecting free calcium ([Ca2+]) levels in the diad. The inclusion of surface charge effects calculated from Gouy-Chapman theory resulted in a marked decrease in [Ca2+] levels at all times and a faster decay of [Ca2+] after termination of DHPR influx. For a DHPR current of 200 fA, [Ca2+] at the center of the diad reached peak levels of approximately 73 microM. In larger diads (> or = 400 nm diameter), [Ca2+] decayed more slowly than in smaller diads (100-200 nm diameter), although peak [Ca2+] levels reached during typical DHPR open times were similar. For a wide range of DHPR single-channel current magnitudes (Ica = 25-200 fA), [Ca2+] levels in the diad were approximately proportional to ICa. The decrease in calculated [Ca2+] levels due to the effects of surface charge can be interpreted as resulting from an effective "volume expansion" of the diad space. Furthermore, the layer of increased [Ca2+] close to the sarcolemmal membrane can act as a fast buffer.     

The influence of auxins on transformation of wheat and tritordeum and analysis of transgene integration patterns in transformants

 Although it is possible to transform wheat, broad application of the technology is limited because of the low overall efficiency and the lack of reliability of the technique. In addition there is little published data on transgene integration patterns and inheritance in wheat. We have generated a population of transgenic wheat and tritordeum lines under different auxin regimes and show that, under the conditions described, the presence of picloram results in higher transformation efficiencies than the presence of 2,4-D. Molecular analysis shows low-copy numbers and simple integration patterns to be prevalent in the transgenic lines. Mendelian inheritance of transgenes in T ₁ progeny was observed for the majority of lines. Received: 2 December 1997 / Accepted: 12 March 1998     

Soil Carbon Storage Response to Temperature: an Hypothesis

Recently, global and some regional observations of soil carbonstocks and turnover times have implied that warming may notdeplete soil carbon as much as predicted by ecosystem models.The proposed explanation is that microbial respiration of carbonin ‘old’ mineral pools is accelerated less by warmingthan ecosystem models currently assume. Data on the sensitivityof soil respiration to temperature are currently conflicting.An alternative or additional explanation is that warming increasesthe rate of physico-chemical processes which transfer organiccarbon to ‘protected’, more stable, soil carbonpools. These processes include adsorption reactions, some ofwhich are known to have positive activation energies. Theoretically,physico-chemical reactions may be expected to respond more towarming than enzyme-mediated microbial reactions. A simple analyticalmodel and a complex multi-pool soil carbon model are presented,which separate transfers between pools due to physico-chemicalreactions from those associated with microbial respiration.In the short-term, warming depletes soil carbon. But in thelong-term, carbon losses by accelerated microbial respirationare offset by increases in carbon input to the soil (net production)and any acceleration of soil physico-chemical ‘stabilization’reactions. In the models, if net production rates are increasedin response to notional warming by a factor of 1.3, and microbialrespiration (in all pools) by 1.5, then soil carbon at equilibriumremains unchanged if physico-chemical reactions are acceleratedby a factor of about 2.2 (50% more than microbial reactions).Equilibrium soil carbon increases if physico-chemical reactionsare over 50% more sensitive to warming than soil respiration.Copyright 2001 Annals of Botany Company Soil organic matter, carbon, respiration, temperature, stabilization, decomposition, model     

Inhibition of tubulin assembly and covalent binding to microtubular protein by valproic acid glucuronide in vitro

Acyl glucuronides are reactive metabolites of carboxylate drugs, able to undergo a number of reactions in vitro and in vivo, including isomerization via intramolecular rearrangement and covalent adduct formation with proteins. The intrinsic reactivity of a particular acyl glucuronide depends upon the chemical makeup of the drug moiety. The least reactive acyl glucuronide yet reported is valproic acid acyl glucuronide (VPA-G), which is the major metabolite of the antiepileptic agent valproic acid (VPA). In this study, we showed that both VPA-G and its rearrangement isomers (iso-VPA-G) interacted with bovine brain microtubular protein (MTP, comprised of 85% tubulin and 15% microtubule associated proteins {MAPs}). MTP was incubated with VPA, VPA-G and iso-VPA-G for 2 h at room temperature and pH 7.5 at various concentrations up to 4 mM. VPA-G and iso-VPA-G caused dose-dependent inhibition of assembly of MTP into microtubules, with 50% inhibition (IC₅₀) values of 1.0 and 0.2 mM respectively, suggesting that iso-VPA-G has five times more inhibitory potential than VPA-G. VPA itself did not inhibit microtubule formation except at very high concentrations (≥2 mM). Dialysis to remove unbound VPA-G and iso-VPA-G (prior to the assembly assay) diminished inhibition while not removing it. Comparison of covalent binding of VPA-G and iso-VPA-G (using [¹⁴C]-labelled species) showed that adduct formation was much greater for iso-VPA-G. When [¹⁴C]-iso-VPA-G was reacted with MTP in the presence of sodium cyanide (to stabilize glycation adducts), subsequent separation into tubulin and MAPs fractions by ion exchange chromatography revealed that 78 and 22% of the covalent binding occurred with the MAPs and tubulin fractions respectively. These experiments support the notion of both covalent and reversible binding playing parts in the inhibition of microtubule formation from MTP (though the acyl glucuronide of VPA is less important than its rearrangement isomers in this regard), and that both tubulin and (perhaps more importantly) MAPs form adducts with acyl glucuronides.     

Quantifying changes in gap junction structure as a function of lens fiber cell differentiation

The ocular lens is an ideal model system for studying gap junction structure-function relationships. Here we apply novel methods to quantitatively compare connexin expression over macroscopic distances while simultaneously resolving the intracellular distribution of gap junctions in sub-micron detail. Our approach has identified three distinct zones of connexin density and allowed changes in gap junction plaque size, number and dispersion to be quantified. Our analysis is the first to precisely correlate changes in gap junction plaque structure with the reported changes in gap junction function that occur as a consequence of fiber cell differentiation.     

Ryanodine block of calcium oscillations in heart muscle and the sodium-tension relationship

The control of tension is examined in cardiac Purkinje fibers. We show, in accordance with earlier results (14, 15), that tension produced by this preparation is a steep power function of intracellular sodium. With the aid of ryanodine, a pharmacological agent that blocks spontaneous and spatially asynchronous calcium release from the sarcoplasmic reticulum (SR), we investigate the influence that such calcium fluctuations have on tension. We find that even when we control for alterations of intracellular pH, the presence of such fluctuations reduces the dependence of tension on intracellular sodium. We present a simple model that can explain how the presence of oscillations of intracellular calcium leads to a reduction of the slope of the tension-calcium relationship. We show, furthermore, that when the oscillations are spatially asynchronous, this reduction of slope is even greater. The modeling takes account of the known relationships between tension and calcium and tension and sarcomere length. We conclude that the effect of ryanodine to steepen the tension-sodium relationship can be explained by ryanodine's blocking calcium release from the SR, thereby abolishing oscillations of intracellular calcium.