Grayanotoxin-I-modified eel electroplax sodium channels. Correlation with batrachotoxin and veratridine modifications.

To probe the structure-function relationships of voltage-dependent sodium channels, we have been examining the mechanisms of channel modification by batrachotoxin (BTX), veratridine (VTD), and grayanotoxin-I (GTX), investigating the unifying mechanisms that underlie the diverse modifications of this class of neurotoxins. In this paper, highly purified sodium channel polypeptides from the electric organ of the electric eel were incorporated into planar lipid bilayers in the presence of GTX for comparison with our previous studies of BTX (Recio-Pinto, E., D. S. Duch, S. R. Levinson, and B. W. Urban. 1987. J. Gen. Physiol. 90:375-395) and VTD (Duch, D. S., E. Recio-Pinto, C. Frenkel, S. R. Levinson, and B. W. Urban. 1989. J. Gen. Physiol. 94:813-831) modifications. GTX-modified channels had a single channel conductance of 16 pS. An additional large GTX-modified open state (40-55 pS) was found which occurred in bursts correlated with channel openings and closings. Two voltage-dependent processes controlling the open time of these modified channels were characterized: (a) a concentration-dependent removal of inactivation analogous to VTD-modified channels, and (b) activation gating similar to BTX-modified channels, but occurring at more hyperpolarized potentials. The voltage dependence of removal of inactivation correlated with parallel voltage-dependent changes in the estimated K1/2 of VTD and GTX modifications. Ranking either the single channel conductances or the depolarization required for 50% activation, the same sequence is obtained: unmodified > BTX > GTX > VTD. The efficacy of the toxins as activators follows the same ranking (Catterall, W. A. 1977. J. Biol. Chem. 252:8669-8676).     

The Shibata Shift and the Transformation of Etioplasts to Chloroplasts in Wheat with Clomazone (FMC 57020) and Amiprophos-Methyl (Tokunol M)

The Shibata shift is a change in the absorption maximum of chlorophyllide from 684 to 672 nanometers that occurs within approximately 0.5 hour of phototransformation of protochlorophyllide to chlorophyllide. Two compounds, clomazone and amiprophos-methyl, which previously have been shown to inhibit the Shibata shift in vivo, were used to look for correlations between the Shibata shift and other processes that occur during etioplast to chloroplast transformation. Leaf sections from 6-day-old etiolated wheat seedlings (Triticum aestivum L. cv Walde) were treated with 0.5 millimolar clomazone or 0.1 millimolar amiprophos-methyl in darkness. In addition to the Shibata shift, the esterification of chlorophyllide to chlorophyll and the relocation of protochlorophyllide reductase from the prolamellar bodies to the developing thylakoids were inhibited by these treatments. Prolamellar body transformation did not appear to be affected by amiprophos-methyl and was only slightly affected by clomazone. The results indicate that: (a) there is a strong correlation between the occurrence of the Shibata shift and esterification activity; (b) transformation of the prolamellar bodies does not depend on the Shibata shift; and (c) the occurrence of the Shibata shift may be a prerequisite to the relocation of protochlorophyllide reductase from prolamellar bodies to thylakoids.     

Effect of capsaicin and resiniferatoxin on peptidergic neurons in cultured dorsal root ganglion.

The neurotoxic effect of capsaicin has been shown to be selective on a subpopulation of small dorsal root ganglion neurons in newborn animals. The aim of this study was to provide evidence of the long lasting effect of capsaicin and its ultrapotent analog resiniferatoxin (RTX) on sensory peptidergic neurons maintained in organotypic cultures. The effects of the two irritants were examined on neurons that contained substance P (SP) and calcitonin gene-related peptide (CGRP). Exposure of the cultures to 10 microM capsaicin and 100 nM RTX for periods of 2 days or longer resulted in almost complete elimination of SP-immunoreactive (IR) neurites and reduction, but not elimination, of CGRP-IR neurites. In addition, both 10 microM capsaicin and 100 nM RTX significantly reduced the number of SP- and CGRP-IR cell bodies within DRG explants. Capsaicin in 100 microM concentration produced complete elimination of SP-IR fibers and a greater decrease in the number of CGRP-IR fibers, but failed to completely eliminate IR cell bodies. Exposure of the cultures to the irritants in the same concentrations for 90 min did not produce a measurable effect on SP- or CGRP-IR in neurites or cell bodies. It is important to establish that the effect of capsaicin and RTX on cultured neurons was of long duration (longer than 4 days) and is therefore different from depletion of peptides. These findings demonstrate that processes of cultured sensory neurons are much more sensitive to capsaicin and RTX than cell bodies. Furthermore, our results show that SP-IR neuronal elements are more sensitive to capsaicin than CGRP-IR elements. These data suggest that cultured sensory neurons express the functional properties of differentiated sensory neurons in vivo.     

Cytokines: making the right choice

Fred Finkelmon and Joseph Urban propose that optimal host defense against different classes of parasite depends upon induction of different sets of immune effector mechanisms, which are, in turn, dependent upon secretion of different sets of cytokines. The authors suggest that hosts identify characteristics common to parasites of a given type as those triggers that stimulate secretion of the proper cytokine set.     

Correlation of chromatin composition with metabolic changes in nuclei of primitive erythroid cells from chicken embryos

Changes in levels of biosynthesis of DNA, RNA, and histones were compared with relative proportions of each histone class during primitive erythropoiesis in embryonic chicks. We confirmed that erythrocyte-specific histone 5 (H5) was substantial in the earliest accessible, erythroblast-enriched stage and that it doubled in relative amount between polychromatic and orthochromatic stages to about 1 mol per 2 mol of each nucleosomal histone, still considerable less than in adult definitive erythrocytes. No other histones changed during primitive erythropoiesis, but the molar proportion of histone 1 (H1) always exceeded that of H5 in these cells, unlike definitive erythrocytes. The increase in content of H5 was accompanied by continued decline in synthesis of the other histones and DNA. The accumulation of H5 during development appears to occur in steps corresponding to the maturation of the primitive and definitive erythroid cell lines. Lysine-rich histones were more easily extracted from nuclei of the erythrosynthesis in whole cells and in isolated nuclei.     

Triphasic effect of prostaglandins E1, E2 and F2α on the fluid transport of isolated gall-bladder of guinea-pigs

Prostaglandins (PGs) F_2α, E₁ and E₂ exerted a triphasic influence on the fluid transport of isolated guinea-pig gall-bladders, when applied to the serosal side. PGE₁ and PGE₂ produced these effects in lower concentrations than F_2α. Directly after PG addition to the serosal side a short stimulation of fluid transport to between 200 and 400% was observed. The stimulatory effect of PGs was most distinct in gall-bladders from female guinea-pigs, less pronounced in male and nearly absent in pregnant animals. Since PGs increased intraluminal hydrostatic pressure in gall-bladders by contraction of the smooth muscle, experiments were performed in which hydrostatic pressure was increased by different procedures. These included the addition of imidazole (10⁻² M), raising of K⁺ in the bathing solution and an increase in intraluminal pressure by addition of Ringer's solution into the lumen. All three procedures stimulated fluid reabsorption temporarily in the same way as PGs, hence increase of intraluminal pressure is thought to be the reason for the observed temporary stimulation of fluid transport. Direct evidence for this thesis was obtained when the gall-bladder was mounted as a flat sheet over a chamber; in this preparation no stimulation of fluid transport was obtained. The second phase of the PG influence was characterized by a concentration-related inhibition of fluid reabsorption followed by a significant but small reverse of fluid transport (secretion of fluid). When PGs were applied to the mucosal side, only an inhibition of fluid transport was observed, which was much weaker compared to the addition to the serosal side.     

Mechanisms and cellular functions of intramembrane proteases

The turn of the millennium coincided with the branding of a fundamentally different class of enzyme - proteases that reside immersed inside the membrane. This new field was the convergence of completely separate lines of research focused on cholesterol homeostasis, Alzheimer's disease, and developmental genetics. None intended their ultimate path, but soon became a richly-integrated fabric for an entirely new field: regulated intramembrane proteolysis. Our aim in this Special Issue is to focus on the ancient and nearly ubiquitous enzymes that catalyze this unexpected yet important reaction. The pace of progress has been dramatic, resulting in a rapidly-expanding universe of known cellular functions, and a paradigm shift in the biochemical understanding of these once heretical enzymes. More recently, the first therapeutic successes have been attained by targeting an intramembrane protease. We consider these advances and identify oncoming opportunities in four parts: growing spectra of cellular roles, insights into biochemical mechanisms, therapeutic strategies, and newly-emerging topics. Recent studies also expose challenges for the future, including non-linear relationships between substrate identification and physiological functions, and the need for potent and specific, not broad-class, inhibitors.