Oxygen: a master regulator of pancreatic development?

Beyond its role as an electron acceptor in aerobic respiration, oxygen is also a key effector of many developmental events. The oxygen‐sensing machinery and the very fabric of cell identity and function have been shown to be deeply intertwined. Here we take a first look at how oxygen might lie at the crossroads of at least two of the major molecular pathways that shape pancreatic development. Based on recent evidence and a thorough review of the literature, we present a theoretical model whereby evolving oxygen tensions might choreograph to a large extent the sequence of molecular events resulting in the development of the organ. In particular, we propose that lower oxygenation prior to the expansion of the vasculature may favour HIF (hypoxia inducible factor)‐mediated activation of Notch and repression of Wnt/β‐catenin signalling, limiting endocrine cell differentiation. With the development of vasculature and improved oxygen delivery to the developing organ, HIF‐mediated support for Notch signalling may decline while the β‐catenin‐directed Wnt signalling is favoured, which would support endocrine cell differentiation and perhaps exocrine cell proliferation/differentiation.     

Studies on Analogues of Succinic Semialdehyde as Substrates for Succinate Semialdehyde Dehydrogenase from Rat Brain

The methyl ester of succinic semialdehyde (SSA) was examined as a substrate for succinate semialdehyde dehydrogenase (SSADH) from rat brain. It was found that the ester can be oxidized by the enzyme. Values of Km for SSA-Me were higher than for those for SSA, and for this substrate the enzyme showed a substrate-dependent inhibition. This finding suggests that the carboxylate group of SSA is not essential in the process of inhibition of SSADH by the substrate. Cyclopropyl analogues of SSA, cis- and trans-1-formyl-cyclopropan-2-carboxylic acids, were also individually tested as substrates of SSADH. Only the trans isomer was found to be oxidized to the corresponding dicarboxylic acid; it inhibited the enzyme in the same range of concentrations as SSA. The above data suggest that, as for gamma-aminobutyric acid, SSA is present in an unfolded, transoid conformation at the active site of SSADH.     

Is the C-terminal arm of lens gap junction channel protein the channel gate?

Lens gap junction channels are studied in a reconstituted system obtained by incorporating into liposomes, with or without calmodulin, the lens junction protein (MIP26) and its trypsin-cleaved product (MIP21) that lacks the C-terminal arm. Channel permeability is studied with an osmotic swelling assay. MIP26 and MIP21 liposomes swell in sucrose or polyethyleneglycol with or without Ca++ indicating the presence of large channels. Without Ca++, MIP26 and MIP21 liposomes swell in both permeants. With Ca++, MIP26-calmodulin liposomes do not swell in either permeant, indicating complete channel closure, while MIP21-calmodulin liposomes swell in sucrose but not in polyethyleneglycol. This suggests that the C-terminal arm participates in channel gating.     

Lens cell-to-cel channel protein: II. Conformational change in the presence of calmodulin

Summary Lens fibers are coupled by communicating junctions, clusters of cell-to-cell channels composed of a 28-kD intrinsic membrane protein (MIP26). Evidence suggests that these and other cell-to-cell channels may close as a result of protein conformational change induced by activated calmodulin. To test the validity of this hypothesis, we have measured the intrinsic fluorescence emission and far-ultraviolet circular dichroism of the isolated components MIP26, calmodulin, and the MIP26-calmodulin complex, both in the absence and presence of Ca⁺⁺, an uncoupling agent. MIP26 shows no change in either, fluorescence emission (primarily tryptophan and a measure of aromatic constitutivity) or in its circular dichroism spectrum. Calmodulin exhibits a 32% increase in fluorescence emission intensity with constant emission wavelength, entirely tyrosine, and a 44% increase in -helicity, changes previously described. The MIP26-calmodulin complex, on the other hand, displays fluorescence emission and circular dichroism spectra which are slightly different from the sum of the two single components, but shows marked differences in both spectra upon Ca⁺⁺ addition. This indicates a change in conformation in one or both of the two components. Spectral changes include a 5-nm blue-shift, a 50% increase in tyrosine fluorescene emission, a 25% decrease in tryptophan fluorescence emission, and a 5% increase in the -helicity of the complex. These changes also occur about an isosbestic point and are fully reversible. These data provide additional evidence that activated calmodulin may modulate gating of cell-to-cell channels by affecting channel protein.     

Communicating junctions and calmodulin: Inhibition of electrical uncoupling inXenopus embryo by calmidazolium

Summary This paper reports the inhibitory effects of calmidazolium (CDZ), a calmodulin inhibitor, on electrical uncoupling by CO₂. Membrane potential and coupling ratio (V ₂/V₁) are measured in two neighboring cells ofXenopus embryos (16 to 64 cell stage) for periods as long as 5.5 hr. Upon exposure to 100% CO₂, control cells consistently uncouple even if the CO₂ treatments are repeated every 15 min for 2.5 hr. CDZ (5×10^–8–1×10^–7 m) strongly inhibits uncoupling. The inhibition starts after 30, 50 and 60 min of treatment with 1×10^–7, 7×10^–8 and 5×10^–8 m CDZ, respectively, is concentration-dependent and partially reversible. In the absence of CO₂, CDZ also improves electrical coupling. CDZ has no significant effect on membrane potential and nonjunctional membrane resistance. These data suggest that calmodulin or a calmodulin-like protein participates in the uncoupling mechanism.     

Effects of caffeine and raynodine on low pHi-induced changes in gap junction conductance and calcium concentration in crayfish septate axons

Summary Electrical uncoupling of crayfish septate axons with acidification has been shown to cause a substantial increase in [Ca²⁺]_i which closely matches in percent the increase in junctional resistance. To determine the origin of [Ca²⁺]_i increase, septate axons have been exposed either to drugs that influence Ca²⁺ release from internal stores, caffeine and ryanodine, or to treatments that affect Ca²⁺ entry. A large increase in junctional resistance and [Ca²⁺]_i maxima above controls resulted from addition of caffeine (10–30mm) to acetate solutions, while a substantial decrease in both parameters was observed when exposure to acetate-caffeine was preceded by caffeine pretreatment. In contrast, ryanodine (1–10 m) always caused a significant decrease in junctional resistance and [Ca²⁺]_i maxima when applied either together with acetate or both before and with acetate. Calcium channel blockers such as La³⁺, Cd²⁺ and nisoldipine had no effect, while an increase in the [Ca²⁺] of acetate solutions either decreased junctional resistance and [Ca²⁺]_i maxima or had no effect. The data suggest that cytoplasmic acidification causes an increase in [Ca²⁺]_i by releasing Ca²⁺ from caffeine and ryanodine-sensitive Ca²⁺ stores. The increase in [Ca²⁺]_i results in a decrease in gap junction conductance.     

Drought signal transduction in plants

Water deficit is one of the most common environmental limitations of crop productivity by affecting growth through alterations in metabolism and gene expression. The mechanisms involved in drought perception and signal transduction pathways are poorly understood. The participation of the plant hormone abscisic acid (ABA) has been well established. ABA levels increase when there are changes in the environment that result in cellular dehydration. Different approaches have been taken to understanding the molecular responses to desiccation and how ABA regulates gene expression. Recent efforts have identified particular topics of importance in the dissection of the signal transduction pathway which are summarized as follows: physiological approaches: identification of signalling molecules. Genetic approaches: the use of mutants, and Molecular approaches: promoter analysis.     

Competition between electron acceptors in photosynthesis: Regulation of the malate valve during CO2 fixation and nitrite reduction

For maximal rates of CO₂ assimilation in isolated intact spinach chloroplasts the generation of the adequate NADPH/ATP ratio is achieved either by cyclic electron flow around photosystem I or by linear electron transport to oxaloacetate, nitrite or oxygen (Mehler-reaction). The interrelationships between these poising mechanisms turn out to be strictly hierarchical. In the presence of antimycin A, an inhibitor of ferredoxin-dependent cyclic electron transport, the reduction of both, oxaloacetate and nitrite, but not that of oxygen restores CO₂ fixation. When oxaloacetate and nitrite are added at low concentrations simultaneously during steady-state CO₂ fixation, the reduction of nitrite is clearly preferred over the reduction of oxaloacetate, but CO₂ fixation is not influenced. Nitrite reduction is not decreased upon addition of oxaloacetate, but vice versa. This is due to the regulation of NADP-malate dehydrogenase activation by electron pressure via the ferredoxin/thioredoxin system on the one hand, and by the NADPH/(NADP+NADPH) ratio (anabolic reduction charge, ARC) on the other hand. Thus the closing of the malate valve prevents drainage of reducing equivalents from the chloroplast (1) when a low ARC indicates a high demand for NADPH in the stroma and (2) when nitrite reduction reduces the electron pressure at ferredoxin. The malate valve is opened when cyclic electron transport is inhibited by antimycin A. Under these conditions the rate of malate formation is higher than in the absence of the inhibitor even in the presence of oxaloacetate, thus indicating that the regulation of the malate valve functions at various redox states of the acceptor side of Photosystem I.Abbreviations ARC anabolic reduction charge (NADPH/(NADP+NADPH)) - Chl chlorophyll - DTT dithiothreitol; Fd-ferredoxin - NADP-MDH NADP-malate dehydrogenase - OAA oxaloacetate - PS photosystem - qN non-photochemical quenching - qP photochemical quenching - _E quantum efficiency of PS II Dedicated to Prof. Dr. Hans Walter Heldt on the occasion of his 60th birthday.     

Gap junction structure and cell-to-cell coupling regulation: is there a calmodulin involvement?

In most tissues neighboring cells communicate directly with each other by exchanging ions and small metabolites via cell-to-cell channels located at the intermembrane particles of gap junctions. Evidence indicates that the channels close when the [Ca2+]i or [H+]i increases. The channel occlusion (cell-to-cell uncoupling) is mainly a safety device by which cells can isolate themselves from damaged neighboring cells ("healing-over" process). Despite our knowledge of uncoupling agents, the uncoupling mechanism is still poorly understood. Uncoupling treatments have been shown to cause structural changes in gap junctions, characterized by an increase in tightness and regularity (crystallization) of particle packing and a decrease in particle size. Recently these changes have been shown to be induced by Ca2+ or H+ in isolated lens junctions and by Ca2+ in liver junctions, which suggests a close relationship between structural changes and uncoupling, but preliminary studies indicate that the junctional changes may not be synchronous with uncoupling but may lag behind it. However, recent X-ray diffraction data show that the channels of crystalline gap junctions (typical of uncoupled cells) are indeed closed, because they are inaccessible to sucrose (a gap junction permeant). Thus it seems that crystalline junctions are indeed in a non-permeable state, but the occlusion of the channels may precede the crystallization process. In the lens, junction crystallization is inhibited by a calmodulin (CaM) inhibitor, trifluoperazine (TFP). Is CaM involved in the uncoupling mechanism? To test this hypothesis, TFP and calmidazolium (CDZ), the most specific CaM inhibitor, were used on amphibian embryonic cells electrically uncoupled by CO2. Both TFP and CDZ effectively protect the cells from uncoupling, which suggests that CaM participates in the process. As a hypothesis, we propose that channel occlusion follows a CaM-mediated conformational change in the junctional protein. Particle crystallization may follow the conformational changes and result from a modification in electrostatic repulsion among the particles.     

Effects of the anesthetics heptanol,halothane and isoflurane on gap junction conductance in crayfish septate axons: A calcium- and hydrogen-independent phenomenon potentiated by caffeine and theophylline,and inhibited by 4-aminopyridine

Summary This study has monitored junctional and nonjunctional resistance. [Ca²⁺] _i and [H^–] _i , and the effects of various drugs in crayfish septate axons exposed to neutral anesthetics. The uncoupling efficiency of heptanol and halothane is significantly potentiated by caffeine and theophylline. The modest uncoupling effects of isoflurane, described here for the first time, are also enhanced by caffeine. Heptanol causes a decrease in [Ca²⁺] _i and [H⁺] _i both in the presence and absence of either caffeine or theophylline. A similar but transient effect on [Ca²⁺] _i is observed with halothane. 4-Aminopyridine strongly inhibits the uncoupling effects of heptanol. The observed decrease in [Ca^2–] _i with heptanol and halothane and negative results obtained with different [Ca²⁺] _o , Ca²⁺-channel blockers (nisoldipine and Cd²⁺) and ryanodine speak against a Ca²⁺ participation. Negative results obtained with 3-isobutyl-l-methylxanthine, forskolin, CPT-cAMP, 8Br-cGMP, adenosine, phorbol ester and H7, superfused in the presence and absence of caffeine and/or heptanol. indicate that neither the heptanol effects nor their potentiation by caffeine are mediated by cyclic nucleotides, adenosine receptors and kinase C. The data suggest a direct effect of anesthetics. possibly involving both polar and hydrophobic interactions with channel proteins. Xanthines and 4-aminopyridine may participate by influencing polar interactions. The potentiating effect of xanthines on cell-to-cell uncoupling by anesthetics may provide some clues on the nature of cardiac arrhythmias in patients treated with theophylline during halothane anesthesia.