Heme oxygenase-1 (HO-1), a stress-inducible enzyme anchored in the endoplasmic reticulum (ER) by a single transmembrane segment (TMS) located at the C terminus, interacts with NADPH cytochrome P450 reductase and biliverdin reductase to catalyze heme degradation to biliverdin and its metabolite, bilirubin. Previous studies suggested that HO-1 functions as a monomer. Using chemical cross-linking, co-immunoprecipitation, and fluorescence resonance energy transfer (FRET) experiments, here we showed that HO-1 forms dimers/ oligomers in the ER. However, oligomerization was not observed with a truncated HO-1 lacking the C-terminal TMS (amino acids 266 -285), which exhibited cytosolic and nuclear localization, indicating that the TMS is essential for the selfassembly of HO-1 in the ER. To identify the interface involved in the TMS-TMS interaction, residue Trp-270, predicted by molecular modeling as a potential interfacial residue of TMS ␣-helices, was mutated, and the effects on protein subcellular localization and activity assessed. The results showed that the W270A mutant was present exclusively in the ER and formed oligomers with similar activity to those of the wild type HO-1. Interestingly, the W270N mutant was localized not only in the ER, but also in the cytosol and nucleus, suggesting it is susceptible to proteolytic cleavage. Moreover, the microsomal HO activity of the W270N mutant was significantly lower than that of the wild type. The W270N mutation appears to interfere with the oligomeric state, as revealed by a lower FRET efficiency. Collectively, these data suggest that oligomerization, driven by TMS-TMS interactions, is crucial for the stabilization and function of HO-1 in the ER.Heme oxygenase (HO) 3 catalyzes the NADPH cytochrome P450 reductase-dependent oxidative degradation of cellular heme to biliverdin, carbon monoxide (CO), and free iron (1, 2). Biliverdin is subsequently converted to bilirubin by biliverdin reductase in the cytosol. Two HO isoforms have been identified in mammalian systems. HO-1 is a 288 amino acid protein and is expressed at high amounts in a variety of pathological conditions associated with cellular stress. There is compelling evidence that HO-1 induction represents an important cytoprotective defense mechanism against oxidative insults by virtue of the anti-oxidant properties of the bilirubin and the anti-inflammatory effect of the CO produced (2). HO-1 is anchored in the endoplasmic reticulum (ER) through a single transmembrane segment (TMS) located at the C terminus, while the rest of the molecule is cytoplasmic (3). HO-1 is sensitive to proteolytic cleavage (4), and it was recently shown that HO-1 can be proteolytically cleaved from the ER and translocated to the nucleus under certain stress conditions (5). Although the catalytic site in the cytoplasmic domain remains intact, the activity of soluble HO-1 is drastically reduced (5), indicating that ER localization is important for its full enzymatic function.Self-assembly to form dimers and higher oligomers is a common pheno...
The unusual rate and extent of environmental changes due to human activities may exceed the capacity of marine organisms to deal with this phenomenon. The identification of physiological systems that set the tolerance limits and their potential for phenotypic buffering in the most vulnerable ontogenetic stages become increasingly important to make large-scale projections. Here, we demonstrate that the differential sensitivity of non-calcifying Ambulacraria (echinoderms and hemichordates) larvae towards simulated ocean acidification is dictated by the physiology of their digestive systems. Gastric pH regulation upon experimental ocean acidification was compared in six species of the superphylum Ambulacraria. We observed a strong correlation between sensitivity to ocean acidification and the ability to regulate gut pH. Surprisingly, species with tightly regulated gastric pH were more sensitive to ocean acidification. This study provides evidence that strict maintenance of highly alkaline conditions in the larval gut of Ambulacraria early life stages may dictate their sensitivity to decreases in seawater pH. These findings highlight the importance of identifying and understanding pH regulatory systems in marine larval stages that may contribute to substantial energetic challenges under near-future ocean acidification scenarios.
It has been known for more than three decades that outward Kir currents (I K1 ) increase with increasing extracellular K ؉ con- Inward rectifier K ϩ channels (Kir) 3 channels are important in maintaining stable resting membrane potentials, controlling excitability, and shaping the initial depolarization, as well as the final repolarization of action potentials in many cell types, including heart cells (1-6). The physiological functions of Kir channels are closely related to their unique inward rectification mechanism, which allows inward currents to pass through the channel more easily than outward currents (6). Although small, the outward I K1 plays a crucial role in controlling membrane excitability and action potential duration. The gain or loss of outward I K1 in the heart can lead to re-entry or arrhythmia, respectively (7). In contrast to normal conditions, in which the extracellular is increased, the outward I K1 increases, despite a reduction in the electrochemical gradient (1, 11). Accordingly, increases in I K1 result in reduced excitability, slow conductance, and abbreviation of the refractory period, and thereby predispose the heart to re-entrant ventricular arrhythmias, the leading cause of death from coronary artery disease (12). The [K ϩ ] o dependence of the outward I K1 thus might be important for regulating the physiological and pathological functions of the heart. Despite the importance of this long known [K ϩ ] o dependence of the outward I K1 , the underlying mechanism has remained unclear.Previous studies have shown that the dependence of Kir channel activity on membrane potential (V m ) shifts in parallel with V m -E K (1-6), where E K is the equilibrium potential for K ϩ . Thispropertyhasbeenpreviouslyattributedtothedrivingforcedependent block of Kir2.1 channels by intracellular blockers (13,14). According to this hypothesis, known as the blockingparticle model, cytoplasmic blockers are dragged into or pushed out of the channel pore by the outward or inward flux of K ϩ , respectively.
Understanding Na+ uptake mechanisms in vertebrates has been a research priority since vertebrate ancestors were thought to originate from hyperosmotic marine habitats to the hypoosmotic freshwater system. Given the evolutionary success of osmoregulator teleosts, these freshwater conquerors from the marine habitats are reasonably considered to develop the traits of absorbing Na+ from the Na+-poor circumstances for ionic homeostasis. However, in teleosts, the loss of epithelial Na+ channel (ENaC) has long been a mystery and an issue under debate in the evolution of vertebrates. In this study, we evaluate the idea that energetic efficiency in teleosts may have been improved by selection for ENaC loss and an evolved energy-saving alternative, the Na+/H+ exchangers (NHE3)-mediated Na+ uptake/NH4+ excretion machinery. The present study approaches this question from the lamprey, a pioneer invader of freshwater habitats, initially developed ENaC-mediated Na+ uptake driven by energy-consuming apical H+-ATPase (VHA) in the gills, similar to amphibian skin and external gills. Later, teleosts may have intensified ammonotelism to generate larger NH4+ outward gradients that facilitate NHE3-mediated Na+ uptake against an unfavorable Na+ gradient in freshwater without consuming additional ATP. Therefore, this study provides a fresh starting point for expanding our understanding of vertebrate ion regulation and environmental adaptation within the framework of the energy constraint concept.
Background: Cephalopods have evolved strong acid-base regulatory abilities to cope with CO 2 induced pH fluctuations in their extracellular compartments to protect gas transport via highly pH sensitive hemocyanins. To date, the mechanistic basis of branchial acid-base regulation in cephalopods is still poorly understood, and associated energetic limitations may represent a critical factor in high power squids during prolonged exposure to seawater acidification. Results: The present work used adult squid Sepioteuthis lessoniana to investigate the effects of short-term (few hours) to medium-term (up to 168 h) seawater acidification on pelagic squids. Routine metabolic rates, NH 4 + excretion, extracellular acid-base balance were monitored during exposure to control (pH 8.1) and acidified conditions of pH 7.7 and 7.3 along a period of 168 h. Metabolic rates were significantly depressed by 40% after exposure to pH 7.3 conditions for 168 h. Animals fully restored extracellular pH accompanied by an increase in blood HCO 3 − levels within 20 hours. This compensation reaction was accompanied by increased transcript abundance of branchial acid-base transporters including V-type H +-ATPase (VHA), Rhesus protein (RhP), Na + /HCO 3 − cotransporter (NBC) and cytosolic carbonic anhydrase (CAc). Immunocytochemistry demonstrated the sub-cellular localization of Na + /K +-ATPase (NKA), VHA in basolateral and Na + /H +-exchanger 3 (NHE3) and RhP in apical membranes of the ion-transporting branchial epithelium. Branchial VHA and RhP responded with increased mRNA and protein levels in response to acidified conditions indicating the importance of active NH 4 + transport to mediate acid-base balance in cephalopods. Conclusion: The present work demonstrated that cephalopods have a well developed branchial acid-base regulatory machinery. However, pelagic squids that evolved a lifestyle at the edge of energetic limits are probably more sensitive to prolonged exposure to acidified conditions compared to their more sluggish relatives including cuttlefish and octopods.
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