A Nitrate-Inducible Plasma Membrane Protein of a Marine Alga, Heterosigma akashiwo

The rate of nitrate uptake by Heterosigma akashiwo cells thathad been cultured in medium with nitrate or ammonium ions asthe source of nitrogen was measured using¹⁵NO_3– The ratioof ¹⁵N/¹⁴N increased dramatically in nitrate-grown cells. Inammonium-grown cells, the ratio of ¹⁵N/¹⁴N did not increasefor 3 h but then it began to increase. Even when nitrate reductaseactivity was inhibited by tungstate, nitrate-grown cells couldtake up nitrate. Plasma membranes from nitrate-grown and ammonium-grown cellswere purified by the silica-microbead method, and polypeptidesassociated with the membranes were analyzed by SDS-PAGE andimmunostaining. A major polypeptide with a molecular mass of26 kDa appeared 3 h after the transfer of ammonium-grown cellsto nitrate-containing medium, and it disappeared 2 d after thetransfer of nitrate-grown cells to ammonium-containing medium.The 26 kDa polypeptide also appeared when cell growth shiftedfrom the logarithmic phase to the stationary phase and the ammoniumcontent of the medium decreased, even when the cells were culturedin ammonium-containing medium. (Received April 10, 1992; Accepted July 30, 1992)     

Cl- Fluxes and Cl- Content of Dunaliella acidophila--An Alga with a Positive Membrane Potential

The Cl^– fluxes across the plasma membrane and the Cl^–content of the acid–resistant alga Dunaliella acidophila(optimal growthat pH 1.0, positive membrane potential) werestudied in the presence of 0.01–300 mM Cl^–. Up to40 mM Cl^– in the medium, theinternal Cl^– concentrationis higher than that predicted by the electrochemical equilibrium,whereas at higher external Cl^– concentrations internalCl^– levels are lower than expected for the electrochemicalequilibrium. Growth in the absence of Cl^– is significantlylower than in the standard growth medium (2.2 mM Cl^–)and this reduction cannot be overcome by the addition ofothermonovalent anions such as Br^– or NO^–₃ The latterimplies a specific Cl^– requirement in addition to therole of Cl^– as apermeant anion during ion translocations.Growth and photosynthesis tolerate an excess of Cl^– upto 300 mM (without stepwiseadaptation to increasing salinity).The uptake of Cl^– (measured by tracer techniques) exhibitsMichaelis–Menten kinetics (K_M = 0.75 mM Cl^–) andis stimulated by light and high H⁺ concentrations. Internalacidification by acetic acid causes an inhibition of Cl^–uptake. The uptake of Cl^– is inhibited by the monovalentanions Br^–, I^–, and NO^–₃ with K¹, values notvery much different from the K_M. value for Cl^–. The aniontransport inhibitors SITS and DIDS do not affect photosynthesis,but strongly suppressthe uptake of Cl^–. The Cl^–channel blockers A–9–C and NPPB cause inhibitionsof Cl^– uptake as well as of photosynthesis andthe ATPpool. FCCP strongly depresses the internal ATP–pool withouta marked effect on Cl^– uptake. Cl^– efflux was inhibitedbyDIDS and SITS, but stimulated or inhibited by FCCP, dependingon the external Cl^– concentration. Results are in agreementwiththe hypothesis that Cl^– uptake into D. acidophila is dueto catalysed diffusion and is primarily independent of the hydrolysisofATP. Cl^– efflux is assumed to be coupled to an activepump. Data suggest tight co–operativity between the systemsresponsiblefor Cl^– uptake and Cl^– efflux, with thecytoplasmic pH and the membrane potential being important mediators. Key words: Acid resistance, chloride carrier, chloride channels, Dunaliella acidophila, membrane potential, plasma membrane     

杜氏盐藻质膜ATPase在渗透调节中的可能作用

杜氏盐藻是一种以甘油为渗透调节物质的单细胞海藻,能够在0.08～5.0mol/L NaGl的培养液中生长。当外界NaGl浓度从0.5mol/L上升到4.0mol/L时,藻细胞内的Na~+和K~+含量变化不大,甘油含量则从6.20Pg/cell上升到51.50pg/cell。当藻细胞承受2.0mol/L到3.0mol/L NaCl的高渗胁迫时,能通过增加细胞内甘油含量来恢复原有形态;同时,藻细胞的H~+分泌增加,ATP含量下降;20μmol/L Na_3VO_4抑制了这些变化。KGN处理虽降低藻细胞内的ATP含量,却增加K~+外流和Na~+内渗。     

Involvement of the Plasma Membrane ATPase in the Osmoregulatory Mechanism of the Alga Dunaliella salina

The unicellular halotolerant alga Dunaliella salina recovers normally from a hypertonic shock even when suspended in NaCl and buffer only. Furthermore, addition of Cu²⁺, valinomycin and KCl, or permeable ions such as methyltriphenylphosphonium or thiocyanate, do not affect the recovery. However, treatment with two specific inhibitors of the plasma membrane adenosine triphosphatase (ATPase), diethylstilbestrol, or vanadate, fully inhibit the recovery. The inhibition is manifested by the inability of the cells to both synthesize glycerol and return to their original volume. The inhibitions are nonlethal, reversible and equally effective in the dark or the light. Since the plasma membrane ATPase is the only enzyme known to be inhibited by both diethylstilbestrol and vanadate, it is concluded that its activity is essential for the recovery of Dunaliella from a hypertonic shock. Mechanisms by which the plasma membrane ATPase may participate in the activation of glycerol production in the algae are discussed.     

Plasma Membrane Sterols Are Essential for Sensing Osmotic Changes in the Halotolerant Alga Dunaliella

The halotolerant alga Dunaliella responds to hyperosmotic stress by synthesis of massive amounts of glycerol. The trigger for this osmotic response is the change in cell volume, but the mechanism that senses volume changes is not known. Preincubation of Dunaliella salina with tridemorph, a specific inhibitor of sterol biosynthesis, inhibits glycerol synthesis and volume recovery. The inhibition is associated with suppression of [14C]bicarbonate incorporation into sterols and is correlated with pronounced depletion of plasma membrane sterols. Incubation of sterol-depleted cells with cholesterol hemisuccinate restores the capacity for volume regulation in response to hyperosmotic stress. Tridemorph as well as lovastatin also inhibit volume changes that are induced by high light in Dunaliella bardawil, a species that responds to high light intensity by synthesis of large amounts of [beta]-carotene. These volume changes result from accumulation of glycerol and are associated with de novo synthesis of sterols. The major plasma membrane sterol in D. salina and the high-light-induced sterol in D. bardawil co-migrate with ergosterol on thin-layer chromatography and on reversed-phase high-performance liquid chromatography. These results suggest that the osmosensory mechanism in Dunaliella resides in the plasma membrane, and that sterols have an important role in sensing osmotic changes.     

Purification and Properties of a Plasma Membrane H+-ATPase from the Extremely Acidophilic Alga Dunaliella acidophila

This paper describes partial purification and characterization of a vanadate-sensitive H+-ATPase from plasma membranes of Dunaliella acidophila, an extremely acidophilic unicellular alga (I. Sekler, H.U. Glaser, U. Pick [1991] J Membr Biol 121: 51-57). Purification is based on the insolubility in and stability of the enzyme in Triton X-100. The purified enzyme is highly enriched in a polypeptide of molecular mass 100 kD, which cross-reacts with antibodies against the plant plasma membrane H+-ATPase. Upon reconstitution into proteoliposomes, the enzyme catalyzes an ATP-dependent electrogenic H+ uptake. ATP hydrolysis is stimulated by lipids, is inhibited by vanadate, diethylstilbestrol, dicyclohexylcarbodiimide, erythrosine, and mercurials, and shows a sharp optimum at pH 6. Unusual properties of this enzyme, by comparison with plant plasma membrane H+-ATPases, are a higher affinity for ATP (Km = 40 [mu]M) and a larger stimulation by K+, which interacts with the enzyme from its cytoplasmic side. Comparative studies with cross-reacting antibodies, prepared against different domains of the plant H+-ATPase, suggest that the central hydrophilic domain containing the catalytic site is more conserved than the C- and N-terminal ends. The high abundance and stability of the plasma membrane H+-ATPase from D. acidophila make it an attractive model system for studies of the structure-function relations and regulation of this crucial enzyme.     

Extreme Secretion: Protein Translocation Across the Archaeal Plasma Membrane

In all three domains of life, extracytoplasmic proteins must overcome the hurdle presented by hydrophobic, lipid-based membranes. While numerous aspects of the protein translocation process have been well studied in bacteria and eukarya, little is known about how proteins cross the membranes of archaea. Analysis to date suggests that archael protein translocation is a mosaic of bacterial, eukaryal, and archaeal features, as indeed is much of archaeal biology. Archaea encode homologues of selected elements of the bacterial and eukaryal translocation machines, yet lack other important components of these two systems. Other aspects of the archaeal translocation process appear specific to this domain, possibly related to the extreme environmental conditions in which archsea thrive. In the following, current understanding of archaeal protein translocation is reviewed, as is recent progress in reconstitution of the archaeal translocation process in vitro.     

Vibrio fischeri Outer Membrane Protein OmpU Plays a Role in Normal Symbiotic Colonization

The nascent light-emitting organ of newly hatched juveniles of the Hawaiian sepiolid squid Euprymna scolopes is specifically colonized by cells of Vibrio fischeri that are obtained from the ambient seawater. The mechanisms that promote this specific, cooperative colonization are likely to require a number of bacterial and host-derived factors and activities, only some of which have been described to date. A characteristic of many host-pathogen associations is the presence of bacterial mechanisms that allow attachment to specific tissues. These mechanisms have been well characterized and often involve bacterial fimbriae or outer membrane proteins (OMPs) that act as adhesins, the expression of which has been linked to virulence regulators such as ToxR in Vibrio cholerae. Analogous or even homologous mechanisms are probably operative in the initiation and persistence of cooperative bacterial associations, although considerably less is known about them. We report the presence in V. fischeri of ompU, a gene encoding a 32.5-kDa protein homolog of two other OMPs, OmpU of V. cholerae (50.8% amino acid sequence identity) and OmpL of Photobacterium profundum (45.5% identity). A null mutation introduced into the V. fischeri ompU resulted in the loss of an OMP with an estimated molecular mass of about 34 kDa; genetic complementation of the mutant strain with a DNA fragment containing only the ompU gene restored the production of this protein. The expression of the V. fischeri OmpU was not significantly affected by either (i) iron or phosphate limitation or (ii) a mutation that renders V. fischeri defective in the synthesis of a homolog of the OMP-regulatory protein ToxR. The ompU mutant grew normally in complex nutrient media but was more susceptible to growth inhibition in the presence of either anionic detergents or the antimicrobial peptide protamine sulfate. Interestingly, colonization experiments showed that the ompU null mutant initiated a symbiotic association with juvenile light organ tissue with only about 60% of the effectiveness of the parent strain. When colonization did occur, it proceeded more slowly and resulted in an approximately fourfold-smaller bacterial population. Surprisingly, there was no evidence that in a mixed infection with its parent, the ompU-defective strain had a competitive disadvantage, suggesting that the presence of the parent strain provided a shared compensatory activity. Thus, the OmpU protein appears to play a role in the normal process by which V. fischeri initiates its colonization of the nascent light organ of juvenile squids.     

Salt-dependent Protein Composition in the Halotolerant Green Alga,Dunaliella parva

The extremely halotolerant green alga, Dunaliella parva, tolerates salt concentrations from 0.3 to 3.0 M NaCl. Effects of long-term adaptation to five distinct salinities were analyzed. Salt-dependent differences of physiological parameters such as growth rate, pigments, quantitative protein contents, and gas exchange were measured; furthermore the qualitative protein composition in salt-adapted cells was investigated using SDS-polyacrylamide gel electrophoresis. Proteins of apparent molecular masses of 26, 35, 39, 50, and 63 kDa were induced or intensified with an increase in external sodium chloride concentration whereas proteins of 85 and 101 kDa were diminished in high salt algae. After selective staining, four modifications of glycoproteins were observed. A glycoprotein of 96 kDa was produced exclusively in low salt cells whereas glycosylations of 105, 135, and 260 kDa were induced by high salt concentrations.     

Membrane Protein Rim21 Plays a Central Role in Sensing Ambient pH in Saccharomyces cerevisiae

External alkalization activates the Rim101 pathway in Saccharomyces cerevisiae. In this pathway, three integral membrane proteins, Rim21, Dfg16, and Rim9, are considered to be the components of the pH sensor machinery. However, how these proteins are involved in pH sensing is totally unknown. In this work, we investigated the localization, physical interaction, and interrelationship of Rim21, Dfg16, and Rim9. These proteins were found to form a complex and to localize to the plasma membrane in a patchy and mutually dependent manner. Their cellular level was also mutually dependent. In particular, the Rim21 level was significantly decreased in dfg16Δ and rim9Δ cells. Upon external alkalization, the proteins were internalized and degraded. We also demonstrate that the transient degradation of Rim21 completely suppressed the Rim101 pathway but that the degradation of Dfg16 or Rim9 did not. This finding strongly suggests that Rim21 is the pH sensor protein and that Dfg16 and Rim9 play auxiliary functions through maintaining the level of Rim21 and assisting in its plasma membrane localization. Even without external alkalization, the Rim101 pathway was activated in a Rim21-dependent manner by either protonophore treatment or depletion of phosphatidylserine in the inner leaflet of the plasma membrane, both of which caused plasma membrane depolarization like the external alkalization. Therefore, plasma membrane depolarization seems to be one of the key signals for the pH sensor molecule Rim21.     

Isolation and Characterization of a Protein Associated with Carotene Globules in the Alga Dunaliella bardawil

The halotolerant alga Dunaliella bardawil accumulates very large amounts of [beta]-carotene when exposed to high light intensity. The accumulated [beta]-carotene is concentrated in small, oily globules within the chloroplast and has been suggested to protect the alga against photodamage by high irradiation (A. Ben-Amotz, A. Katz, M. Avron [1982] J Phycol 18:529-537;A. Ben-Amotz, M. Avron [1983] Plant Physiol 72: 593-597; A. Ben-Amotz, A. Shaish, M. Avron [1989] Plant Physiol 91: 1040-1043). A 38-kD protein was identified and purified from [beta]-carotene globules and was designated carotene globule protein (Cgp). Induction of Cgp occurs in parallel with [beta]-carotene accumulation in D. bardawil grown under different inductive conditions. Cgp is overproduced in a constitutive mutant strain that overproduces [beta]-carotene and is not detected in Dunaliella salina, a species that does not accumulate [beta]-carotene. Cgp production was not suppressed by norflurazon, an inhibitor of [beta]-carotene synthesis that leads to accumulation of the carotenoid precursor phytoene. Immunogold-labeling analysis by electron microscopy demonstrates that the protein is localized at the periphery of the globules. Proteolytic cleavage by trypsin enhances the coalescence and destruction of the globules, in parallel with Cgp disappearance. It is suggested that the function of Cgp is to stabilize the structure of the globules within the chloroplast.     

A Sodium Pump in the Plasma Membrane of the Marine Alga Heterosigma akashiwo

ATP-dependent transport of ²²Na⁺ into liposomes reconstitutedfrom plasma membrane proteins of Heterosigma akashiwo was examined.The apparent K^m values for transport of Na⁺ were 400 µMfor ATP and 7 mM for Na⁺. ATP-dependent transport of ²²Na⁺ wasnot inhibited by a protonophore or a membrane-permeable cationbut was inhibited by an inhibitor of P-type ATPases. (Received October 2, 1995; Accepted February 1, 1996)     

The Role of Glycerol in the Osmotic Regulation of the Halophilic Alga Dunaliella parva

Dunaliella parva, a green halophilic alga, was found to accumulate very large amounts of intracellular glycerol. Through measurements of the intracellular volume the internal concentration of glycerol was calculated and found to be around 2.1 m in cells cultured in 1.5 m NaCl. When the extracellular salt concentration of an algal suspension was increased or decreased, the intracellular glycerol varied accordingly, reaching its new osmotic equilibrium after about 90 minutes. Since no leakage of intracellular glycerol was observed above 0.6 m NaCl, these alterations in glycerol content are interpreted as due to metabolic formation and degradation of intracellular glycerol. The above results indicate the existence of a new type of algal osmoregulation, in which the osmotic balance depends on the synthesis or degradation of intracellular glycerol in response to the external salt concentration.     

A 150 Kilodalton Cell Surface Protein Is Induced by Salt in the Halotolerant Green Alga Dunaliella salina

Dunaliella salina is an extremely halotolerant, unicellular, green alga lacking a rigid cell wall. Osmotic adaptation to high salinities is based on the accumulation of glycerol. To uncover other functions responsible for halotolerance, protein profiles of algae continuously grown in different salinities were compared. A 150 kilodalton protein (p 150) increased in amount with salt concentration. Furthermore, when the cells were subjected to drastic hyperosmotic shocks, p150 started to rise long after completion of the osmotic response but coincident with reinitiation of cell proliferation. Cells with an initially higher level of p150 resumed growth faster than cells with a lower level of the protein. Addition of cycloheximide early after hyperosmotic shock prevented the rise in p150, indicating this rise was due to de novo synthesis of the protein. These observations suggest that p150 is a saltinduced protein required for proliferation of the cells in saline media. p150 was purified to homogeneity and found to be a detergent-soluble glycoprotein. Polyclonal antibodies against p150 recognized a single protein component in D. salina crude extracts. A high M_r cross-reacting protein was also observed in another Dunaliella strain, D. bardawil. Immunoelectron microscopy localized p150 to the cell surface.     

ATP-Regulated Ion Channels in the Plasma Membrane of a Characeae Alga, Nitellopsis obtusa

Using the patch-clamp technique, we recorded single-channel currents across the excised patch of the plasma membrane of Nitellopsis. Both K⁺ and Na⁺ can pass this channel, but currents were not carried by Cl⁻. Upon the addition of ATP or AMP to the cytoplasmic side, the frequency of channel opening decreased. This is the first report on an ATP-regulated channel in plant cells.     

Modulation of Na/H Antiporter Activity by Extreme pH and Salt in the Halotolerant Alga Dunaliella salina

The effect of different growth conditions on the activity of the Na⁺/H⁺ antiporter in Dunaliella salina has been investigated. Adaptation of D. salina cells to ammonia at alkaline pH or to high NaCl concentrations is associated with a pronounced increase in the plasma membrane Na⁺/H⁺ exchange activity. The enhanced activity is manifested both in vivo, by stimulation of Na⁺ influx into intact cells in response to internal acidification, and in vitro, by a larger ²²Na accumulation in plasma membrane vesicles in response to an induced pH gradient. Kinetic analysis shows that the stimulation does not result from a change of the K_m for Na⁺ but from an increase in the V_max. In contrast, adaptation of cells to a high LiCl concentration (0.8 m) depresses the activity of the Na⁺/H⁺ antiporter. Adaptation to ammonia is also associated with a large increase of three polypeptide bands in purified plasma membrane preparations, indicating that they may compose the antiporter polypeptides. These results suggest that adaptation to ammonia or to high salinity induces overproduction of the plasma membrane Na⁺/H⁺ antiporter in Dunaliella.