Localization of a protein,immunologically similar to a sucrose-binding protein from developing soybean cotyledons,on the plasma membrane of sieve-tube members of spinach leaves

Immunocytochemical studies using antibodies raised against a 62-kDa membrane protein isolated from developing soybean (Glycine max (L.) Merr.) cotyledons were performed on leaf tissue of spinach (Spinacia oleracea L.). This 62-kDa protein was labeled by 6′-deoxy-6′-(4-azido-2-hydroxy)-benzamidosucrose (HABS), a photoaffinity sucrose analogue (K. G. Ripp et al., 1988, Plant Physiol.88, 1435–1445). Western-blot analysis of spinach plasma-membrane proteins indicated a cross-reactive polypeptide identical in molecular mass to that found in soybean. Indirect immunogold labeling of resin-embedded sections of fully expanded leaf tissue resulted in specific localization of colloidal gold on the sieve-tube plasma membrane. The label was uniform and, except for a few non-specific gold particles over the cell wall, all other cellular organelles and membrane systems were free of label. With the exception of occasional gold particles associated with the companion-cell plasma membrane, all other cell types of the leaf contained little or no label. Control sections treated with non-immune rabbit immunoglobulin-G were also essentially free of label. Immunogold labeling of young leaves, in which the phloem contained no mature sieve-tube members, were free of label for the 62-kDa protein. However, young leaf tissue in which mature or nearly mature sieve tubes could be identified, contained immunolabel associated with the sieve-tube plasma membranes. Similar results were obtained with mature leaf tissue of sugar beet (Beta vulgaris L.). The results of the immunocytochemical studies are consistent with the suggestion that the concentrating step in the phloem-loading process in this species may occur across the sieve-tube plasma membrane. This paper is dedicated to the memory of William A. Dungey     

Characterization and expression of plasma and tonoplast membrane aquaporins in elongating cotton fibers

Cotton fiber (Gossypium hirsutum L. and G. barbadense L.) is a good model for studies of plant cell elongation and cell wall biogenesis. Aquaporins are ancient membrane channel proteins that facilitate the permeation of water across biological membranes. We studied GhPIP1-2, encoding plasma membrane intrinsic protein, and GhgammaTIP1, encoding tonoplast intrinsic protein, during cotton fiber development. The full-length cDNAs of GhPIP1-2 and GhgammaTIP1 were obtained through 5' RACE. The deduced amino acid sequences of GhPIP1-2 and GhgammaTIP1 share high sequence identity with aquaporins from diverse plant species. Phylogenetic analysis of GhPIP1-2 and GhgammaTIP1 with other plant aquaporins showed that GhPIP1-2 belongs to the PIP1 group of the PIP subfamily and GhgammaTIP1 belongs to the gammaTIP group of the TIP subfamily. GhPIP1-2 and GhgammaTIP1 contain three and two introns, respectively. Genomic Southern blot analysis indicated that GhPIP1-2 and GhgammaTIP1 have several copies and multiple homologous genes in allotetraploid cotton. Northern blot analysis with gene-specific probes and real-time PCR demonstrated that GhPIP1-2 and GhgammaTIP1 are predominantly expressed during cotton fiber elongation, with the highest expression levels at 5 days post-anthesis. Moreover, expression patterns of the two genes in G. hirsutum and G. barbadense are similar, whereas the expression levels in G. barbadense are much lower than that in G. hirsutum. The high and preferential expression of GhPIP1-2 and GhgammaTIP1 during fiber cell elongation suggests that they may play important roles in supporting the rapid influx of water into vacuoles during cotton fiber cell expansion.     

Separation of tonoplast and plasma membrane potential and resistance in cells of oat coleoptiles

Summary Membrane potential and resistance were recorded from parenchymal cells of oat (Avena) coleoptiles, using one and two intracellular electrodes. Membrane potential is largest (–100 mV) in impalements with low input resistance (2–4 M), and is less negative (–50 mV) in penetrations with high input resistance (> 20 m). The interpretation is that the electrode lodges in the vacuole which is positive to the cytoplasm (but still negative to the external solution), and that measurements of net membrane potential are compromised to varying degrees by leakage shunts introduced across the high resistance vacuolar membrane by the electrode. This conclusion is supported by several additional lines of evidence. (1) It is possible to convert large-R/small-V impalements into small-R/large-V penetrations by passing excess current through the electrode or by briefly ringing the capacitance neutralization circuit in the amplifier. The cells usually recover their resistance in a few minutes, with a concomitant decrease in the negativity of the membrane potential. (2) Changes in external [K] affect the measuree potential by an amount that is independent of the input resistance of the impalement. This is consistent with an effect of [K] _o on the potential of the plasma membrane and the occurrence of leakage shunts primarily at the tonoplast. (3) Quantitatively, the effects of a change in [K] _o on resistance indicate that nearly 90 percent of the input resistance of unshunted cells resides in the tonoplast. (4) The effects of metabolic inhibitors (DNP, CN^–) on potential are smaller in large-R than in small-R impalements. This observation suggests there are electrogenic pumps contributing to the membrane potential at both the plasmalemma and tonoplast. Finally, we conclude that with an electrode in the vacuole it is possible to record potentials that are dominated by the contribution of the plasma membrane, provided care is taken to select impalements combining both large, negative potential and low input resistance.     

Physiological characteristics and regulation mechanisms of the H+ pumps in the plasma membrane and tonoplast of characean cells

The relationship between the physiological characteristics and changes in the activities of H⁺ pumps of the plasma membrane and tonoplast of characean cells is discussed. The large size of the characean internodal cells allows us to perform various experimental operations. The intracellular perfusion technique developed by Tazawaet al. (1976) is a powerful tool for analyzing the characteristics and control mechanisms of the H⁺ pumps (Tazawa and Shimmen 1987, Tazawaet al. 1987, Shimmenet al. 1994) Respiration-dependent changes in the activity of the plasma membrane H⁺ pump are explained by changes in the supply of energy substrate. Photosynthesis-dependent changes in activities of both the plasma membrane and the tonoplast H⁺ pumps are explained in terms of changes in the level of inorganic phosphate in the cytoplasm. Cytoplasmic and vacuolar pHs are suggested to be controlling factors forin vivo activities of the H⁺ pumps. Furthermore, the membrane potential and various ions are considered to bein vivo factors that regulate the activities of the H⁺ pumps. Recipient of the Botanical Society Award of Young Scientists, 1993.     

Effects of microtubule agents on the spatial and electrical properties of the plasma membrane inChara corallina

The freshwater algaChara corallina Klein ex Willd., em. R.D.W. (=C. australis R.Br.) develops alternating outward (acid) and inward (alkaline) current areas on its surface when illuminated. Exposure of cells to vinblastine, colchicine, or oryzalin caused a reduction in and a shifting of this extracellular current pattern. Removal of these agents from the bathing media resulted in regeneration of the initial current profile. Because these agents all affect tubulin, microtubules may be responsible for orchestrating the transmembrane currents responsible for the acid and alkaline banding phenomenon. Analysis of the membrane potential showed a fast depolarization after vinblastine exposure; however, analysis of the current-voltage curve did not show a change in membrane conductance. A 30-min colchicine treatment decreased the conductance of the plasma membrane with either an hyperor a depolarization in the membrane potential. In contrast, although a 9-h exposure to oryzalin caused a major reduction in the extra-cellular current pattern, only minor changes were observed in the membrane potential and conductance. However, in the presence of oryzalin, the time constants in the light response of the membrane potential increased over this 9-h period. Collectively, these results implicate an involvement of microtubules in spatial control of plasma-membrane transport events inC. corallina. This research was supported by National Science Foundation grant DCB-88-16077.     

Phenotypic changes in the fluidity of the tonoplast membrane of crassulacean-acid-metabolism plants in response to temperature and salinity stress

Electron paramagnetic resonance-spectroscopic studies on spin-labeled purified tonoplast membranes showed that in the obligate crassulacean-acid-metabolism (CAM) plant Kalanchoë daigremontiana Hamet et Perr. the fluidity of the tonoplast decreased during acclimation to higher temperatures. This phenotypic change in tonoplast fluidity was paralleled by a decrease in the mobilization of malic acid from the vacuoles during CAM in the light. The shift from the C₃ to the CAM mode of photosynthesis in the facultative CAM plant Mesembryanthemum crystallinum L. also led to a decrease in the fluidity of the tonoplast membrane. The results are consistent with the hypothesis that the ability to store malic acid during CAM in the vacuoles depends largely on the actual fluidity of the tonoplast membrane.     

Symplastic isolation of the sieve element-companion cell complex in the phloem of Ricinus communis and Salix alba stems

The anatomical and physiological isolation of the sieve element-companion cell complex (se-cc complex) was investigated in stems of Ricinus communis L. and Salix alba L. In Ricinus, the plasmodesmatal frequencies were in the proportions 8∶1∶2∶30, in the order given, at the interfaces between sieve tube-companion cell, sieve tube-phloem parenchyma cell, companion cellphloem parenchyma cell, and phloem parenchyma cellphloem parenchyma cell. The membrane potentials of the se-cc complex and the surrounding phloem-parenchyma cells sharply contrasted: the membrane potential of the se-cc complex was about twice as negative as that of the phloem parenchyma. Lucifer Yellow CH injected into the sieve element or into the companion cell remained within the se-cc complex. Dye introduced into phloem parenchyma only moved (mostly poorly) to other phloem-parenchyma cells. The distribution of the plasmodesmatal frequencies, the differential dye-coupling and the sharp discontinuities in membrane potentials indicate that the se-cc complexes constitute symplast domains in the stem phloem. Symplastic autonomy is discussed as a basic necessity for the functioning of the se-cc complex in the stem.     

Identification of tonoplast and plasma membrane in membrane fractions from garden cress (Lepidium sativum L.) with and without filipin treatment

Membranes from roots of Lepidium sativum L. were investigated in situ and after fractionation by applying morphological and biochemical methods. After freeze-fracture combined with filipin labelling the tonoplast and the plasma membrane could be easily characterized by the frequency of intramembranous particles and the arrangement of filipin-induced lesions. On tonoplast vesicles, the filipin-induced lesions were arranged in clusters of different size whereas they were evenly distributed on plasma membrane vesicles. Enrichment of tonoplast and plasma membrane in different fractions was documented by filipin labelling, phosphotungstic acid staining and by the profiles of marker enzyme activities and ATP-dependent H⁺-transport. Additionally, the presence of rightside-out and inside-out vesicles of both tonoplast and plasma membrane could be demonstrated. It was found that filipin labelling used in combination with freeze-fracturing is suitable for quantitative determinations of the percentages of tonoplast and plasma membrane in membrane fractions, which have been found to be more than 40% for the tonoplast and about 40% for plasma membrane in the respective enriched fractions.Abbreviations EF extraplasmatic fracture face - FIL filipin induced lesion - IMP intramembranous particle - PF plasmatic fracture face - PTA phosphotungstic acid-chromic acid stain - UDPG uridine 5-diphosphate glucose A preliminary report was presented at the joint Annual Meeting of the Belgian and German Societies for Cell Biology, Bonn, March 1985Dedicated to Professor Augustin Betz on the occasion of his 66th birthday     

Depolarization of the cell membrane causes inhibition of cell locomotion and pinocytosis inAcanthamoeba castellanii andAmoeba proteus

Summary 10 M CCCP protonophore in an acidic medium causes depolarization of the cell membrane and immediate cessation of locomotion inAcanthamoeba castellanii andAmoeba proteus. In the basic media there is no depolarization or inhibition of cell locomotion. Other depolarizing agents (alkali cations, crown molecules) also stop locomotion and induce pinocytosis in amoeba. Pinocytotic uptake of horseradish peroxidase byAcanthamoeba castellanii is increased by 69% in the presence of CCCP in the medium at pH 5.7 but is not influenced at higher pH values. This might indicate that both amoeboid locomotion and pinocytosis are controlled by membrane potential.     

Separation of tonoplast and plasma membrane H+-ATPase from Zucchini hypocotyls by consecutive sucrose and glycerol gradient centrifugation

Summary In order to isolate tonoplast and plasma membrane vesicles involved in ATP-dependent proton transport we devised a preparative procedure with two consecutive centrifugations. Three fractions were obtained on a sucrose step gradient: light microsomes, heavy microsomes, and a mitochondria-rich fraction. The light and heavy microsomal fractions were each recentrifuged on an isopycnic glycerol density gradient. Recentrifugation of light microsomes resulted in two fractions with H⁺-ATPase activity, one equilibrating at a density less than 1.11 g/cm³ and one equilibrating at a density of about 1.17g/cm³. Comparison with marker enzyme activities suggests that the upper fraction was enriched in tonoplast, and the dense fraction with plasma membrane. In addition to marker enzyme content, H⁺ transport in the H⁺-ATPase-containing fractions was further characterized with respect to pH dependence, cation and anion dependence, and uncouplers and inhibitors. H⁺ transport in all fractions was strongly dependent on the presence of halides but no specific stimulation by potassium or any other monovalent cation was found. Of the anions tested, malate and fumarate preferentially stimulated H⁺ transport in the tonoplast-enriched fraction. It is suggested that a Ca²⁺/H⁺ antiporter is present in all fractions. Only H⁺-ATPase in the plasma membrane-enriched fractions was sensitive to nystatin, an uncoupler, and to orthovanadate, an inhibitor. The tonoplast fraction was more sensitive to nitrate than the plasma membrane-enriched fraction, and all fractions showed some sensitivity to high concentrations of oligomycin. Oligomycin sensitivity was not due to the presence of mitochondria.     

The plasma membrane ofPhysarum cell fragments: a morphological and electrophysiological study

Summary Small, spherical cell fragments derived from macroplasmodia of the acellular slime moldPhysarum polycephalum by incubation in a 15 mM caffeine solution were investigated with morphological and electrophysiological techniques. Analysis of cell surface composition with the fluorescence microscope and different RITC-conjugated lectins revealed strong binding of ConA and RCA-I, weak binding of PEA, DBA and WGA and no binding of UEA-I. In addition, binding sites for external calcium ions were detected by chlorotetracycline-fluorescence. Electron microscopical staining with ruthenium red, iron or lanthanum delivered evidence for localization of lectin and calcium binding sites in a thin mucous layer on the cell surface.Electrical recordings by means of intracellular microelectrodes yielded an average membrane potential (MP) of –113 mV. Spontaneous depolarizations of the MP, with amplitudes between 10 and 80 mV and a duration of 20–30 s, failed to show a correlation with contractile activity. The ionic nature of MP was studied by varying the composition of the perfusing medium. The MP was not much affected by changes in external [Ca²⁺], [K⁺], or [Na⁺] but was sensitive to changes in [Cl^–] or [H⁺], with a linear dependence on pH₀ in the range between 7 and 5. Metabolic inhibition by potassium cyanide or low temperature (11°C) as well as application of the protonophore CCCP caused a depolarization of the MP. The results strongly support the hypothesis that the MP inPhysarum cell fragments is mainly generated by an electrogenic H⁺-extrusion mechanism.Abbreviations CCCP carbonylcyanide-m-chlorophenylhydrazone - ConA Concanavalin agglutinin - CTC chlorotetracycline - DBA Dolichos biflorus agglutinin - EGTA ethylene glycol-bis(-amino ethylether) N,N,N,N-tetracetate - PBS phosphate-buffered saline - PEA Peanut agglutinin - PIPES 1,4-piperazinediethanesulfonic acid - RCA-I Ricinus communis agglutinin I - RITC rhodamine isothiocyanate - SBA Soy bean agglutinin - UEA-I Ulex europeaeus agglutinin I - WGA Wheat germ agglutinin The paper is dedicated to Prof. Dr. K. E. Wohlfarth-Bottermann on the occasion of his 65th birthday.     

The permeability of the epidermal cell plasma membrane of barley leaves to abscisic acid

Uptake of ³H-labelled (±)-abscisic acid (ABA) into isolated barley (Hordeum vulgare L.) epidermal cell protoplasts (ECP) was followed over a range of pH values and ABA concentrations. The present results show that ABA uptake is not always linearly correlated with the external concentration of undissociated ABA (ABAH). At pH 7.25, ABA uptake exhibited saturation kinetics with an apparent K _m value of 75 mmol·m^–3 to tal ABA. This saturable transport component was inhibited by pretreating the protoplasts with 1 mol·m^–3 p-chloromercuribenzenesulfonic acid at pH 8.0, conditions that minimized the uptake of this acid sulfhydryl reagent. Moreover, the rate of (±)-[^3]HABA uptake was reduced by addition of 0.1 mol·m^–3 (±)-ABA to 41%, whereas the same concentration of (±)-ABA was approximately half as effective (46% of the inhibitory effect). Thus, it was concluded that only (±)-ABA competes for an ABA carrier that is located in the epidermal cell plasma membrane. The permeability of the epidermal cell plasma membrane was studied by performing a Collander analysis. At pH 6 the overall plasma-membrane permeability of epidermal cells was similar to that of guard cells but was about two times higher than that of mesophyll cells.Abbreviations ABA abscisic acid - ABA^– anion of ABA - ABAH undissociated ABA - 2,4-D 2,4-dichlorophenoxyacetic acid - DMO 5,5-dimethyloxazolidine-2,4-dione - ECP deepidermal cell protoplast - K_r partition coefficient - M_r relative molecular mass - NEM N-ethylmaleimide - PCMBS p-chloromercuriben zenesulfonic acid - P_s permeability coefficient We are grateful to Barbara Dierich for expert technical assistance, to Prof. H. Gimmler (Lehrstuhl für Botanik I, Universität Würzburg, FRG) for helpful discussions and to the Deutsche Forschungsgemeinschaft (SFB 251, TP 3) for financial support.     

Temperature effects on kinetic properties of plasma membrane ATPase from the yeast Saccharomyces cerevisiae

The reaction of plasma membrane ATPase from yeast with Mg²⁺ and Mg · ATP was studied in a temperature range of 10 – 30°C. The random mechanism of activation by Mg²⁺ and the pseudocompetitive inhibition at higher concentrations was not altered when the temperature was varied, nor were the kinetic constants representing substrate binding. However, at low temperature, the affinity of the enzyme for Mg²⁺ is greatly reduced. The Arrhenius plot of log V vs. 1/T shows straight lines with an inflection point at 24°C, which disappears in the presence of detergent. Calorimetric studies of the plasma membranes show a transition point at the same temperature. From these findings we suppose that Mg²⁺ is bound at a regulatory site of the ATPase, which is influenced by the surrounding phospholipids.     

Electrical properties of the plasma membrane of microplasmodia ofPhysarum polycephalum

Summary Microplasmodia ofPhysarum polycephalum have been investigated by conventional electrophysiological techniques. In standard medium (30mm K⁺, 4mm Ca⁺⁺, 3mm Mg⁺⁺, 18mm citrate buffer, pH 4.7, 22°C), the transmembrane potential differenceV _m is around –100 mV and the membrane resistance about 0.25 m².V _m is insensitive to light and changes of the Na⁺/K⁺ ratio in the medium. Without bivalent cations in the medium and/or in presence of metabolic inhibitors (CCCP, CN^–, N ₃ ^– ),V _m drops to about 0 mV. Under normal conditions,V _m is very sensitive to external pH (pH _o ), displaying an almost Nernstian slope at pH _o =3. However, when measured during metabolic inhibition,V _m shows no sensitivity to pH _o over the range 3 to 6, only rising (about 50 mV/pH) at pH _o =6. Addition of glucose or sucrose (but not mannitol or sorbitol) causes rapid depolarization, which partially recovers over the next few minutes. Half-maximal peak depolarization (25 mV with glucose) was achieved with 1mm of the sugar. Sugar-induced depolarization was insensitive to pH _o . The results are discussed on the basis of Class-I models of charge transport across biomembranes (Hansen, Gradmann, Sanders and Slayman, 1981,J. Membrane Biol. 63:165–190). Three transport systems are characterized: 1) An electrogenic H⁺ extrusion pump with a stoichiometry of 2 H⁺ per metabolic energy equivalent. The deprotonated form of the pump seems to be negatively charged. 2) In addition to the passive K⁺ pathways, there is a passive H⁺ transport system; here the protonated form seems to be positively charged. 3) A tentative H⁺-sugar cotransport system operates far from thermodynamic equilibrium, carrying negative charge in its deprotonated states.     

The isolation and some properties of a lectin (Haemagglutinin) from Cucurbita phloem exudate

The occurrence of high haemagglutinating (lectin) activity in phloem exudate from three cucurbit species is reported. The protein responsible for this lectin activity in Cucurbita maxima Duch. has been isolated by cation exchange chromatography on Sepharose and identified by gel electrophoresis. The lectin showed agglutinating activity at concentrations as low as 0.1 g/ml. No sugar, including those transported in the phloem of these species, interacted with agglutination. The lectin could not be extracted from cucurbit seed, but appeared in 5-day old seedlings. The possible role of a lectin in the sieve element is discussed.     

Dynamic changes in plasma membrane properties of semliki forest virus infected cells related to cell fusion

The mechanism of the processes leading to membrane fusion is as yet unknown. In this report we demonstrate that changes in membrane potential and potassium fluxes correlate with Semliki Forest virus induced cell-cell fusion at mildly acidic pH. The changes observed occur only at pH's below 6.2 corresponding to values required to trigger the fusion process. A possible role of these alterations of the plasma membrane related to membrane fusion phenomena is discussed.     

Interrelationships among the plasma membrane,the membrane skeleton and surface form in a unicellular flagellate

Summary Surface isolates or membrane skeletons from surface isolates can maintain the cell and surface form characteristic of euglenoids. We now report that the plasma membrane alone obtained by trypsin or urea digestion of surface isolates can also maintain surface form, but the membrane skeleton is able to produce striking changes in membrane organization. Trypsin digests microtubules, the membrane skeleton and partially digests the major integral membrane protein from surface isolates but does not alter the paracrystalline plasma membrane interior. Extraction of surface isolates with 4M urea leaves an insoluble plasma membrane and a subset of proteins arranged perpendicularly to the membrane surface. To resolve further the relationship between the plasma membrane and the membrane skeleton we have perturbed membrane organization by extraction of surface isolates with NaOH and find that readdition of the extract followed by neutralization restored important features of the membrane skeleton and caused patching of the membrane interior. Biochemically, the reassembled membrane skeleton consisted of 80 and 86 kD polypeptides and other less abundant proteins, and structurally the reassembled membrane skeleton was about the same thickness as the native membrane skeleton. Reassembly of the membrane skeleton appeared to be saturatable in that addition of an excess of extract had no effect on the thickness of the membrane skeletal layer. When the 80 kD protein was depleted from the reassembly mixture by affinity chromatography using Sepharose-bound monoclonal antibodies, the amount of 86 kD protein bound was significantly reduced, suggesting a dependance of 86 kD protein on 80 kD binding. A urea soluble fraction enriched in the 80 and 86 kD proteins was added to alkali-stripped membranes and 170 Å filaments were formed perpendicularly to the membrane surface. From the sum of these experiments we suggest that a) the native amorphous membrane skeleton ofEuglena may consist of a framework of 80 and 86 kD filaments arranged in a brush-like layer, b) the framework can direct plasma membrane organization, but once determined, membrane form remains stable to urea and trypsin but not to alkali, and c) new surface growth can in theory occur as an expansion of the brush-like layer by direct intercalation of filaments enriched in or consisting wholly of 80 and 86 kD proteins.Abbreviations BSA bovine serum albumin - ELISA enzyme linked immunosorbant assay - EF ectoplasmic fracture face - IMPs intramembrane particles - PF protoplasmic fracture face This work was supported by a University of Illinois Fellowship to RRD and NSF grant DCB-8602793 to GBB.     

Purification of plastids from higher-plant roots

A procedure is described for the purification of plastids from the roots of Pisum sativum L. The preparations obtained are appreciably free of contamination by other particles as judged by the distribution of organelle-specific marker enzymes and by electron microscopy. Latency of glutamate synthase (EC 2.6.1.53) within these preparations indicates that the plastids obtained are 90–95% intact, whilst the resistance of this enzyme, and glucose-6-phosphogluconate dehydrogenase (EC 1.1.1.43) to tryptic digestion in unlysed organelles indicates that they are at least 70–85% intact and may be suitable for studies of metabolite transport.     

Monoclonal antibodies to a higher-plant nitrate reductase: Differential inhibition of enzyme activities

A set of monoclonal antibodies has been raised against NADH-nitrate reductase (NR; EC 1.6.6.1) from spinach (Spinacea oleracea L.) leaves. Antibodies were screened by enzyme-linked immunosorbent assay and by their ability to inhibit various activities of the enzyme. The six monoclonals selected (AFRC MAC 74 to 79) are all gamma globulins; four (MAC 74 to 77) inhibit all terminal donating activities (NADH-NR; flavin mononucleotide, reduced form (FMNH₂)-NR; and methyl viologen, reduced form (MV)-NR) and two (MAC 78 and 79) inhibit the acceptor activities (NADH-NR, and NADH-cytochrome c reductase). MAC 74 to 77 inhibit the NADH-NR activity of crude extracts of a variety of species (mono- and dicotyledoneae) while MAC 78 and 79 are effective against spinach and marrow, but not oil-seed rape, cucumber, oats, wheat and barley.Abbreviations Cyt c Rase cytochrome c reductase - ELISA enzyme-linked immunosorbent assay - FAD(H₂) flavin adenine dinucleotide (reduced form) - FMN(H₂) flavin mononucleotide (reduced form) - McAb monoclonal antibody - MV methyl viologen reduced form - NR nitrate reductase     

Location,expression and orientation of the putative chlororespiratory enzymes,Ndh and IMMUTANS,in higher-plant plastids

The chloroplasts of many plants contain not only the photosynthetic electron transport chain, but also two enzymes, Ndh and IMMUTANS, which might participate in a chloroplast respiratory chain. IMMUTANS encodes a protein with strong similarities to the mitochondrial alternative oxidase and hence is likely to be a plastoquinol oxidase. The Ndh complex is a homologue of complex I of mitochondria and eubacteria and is considered to be a plastoquinone reductase. As yet these components have not been purified to homogeneity and their expression and orientation within the thylakoid remain ill-defined. Here we show that the IMMUTANS protein, like the Ndh complex, is a minor component of the thylakoid membrane and is localised to the stromal lamellae. Protease digestion of intact and broken thylakoids indicates that both Ndh and IMMUTANS are orientated towards the stromal phase of the membrane in Spinacia oleracea L. Such an orientation is consistent with a role for the Ndh complex in the energisation of the plastid membrane. In expression studies we show that IMMUTANS and the Ndh complex are present throughout the development of both Pisum sativum L. cv Progress No. 9 and Arabidopsis thaliana (L.) Heynh. leaves, from early expansion to early senescence. Interestingly, both the Ndh complex and the IMMUTANS protein accumulate within etiolated leaf tissue, lacking the photosystem II complex, consistent with roles outside photosynthetic electron transport.Abbreviations PQ plastoquinone - PSI, PSII photosystem I, II