The development of NAD(P)H-dependent and ferredoxin-dependent glutamate synthase in greening barley and pea leaves

The activity of NAD(P)H-dependent glutamate synthase (E.C. 1.4.1.14) has been demonstrated in extracts from etiolated shoots of pea (Pisum sativum L.) and barley (Hordeum vulgare L.). This activity does not significantly alter upon greening of the etiolated shoots, and is at a similar level in light-grown material. Ferredoxin-dependent glutamate synthase (E.C. 1.4.7.1) has low activity in etiolated shoots but increases rapidly on greening. In light grown leaves ferredoxin-dependent activity is 30–40-fold higher than NAD(P)H-dependent activity. It is not considered that the NAD(P)H-dependent glutamate synthase plays an important role in ammonia assimilation in the photosynthetic tissue of higher plants.     

Long-distance signalling and a mutational analysis of branching in pea

Four ramosus mutants with increased branching at basal andaerial nodes have been used to investigate the genetic regulation of budoutgrowth in Pisum sativum L. (garden pea). Studies oflong-distance signalling, xylem sap cytokinin concentrations, shootauxin level, auxin transport and auxin response are discussed. A modelof branching control is presented that encompasses twograft-transmissible signals in addition to auxin and cytokinin. Mutantsrms1 through rms4 are not deficient in indole-3-aceticacid (IAA) or in the basipetal transport of this hormone. Three of thefour mutants, rms1, rms3 and rms4, have veryreduced cytokinin concentrations in xylem sap from roots. This reductionin xylem sap cytokinin concentration appears to be caused by a propertyof the shoot and may be part of a feedback mechanism induced by anaspect of bud outgrowth. The shoot-to-root feedback signal is unlikelyto be auxin itself, as auxin levels and transport are not correlatedwith xylem sap cytokinin concentrations in various intact and graftedmutant and wild-type plants. Rms1 and Rms2 act inshoot and rootstock to regulate the level or transport ofgraft-transmissible signals. Various grafting studies and double mutantanalyses have associated Rms2 with the regulation of theshoot-to-root feedback signal. Rms1 is associated with a secondunknown graft-transmissible signal that is postulated to move in thedirection of root-to-shoot. Exogenous auxin appears to interact withboth of the signals regulated by Rms1 and Rms2 in theinhibition of branching after decapitation. The action of Rms3and Rms4 is less apparent at this stage, although both appearto act largely in the shoot.     

Asymbiotic association of Rhizobium with pea epicotyls treated with a plant hormone

Treatment of epicotyls of dark-grown pea (Pisum sativum L.) seedlings with indole-3-acetic acid causes swelling of the tissue. Application of Rhizobium to the cut surface of the swollen tissue results in the development of an infection. The infection spreads in the cortical cells and proceeds 2–3 mm deep into the stem within 3–4 days. An acetylene reduction assay used for detecting nitrogen-fixation capacity of the infected tissue was negative at 10% [O₂]; however, if [O₂] was reduced to below 1%, some activity could be detected. Ultrastructural observations indicate that the cytoplasmic contents of the infected cells are destroyed and no membrane structure around the bacteria is formed during this infection. Rhizobium does not appear to have developed any symbiotic relationship with the host. Failure to develop symbiosis appears to result in a parasitic or saprophytic association and the nitrogen fixed under such conditions may not be of any use to the plant.     

Localisation and characterisation of homoserine dehydrogenase isolated from barley and pea leaves

Two forms of homoserine dehydrogenase exist in the leaves of both barley and pea; one has a large molecular weight and is inhibited by threonine, the other is of smaller molecular weight and insensitive to threonine but inhibited by cysteine. The subcellular localisation of these enzymes has been examined. Both plants have 60–65% of the total homoserine dehydrogenase activity present in the chloroplast and this activity is inhibited by threonine. The low molecular weight, threonine-insensitive form is present in the cytoplasm. Total homoserine dehydrogenase activity from barley leaves showed progressive desensitisation towards threonine with age in a similar manner to that previously described for maize. It was shown that the effect was due to desensitisation of the chloroplast enzyme, and not to an increase in the insensitive cytoplasm enzyme. No corresponding desensitisation to threonine was detected in pea leaves. The different forms of homoserine dehydrogenase could be separated from pea leaves by chromatography on Blue Sepharose; the threonine-sensitive enzyme passed straight through and the threonine insensitive form was bound. A similar separation of the barley leaf isoenzymes was obtained using Matrex Gel Red A affinity columns; in this case however, the threonine-sensitive isoenzyme was bound. In both plants, the threonine insensitive isoenzyme was subject to greater inhibition by cysteine than was the threonine-sensitive isoenzyme.Abbreviation HSDH homoserine dehydrogenase     

Transport of exogenous auxin in two-branched dwarf pea seedlings (Pisum sativum L.)

Dwarf pea plants bearing two cotyledonary shoots were obtained by removing the epicotyl shortly after germination, and the patterns of distribution of ¹⁴C in these plants was investigated following the application of [¹⁴C]IAA to the apex of one shoot. Basipetal transport to the root system occurred, but in none of the experiments was ¹⁴C ever detected in the unlabelled shoot even after transport periods of up to 48 h. This was true both of plants with two equal growing shoots and of plants in which one shoot had become correlatively inhibited by the other, and in the latter case applied whether the dominant or subordinate shoot was labelled. In contrast, when [¹⁴C]IAA was applied to a mature foliage leaf of one shoot transfer of ¹⁴C to the other shoot took place, although the amount transported was always low. Transport of ¹⁴C from the apex of a subordinate shoot on plants bearing one growing and one inhibited shoot was severely restricted compared with the transport from the dominant shoot apex, and in some individual plants no transport at all was detected. Removal of the dominant shoot apex rapidly restored the capacity of the subordinate shoot to transport apically-applied [¹⁴C]IAA, and at the same time led to rapid cambial development and secondary vascular differentiation in the previously inhibited shoot. Applications of 1% unlabelled IAA in lanolin to the decapitated dominant shoot maintained the inhibition of cambial development in the subordinate shoot and its reduced capacity for auxin transport. These results are discussed in relation to the polarity of auxin transport in intact plants and the mechanism of correlative inhibition.Abbreviations IAA Indol-3-yl-acetic acid - TIBA 2,3,5-triiodobenzoic acid - 2,4D 2,4-dichlorophenoxyacetic acid - IAAsp Indol-3-yl-acetyl aspartic acid     

The effects of heterozygosity at the af,st and tl loci in peas

Summary Eight near-isogenic lines of pea representing all the homozygous combinations of three genes af, st and tl, which modify leaf shape and size, were crossed in all possible ways excepting reciprocals. An analysis of the resulting 36 families has shown that homozygous mutant alleles at the tl locus acting with homozygous mutant alleles at the af and st loci increase both seed weight and plant haulm weight. The mutant alleles at the af and st loci seem, when homozygous, to have little effect by themselves upon seed weight but they do increase or decrease haulm weight, respectively. There is clear evidence of heterotic effects resulting from heterozygosity at each one of the three loci which modify seed weight, haulm weight and basal branching. The implications of such heterotic effects in pea breeding programmes are discussed.     

Spectral properties of soluble and pelletable phytochrome from epicotyls of etiolated pea seedlings

The red-light(R)-absorbing form of phytochrome (Pr) was detected spectrophotometrically in a 20,000 g particulate fraction prepared from a 1,000 g supernatant fraction from epicotyl tissue of pea (Pisum sativum L.) seedlings grown in the dark and only briefly exposed to dim green light. The difference spectrum of phytochrome in this fraction was essentially the same as that of soluble phytochrome from the same tissue. When the non-irradiated 20,000 g particulate fraction was incubated in the dark at 25° C, an absorbance change (decrease) of Pr after actinic red irradiation was found only in the far-red (FR) region. When the 20,000 g particulate fraction was irradiated with R and then incubated in the dark, the FR-absorbing form of phytochrome (Pfr) disappeared spectrally at a rate about half that in the soluble fraction, and the difference spectrum of the Pr which became detectable after dark incubation of the 20,000 g particulate fraction was markedly distorted. In contrast, Pfr in a 20,000 g particulate fraction prepared from tissues irradiated with R did not change optically during dark incubation at 25° C for 60 min, while Pfr in the soluble fraction from the same tissue disappeared in the dark. No dissociation of either Pr or Pfr from the 20,000 g particulate fraction was indicated during a 60-min dark incubation at 25° C, but Pfr in a 20,000 g particulate fraction prepared in vitro from R-irradiated 1,000 g supernatant fraction in the presence of CaCl₂ disappeared spectrally and the difference spectrum of Pr in the 20,000 g particulate fraction became quite distorted during the dark incubation.Abbreviations Pr red-light-absorbing form of phytochrome - Pfr far-red-light-absorbing form of phytochrome - FR far-red light - FR1 first actinic far-red light - FR2 second actinic far-red light - R red light - R1 first actinic red light - 1kS 1,000 g supernatant fraction - 20kS 20,000 g supernatant fraction - 20kP 20,000 g particulate fraction     

Regulation of synthesis of nitrite reductase in pea leaves: in-vivo and in-vitro studies

The cellular location of three peroxidase isoenzymes (PRX) in mature leaf tissue of Petunia and their affinity for Concanavalin A-Sepharose were investigated. The isoenzymes PRXa, PRXb and PRXc were identified by their positions in starch-gel zymograms. The fast-moving anodic and cathodic peroxidase bands, the isoenzymes PRXa and PRXc respectively, were the most active peroxidases in extracellular extracts. The molecular forms of PRXa showed a tissue-specific distribution between midrib and remaining leaf tissue. An intermediate-moving anodic peroxidase band, the isoenzyme PRXb, was the most active peroxidase released after extraction of isolated mesophyll protoplasts. Small amounts of the peroxidase isoenzymes were present in cell-wall-bound fractions. Incubation of a crude protein fraction with Concanavalin A-Sepharose showed that the isoenzyme PRXb bound more firmly to Concanavalin A-Sepharose than the isoenzymes PRXa and PRXc, of which only one molecular form bound partly. The results are discussed with respect to a possible function of one of the peroxidase isoenzymes, and a possible role of oligosaccharide chains in determining the cellular location of plant peroxidases is suggested.Abbreviations Con A Concanavalin A - PRX peroxidase (isoenzyme)     

Performance of active Photosystem II centers in photoinhibited pea leaves

Effects of photoinhibition on photosynthesis in pea (Pisum sativum L.) leaves were investigated by studying the relationship between the severity of a photoinhibitory treatment (measured as F_v/F_m) and several photoacoustic and chlorophyll a fluorescence parameters. Because of the observed linear relationship between the decline of F_v/F_m and the potential oxygen evolution rate determined by the photoacoustic method, the parameter F_v/F_m was used as an indicator for the severity of photoinhibition. Our analysis revealed that part of the Photosystem II (PS II) reaction centers is inactive in oxygen evolution and is also less sensitive to photoinhibition. Correcting the parameter q_P (fraction of open PS II reaction centers) for inactive PS II centers unveiled a strong increase of q_P in severely inhibited pea leaves, indicating that the inactivated active centers do no longer contribute to q_P and that photoinhibition has an all or none effect on PS II centers. Analysis of q_E (energy quenching) demonstrated its initial increase possibly associated with dephosphorylation of LHC II. Analysis of q_I (photoinhibition dependent quenching) showed that the half-time of recovery of q_I increases steeply below an F_v/F_m of 0.65. This increase of the relaxation half-time corresponds with a decrease of the electron transport rate J and tentatively indicates that the supply of ATP, needed for the recovery, starts to decrease. The data indicate the necessity of correcting for inactive centers in order to make valuable conclusions about effects of photoinhibition on photosynthetic parameters.     

The intracellular location of the enzymes of nitrate assimilation in the apices of seedling pea roots

The intracellular distribution of the enzymes of nitrate and ammonia assimilation in apical cells of pea (Pisum sativum L.) roots is described. Nitrate reductase (EC 1.6.6.2) was found to have no organelle association, and is considered to be located in the cytosol or possibly loosely bound to the outside of an organelle. Nitrite reductase and glutamate synthase (EC 2.6.1.53) are plastid located, as is glutamine synthetase (EC 6.3.1.2) although this enzyme also has activity in the cytosol. Glutamate dehydrogenase (EC 1.4.1.3) was found only in the mitochondrion.     

Effects of temperature and sink activity on the transport of 14C-labelled indol-3yl-acetic acid in the intact pea plant (Pisum sativum L.)

The velocity and intensity of basipetal transport of ¹⁴C-labelled indol-3yl-acetic acid (IAA) applied to the apical bud of the intact pea plant were influenced by the temperature to which the stem was exposed and were not influenced by changes in the temperature of the root system when this was controlled independently between 5°C and 35°C. The velocity of transport increased steadily with temperature to a maximum in excess of 35°C and then fell sharply with further increase in temperature. The Q₁₀ for velocity, determined from Arrhenius plots, was low (ca. 1.3). Transport intensity increased to a maximum at about 25°C (Q₁₀=2.2) and then declined gradually with further increase in temperature. It is suggested that transport velocity and transport intensity are controlled independently.The characteristics of auxin transport through the stem were not affected by removal of the root system, or by the withdrawl of root aeration. Labelled IAA did not pass a region of the stem cooled to about 1.0°C, or through a narrow zone of stem tissue killed by heat treatment. In the latter case the heat treatment was shown not to interfere with the upward transport of water in the xylem. Labelled IAA continued to move into, and to accumulate in, the tissues immediately above a cooled or heat-killed region of the stem. It was concluded that the long-distance basipetal transport of auxin through the stem of the intact plant is driven by the transporting cells themselves and is independent of the activity of sinks for the transported auxin.The fronts of the observed tracer profiles in the stem were closely fitted by error function diffusion analogue curves. However, diffusion of IAA alone could not account for the observed characteristics of the transport and it is suggested that the curvilinear fronts of the profiles resulted from a diffusive mixing of exogenous IAA (or IAA-carrier complexes) with endogenous IAA already in the transport pathway.Abbreviations IAA indol-3yl-acetic acid - IAAsp indol-3yl-acetyl aspartic acid - CFM methyl 2-chloro-9-hydroxyfluorene-9-carboxylate (morphactin) - TIBA 2,3,5-triiodobenzoic acid - ABA abscisic acid     

Two distinct blue-light responses regulate the levels of transcripts of specific nuclear-coded genes in pea

Fluence-response characteristics for bluelight(BL)-mediated changes in the steady-state levels ofCab-, pEA215 and pEA207-RNA in red-light(RL) grown pea (Pisum sativum L. cv. Alaska) seedlings indicate the existence of two BL responses: a blue-lowfluence (BLF) response, causing an increase inCab- and pEA215-RNA, and a blue-high-fluence (BHF) response, causing a return to control levels forCab- and pEA215-RNA and a decrease in pEA207-RNA levels (Warpeha and Kaufman, 1989, Plant Physiol.,91, 1030–1035). We now show that under dark growth conditions, only the BLF response is apparent;Cab- and pEA215-RNA increase at all fluences tested, whereas pEA207-RNA levels are unaltered over the range of BL fluence tested. The treatment of dark-grown seedlings with RL immediately prior to BHF irradiation does not elicit the BHF response forCab-, pEA215 and pEA207-RNA, indicating that the role of growth in RL is to enable the seedling to reach a particular developmental state, rather than ensuring the presence of active phytochrome at the time of BL-irradiation. The apical bud of RL-grown seedlings has only the BLF response;Cab-RNA levels increase while pEA207-RNA exhibits no change at any of the fluences tested. The developing leaves of the fourth node show the BHF response; bothCab- and pEA207-RNA decrease following treatment with high-fluence BL. These data also indicate the necessity for reaching a specific developmental state before the BHF response can be activated. This research was supported by U.S. Department of Agriculture, Competitive Grants Office, grant No. 86CRCR12228 to L.S.K. K.M.F.W. gratefully acknowledges a University of Illinois at Chicago Laboratory for Molecular Biology Fellowship.     

Distribution of calmodulin in pea seedlings: Immunocytochemical localization in plumules and root apices

Immunofluorescence techniques have been used to study the distribution of calmodulin in several tissues in young etiolated pea (Pisum sativum L.) seedlings. A fairly uniform staining was seen in the nucleoplasm and background cytoplasm of most cell types. Cell walls and nucleoli were not stained. In addition, patterned staining reactions were seen in many cells. In cells of the plumule, punctate staining of the cytoplasm was common, and in part this stain appeared to be associated with the plastids. A very distinctive staining of amyloplasts was seen in the columella of the root cap. Staining associated with cytoskeletal elements could be shown in division stages. By metaphase, staining of the spindle region was quite evident. In epidermal cells of the stem and along the underside of the leaf there was an intense staining of the vacuolar contents. Guard cells lacked this vacuolar stain. Vacuolar staining was sometimes seen in cells of the stele, but the most distinctive pattern in the stele was associated with young conducting cells of the xylem. These staining patterns are consistent with the idea that the interactions of plastids and the cytoskeletal system may be one of the Ca²⁺-mediated steps in the response of plants to environmental stimuli. Nuclear functions may also be controlled, at least in part, by Ca²⁺.     

Adenylate effects on protein phosphorylation in the interenvelope lumen of pea chloroplasts

A 64-kilodalton (kDa) protein, situated in the lumen between the inner and outer envelopes of pea (Pisum sativum L.) chloroplasts (Soll and Bennett 1988, Eur. J. Biochem., 175, 301–307) is shown to undergo reversible phosphorylation in isolated mixed envelope vesicles. It is the most conspicuously labelled protein after incubation of envelopes with 33 nmol·1^-1 [-³²P]ATP whereas incubation with 50 mol·1^-1 [-³²P]ATP labels most prominently two outer envelope proteins (86 and 23 kDa). Half-maximum velocity for phosphorylation of the 64-kDa protein occurs with 200 nmol·1^-1 ATP, and around 40 mol·1^-1 ATP for phosphorylation of the 86- and 23-kDa proteins, indicating the operation of two distinct kinases. GGuanosine-, uridine-, cytidine 5-triphosphate and AMP are poor inhibitors of the labelling of the 64-kDa protein with [-³²P]ATP. On the other hand, ADP has a potent influence on the extent of labelling (half-maximal inhibition at 1–5 mol·1^-1). The ADP-dependent appearance of ³²P in ATP indicates that ADP acts by reversal of kinase activity and not as a competitive inhibitor. However, the most rapid loss of ³²P from pre-labelled 64-kDa protein occurs when envelope vesicles are incubated with ATP t1/2=15 s at 20 molsd1^-1 ATP). This induced turnover of phosphate appears to be responsible for the rapid phosphoryl turnover seen in situ.Abbreviations LHCP ligh-harvesting chlorophyll-a/b-binding protein - S_0.5 concentration giving half-maximal phosphorylation - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - Tricine N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine     

Patterns of protein synthesis in dormant and growing vegetative buds of pea

Lateral buds on intact pea plants (Pisum sativum L. cv. Alaska) remain dormant until they are stimulated to develop by decapitating the terminal bud. Using two-dimensional gel electrophoresis, we have examined the protein content of terminal and lateral buds from intact plants and from plants at various times after decapitation. Silver-staining and in-vivo-labeling demonstrated very different sets of proteins. The level of expression of 18 stained and 25 labeled proteins was altered when growth was stimulated; this represents 3.4% and 9.1% of the total proteins detected by each method, respectively. Within 24 h of being stimulated, lateral buds doubled in length and their protein content was qualitatively nearly the same as that of terminal buds. Six hours after decapitation, before the onset of detectable growth, the overall pattern of protein synthesis in lateral buds was more like that of growing lateral buds or of terminal buds than that of dormant lateral buds. Direct application of N⁶-furfurylaminopurine (kinetin) to buds on intact plants stimulated their growth and resulted in the same pattern of protein synthesis as did decapitation. Inhibition of bud growth by addition of indole-3-acetic acid to the stumps of decapitated plants resulted in the synthesis of dormancy-related proteins. Lateral buds at all stages of development incorporated labeled amino acids at similar rates, indicating that metabolic activity is not a component of dormancy in these buds.Abbreviations IAA indole-3-acetic acid - IEF isoelectric focusing - KIN kinetin (N⁶-furfurylaminopurine) - SDS sodium dodecylsulfate - TCA trichloroacetic acid - 2D-PAGE two-dimensional polyacrylamide gel electrophoresis     

Immunofluorescence localization of chalcone synthase in roots ofPisum sativum L. andPhaseolus vulgaris L. and comparable immunochemical analysis of chalcone synthase from pea leaves

Summary Chalcone synthase in roots ofPisum sativum andPhaseolus vulgaris was demonstrated enzymatically and immunochemically. In situ localization by indirect immunofluorescence revealed that chalcone synthase is chiefly present in the lateral regions of the calyptra, in the rhizodermis, and the cortex. In the central cylinder the enzyme protein is no longer detectable a short distance behind the meristem. Chalcone synthase was not found in root tips ofZea mays. Two isoforms of chalcone synthase were separated by chromatofocusing of protein extracts from pea leaves. The two forms differed in their subunit molecular masses. The smaller isoform was not detected in roots.Abbreviations CHS chalcone synthase - FITC fluorescein isothiocyanate - IgG immunoglobulin G - DTE dithioerythritol     

Nitrogen resorption from senescing leaves of three salt marsh plant species

Seasonalvariation in leaf nitrogen of mature green and senescent leaves and nitrogenresorption efficiency in three plants (Spartina maritima, Halimioneportulacoides and Arthrocnemum perenne) of aTagus estuary salt marsh are reported. Total nitrogen concentrations in greenand senescent leaves were higher during winter (December and March). Soilinorganic nitrogen availability showed an opposite pattern with higherconcentrations during summer (June and September) when total leaf biomass washigher. Nitrogen resorption efficiency ranged between 31 and 76% andH. portulacoides was the plant that better minimizednitrogen loss by this process. Nitrogen resorption occurred mainly from thesoluble protein pool, although other fractions must have been broken down duringthe resorption process. No significant seasonal variation in nitrogen resorptionefficiency and no relation to leaf total nitrogen or soil nitrogen availabilitywere found. This suggests that the efficiency of the resorption process is notdetermined by the plant nitrogen status nor by the availability of the nutrientin the soil. Nevertheless, resorption from senescing leaves may play animportant role in the nitrogen dynamics of salt marsh plants and reduce thenitrogen requirements for plant growth.     

Metabolism of some amino acids in relation to the photorespiratory nitrogen cycle of pea leaves

¹⁵N-labelled (amino group) asparagine (Asn), glutamate (Glu), alanine (Ala), aspartate (Asp) and serine (Ser) were used to study the metabolic role and the participation of each compound in the photorespiratory N cycle ofPisum sativum L. leaves. Asparagine was utilised as a nitrogen source by either deamidation or transamination, Glu was converted to Gln through NH₃ assimilation and was a major amino donor for transamination, and Ala was utilised by transamination to a range of amino acids. Transamination also provided a pathway for Asp utilisation, although Asp was also used as a substrate for Asn synthesis. In the photorespiratory synthesis of glycine (Gly), Ser, Ala, Glu and Asn acted as sources of amino-N, contributing, in the order given, 38, 28, 23, and 7% of the N for glycine synthesis; Asp provided less than 4% of the amino-N in glycine. Calculations based on the incorporation of¹⁵N into Gly indicated that about 60% (Ser), 20% (Ala), 12% (Glu) and 11% (Asn) of the N metabolised from each amino acid was utilised in the photorespiratory nitrogen cycle.Abbreviations Ala alamine - Asn asparagine - Asp aspartate - Glu glutamate - MOA methoxylamine - Ser serine