Blue-Light Regulation of Epicotyl Elongation in Pisum sativum

Blue light is known to induce suppression of stem elongation. To avoid the complication of blue-light-induced transformation of phytochrome we have adapted the procedure of measuring blue-light-induced suppression of stem elongation in Pisum sativum L. var Alaska grown under continuous red light. The resulting fluence-response curve for suppression of epicotyl elongation measured twenty-four hours after a blue-light treatment is bell-shaped, with the peak of suppression between 10⁰ and 10¹ micromoles per square meter, and no suppression at 10⁴ micromoles per square meter. Suppression is first observed 5 and 11 hours after the blue-light treatment for the fourth and third internodes, respectively. No significant differences in elongation rates were noted for the 10⁴ micromoles per square meter treated seedlings throughout the 24 hour period. Reciprocity holds for both third and fourth internodes in response to 10¹ and 10⁴ micromoles per square meter of blue light over the range of irradiation times tested (10⁰ to 10⁴ seconds, 10¹ micromoles per square meter; 10⁰ to 10³ seconds, 10⁴ micromoles per square meter). In contrast to the bell-shaped fluence-response obtained for epicotyl elongation, measurements of chlorophyll and carotenoid accumulation indicate increasing accumulation with increasing fluence.     

Hydroxyproline and Peroxidases in Cell Walls of Pisum sativum: Regulation by Ethylene

Purified cell-wall preparations from the epicotyl of etiolatedPisum sativum contain covalently bound peroxidases and hydroxyproline-richproteins. Towards the end of cell elongation there is a largerise in these wall components and thereafter a continuing slowrise which is associated with increasing age of tissue. Ethyleneat concentrations of 0.1 ppm or more increases both peroxidaseactivity and hydroxyproline levels in the walls, the greatestresponse occurring in immature tissue including the apical hook.Growth of these tissues is highly sensitive to ethylene whichcauses an inhibition of elongation in extending cells and anenhanced lateral cell expansion. We suggest that the effectsof ethylene on wall-bound peroxidase and hydroxyproline areimplicated in the ethylene regulation of cell growth. The covalently bound wall peroxidase was found to be extremelystable and to contain unique isoenzymes which do not occur ineither the cytoplasm or in the peroxidase which is ionicallybound to walls. Ethylene increases peroxidase activity in boththe cytoplasmic and the ionically bound wall fractions, butthere is little or no increase in their hydroxyproline content.The possible relationships between covalently bound wall peroxidaseand hydroxyproline are discussed and we speculate that thisperoxidase may be involved in the hydroxylation of proline inthe walls.     

Regulation of Glutathione Synthesis by Cadmium in Pisum sativum L

In roots and shoots of pea plants (Pisum sativum L.) cultivated with CdCl₂ concentrations up to 50 micromolar, growth, the content of total acid soluble thiols, and the activity of glutathione synthetase (EC 6.3.2.3) and of adenosine 5′-phosphosulfate sulfotransferase were measured. In addition, the occurrence of Cd-binding peptides (phytochelatins) and the contents of glutathione and cysteine were determined in roots of plants exposed to 20 micromolar Cd and/or 1 millimolar buthionine sulfoximine, an inhibitor of glutathione synthesis. An appreciable increase in activity of glutathione synthetase at 20 and 50 micromolar Cd and of adenosine 5′-phosphosulfate sulfotransferase at 5 micromolar and higher Cd concentrations was detected in the roots. Most of the additional thiols formed due to Cd treatment were eluted from a gel filtration HPLC column together with Cd, indicating the presence of phytochelatins. In plants treated with buthionine sulfoximine and Cd, no phytochelatins could be detected but the cysteine content increased 21-fold. Additionally, a larger increase in both enzyme activities occurred than with Cd alone. Taken together, our results are consistent with the hypothesis that glutathione is a precursor for phytochelatin synthesis.     

Genetic Regulation of Flowering in Grafts on Pisum sativum L

Lf, E, Sn, and Hr are major loci that condition the flowering and photoperiod responses of Pisum sativum L. Genetic lines containing the dominant alleles of these loci are characterized by flowering in long days, but having a prolonged (>50 node) vegetative phase in short days. A representative of this class, response type G, was used as a receptor in short days for donors of other flowering response types. The qualitative and quantitative flowering response of G receptors depended on the genotype of the donor. Donors containing sn hr induced the earliest development, followed by sn Hr and Sn hr donors. The Lf and E loci in foliar donors apparently did not affect flowering of G. Five-leaved > single-leaved > cotyledonary donors in effecting a flowering response in G, in part due to the longer life of the foliar donors. The responses of G to the various donors were generally consistent with the proposed roles of Lf, E, and Sn, but the role of Hr in these grafts was unclear.     

Developmental and Varietal Comparisons of Pod Carboxylase Levels in Pisum sativum L.

The activities of phosphoenolpyruvate (PEP) carboxylase andribulose-1, 5-bisphosphate (RuDP) carboxylase have been determinedin the developing pod walls of six genotypes of Pisum sativum.Genotypes were chosen which varied in pod characters such aschlorophyll content and tissue morphology, which it was hopedwould be associated with variation in carboxylase levels. Whilst both enzymes were detected in all genotypes, the levelsof activity varied considerably with pod type and with age.In general RuDP carboxylase activity correlated with chlorophyllconcentration, and yellow podded types had considerably lessactivity than green types. The yellow podded genotypes, however,contained significantly higher levels of PEP carboxylase which,in terms of total carboxylase activity, compensated for thelower RuDP carboxylase levels. The activities of both enzymes were determined within the endocarpand within the mesocarp plus exocarp, using 16-day-old pods.All genotypes showed an enrichment for PEP carboxylase in theendocarp and all but one genotype showed a similar enrichmentfor RuDP carboxylase activity in this layer. The role of the carboxylase enzymes within the pod wall is discussedand it is suggested that their main function may be to maintainan appropriate level of CO₂ within the pod cavity as well asrecycling carbon to the developing seeds. Pisum savitum L., pea, pods, carboxylase levels, genetic variation     

Purification and Characterization of Cytosolic NADP Specific Isocitrate Dehydrogenase from Pisum sativum

Cytosolic NADP-specific isocitrate dehydrogenase was isolated from leaves of Pisum sativum. The purified enzyme was obtained by ammonium sulfate fractionation, ion exchange, affinity, and gel filtration chromatography. The purification procedure yields greater than 50% of the total enzyme activity originally present in the crude extract. The enzyme has a native molecular weight of 90 kilodaltons and is resolved into two catalytically active bands by isoelectric focusing. Purified NADP-isocitrate dehydrogenase exhibited K_m values of 23 micromolar for dl-isocitrate and 10 micromolar for NADP, and displayed optimum activity at pH 8.5 with both Mg²⁺ and Mn²⁺.     

Sucrose Loading in Isolated Veins of Pisum sativum: Regulation by Abscisic Acid, Gibberellic Acid, and Cell Turgor

Enzymatically isolated vein networks from mature pea (Pisum sativum L. cv Alaska) leaves were employed to investigate the properties of sucrose loading and the effect of phytohormones and cell turgor on this process. The sucrose uptake showed two components: a saturable and a first-order kinetics system. The high affinity system (K_m, 3.3 millimolar) was located at the plasmalemma (p-chloromercuriphenylsulfonic acid and orthovanadate sensitivity). Further characterization of this system, including pH dependence and effects of energy metabolism inhibitors, supported the H⁺-sugar symport concept for sucrose loading. Within a physiological range (0.1-100 micromolar) and after 90 min, abscisic acid (ABA) inhibited and gibberellic acid (GA₃) promoted 1 millimolar sucrose uptake. These responses were partially (ABA) or totally (GA₃) turgor-dependent. In experiments of combined hormonal treatments, ABA counteracted the GA₃ positive effects on sucrose uptake. The abolishment of these responses by p-chloromercuriphenylsulfonic acid and experiments on proton flux suggest that both factors (cell turgor and hormones) are modulating the H⁺ ATPase plasmalemma activity. The results are discussed in terms of their physiological relevance.     

Changes in Chloroplast DNA Levels during Development of Pea (Pisum sativum)

Determinations were made of the percentage of chloroplast DNA (ct DNA) in total cell DNA isolated from shoots of pea at different stages of development. Labeled pea ct DNA was reassociated with a high concentration of total DNA; the percentage of ct DNA was estimated by comparing the rate of reassociation of this reaction with that of a model reaction containing a known concentration of unlabeled ct DNA. The maximum change in ct DNA content was from 1.3% of total DNA in young shoots to 7.3% in fully greened shoots. Analyses were also performed on DNA from embryos, etiolated tissue, roots, and leaves. The first leaf set to develop in pea was excised over a growth period of 8 days during which leaf length increased from 4 to 12 millimeters. Young leaves contained about 8% ct DNA; in fully greened leaves the level of ct DNA approached 12%, equivalent to as many as 9,575 copies of ct DNA per cell. Root tissue contained only 0.4% ct DNA.     

Effect of Ammonium, Sucrose and Light on the Regulation of Nitrate Reductase Level in Pisum sativum

In shoot apices of 7-day-old dark-grown peas the addition of ammonium along with the inducer nitrate resulted in a more than two-fold increase in nitrate reductase activity. Individual amino acids, amides and amino-acid mixture could not replace the ammonium effect. Ammonium also stimulated NADH-glutamate dehydrogenase but not glucose-6-phosphate dehydrogenase. Sucrose caused a marked stimulation of nitrate reductase induction and showed synergistic effect with light. In presence of cordycepin and cycloheximide, induction of nitrate reductase was inhibited more if ammonium or sucrose was supplied along with the inducer. With actinomycin D, α-amanitin or chloramphenicol, no differential inhibition took place in presence of ammonium. The inhibition of enzyme activity by chloramphenicol and 3-(3,4-dichlorophenyl)-l,dimethyl urea was completely relieved by sucrose. Incorporation of ¹⁴C-lysine was markedly stimulated by sucrose, but was not affected by ammonium. The effect of sucrose and light on ¹⁴C-lysine incorporation was additive. Cordycepin and cycloheximide did not have any differential effect on ¹⁴C-lysine incorporation in the presence of ammonium as well as sucrose. The inhibition of ¹⁴C-lysine incorporation caused by chloramphenicol was relieved by sucrose. Sucrose also caused a marked increase in ³H-uridine incorporation but ammonium had no effect. Actinomycin D and cordycepin blocked the sucrose dependent increase in ³H-uridine incorporation. The results suggest that ammonium mediated stimulation may depend on a regulatory protein(s) synthesized in response to ammonium, whereas sucrose acts mainly by an overall increase in RNA and protein synthesis. The effect of light does not seem to be dependent on photosynthetic light reactions.     

The Involvement of Cytokinin Oxidase/Dehydrogenase and Zeatin Reductase in Regulation of Cytokinin Levels in Pea (Pisum sativum L.) Leaves

Cytokinin metabolism in plants is very complex. More than 20 cytokinins bearing isoprenoid and aromatic side chains were identified by high performance liquid chromatography-mass spectrometry (HPLC-MS) in pea (Pisum sativum L. cv. Gotik) leaves, indicating diverse metabolic conversions of primary products of cytokinin biosynthesis. To determine the potential involvement of two enzymes metabolizing cytokinins, cytokinin oxidase/dehydrogenase (CKX, EC 1.5.99.12) and zeatin reductase (ZRED, EC 1.3.1.69), in the control of endogenous cytokinin levels, their in vitro activities were investigated in relation to the uptake and metabolism of [2−³H]trans-zeatin ([2−³H]Z) in shoot explants of pea. Trans-zeatin 9-riboside, trans-zeatin 9-riboside-5′-monophosphate and cytokinin degradation products adenine and adenosine were detected as predominant [2−³H]Z metabolites during 2, 5, 8, and 24 h incubation. Increasing formation of adenine and adenosine indicated extensive degradation of [2−³H]Z by CKX. High CKX activity was confirmed in protein preparations from pea leaves, stems, and roots by in vitro assays. Inhibition of CKX by dithiothreitol (15 mM) in the enzyme assays revealed relatively high activity of ZRED catalyzing conversion of Z to dihydrozeatin (DHZ) and evidently competing for the same substrate cytokinin (Z) in protein preparations from pea leaves, but not from pea roots and stems. The conversion of Z to DHZ by pea leaf enzyme was NADPH dependent and was significantly inhibited or completely suppressed in vitro by diethyldithiocarbamic acid (DIECA; 10 mM). Relations of CKX and ZRED in the control of cytokinin levels in pea leaves with respect to their potential role in establishment and maintenance of cytokinin homeostasis in plants are discussed.     

Pigments and Gas Exchange Characteristics in Leaves of Chlorophyll Mutants of Pisum sativum

Quantitative and qualitative characteristics of pigment composition and gas exchange were studied in chlorophyll mutants of pea, Pisum sativum L.: chlorotica 2004 and 2014. The mutant 2004 had light-green color, whereas the mutant 2014 has yellow-green leaves and stems; they contained about 80 and 50% of chlorophyll, respectively, compared to the initial line. cv. Torsdag. Leaves of the mutant 2004 had significantly lower carotene content and accumulated more lutein and violaxanthin. In the mutant 2014, the contents of chlorophyll and all carotenoids were reduced almost proportionally. The quantum efficiency of photosynthesis was by 29–30% lower in the mutants, and it was 1.5–2 times higher in F₁ hybrids, as compared to control plants. Our data allow us to conclude that the impairment of photosynthesis in the mutant 2014 is caused by the changed mesostructure of leaves, whereas in the mutant 2004, it may be caused by an impairment of photosystem reaction centers.     

Apyrase,streptavidin-binding proteins,and antimicrobial activity in Pisum sativum

The 49 kD apyrase (EC 3.6.1.5), streptavidin-binding proteins, and antimicrobial activity in the subcellular fractions from different seed parts of Pisum sativum L. var. Alaska were examined. Except cotyledons, all subcellular fractions contained 49 kD apyrase, and a considerable relationship was found between 49 kD apyrase and NTPase activities that increased with increasing time of germination. The bulk of 49 kD apyrase and NTPase activities was found in the nucleus pellets and cytoskeleton-enriched fraction, indicating their physiological importance. At 72 h of germination, all subcellular fractions of primary stems have a greater amount of 49 kD apyrase and NTPase than primary leaves and much more than primary roots and cotyledonary stalks. All seed parts showed antimicrobial activities, and the bulk of inhibition activities was found in the cytoskeleton-enriched and nucleus pellets, which was greater in the primary stems and leaves than in other parts. Current findings reveal that apyrases have important roles in metabolic activities in all parts of the pea plants except cotyledons. Cotyledons contained much streptavidin-binding proteins, which might have different physiological roles than apyrases.     

Dominance,overdominance and epistasis in Pisum sativum L.

Summary Dominant genes are the main cause of the heterosis induced by fasciated mutants of different lines of Pisum sativum. Most of these cases were originally interpreted by different authors as examples of monogenic overdominance. Several not-closely-linked genes appear to have mutated simultaneously in most of the fasciated lines. Although fasciation itself is recessive, other mutant characters, such as lateness, increased stem length (number and length of internodes) and, in part, seed production per plant, show dominant inheritance. The latter two features are, however, to a considerable extent suppressed in the fasciated lines by unfavourable gene-interactions (epistasis). Crossing these lines with non-fasciated ones shows that the epistatic genes are recessive and the dominant genes are then no longer hindered in their action. By eliminating the epistatic genes from the genomes of fasciated lines by recombination, the heterosis phenomenon has been fixed on six independent occasions for different lines. The fasciata genes themselves were found to be the most probable cause of these cases of recessive epistasis. The question whether different kinds of fasciation affect heterosis differently is examined. Recessive epistasis and dominance explain most of the quantitative distinctions between the different hybrids. In addition, one example of heterosis between non-fasciated lines is given and the possible meaning of the overall results for plant breeding and population genetics is mentioned.     

Relationship between gibberellin, ethylene and nodulation in Pisum sativum

? Gibberellin (GA) deficiency resulting from the na mutation in pea (Pisum sativum) causes a reduction in nodulation. Nodules that do form are aberrant, having poorly developed meristems and a lack of enlarged cells. Studies using additional GA-biosynthesis double mutants indicate that this results from severe GA deficiency of the roots rather than simply dwarf shoot stature. ? Double mutants isolated from crosses between na and three supernodulating pea mutants exhibit a supernodulation phenotype, but the nodule structures are aberrant. This suggests that severely reduced GA concentrations are not entirely inhibitory to nodule initiation, but that higher GA concentrations are required for proper nodule development. ? na mutants evolve more than double the amount of ethylene produced by wild-type plants, indicating that low GA concentrations can promote ethylene production. The excess ethylene may contribute to the reduced nodulation of na plants, as application of an ethylene biosynthesis inhibitor increased na nodule numbers. However, these nodules were still aberrant in structure. ? Constitutive GA signalling mutants also form significantly fewer nodules than wild-type plants. This suggests that there is an optimum degree of GA signalling required for nodule formation and that the GA signal, and not the concentration of bioactive GA per se, is important for nodulation.     

Nodulation and nitrogen fixation mutants of pea,Pisum sativum

Summary The 36 mutants which did not nodulate and 24 mutants which formed inefficient nodules with no or very low acetylene reduction activity were isolated among 86,000 M₂-seedlings of Finale pea, Pisum sativum L., after treatment with chemical mutagens. One mutant was found for approximately every 50 chlorophyll mutants. Most mutations were induced by ethyl methanesulfonate; some by diethyl sulfate, ethyl nitrosourea and acidified sodium azide. Putative mutants were selected as nitrogen deficient plants, yellowing from the bottom and up, when M₂ seedlings were grown in sand with a Rhizobium mixture and PK fertilizer. The mutants were verified in the M₃ generation by acetylene reduction assay on intact plants.     

Auxin Physiology of Dwarfism in Pisum sativum

Similar levels of diffusible auxin are measured for the apices of both Little Marvel (dwarf) and Alaska (normal) cultivars of the pea when grown in sunlight and darkness. In sunlight, however, diffusible auxin disappears in the subtending internode of the Little Marvel plant but remains at 50 per cent of the level of the apex in the subtending internode of the Alaska plant. The enzyme preparation from the apex of the dwarf plant converts tryptophan and tryptamine to IAA more readily than that from the normal plant. Indoleacetyl aspartate synthetase activity is also higher in the dwarf plant than in the normal plant and the dwarf plant contains four times as much conjugate as the normal plant with or without treatment with gibberellic acid. Gibberellic acid (GA) does not affect the induction of the synthetase enzyme nor the enzymatic formation of indoleacetyl aspartate. The growth induced by GA is the result of an increased synthesis of auxin.     

Glucolipids of Zea mays and Pisum sativum

The glucolipids formed upon feeding (U-¹⁴C)glucose to embryos of Zea mays were partially characterized with respect to: (a) metabolic turnover, (b) acid lability, (c) phosphorus content, (d) chromatographic properties, and (e) hydrolysis products. The chloroform-methanol-soluble assimilated radioactivity was examined specifically for occurrence of a glycosylated prenol phosphate. With the extraction conditions used, no evidence was found for formation of a glucosylated prenol phosphate. Several, as yet unidentified, acid-labile glucolipids undergoing metabolic turnover were observed. Four diglycerides were characterized as hydrolysis products of a fraction that contained ¹⁴C-glucose and phosphorus, and was subject to metabolic turnover. Examination of the 1-butanol-soluble glucolipids from pea (Pisum sativum) seedlings also demonstrated anionic glucolipids, evidencing metabolic turnover but none with the properties of glucosylated prenol phosphate.