Expression of transferred genes during hairy root development in pea

Root border cell development and expression of reporter genes were evaluated in transgenic pea hairy roots. Successful induction of hairy roots in pea is conditioned by bacterial strain and plant genotype, as well as by developmental and environmental factors. Morphological changes sometimes occur when hairy roots are transferred from infected plants to tissue culture media, but such changes are confined to specific clones. Expression of reporter genes under the control of promoters from bean (Phaseolus vulgaris L.) stress genes encoding phenylalanine ammonia lyase and chalcone synthase were evaluated. Expression patterns vary between hairy roots taken directly from infected plants, and those grown in culture; most hairy roots taken from infected plants exhibit expression throughout all tissues, whereas expression in cultured hairy roots is most often localized to specific tissues. Patterns of expression that occur during different stages of hairy root development are very similar to those observed in transgenic plants expressing the same fusion genes. Border cell separation and release in hairy roots is normal, and expression of glucuronidase in border cells of some transgenic roots resulted in development of bright blue single cells. Cultured hairy roots should provide a very useful model for studying the effect of defined changes in root border cells on microbial associations with roots of this important legume.Abbreviations YEM yeast extract-mannitol - GUS glucuronidase - PAL phenylalanine ammonium lyase - CHS chalcone syntase     

Lateral root formation in pine seedlings

The role of assimilates in lateral root development was studied in Pinus pinea seedlings grown in a nutrient solution. Seedlings were treated with ¹⁴CO₂ for 2 h following removal of the tap root tip at various times prior to the application of ¹⁴CO₂ or removal of a different number of cotyledons at one time. In seedlings with intact root systems most of the radioactivity accumulated in the lower section of the root containing the tap root apex. When the tap root tip was removed, the pattern of radioactivity accumulation along the root was affected by the presence and the stage of lateral root development. Removing the tap root tip of young seedlings (with no lateral roots) resulted in an almost equal distribution of radioactivity along the root. About 50% of the total radioactivity was found in the section showing the highest lateral root growth. Removing the tap root tip of mature seedlings (with lateral roots in the upper section) resulted in an immediate increase in the radioactivity accumulation in the upper section. When lateral roots appeared in the middle section, the pattern of radioactivity distribution was similar to that found in root decapitated young seedlings. Removal of cotyledons of mature seedlings somewhat increased the transport of radioactivity to the lower root section at the expense of the radioactivity in the lateral roots of the upper section. The present study suggests that competition within the root system between the tap root apex and the lateral roots may play an important role in determining the morphology of the root system.     

Stimulatory effect of cytokinins and interaction with IAA on the release of lateral buds of pea plants from apical dominance

Lateral buds of pea plants can be released from apical dominance and even be transformed into dominant shoots when repeatedly treated with synthetic exogenous cytokinins (CKs). The mechanism of the effect of CKs, however, is not clear. The results in this work showed that the stimulatory effects of CKs on the growth of lateral buds and the increase in their fresh weights in pea plants depended on the structure and concentration of the CKs used. The effect of N-(2-chloro-4-pyridyl)-N'-phenylurea (CPPU) was stronger than that of 6-benzylaminopurine (6-BA). Indoleacetic acid (IAA) concentration in shoot, IAA export out of the treated apex and basipetal transport in stems were markedly increased after the application of CPPU or 6-BA to the apex or the second node of pea plant. This increase was positively correlated with the increased concentration of the applied CKs. These results suggest that the increased IAA synthesis and export induced by CKs application might be responsible for the growth of lateral shoots in intact pea plants.     

The effect of surface soil consolidation on the early root development of pea (Pisum sativum L.)

Cores of repacked soil were consolidated with a compressive strength testing machine, after peas had been planted in the centre of the core. The number that emerged were counted and root and shoot lengths and diameters were measured. Consolidation had no effect on emergence, root length or root diameter of the peas grown in a loamy sand, whereas emergence, root length and root diameter were affected by a small increase in load in a clay loam.     

Division frequency of pea protoplasts in relation to starch accumulation

Division frequency of alginate-embedded pea (Pisum sativum var. Belman) protoplasts derived from embryonic shoot tips was studied quantitatively by image analysis in relation to starch accumulation and protoplast size. Protoplast divisions were observed from day 4 on and the number of protoplasts undergoing division increased in a stepwise manner to 70% the following days. The starch content increased rapidly during the first 3 days of culture prior to the onset of division and resulted a 4.2-fold increase in the intracellular starch area and a 3.0-fold increase (from 27% to 80%) in the number of protoplasts containing starch. Subsequent periods with rapid increases the number of dividing protoplasts were preceded by further starch accumulation. Dividing protoplasts were 33–60% smaller and contained 8–42% less starch than non-dividing protoplasts. However, calculations showed that, in the dividing protoplasts, the relative area covered by starch was 6–12% higher than in non-dividing protoplasts. These data suggest that starch accumulation precedes division of pea protoplasts.     

The role of ethylene in the control of cell division in cultured pea root tips: a mechanism to explain the excision effect

Summary A transitory cell division block, or excision effect, occurs in the meristem of roots after excision and transfer to culture medium. This block can be induced, in intact seedling roots, by exogenous treatment with ethylene gas. With continuous treatment, the block is longer and the recovery less than after a 4 hour pulse. In excised roots the excision effect can be eliminated by treatment with an inhibitor of ethylene synthesis (aminoethoxyvinylglycine) or action (silver thiosulfate). These experiments provide evidence to support the hypothesis that ethylene from the wounded end of an excised root is involved in a process resulting in a transitory block in cell cycle progression in the meristem. The implications of this hypothesis are discussed.     

Changes induced on the prolamellar body of pea seedlings by white,red and blue low intensity light

Summary We analyzed transformation, recrystallization, splitting and dispersion of prolamellar bodies during chloroplast development in pea seedlings illuminated by white, red and blue light of low intensity. With the help of a stereometric method we determined that there was a significant increase of prolamellar body number and a sharp decrease of their volume in differentiating chloroplast even in the first 2 hours of illumination. Decrease of prolamellar body dimensions was due both to gradual dispersion of its elements into primary thylakoids (indicated by the decrease of total volume of prolamellar bodies in plastid) and to splitting of prolamellar bodies (indicated by the increase of number of promellar bodies in plastid). Red light was more effective in transformation, splitting and dispersion of prolamellar bodies than blue light during the first 8–12 hours. Longer treatment with blue light had a stronger influence on these processes and on complete recrystallization than other light treatments.     

Sulphate uptake and xylem loading of young pea (Pisum sativum L.) seedlings

Sulphate uptake and xylem loading was analysed in young pea (Pisum sativum) seedlings. The rate of sulphate uptake into intact 8-days-old pea seedlings (determined by a 1 h exposure to radiolabelled sulphate in the nutrient solution) was 585 nmol sulphate g^–1 root fresh weight h^–1. When the cotyledons were removed on day 6 the 8-days-old seedlings took up only 7% of the controls. Interruption of the phloem transport by steam girdling of the stem or the root (1 h before incubation with radiolabelled sulphate) diminished sulphate uptake by approximately 50%. The addition of sucrose to the nutrient solution during incubation did not restore sulphate uptake rates indicating that the decrease was not due to a lack of energy. Apparently, a signal from the shoot and/or the cotyledons is necessary to stimulate sulphate uptake into the roots of pea seedlings. Glutathione fed to the roots for 3 h prior to incubation with radiolabelled sulphate diminished sulphate uptake by approximately 50%. The relative proportion of the sulphate taken up that was loaded into the xylem remained unchanged (between 7 and 9% of total uptake), even when the stem was girdled above the cotyledons or when the seedlings were pre-exposed to glutathione. Only removal of the cotyledons or girdling of the root below the cotyledons increased the proportion of sulphate loaded into the xylem to 13–15% of total uptake upon exposure to glutathione. Apparently, a signal from the cotyledons represses xylem loading to some extent.     

Polysome formation and stability in pea stem and root tissue

Polysome stability and the formation of various polysomal populations in pea stem and root tissue were examined. Both total ribosomal fraction and four polysome populations were isolated: FP (free polysomes), MBP (membrane-bound polysomes), CBP (cytoskeleton-bound polysomes) and CMBP (cytoskeleton-membrane-bound polysomes). The content of above mentioned populations decreased in roots and stems during germination. In both roots and stems a gradual decrease of FP participation in the total polysomal population was also observed during germination. On the other hand, an obvious increase in participation of CMBP population in the total polysomes pool was observed in later stages of germination. Increase of CMBP participation in pea root and stem tissues in later stages of germination is probably due to intensive enzymatic protein synthesis taking place in them. These proteins may participate in elongating growth of cells. The results of investigation on polysomes stability showed that total polysomes isolated from pea roots appeared to be more resistant to digestion by exogenous ribonuclease (EC 3.1.27.5) than polysomes isolated from stems. As protein-mRNA interactions are widely known and ribosomes are also very adhesive structures, numerous non-ribosomal proteins are present in the polysome preparations. We suppose that changes in proteins bound to polysomes indicated by us previously, significantly influence both the stability and also translatability of polysomes isolated from different plant organs.     

Identification of the cytokinins in red pine seedlings

Zeatin-9-riboside was identified in shoots and roots of Pinus resinosa by GC-MS analysis of its permethyl derivative. Based on their chromatographic properties on Sephadex LH-20 and C₁₈ HPLC, and their susceptibility to enzymatic degradation, several other cytokinins have been tentatively identified. The basic fraction of both the roots and shoots contained zeatin, whereas the shoots contained dihydrozeatin-O-glucoside and the roots contained zeatin-O-glucoside. Zeatin-9-riboside monophosphate, isopentenyladenosine monophosphate ([9R-5P]iP) and glucosyl phosphate derivatives were detected in the acidic fractions from both roots and shoots. There were equivalent amounts of [9R-5P]iP in both roots and shoots. The presence of equivalent amounts of [9R-5P]iP in both the roots and shots suggests that cytokinin biosynthesis may be occurring in both locations.Abbreviations AMP adenosine-5-monophosphate - BAP benzylaminopurine - BSA bovine serum albumin - BuOH butan-1-ol - CK cytokinin - (diH)Z dihydrozeatin - (diH OG)Z dihydrozeatin-O-glucoside - (diH OG)[9R]Z dihydrozeatin-9-riboside-O-glucoside - DW dry weight - EtOH ethanol - FW fresh weight - GC-MS gas chromatography-mass spectrometry - HPLC high-performance liquid chromatography - [9R]iP isopentenyladenosine - [9R-5P]iP isopentenyladenosine monophosphate - MeOH methanol - PVP polyvinylpyrrolidone - RFE rotary film evaporation - TEAB triethyl ammonium bicarbonate - Z zeatin - [9R]Z zeatin-9-riboside - (OG)Z zeatin-O-glucoside - [7G]Z zeatin-7-glucoside - [9R-5P]Z zeatin-9-riboside monophosphate     

Possible control sites of polysaccharide synthesis during cell growth and wall expansion of pea seedlings (Pisum sativum L.)

The activities of the enzymes of uridine diphosphate sugar interconversions (UDP-D-glucose 4-epimerase, UDP-D-glucuronate 4-epimerase, UDP-D-xylose 4-epimerase, UDP-D-glucose dehydrogenase and UDP-D-glucuronate decarboxylase) were measured by using enzymic preparations (protein precipitated between 40–65% (NH₄)₂SO₄ saturation) isolated from segments at different stages of elongation of the third internode of pea seedlings. All enzymic activities increased from dividing and non-elongated cells to fully elongated cells. At all stages of growth, the specific activity or the activity per cell of UDP-D-glucose dehydrogenase was much lower than that of UDP-D-glucuronate decarboxylase and this may represent a controlling step in the formation of UDP-D-xylose. During elongation, changes were also found in the activities of the epimerases. These could be correlated with the corresponding variations which occur in the chemical structure and physical properties of pectins during cell wall extension. However, the high levels of the epimerases present in cells which have completed elongation growth suggest that pectin synthesis is mainly controlled at the sites of the synthetase reactions.     

The effects of root decapitation on lateral root formation and cytokinin production in Pisum sativum

Decapitation of the primary roots of Pisum sativum L. resulted in a significant increase in the initiation of lateral root primordia within 12 h of the surgical treatment. Although this increase occurred both in the light and in the dark, lateral root initiation and development was much more rapid in the dark. The formation of lateral root primordia was accompanied by increased levels of endogenous cytokinins suggesting that newly formed root primordia start producing cytokinins very soon after being initiated. The significance of the present results in terms of possible sites of synthesis in vegetative tissue is discussed.     

Dynamics of localization and protein composition of plastid nucleoids in light-grown pea seedlings

Summary Localization and protein composition of plastid nucleoids was analyzed in light-grown pea seedlings at various stages of leaf development. In young plastids of unopened leaf buds, nucleoids were abundant and localized in the periphery of plastids, whereas, in mature leaves, chloroplasts contained nucleoids within narrow spaces restricted by thylakoids or grana. The migration of nucleoids into the interior of plastids preceded the formation of grana, and hence, the maturation of the photosynthetic apparatus. The protein composition of nucleoids was considerably different in young plastids and mature chloroplasts. Polypeptides with a molecular mass of 70–100 kDa predominated in the nucleoids of young plastids, whereas polypeptides with molecular mass of 20–30 kDa were abundant in the nucleoids of mature chloroplasts. Immuno-blot analysis with antibodies against the nucleoids of young plastids identified various polypeptides that were significantly more abundant in the nucleoids of young plastids than in the nucleoids of mature chloroplasts. These results demonstrate that plastid nucleoids are subject to dynamic changes in both localization and composition during the normal development of chloroplasts in the light.Abbreviations DAPI 4,6-diamidino-2-phenylindol - DiOC₆ 3,3-dihexyloxacarbocyanine iodide     

Insertion polymorphism in pea chloroplast DNA

Summary The chloroplast DNA of higher plants is suitable for restriction endonuclease analysis due to its size and homogeneity. We have analysed 48 different cultivars of pea (Pisum sativum) with EcoRI and HindIII. Of these, only 24 show the standard genotype, the remaining 24 comprise four different classes of short insertions, three of which are found at the same site. Even though this kind of insertion polymorphism has not been detected elsewhere in the plant kingdom, it is consistent with the discovery that the chloroplast DNA of pea is destabilised through the loss of an inverted repeat.     

Nitrogen transfer in the interface between the symbionts in pea root nodules

Transport mechanisms for transfer of nitrogen from the bacteroid side across the symbiosome membrane of pea (Pisum sativum L.) root nodules were identified by the use of energised bacteroid side-out symbiosome membrane vesicles. Such membrane vesicles were used to study a mechanism with high capacity for transport of ammonium and another mechanism capable of transporting aspartate. Both transport mechanisms are voltage driven and the rate of transport relates positively to the magnitude of the imposed membrane potentials. Competition for transport between ammonium and aspartate was not observed. The ammonium transporter has been identified as a voltage-driven channel whereas the symbiosome membrane aspartate transporter appears to be a H⁺/aspartate symport. The results suggest that nitrogen transfer between the symbionts in pea root nodules involves transfer of amino acids as well as ammonium. In the symbiosome subfraction, which represents the interface between the symbionts, specific aspartate aminotransferase activity was more than four times as high as in the bacteroid cytosol. This finding supports a hypothesis that transamination cycles operating between the symbionts may constitute a component of the transfer of nitrogen between the symbionts.     

Effects of auxins,cytokinins, carbohydrates and amino acids on somatic embryogenesis induction from shoot apices of pea

Studies were conducted to test the effects of various auxins, cytokinins, carbohydrates and amino acids on somatic embryogenesis from shoot apices of pea (Pisum sativum L.) cultured on a sole medium. Picloram (4.5 M) and 4-chlorophenoxyacetic acid (45 M) were the most effective auxins. Addition of cytokinins (benzyladenine, zeatin, kinetin) to auxin-containing medium reduced embryo production. Amino acids (glutamine, alanine, proline) did not improve somatic embryogenesis. Carbohydrate seemed to be a critical factor. Embryogenic efficiency and embryo development were promoted by high carbohydrate concentration. The best results were obtained with fructose (252–504 mM); the number of somatic embryos per cultured explant was 3- to 4-fold higher compared to the control (84 mM sucrose). From these results, an optimized induction medium is proposed.Abbreviations BA benzyladenine - 4-CPA 4-chlorophenoxyacetic acid - 2,4-d 2,4-dichlorophenoxyacetic acid - NAA 1-naphthaleneacetic acid - 2,4,5-T 2,4,5-trichlorophenoxyacetic acid - MS Murashige & Skoog - EE embryogenic explants - G globular somatic embryos     

Fasciation in pea: Basic principles of morphogenesis

A study of fasciated pea Pisum sativum L. (Fabaceae) mutant Shtambovy in comparison with the wild type (Nemchinovsky cultivar) has shown that fasciation is a result of abnormal cohesion of axial or other structures which arise in a superfluous amount due to uncontrolled meristic processes. In some cases, the organs with the same number and position as in the wild type can be fascinated. Subsequent defasciation and some features of tissue differentiation suggest that the meristem of a fasciated shoot retains a certain degree of discreteness which reflects its complex structure. The number and position of leaves in a node is a function of the diameter of the leaf primordium inhibitory zone, size of the shoot apical meristem, and number of bundles in a shoot. In the absence of the apex proliferative activity combined with the reduction of phyllomes in the upper nodes, abnormal cohesion of the second order axes, racemes, can take place. As a result, inflorescences of special type develop.     

Development of photosynthetic apparatus and respiration in pea seedlings during greening as influenced by toxic concentration of lead

Detached leaves of 14 day-old dark-grown pea seedlings were immersed with their cut ends either in water (control) or in 20 mM Pb(NO₃)₂ solution. They were exposed to continuous illumination during 24 and 48 h. The formation of PSII primary photochemistry in thylakoids was determined in vivo by measuring changes in values of parameters of chlorophyll a fast fluorescence kinetics: Fo, Fm, Fv, Fv/Fm and t 1/2. The amount of lead accumulation in leaves, content of chlorophylls and carotenoids and rates of CO₂ uptake in light and evolution in darkness (Pn-net photosynthesis and DR - dark respiration respectively) were determined. It has been found that with the exception of Fo, values of Fv, Fm and Fv/Fm were reduced by Pb²⁺. The values of t 1/2 were significantly larger in Pb²⁺ treated leaves. Decrease in the chlorophyll a fluorescence parameters was paralleled with the strong inhibition by this metal the biosynthesis of chlorophyll a and b but less of the carotenoids. Pb²⁺ drastically reduced Pn but had a stimulatory action on DR after 24 h and small inhibition of DR after 48 h exposure of leaves to this metal. As a consequence, after 48 h of greening the ratio of DR/Pn of control leaves was 0.45 whereas in Pb²⁺ treated leaves 2.7. It is proposed that DR in leaves plays a protective role against damage of Pn by Pb²⁺. Protection can be due to the supply the respiratory derived reductant and ATP to carry out cell metabolism upon reduced photosynthesis.     

Plasmodesmal widening accompanies the short-term increase in symplasmic phloem unloading in pea root tips under osmotic stress

Summary Root tips ofPisum sativum seedlings were exposed to 350 mM mannitol, which was shown to effect a transient but dramatic increase in phloem unloading, and investigated by electron microscopy. After chemical fixation and embedding, extremely thin sections of the root extension zone were examined. Outer, inner, and desmotubule diameters of 830 primary plasmodesmata in transverse walls of cortical cells were measured. Statistical analysis indicated that the majority of plasmodesmata had no neck constriction during osmoregulation. Compared to controls, a highly significant increase in mean plasmodesmata diameter was found, but the desmotubule diameter remained unchanged. Both loss of neck constriction and widening of the cytoplasmic sleeve indicate an increase in effective passage area of plasmodesmata. Spokes between plasma membrane and desmotubule were preserved. Continued exposure of the root tips to mannitol led to a return to control values for plasmodesmal diameters. In contrast to these responses, plasmolysis of cortical cells by 1,000 mM sucrose, diminishing phloem unloading, was accompanied by a reduction in those plasmodesmata classified as open. This is the first report showing a correlation between the ultrastructure of plasmodesmata and the rate of symplasmic transport. The role of the different plasmodesmal components in controlling the passage area of symplasmic transport is discussed.