Compensatory response of a legume root-nodule system to nodule herbivory by Sitona hispidulus

A laboratory study was conducted to examine the hypothesis that herbivory of nitrogen-fixing root nodules on legumes causes an exact compensatory response in nodule growth. Plants of Medicago sativa (L.) were grown hydroponically in clear plastic growth pouches so that the number and biomass of root nodules could be estimated nondestructively before, and 10 and 18 days after, partial denodulation. For treatments, plants were subjected to 23% denodulation by first-instar larvae of Sitona hispidulus (F.) (a common herbivore of Medicago and Trifolium) or 50% nodule pruning; additional plants were left untreated. Results indicated that nodule herbivory and nodule pruning caused an overcompensatory response in number of nodules. This was also true for number of nodule units (an indirect measure of nodule biomass) per plant at 10 days after denodulation but had changed to an exact compensatory response by day 18. An inverse relationship between change in number of nodule units and initial number of nodules indicated that compensatory nodulation was regulated by a feedback mechanism. Shoot and root biomasses were not affected by denodulation in this study.     

Survival and growth of pea protoplasts after transformation by electroporation

Protoplasts from two different pea cultivars, Belman and Filby, were stably transformed by direct gene transfer using electroporation. Transgenic calli could be obtained after selection, when hygromycin resistance was used as the selective trait introduced into the protoplasts, while no transformants were obtained when kanamycin resistance was used as selective marker in either of the two pea cultivars tested. The effect of the field strength on survival and division rates of the protoplasts was studied. Two different culture systems and osmotica were compared for induction of sustained divisions in and regeneration of transgenic callus from the protoplasts. The choice of the culture system had a considerable effect on the initial division frequency of the treated protoplasts, as well as on the later growth of the colonies. Transformation efficiency was monitored by histochemical GUS assay, and the transgenic nature of the calli selected for resistance against antibiotics was confirmed by DNA analysis.     

Interaction of pea (Pisum sativum L.) lectins with rhizobial strains

Lectins from two varieties (PG-3 and LFP-48) of pea have been purified by affinity chromatography on Sephadex G-50. The specific activity increased by 23 and 25 folds, respectively. These lectins from both the varieties were found to be specific for mannose. The purified fluorescein isothiocyanate (FITC) – labelled lectins showed binding reaction with homologous as well as heterologous strains of Rhizobium spp. The results revealed that pea lectins are not highly specific to their respective rhizobia. Moreover, these lectins showed a greater stimulatory effect on homologous Rhizobium leguminosarum strains.     

The effect of elevated UV-B radiation on herbivory of pea byAutographa gamma

Leaves exposed to above-ambient fluxes of ultraviolet-B (UV-B) radiation commonly contain increased concentrations of phenolic compounds which may influence herbivores. However, the hypothesis that elevated UV-B modifies herbivory, whether mediated by phenolics or other plant constituents, has rarely been studied experimentally. We investigated the responses of the mothAutographa gamma L. (Lepidoptera: Noctuidae) to pea (Pisum sativum L.) grown at a range of plant-effective UV-B fluxes. Although total phenolics did increase significantly with increasing UV-B, this change had little deleterious effect on the 5th instar larvae ofA. gamma. However, tissue nitrogen also increased with increasing UV-B. Increased nitrogen was correlated with an increase in the efficiency with which larvae utilized their food and in larval growth rate, but in a reduction in the amount of plant material consumed. The apparently major role of nitrogen in determining herbivore responses to changing UV-B demonstrates the risks in predicting such responses soley on the basis of changes in phenolics and other secondary metabolites.     

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.     

Pea dehydrins: identification,characterisation and expression

An antiserum raised against dehydrin from maize (Zea mays) recognised several polypeptides in extracts of pea (Pisum sativum) cotyledons. A cDNA expression library was prepared from mRNA of developing cotyledons, screened with the antiserum and positive clones were purified and characterised. The nucleotide sequence of one such clone, pPsB12, contained an open reading frame which would encode a polypeptide with regions of significant amino acid sequence similarity to dehydrins from other plant species.The deduced amino acid sequence of the pea dehydrin encoded by B12 is 197 amino acids in length, has a high glycine content (25.9%), lacks tryptophan and is highly hydrophilic. The polypeptide has an estimated molecular mass of 20.4 kDa and pI=6.4. An in vitro synthesised product from the clone comigrates with one of the in vivo proteins recognised by the antiserum.A comparison of the pea dehydrin sequence with sequences from other species revealed conserved amino acid regions: an N-terminal DEYGNP and a lysine-rich block (KIKEKLPG), both of which are present in two copies. Unexpectedly, pea dehydrin lacks a stretch of serine residues which is conserved in other dehydrins.B12 mRNA and dehydrin proteins accumulated in dehydration-stressed seedlings, associated with elevated levels of endogenous abscisic acid (ABA). Applied ABA induced expression of dehydrins in unstressed seedlings. Dehydrin expression was rapidly reversed when seedlings were removed from the stress or from treatment with ABA and placed in water.During pea cotyledon development, dehydrin mRNA and proteins accumulated in mid to late embryogenesis. Dehydrin proteins were some of the most actively synthesised at about the time of maximum fresh weight and represent about 2% of protein in mature cotyledons.     

Maximum axial root growth pressure in pea seedlings: effects of measurement techniques and cultivars

Values of the maximum axial growth pressure (σ_max) of seedling pea (Pisum sativum L.) roots reported in the literature, obtained using different apparatuses and cultivars, range from 0.3 MPa to 1.3 MPa. To investigate possible reasons for this large range, we studied the effect of apparatus and cultivar on measurements of σ_max in peas. We describe four types of apparatus which can be used to measure axial root growth force and hence σ_max, and used them to measure σ_max in seedling pea roots using cultivar Meteor. Two of these apparatuses were also used to compare σ_max for three pea cultivars (Helka, Meteor and Greenfeast). Both cultivar and apparatus significantly affected σ_max , but there were greater differences between apparatuses than between the three cultivars. Estimating root cross-sectional area from the diameter of cross-sections, rather than from in situ measurements (i.e. measurements made with the root still in place in the apparatus) may explain these differences. This revised version was published online in June 2006 with corrections to the Cover Date.     

Inheritance of seed yield and quality traits in peas (Pisum sativum L.)

Summary A half diallel analysis involving nine cultivars showed that additive as well as non-additive gene effects were important for the inheritance of seed yield per plant, 100-seed weights, protein content and potassium per cent. For remaining traits non-additive genetic components were important. Overdominance was observed for all traits except for 100-seed weight, which expressed partial dominance. Parents PMR-T10, EC21857, EC109182, T163 and EC109189 were good general combiners for seed yield, seed weight and quality traits. In general there was a good relationship between per se performance and the gca effects of the parents for all traits. Cross combinations such as LMR8 x EC109182,LMR8 x PMR-T10,LMR8 x EC21857,PMRT10 x EC21857 and P23 x EC21857 were found promising. The seed yield was positively correlated with other quality traits. Protein had a positive correlation with methionine and phosphorus. All the values of correlation co-efficients were non-significant except for yield with potassium, 100-seed weight and protein with methionine, indicating that yield and quality attributes can be improved simultaneously by simple selection procedures.     

A dehydrin cognate protein from pea (Pisum sativum L.) with an atypical pattern of expression

Dehydrins are a family of proteins characterised by conserved amino acid motifs, and induced in plants by dehydration or treatment with ABA. An antiserum was raised against a synthetic oligopeptide based on the most highly conserved dehydrin amino acid motif, the lysine-rich block (core sequence KIKEK-LPG). This antiserum detected a novel M _r 40 000 polypeptide and enabled isolation of a corresponding cDNA clone, pPsB61 (B61). The deduced amino acid sequence contained two lysine-rich blocks, however the remainder of the sequence differed markedly from other pea dehydrins. Surprisingly, the sequence contained a stretch of serine residues, a characteristic common to dehydrins from many plant species but which is missing in pea dehydrin.The expression patterns of B61 mRNA and polypeptide were distinctively different from those of the pea dehydrins during seed development, germination and in young seedlings exposed to dehydration stress or treated with ABA. In particular, dehydration stress led to slightly reduced levels of B61 RNA, and ABA application to young seedlings had no marked effect on its abundance.The M _r 40 000 polypeptide is thus related to pea dehydrin by the presence of the most highly conserved amino acid sequence motifs, but lacks the characteristic expression pattern of dehydrin. By analogy with heat shock cognate proteins we refer to this protein as a dehydrin cognate.     

Efficient adventitious shoot regeneration and somatic embryogenesis in pea

A rapid and simple method for adventitious shoot regeneration and somatic embryogenesis from immature cotyledon explants of pea (Pisum sativum L.) is described. Cotyledon size and the explant orientation to the medium surface were shown to have a clear effect on shoot regeneration. The highest frequency of shoot regeneration was achieved when the distal end of the greenest cotyledons (7–8 mm in size) were placed in contact with the agar surface. Shoots rooted at a frequency of 80–90% and grew into normal fertile plants. Somatic embryos were induced in cultures of immature cotyledons on modified MS medium containing high levels of -naphthaleneacetic acid (27–215 M) and 2,4-dichlorophenoxyacetic acid (23–181 M). A higher frequency of somatic embryos with a normal morphology were induced using -naphthaleneacetic acid.Abbreviations BA 6-benzyladenine - 2,4-d dichlorophenoxyacetic acid - IBA indole-3-butyric acid - NAA -naphthaleneacetic acid     

Biophysics of the growth responses of pea roots to changes in penetration resistance

Two experiments were performed in simplified soil-less systems to study how roots respond to changes in mechanical impedance. In the first the increases in root force and diameter that occur when a pea root was impeded mechanically inside a hole with rigid conical walls were determined. The experiment was performed at 8°C and at 25°C, and the root growth pressures generated were calculated during periods of 12, 24, 48 and 72 hours. The maximum growth pressures generated were approximately the same at both temperatures, although the maximum pressure was achieved approximately twice as quickly at 25°C than at 8°C, being reached within 15–20 hours. In the second set of experiments a new technique was developed to measure simultaneously the elongation rate and the force exerted by the roots of seedlings grown in moist air. A constant force was exerted by a force transducer on a pea radicle using a system of pulleys, and the elongation rate of the pea root was monitored using a linear variable differential transformer (LVDT). The changes in root elongation rate were recorded that occurred in response to increases and decreases in the applied force. Root elongation rate decreased by more than 50% within 30 min of increasing the applied force by 100 mN. A similarly fast, but smaller increase in growth rate occurred when the force was removed. The interpretation of results from both studies will be discussed in terms of a modified form of the Lockhart model of growth.     

The effect of cycloheximide on IAA-stimulated transport of 14C-ABA and 14C-sucrose in long pea epicotyl segments

The effect of cycloheximide (CH) on the indol-3yl-acetic acid (IAA)-stimulated transport of ¹⁴C-labelled abscisic acid (ABA) and ¹⁴C-labelled sucrose was studied in 110 mm long pea epicotyl segments. IAA application resulted in elongation growth of the segments. This effect was decreased by CH treatment which also reduced [¹⁴C] ABA and [¹⁴C] sucrose accumulation in the growing apical part of the segments. A reduction in [¹⁴C] IAA uptake and in protein synthesis in this part of the segments was also observed. The simultaneous inhibition of protein synthesis and reduction of [¹⁴C] ABA and [¹⁴C] sucrose transport suggests that IAA can stimulate the transport of ABA and sucrose through a protein synthesis-based elongation growth.     

Nitrogen fixation and assimilation efficiency in Ethiopian and German pea varieties

Dinitrogen (N₂) fixation and assimilation efficiency in a German and two Ethiopian varieties of Pisum sativum L. was studied in a pot experiment during vegetative and reproductive growth. The objective of the study was to assess whether genotypes having contrasting growth habits showed differences in physiological processes that affect the efficiency of N₂ fixation and assimilation. Dry matter formation, nodulation and nitrogen assimilation were compared between two treatments where one depended solely on N₂ fixation while the other was nourished with nitrate. Moreover, carbon (C) costs of N₂ fixation and the capacity of different respiratory chains in roots and nodules were determined at vegetative and reproductive growth. As compared to the Ethiopian cultivars, the German variety displayed a more rapid vegetative growth with intensive N₂ fixation and assimilation and highly efficient individual nodules. However, during reproductive growth, N₂ fixation in the German variety declined sharply, while continuing in the Ethiopian varieties. Lowest C costs of N₂ fixation coincided with most efficient individual nodules in both growth intervals. C costs of N₂ fixation were lower during reproductive growth in all varieties which was accompanied by a shift in root/nodule respiratory capacity towards more C efficient respiratory pathways. The results provide further evidence that unreliable nitrogen fixation rates during reproductive growth of pea can be connected with restricted C supply to nodules. One strategy of pea plants to adapt to critical C availability is an increase in capacity of more C efficient root/nodule respiration.     

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.     

Field Assessment of Outcrossing from Transgenic Pea (Pisum Sativum L.) Plants

The frequency of outcrossing from a transgenic line of peas into three cultivars ('Carneval', 'Montana', 'Tipu') was studied in the field in 1997 and 1999. Two dominant traits, normal leaf form and a highly-expressed -glucuronidase (gusA) gene, were used as markers of pollen transfer. Because of heterogeneity in the commercial seed sources, leaf form alone was unreliable for assessing pollen migration into 'trap' plants. Of approximately 9000 offspring tested, only five plants scored positive for the presence of both markers. All five were located in 'trap' plots situated near the transgenic line. This represents a mean outcrossing rate of 0.07%.     

The effects of sodium chloride-salinity upon growth, nodulation, and root nodule structure of pea (Pisum sativum L.) plants

Pea (Pisum sativum L.) plants inoculated with Rhizobium leguminosarum bv. viciae effective strain 248 were irrigated with nitrogen-free medium supplemented with 0, 25, 50 or 75 mM NaCl. The inhibitory effect of salinity on the growth of pea plants treated with 25 mM NaCl occurred 6 weeks post inoculation. In case of 75 mM NaCl treatment, the same effect was observed 2 weeks post inoculation. In contrast to investigations described in the literature our results clearly indicated that 25 mM NaCl stimulated nodule formation, however, in contrast to control nodules (the medium without NaCl), the nodules were considerably smaller. Remaining variants of salt treatment reduced plant growth, nodulation, and total nodule volume calculated per plant. Microscopic observations showed that salinity: (1) caused the loss of turgor of the nodule peripheral cells, (2) changed nodule zonation, (3) stimulated infection thread enlargement and expansion, (4) caused disturbances in bacterial release from the infection threads, and (5) induced synthesis of electron dense material (EDM) and its deposition in vacuoles. It was also found that cisternae of RER were involved in the formation of special cytoplasmic compartments responsible for synthesis of EDM. Autofluorescence study revealed that salinity increased accumulation of phenolics in pea nodules, as well.     

Isolation and identification of lateral bud growth inhibitor,indole-3-aldehyde,involved in apical dominance of pea seedlings

A lateral bud growth inhibitor was isolated from etiolated pea seedlings and identified as indole-3-aldehyde. The indole-3-aldehyde content was significantly higher in the diffusates from explants with apical bud and indole-3-acetic acid treated decapitated explants, in which apical dominance is maintained, than in those from decapitated ones releasing apical dominance. When the indole-3-aldehyde was applied to the cut surface of etiolated decapitated plants or directly to the lateral buds, it inhibited outgrowth of the latter. These results suggest that indole-3-aldehyde plays an important role as a lateral bud growth inhibitor in apical dominance of pea seedlings.     

Multiple sources of carbonic anhydrase activity in pea thylakoids: soluble and membrane-bound forms

Carbonic anhydrase (CA) activity of pea thylakoids, thylakoid membranes enriched with photosystem I (PSI-membranes), or photosystem II (PSII-membranes) as well as both supernatant and pellet after precipitation of thylakoids treated with detergent Triton X-100 were studied. CA activity of thylakoids in the presence of varying concentrations of Triton X-100 had two maxima, at Triton/chlorophyll (triton/Chl) ratios of 0.3 and 1.0. CA activities of PSI-membranes and PSII-membranes had only one maximum each, at Triton/Chl ratio 0.3 or 1.0, respectively. Two CAs with characteristics of the membrane-bound proteins and one CA with characteristics of the soluble proteins were found in the medium after thylakoids were incubated with Triton. One of the first two CAs had mobility in PAAG after native electrophoresis the same as that of CA residing in PSI-membranes, and the other CA had mobility the same as the mobility of CA residing in PSII-membranes, but the latter was different from CA situated in PSII core-complex (Ignatova et al. 2006 Biochemistry (Moscow) 71:525–532). The properties of the “soluble” CA removed from thylakoids were different from the properties of the known soluble CAs of plant cell: apparent molecular mass was about 262 kD and it was three orders more sensitive to the specific CA inhibitor, ethoxyzolamide, than soluble stromal CA. The data are discussed as indicating the presence of, at least, four CAs in pea thylakoids.     

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.