Effects of sulphur nutrition on growth and nitrogen fixation of pea (Pisum sativum L.)

A S-deficient soil was used in pot experiments to investigate the effects of S addition on growth and N₂-fixation in pea (Pisum sativum L.). Addition of 100 mg S pot⁻¹ increased seed yield by more than 2-fold. Numbers of pods formed were the most sensitive yield component affected by S deficiency. Sulphur addition also increased the concentration of N in leaves and stems, and the total content of N in the shoots. The amounts of N fixed by pea were determined at four growth stages from stem elongation to maturity, using the ¹⁵N dilution technique. Sulphur addition doubled the amount of N fixed at all growth stages. In contrast, leaf chlorophyll content and shoot dry weight were increased significantly by S addition only after the flowering and pod fill stage, respectively. Pea roots were found to have high concentrations of S, reaching approximately 10 mg g⁻¹ dry weight and being 2.6–4.4 times the S concentration in the shoots under S-sufficient conditions. These results suggest that roots/nodules of pea have a high demand for S, and that N₂-fixation is very sensitive to S deficiency. The effects of S deficiency on pea growth were likely to be caused by the shortage of N, due to decreased N₂-fixation. This revised version was published online in June 2006 with corrections to the Cover Date.     

Genetic control of fasciation in pea (Pisum sativum L.)

The inheritance and manifestation of fasciation character in three fasciated lines of common pea Pisum sativum L. were investigated. All studied forms are characterized by abnormal enlargement of stem apical meristem leading to distortions in shoot structure. It was estimated that fasciation in mutant Shtambovyi is connected with recessive mutation in gene FAS, which was localized in linkage group III using morphological and molecular markers. It was demonstrated that fasciation in cultivar Rosacrone and line Lupinoid is caused by recessive mutation of the same gene (FA). The peculiar architecture of inflorescence in the Lupinoid line is a result of interaction of two recessive mutations (det fa). Investigation of interaction of mutations fa and fas revealed that genes FA and FAS control consequential stages of apical meristem specialization. Data on incomplete penetrance and varying expressivity were confirmed for the mutant allele fa studied.     

Quantitative effects of soil nitrate,growth potential and phenology on symbiotic nitrogen fixation of pea (Pisum sativum L.)

The influence of soil nitrate availability, crop growth rate and phenology on the activity of symbiotic nitrogen fixation (SNF) during the growth cycle of pea (Pisum sativum cv. Baccara) was investigated in the field under adequate water availability, applying various levels of fertiliser N at the time of sowing. Nitrate availability in the ploughed layer of the soil was shown to inhibit both SNF initiation and activity. Contribution of SNF to total nitrogen uptake (%Ndfa) over the growth cycle could be predicted as a linear function of mineral N content of the ploughed layer at sowing. Nitrate inhibition of SNF was absolute when mineral N at sowing was over 380 kg N ha^–1. Symbiotic nitrogen fixation was not initiated unless nitrate availability in the soil dropped below 56 kg N ha^–1. However, SNF could no longer be initiated after the beginning of seed filling (BSF). Other linear relationships were established between instantaneous %Ndfa and instantaneous nitrate availability in the ploughed layer of the soil until BSF. Instantaneous %Ndfa decreased linearly with soil nitrate availability and was nil above 48 and 34 kg N ha^–1 for the vegetative and reproductive stages, respectively, levels after which no SNF occurred. Moreover, SNF rate was shown to be closely related to the crop growth rate until BSF. The ratio of SNF rate over crop growth rate decreased linearly with thermal time. Maximum SNF rate was about 40 mg N m^–2 degree-day^–1, equivalent to 7 kg N ha^–1, regardless of the N treatment. From BSF to the end of the growth cycle, the high N requirements of the crop were supported by both SNF and nitrate root absorption but, of the two sources, nitrate root absorption seemed to be less affected by the presence of reproductive organs. However, since soil nitrate availability was low at the end of the growth cycle, SNF was the main source of nitrogen acquisition. The onset of SNF decrease at the end of the growth cycle seemed to be first due to nodule age and then associated to the slowing of the crop growth rate.     

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.     

Transformation of pea (Pisum sativum L.) byAgrobacterium tumefaciens

Explants fromPisum sativum shoot cultures and epicotyls were transformed by cocultivation withAgrobacterium tumefaciens vectors carrying plant selectable markers and transformants could be selected on a medium containing kanamycin. Transformants could also be obtained at a low frequency by cocultivating small protoplast-derived colonies. The transformed nature of the calli obtained from selection was confirmed by opine assay and DNA analysis. In addition five cultivars of pea were tested for their response to seven differentAgrobacterium tumefaciens strains. The response pattern coincided largely between the different pea cultivars, being more dependent on the bacterial strain than the cultivar used.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - BA 6-benzyladenine - Km kanamycin - NAA -naphthaleneacetic acid - NOS nopaline synthase - NPT neomycin phosphotransferase - OCS octopine synthase     

Lectin-gene expression in pea (Pisum sativum L.) roots

The expression of a lectin gene in pea (Pisum sativum L.) roots has been investigated using the copy DNA of a pea seed lectin as a probe. An mRNA which has the same size as the seed mRNA but which is about 4000 times less abundant has been detected in 21-d-old roots. The probe detected lectin expression as early as 4 d after sowing, with the highest level being reached at 10 d, i.e. just before nodulation. In later stages (16-d- and 21-d-old roots), expression was substantially decreased. The correlation between infection by Rhizobium leguminosarum and lectin expression in pea roots has been investigated by comparing root lectin mRNA levels in inoculated plants and in plants grown under conditions preventing nodulation. Neither growth in a nitrate concentration which inhibited nodulation nor growth in the absence of Rhizobium appreciably affected lectin expression in roots.Abbreviation cDNA copy DNA - poly(A)⁺RNA polyadenylated RNA     

Plasmatubules in transfer cells of pea (Pisum sativum L.)

Plasmatubules are tubular evaginations of the plasmalemma. They have previously been found at sites where high solute flux between apoplast and symplast occurs for a short period and where wall proliferations of the transfer cell type have not been developed (Harris et al. 1982, Planta 156, 461–465). In this paper we describe the distribution of plasmatubules in transfer cells of the leaf minor veins of Pisum sativum L. Transfer cells are found in these veins associated both with phloem sieve elements and with xylem vessels. Plasmatubules were found, in both types of transfer cell and it is suggested that the specific distribution of the plasmatubules may reflect further membrane amplification within the transfer cell for uptake of solute from apoplast into symplast.     

Immunolocalization of lipoxygenase in pea (Pisum sativum L.) carpels

Summary Polyclonal antibodies against a part of pea (Pisum sativum L.) LOXG protein have been raised to study the pattern of distribution of related lipoxygenases in pea carpels. The antiserum recognized three lipoxygenase polypeptides in carpels. One of them became undetectable 24 hours after fruit development induction, suggesting that it may correspond to the protein derived from loxg cDNA. Immunolocalization experiments showed that lipoxygenase protein was present only in pod tissues: it was abundant in the mesocarp and, from the day of anthesis, in the endocarp layers. Lipoxygenase distribution is regulated throughout development. The association of lipoxygenase with cells in which processes of expansion and growth will potentially take place support a role in pod growth and development.Abbreviations DTT dithiothreitol - EDTA ethylenediaminetetraacetic acid - IgG immunoglobulin G - GA₃ gibberellic acid - LOX lipoxygenase - PAGE polyacrylamide gel - PVDF polyvinylidene difluoride - SDS sodium dodecyl sulfate - Tris 2-amino-2-hydroxymethyl-1,3-propanediol     

Efficient intergeneric fusion of pea (Pisum sativum L.) and grass pea (Lathyrus sativus L.) protoplasts

Large numbers of viable protoplasts of pea (Pisum sativum) and grass pea (Lathyrus sativus) were efficiently and reproducibly obtained and, for the first time, fused. Different procedures for fusion were compared, based either on electrofusion (750, 1000, 1250 or 1500 V cm(-1)), or on the use of macro or micromethods with a polyethylene glycol (PEG 6000 or PEG 1540), or a glycine/high pH solution. Over 10% of viable heterokaryons were obtained, with PEG as the most efficient and reproducible agent for protoplast fusion (>20% of viable heterokaryons). Both the division of heterokaryons and the formation of small calluses were observed.     

The major albumin protein from pea (Pisum sativum L.)

The major albumin protein in storage parenchyma tissue of developing peas has been localised at an ultrastructural level by immunocytochemistry. Tissue was fixed in buffered aldehyde and embedded in LR White resin which was polymerised by addition of catalyst. Sections were labelled by the indirect method of absorption of Protein A-gold to specifically bound antibodies. This method gives high levels of specific labelling on sections which retain good ultrastructural preservation and have high contrast after conventional staining. The albumin is located throughout the cytoplasm although no labelling was found associated with the endoplasmic reticulum, Golgi apparatus, vacuoles-protein bodies or other organelles.Abbreviation PMA pea major albumin protein     

Inheritance and mapping of isoenzymes in pea (Pisum sativum L.)

Summary Three isoenzyme systems (amylase, esterase and glutamate oxaloacetate transaminase) were examined in seeds of pea (Pisum sativum L.) and shown to give clear variation in their band patterns on gel electrophoresis between different lines. The inheritance of these isoenzyme systems, and the location of their genes on the pea genome was investigated. Reciprocal crosses were made between lines, F2 seeds were analysed for segregation in the band patterns of the isoenzymes, and F2 plants were investigated to find linkage between the genes for these isoenzymes and genes for selected morphological markers. The results obtained showed that each of the investigated isoenzyme systems is genetically controlled by co-dominant alleles at a single locus. The gene for amylase was found to be on chromosome 2, linked to the loci k and wb (wb ... 9 ... k ... 25 ... Amy). The gene for esterase was found to be linked with the gene Br (chromosome 4) but the exact location is uncertain because of the lack of the morphological markers involved in the cross. The gene for glutamate oxaloacetate transaminase was found to be on chromosome 1 and linked with the loci a and d (a... 24... Got... 41 ... d).     

Root system growth and nodule establishment on pea (Pisum sativum L.)

Development of the root system, appearance of nodules, and relationshipsbetween these two processes were studied on pea (Pisum sativumL., cv. Solara). Plants were grown in growth cabinets for 4weeks on a nitrogen—free nutrient solution inoculatedwith Rhizobium leguminosarum. Plant stages, primary root length,distance from the primary root base to the most distal first-orderlateral root, and distance from the root base to the most distalnodule, were recorded daily. Distribution of nodules along theprimary root and distribution of laterals were recorded by samplingroot systems at two plant stages. Primary root elongation ratewas variable, and declined roughly in conjunction with the exhaustionof seed reserves. First-order laterals appeared acropetallyon the primary root. A linear relationship was found betweenthe length of the apical unbranched zone and root elongationrate, supporting the hypothesis of a constant time lag betweenthe differentiation of first-order lateral's primordia and theiremergence. Decline of the primary root elongation rate was precededby a reduction in density and length of first-order laterals.Nodules appeared not strictly but roughly acropetally on theprimary root. A linear relationship was found between the lengthof the apical zone without nodule and root elongation rate,supporting the hypothesis of a constant time lag between infectionand appearance of a visible nodule. A relationship was foundbetween the presence/absence of nodules on a root segment andthe root elongation rate between infection and appearance ofnodules on the considered root segment. Regulation of both processesby carbohydrate availability, as a causal mechanism, is proposed. Key words: Pisum sativum L, root system, nodules     

Effect of exogenous flavonoids on nodulation of pea (Pisum sativum L.)

Selected flavonoids that are known as inducers and a suppressor of nodulation (nod) genes of the symbiotic bacterium Rhizobium leguminosarum bv. viciae were tested for their effect on symbiosis formation with garden pea as the host. A solid substrate was omitted from the hydroponic growing system in order to prevent losses of flavonoids due to adsorption and degradation. The presumed interaction of the tested flavonoids with nod genes has been verified for the genetic background of strain 128C30. A stimulatory effect of a nod gene inducer naringenin on symbiotic nodule number formed per plant 14 d after inoculation was detected at concentrations of 0.1 and 1 micro g ml(-1) nutrient solution. At 10 micro g ml(-1), the highest concentration tested, naringenin was already inhibitory. By contrast, nodulation was negatively affected by a nod gene suppressor, quercetin, at concentrations above 1 micro g ml(-1), as well as by another tested nod gene inducer, hesperetin. The deleterious effect of hesperetin might be due to its toxicity or to the toxicity of its degradation product(s) as indicated by the inhibition of root growth. Both the stimulatory effect of naringenin and the inhibitory effect of quercetin on nodule number were more pronounced at earlier stages of nodule development as revealed with specific staining of initial nodules. The lessening of the flavonoid impact during nodule development was ascribed to the plant autoregulatory mechanisms. Feedback regulation of nodule metabolism might also be responsible for the fact that the naringenin-conditioned increase in nodule number was not accompanied by any increase in nitrogenase activity. By contrast, the inhibitory action of quercetin and hesperetin on nodule number was associated with decreases in total nitrogenase activity. Naringenin also stimulated root hair curling (RHC) as one of the earliest nodulation responses at concentrations of 1 and 10 microg ml(-1), however, the same effect was exerted by the nod gene suppressor, quercetin, suggesting that feedback regulatory mechanisms control RHC in the range of nodulation-inhibiting high flavonoid concentrations. The comparison of the effect of the tested flavonoids in planta with nod gene activity response showed a two orders of magnitude shift to higher concentrations. This shift is explained by the absorption and degradation of flavonoids by both the symbionts during 3 d intervals between hydroponic solution changes. The losses were 99, 96.4, and 90% of the initial concentration of 10 micro g ml(-1) for naringenin, hesperetin, and quercetin, respectively.     

Microsatellite marker polymorphism and mapping in pea (Pisum sativum L.)

This paper aims at providing reliable and cost effective genotyping conditions, level of polymorphism in a range of genotypes and map position of newly developed microsatellite markers in order to promote broad application of these markers as a common set for genetic studies in pea. Optimal PCR conditions were determined for 340 microsatellite markers based on amplification in eight genotypes. Levels of polymorphism were determined for 309 of these markers. Compared to data obtained for other species, levels of polymorphism detected in a panel of eight genotypes were high with a mean number of 3.8 alleles per polymorphic locus and an average PIC value of 0.62, indicating that pea represents a rather polymorphic autogamous species. One of our main objectives was to locate a maximum number of microsatellite markers on the pea genetic map. Data obtained from three different crosses were used to build a composite genetic map of 1,430 cM (Haldane) comprising 239 microsatellite markers. These include 216 anonymous SSRs developed from enriched genomic libraries and 13 SSRs located in genes. The markers are quite evenly distributed throughout the seven linkage groups of the map, with 85% of intervals between the adjacent SSR markers being smaller than 10 cM. There was a good conservation of marker order and linkage group assignment across the three populations. In conclusion, we hope this report will promote wide application of these markers and will allow information obtained by different laboratories worldwide in diverse fields of pea genetics, such as QTL mapping studies and genetic resource surveys, to be easily aligned.Electronic Supplementary Material Supplementary material is available for this article at     

DNA variations in regenerated plants of pea (Pisum sativum L.)

Summary The aim of this study was to determine whether DNA variations could be detected in regenerated pea plants. Two different genotypes were analyzed by cytogenetic and molecular techniques: the Dolce Provenza cultivar and the 5075 experimental line. Dolce Provenza regenerated plants showed a reduction in DNA content, particularly at the level of unique sequences and ribosomal genes. Moreover, regeneration was associated with an increase in DNA methylation of both internal and external cytosines of the CCG sequence. On the other hand, the DNA content of the 5075 line remained stable after regeneration. DNA reduction was found only in 5075 plants regenerated from callus cultures maintained for long incubation periods (about a year). The DNA variations observed are discussed both in relation to the genotype source and the role of tissue-culture stress.     

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.     

Development and study of SCAR markers in pea (Pisum sativum L.)

In order to develop more specific markers that characterize particular regions of the pea genome, the data on nucleotide sequences of RAPD fragments were used for choosing more extended primers, which may be helpful in amplifying a fragment corresponding to the particular DNA region. Of the 14 STS markers obtained from 14 polymorphic RAPD fragments, 12 were polymorphic, i.e., they are SCAR markers that can be used in genetic analysis. The transition from complex RAPD spectra to amplification of a particular SCAR marker substantially facilitates analysis of large samples for the presence or absence of the examined fragment. Inheritance of the developed SCAR markers was studied in F1 and F2. SCAR markers were used to identify various pea lines, cultivars, and mutants. It was established that the study of amplification of STS markers in various pea genotypes at varying temperatures of annealing and the comparison with amplification of the original RAPD fragments in the same genotypes provide an approach for analysis of RAPD polymorphism type.