Flow cytometric and Feulgen densitometric analysis of genome size variation in Pisum

A DAPI and ethidium bromide flow cytometric and Feulgen densitometric analysis of genome size variation in Pisum was conducted. The material included 38 accessions of P. sativum of widely different geographic origin and altogether 14 samples of P. elatius, P. abyssinicum, P. humile and P. fulvum. The relative genome size values obtained with the three staining methods were strongly correlated. No evidence for genome size variation was found among P. sativum cultivars. In particular, certain Italian cultivars, for which strongly deviating C-values have been reported, proved to be invariant. The only occasion when ambiguous evidence for marginal genome size variation was found was when all 38 accessions taxonomically affiliated with P. sativum were considered. Pisum abyssinicum and P. fulvum differed from P. sativum by about 1.066-and 1.070-fold, respectively; 1 accession of P. humile differed by 1.089-fold, and 2 of P. elatius by 1.122- and 1.195-fold, respectively (ethidiumbromide comparison), while the other accessions of these taxa were not different from P. sativum. This variation may indicate taxonomic inhomogeneity and demands further investigation. Cultivated P. sativum has long been suspected of not being constant with respect to genome size. As shown here, these findings were not based on genuine differences, but rather were technical in origin.     

Flow cytometric analysis of genome size variation in cultivated and wildPisum sativum (Fabaceae)

Fifteen cultivars, landraces, and wild accessions ofPisum sativum subspecies, and one accession ofP. abyssinicum were analysed with flow cytometry (DAPI staining) usingP. sativum Kleine Rheinländerin as internal standard. Applying the method of jointly isolating, staining, and measuring nuclei of individual seedlings of test and standard material, it was found that in allP. sativum comparisons G 1 and G 2 peaks were invariably unimodal and symmetric at coefficients of variation mostly less than 2%. This is strong evidence for absence of significant genome size variation in theP. sativum strains analysed. These data are markedly at variance to results of other authors reporting considerable genome size variation withinP. sativum. However, inP. abyssinicum flow cytograms and Feulgen densitometric measurements indicate 4–8% more DNA, at same chromosome number (2n = 14), than inP. sativum. This result demonstrates that genome size variation is indeed existent in the genus and requires further examination.     

Chloroplast DNA variation and evolution in pisum: patterns of change and phylogenetic analysis

Variation in 30 chloroplast DNAs, representing 22 wild and cultivated accessions in the genus Pisum, was analyzed by comparing fragment patterns produced by 16 restriction endonucleases. Three types of mutations were detected. First, an inversion of between 2.2 kilobase pairs (kb) and 5.2 kb distinguished a population of P. humile from all other Pisum accessions examined. Second, deletions and insertions of between 50 and 1200 base pairs produced small restriction fragment length variations in four regions of the 120-kb chloroplast genome. Two of these regions—one of which is located within the sequence that is inverted in P. humile—showed a high degree of size polymorphism, to the extent that size differences were detected between individuals from the same accession. Finally, a total of only 11 restriction site mutations were detected among the 165 restriction sites sampled in the 30 DNAs. Based on these results and previous data, we conclude that the chloroplast genome is evolving very slowly relative to nuclear and mitochondrial DNAs. The Pisum chloroplast DNA restriction site mutations define two major lineages: One includes all tested accessions of P. fulvum, which is known to be cytogenetically quite distinct from all other Pisum taxa. The second includes 12 of 13 cultivated lines of the garden pea (P. sativum) and a wild population of P. humile from northern Israel. These observations strongly reinforce an earlier conclusion that the cultivated pea was domesticated primarily from northern populations of P. humile. A 13th P. sativum cultivar has a chloroplast genome that is significantly different from those of the aforementioned lines and somewhat more similar to those of P. elatius and southern populations of P. humile. This observation indicates that secondary hybridization may have occurred during the domestication of the garden pea.     

A comparative electrophoretic study of the seed albumins fromSophora microphylla andPisum sativum (Leguminosae)

The albumin proteins from seed ofSophora microphylla Ait. and from cotyledons ofPisum sativum L. (cv. Greenfeast) have been analysed electrophoretically using a range of gels of varied pore size. Plots of mobility [as 100 log₁₀ (R _f × 100)] vs.acrylamide content of gel indicate that very few of the albumins fromS. microphylla are homologous with albumins fromP. sativum. Despite the diverse compositions of the two fractions, their amino acid analyses were surprisingly similar.     

Genome size variation inCajanus cajan (Fabaceae): A reconsideration

A recent investigation of genome size in certain samples of the pigeonpea,Cajanus cajan, indicates values from 1.55 pg to 1.99 pg (1C level), which is 1.29-fold variation between accessions. In the present analysis those of these accessions which had particularly high or low DNA contents in that study were subjected to a reanalysis using propidium iodide and DAPI flow cytometry and Feulgen densitometry. Only minor differences in genome size, not more than 1.047-fold, were found with flow cytometry, and no significant differences were obtained with Feulgen densitometry. The previously reported genome size cannot be confirmed. It is about half as large and was determined in the present study as 0.825 pg (1C, propidium iodide flow cytometry,Glycine max as standard) and 0.853 pg (1C, Feulgen densitometry,Allium cepa andPisum sativum as standards), respectively.     

Comparison of seed proteins of some representatives of the genusPisum from the point of view of their relationship comparison by disc electrophoresis

Ten taxa of the genusPisum were examined by disc electrophoresis in gels according to Davis and to Reisfeldet al. For evaluation of band patterns the Jaccard Index was applied. The results in both types of gels show thatPisum abyssinicum and especiallyP. fulvum have biochemically a relatively isolated position.Pisum elatius and its subspeciescaspicum andpalestinicum form a subgroup withP. cinereum;P. sativum var.zeylanicum and cv. Jupiter form another subgroup withP. syriacum. Our results are in good agreement with the results of Przybylskaet al. (with the exception ofP. cinereum) and also with immunoelectrophoretic analyses performed by Turkováet al. (1980), with the same exception.     

A phylogenetic analysis of Pisum based on morphological characters, and allozyme and RAPD markers

Cladistic analyses of 17 wild and cultivated pea taxa were performed using morphological characters, and allozyme and RAPD (random amplified polymorphic DNA) markers. Both branch-and-bound and bootstrap searches produced cladograms that confirmed the close relationships among the wild species and cultivars of Pisum proposed by a variety of systematic studies. Intraspecific rankings were supported for northern P. humile, southern P. humile, P. elatius and P. sativum, which together comprise a single-species complex. P. fulvum, while clearly the most divergent of the pea taxa, could also be assigned to the same species complex without violating the hierarchial logic of the cladogram. Its inclusion or exclusion depends on whether the level of interfertility it displays with other pea taxa or its overall morphological and chromosomal distinction are emphasized. As suggested by previous studies, northern P. humile was the most likely sister taxon to cultivated P. sativum; although, rigorous phylogenetic evaluation revealed a close genealogical affinity among P. elatius, northern P. humile and P. sativum. Despite their limited number, the 16 morphological characters and allozyme markers used precisely organized the pea taxa into established taxonomic groupings, perhaps in part reflecting the role morphology has played historically in pea classification. The RAPD data also generally supported these same groupings and provided additional information regarding the relationships among the taxa. Given that RAPDs are relatively quick and easy to use, are refractory to many environmental influences, can be generated in large numbers, and can complement traditional characters that may be limited in availability, they provide a valuable new resource for phylogenetic studies.     

Band composition of electrophoretic spectra of storage proteins in interspecific pea hybrids

Electrophoretic spectra of storage proteins in parental plants and interspecific F₁ and F₂ hybrids Pisum sativum × Pisum fulvum have been studied. Correspondence between the polymorphism levels of protein components among the species and within the species P. sativum was established. Accessions of P. fulvum I609881 and I609885 manifested low polymorphism. Storage proteins of both parents were observed in spectra of F₁ hybrids. F₂ hybrids segregated at a limited set of bands. Accession I609881 of P. fulvum is characterized by unique band 7, which was inherited in F₁.     

Linkage mapping of quantitative trait loci controlling seed weight in pea (Pisum sativum L.)

Quantitative trait loci (QTLs) affecting seed weight in pea (Pisum sativum L.) were mapped using two populations, a field-grown F₂ progeny of a cross between two cultivated types (Primo and OSU442-15) and glasshouse-grown single-seed-descent recombinant inbred lines (RILs) from a wide cross between a P. sativum ssp. sativum line (Slow) and a P. sativum ssp. humile accession (JI1794). Linkage maps for these crosses consisted of 199 and 235 markers, respectively. QTLs for seed weight in the Primo x OSU442-15 cross were identified by interval mapping, bulked segregant analysis, and selective genotyping. Four QTLs were identified in this cross, demonstrating linkage to four intervals on three linkage groups. QTLs for seed weight in the JI1794 x Slow cross were identified by single-marker analyses. Linkage were demonstrated to four intervals on three linkage groups plus three unlinked loci. In the two crosses, only one common genomic region was identified as containing seed-weight QTLs. Seed-weight QTLs mapped to the same region of linkage group III in both crosses. Conserved linkage relationships were demonstrated for pea, mungbean (Vigna radiata L.), and cowpea (V. unguiculata L.) genomic regions containing seed-weight QTLs by mapping RFLP loci from the Vigna maps in the Primo x OSU442-15 and JI1794 x Slow crosses.     

Sequence of two genes in pea chloroplast DNA coding for 84 and 82 kD polypeptides of the photosystem I complex

Summary The genes encoding the two P700 chlorophyll a-apoproteins of the photosystem I complex were localized on the pea (Pisum sativum) chloroplast genome. The nucleotide sequence of the genes and the flanking regions has been determined. The genes are separated by 25 bp and are probably cotranscribed. The 5 terminal gene (psaA1) codes for a 761-residue protein (MW 84.1 kD) and the 3 terminal gene (psaA2) for a 734-residue protein (MW 82.4 kD). Both proteins are highly hydrophobic and contain eleven putative membrane-spanning domains. The homology to the corresponding polypeptides from maize are 89% and 95% for psaA1 and psaA2, respectively. A putative promoter has been identified for the psaA1 gene, and potential ribosome binding sites are present before both genes.     

Matromorphy in Pisum sativum L.

Summary The possibility of obtaining instant pure breeding lines by matromorph seed development in Pisum sativum L. has been investigated. Two types of maternal parents, namely, homozygous for the recessive marker genes and heterozygous for the dominant marker genes were pollinated with Lathyrus odoratus and the P174 variety of Pisum sativum L. carrying dominant markers. For both pollinators, induction of matromorphy by prickle pollination, irradiated pollen and IAA treatment was examined. Promising matromorphs were identified in the M₁ generation which were studied in the M₂ generation for assessing their genetic status with respect to homozygosis. The success of pod set varied from zero to 28% with a varying number of matromorphic seeds following different treatments. The possible mechanisms for matromorphic origin have been discussed. The evidence presented herein favours induction of matromorphy in peas for the production of homozygous stocks. In addition, the recovery of double recessive seed markers of the maternal parents along with plant markers from the paternals has prospective implications in plant breeding as an alternative tool to recurrent back crossing.     

Polymorphism of insertion sites of Ty1-copia class retrotransposons and its use for linkage and diversity analysis in pea

A sample of 15 cultivars and 56 Pisum accessions from the JIC germplasm core collection has been studied using a modification of the SSAP (sequence-specific amplification polymorphisms) technique; the specific primer was designed to correspond to the polypurine tract (PPT) of PDR1, a Ty1-copia group retrotransposon of pea. Most of these SSAP products were shown to be PDR1 derived. The PDR1 SSAP markers are more informative than previously studied AFLP or RFLP markers and are distributed throughout the genome. Their pattern of variation makes them ideal for integrating genetic maps derived from related crosses. Data sets obtained with AFLP and PDR1 SSAP markers were used to construct neighbour-joining trees and for principal component analysis. These data sets give greater resolution than hitherto available for the characterisation of variation within Pisum, showing that the genus has three main groups: P. fulvum, P. abyssinicum and all other Pisum spp. P. abyssinicum is not a subgroup of cultivated P. sativum, as was previously thought, but has probably been domesticated independently. Modern cultivars are shown to form a single group within Pisum as a whole. Received: 21 April 1998 / Accepted: 9 June 1998     

Analysis of a lipoxygenase pseudogene in Pisum

 Lipoxygenase (LOX) enzymes play important roles in plant biology, and in the quality of plant-derived foods, through the production of fatty acid hydroperoxides that are metabolized either to jasmonate, or to volatile aldehydes that are part of plant defence systems and/or impart tastes and aromas to fruits and vegetables. We have identified a lipoxygenase pseudogene in peas that is composed of three elements: rearranged LOX-2 and LOX-3 genes and an unidentified tract of DNA. We present evidence that such an arrangement is normally present in the genome of Pisum sativum, but is absent from Pisum fulvum lines, including a mutant line that lacks LOX-2 polypeptides. The absence of LOX-2 polypeptides and the pseudogene co-segregate. The pseudogene therefore has utility as a molecular marker for the introgression of the LOX-2-null phenotype into commercial Pisum sativum genotypes. Received: 27 April 1998 / Accepted: 17 September 1998     

A Kunitz trypsin inhibitor from chickpea (<Emphasis Type="Italic">Cicer arietinum</Emphasis> L.) that exerts anti-metabolic effect on podborer (<Emphasis Type="Italic">Helicoverpa armigera</Emphasis>) larvae

Chickpea (Cicer arietinum L.) seeds contain Bowman–Birk proteinase inhibitors, which are ineffective against the digestive proteinases of larvae of the insect pest Helicoverpa armigera. We have identified and purified a low expressing proteinase inhibitor (PI), distinct from the Bowman–Birk Inhibitors and active against H. armigera gut proteinases (HGP), from chickpea seeds. N-terminal sequencing of this HGP inhibitor revealed a sequence similar to reported pea (Pisum sativum) and chickpea -l-fucosidases and also homologous to legume Kunitz inhibitors. The identity was confirmed by matrix assisted laser desorption ionization – time of flight analysis of tryptic peptides and isolation of DNA sequence coding for the mature protein. Available sequence data showed that this protein forms a distinct phylogenetic cluster with Kunitz inhibitors from Glycine max, Medicago truncatula, P. sativum and Canavalia lineata. The isolated coding sequence was cloned into a yeast expression vector and produced as a recombinant protein in Pichia pastoris. -l-fucosidase activity was not detectable in purified or recombinant protein, by solution assays. The recombinant protein did not inhibit chymotrypsin or subtilisin activity but did exhibit stoichiometric inhibition of trypsin, comparable to soybean Kunitz trypsin inhibitor. The recombinant protein exhibited higher inhibition of total HGP activity as compared to soybean kunitz inhibitor, even though it preferentially inhibited HGP-trypsins. H. armigera larvae fed on inhibitor-incorporated artificial diet showed significant reduction in average larval weight after 18 days of feeding demonstrating potent antimetabolic activity. The over-expression of this gene in chickpea could act as an endogenous source of resistance to H. armigera.     

Proximity of an ARS consensus sequence to a replication origin of pea (Pisum sativum)

The replication origin (ori-r9) of the 9.0 kb rDNA repeats of pea (Pisum sativum, cv. Alaska) was cloned and found to reside in a 1.5 kb fragment of the non-transcribed spacer region located between the 25 S and 18 S genes. Labeled rDNA rich in replication forks, from cells positioned at the G₁/S phase boundary, was used to map ori-r9 by hybridization procedures. Ori-r9 is in a 210-base fragment that is 1.6 kb from the 5 end of the 18 S gene and about 1.5 kb from the 3 end of the 25 S gene. The same procedures, using labeled synthetic ARS consensus sequence as a probe, showed than an ARS consensus sequence is located 3 to ori-r9 in a 710-base fragment. An ARS consensus sequence is, therefore, adjacent to ori-r9 but not coincidental with it.     

The chloroplast-located glutamine synthetase of Phaseolus vulgaris L.: nucleotide sequence,expression in different organs and uptake into isolated chloroplasts

Work using a full-length cDNA clone has revealed that the plastid-located glutamine synthetase (GS) of Phaseolus vulgaris is encoded by a single nuclear gene. Nucleotide sequencing has shown that this cDNA is more closely related to a cDNA encoding the plastidic GS of Pisum sativum than to cDNAs encoding three different cytosolic GS subunits of P. vulgaris. The plastid GS subunits are initially synthesized as higher M _r (47000) precursors containing an N-terminal presequence of about 50 amino acids which is structurally similar to the presequences of other nuclear-encoded chloroplast proteins. The precursor has been synthesized in vitro and is imported by isolated pea chloroplasts and processed to two polypeptides of the same size as native P. vulgaris chloroplast GS subunits (M _r 42000). Experiments with fusion proteins show that the N-terminal 68 amino acids of this precursor allow the cytosolic GS subunit also to be imported and processed by isolated chloroplasts. Polyadenylated mRNA specifically related to the plastidic GS gene is most highly abundant in chloroplast-containing organs (leaves and stems) but is also detectable in roots and nodules.     

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     

Polymorphism of insertion sites of Ty1-copia class retrotransposons and its use for linkage and diversity analysis in pea

A sample of 15 cultivars and 56 Pisum accessions from the JIC germplasm core collection has been studied using a modification of the SSAP (sequence-specific amplification polymorphisms) technique; the specific primer was designed to correspond to the polypurine tract (PPT) of PDR1, a Ty1-copia group retrotransposon of pea. Most of these SSAP products were shown to be PDR1 derived. The PDR1 SSAP markers are more informative than previously studied AFLP or RFLP markers and are distributed throughout the genome. Their pattern of variation makes them ideal for integrating genetic maps derived from related crosses. Data sets obtained with AFLP and PDR1 SSAP markers were used to construct neighbour-joining trees and for principal component analysis. These data sets give greater resolution than hitherto available for the characterisation of variation within Pisum, showing that the genus has three main groups: P. fulvum, P. abyssinicum and all other Pisum spp. P. abyssinicum is not a subgroup of cultivated P. sativum, as was previously thought, but has probably been domesticated independently. Modern cultivars are shown to form a single group within Pisum as a whole.     

The fuc1 gene product (20 kDa FUC1) of Pisum sativum has no α-L-fucosidase activity

An -L-fucosidase purified from pea (Pisum sativum L. cv Alaska) epicotyl was previously described as a cell wall enzyme of 20 kDa that hydrolyses terminal -L-fucosidic linkages from oligosaccharide fragments of xyloglucan. cDNA and genomic copies were further isolated and sequenced. The predicted product of the cDNA and the genomic clone (fuc1), was a 20 kDa protein containing a signal peptide and five cysteines. This was the first -L-fucosidase gene to be cloned in plants but its fucosidase activity has not been demonstrated. Here, our biochemical and immuno analyses suggest that fuc1 does not encode an -L-fucosidase. Pea fuc1 expressed in Escherichia coli, insect cells and Arabidopsis thaliana produced recombinant proteins without -L-fucosidase activity. Pea plants had endogenous -L-fucosidase activity, but the enzyme was not recognised by an antibody produced against recombinant FUC1 protein expressed in E. coli. In contrast, the antibody immunoprecipitated a 20 kDa protein which was inactive. By chromatographic analysis of pea protein extracts, we separated -L-fucosidase-active fractions from the 20 kDa protein fractions. We conclude that the -L-fucosidase activity is not attributable to the 20 kDa FUC1 protein. A new function for fuc1 gene product, now named PIP20 (for protease inhibitor from pea) is proposed.