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.     

Partial purification and properties of carbamoyl phosphate synthetase of Alaska pea (Pisum sativum L. cultivar Alaska). Purification and general properties

1. Carbamoyl phosphate synthetase was purified up to 45-fold from Alaska pea seedling (Pisum sativum L. cultivar Alaska). 2. The enzyme was most active with and had the lowest K(m) for l-glutamine as compared with NH(4) (+). 3. The purest preparations utilized very poorly or not at all l-asparagine and urea as nitrogen donors. 4. At saturating concentrations of components of the reaction, the K(m) for l-glutamine was 1.2x10(-4)m, and the K(m) for ATP was approx. 3.9x10(-4)m. 5. Although the enzyme was very labile, stability was improved by glutamine, asparagine, ammonium sulphate, dithiothreitol and especially l-ornithine. 6. Free ATP was markedly inhibitory, and MgATP(2-) and Mg(2+) appeared to be the actual substrates utilized. 7. Fe(2+) and Mn(2+) were also utilized, but not as readily as Mg(2+) except at low concentrations. K(+) increased activity significantly. 8. Of the four nucleotides tested (ITP, ATP, GTP and UTP) only ATP served as an effective phosphate donor.     

Purification, properties and amino acid sequence of a low-Mr abundant seed protein from pea (Pisum sativum L.).

The seeds of pea (Pisum sativum L.) contain several proteins in the albumin solubility fraction that are significant components of total cotyledonary protein (5-10%) and are accumulated in developing seeds concurrently with storage-protein synthesis. One of these proteins, of low Mr and designated 'Psa LA', has been purified, characterized and sequenced. Psa LA has an Mr of 11000 and contains polypeptides of Mr 6000, suggesting that the protein molecules are dimeric. The amino acid sequence contains 54 residues, with a high content (10/54) of asparagine/aspartate. It has no inhibitory action towards trypsin or chymotrypsin, and is distinct from the inhibitors of those enzymes found in pea seeds, nor does it inhibit hog pancreatic alpha-amylase. The protein contains no methionine, but significant amounts of cysteine (four residues per polypeptide), suggesting a possible role as a sulphur storage protein. However, its sequence is not homologous with low-Mr (2S) storage proteins from castor bean (Ricinus communis) or rape (Brassica napus). Psa LA therefore represents a new type of low-Mr seed protein.     

Isolation, characterization and partial amino acid sequence of a chloroplast-localized porphobilinogen deaminase from pea (Pisum sativum L.)

Porphobilinogen deaminase catalyzes the condensation of four porphobilinogen monopyrrole units into hydroxymethylbilane, a linear tetrapyrrole necessary for the formation of chlorophyll and heme in higher plant cells. We report the purification to homogeneity of a chloroplast-localized form of the enzyme from pea (Pisum sativum L.) by a novel purification scheme involving dye-ligand affinity chromatography. The purified chloroplast porphobilinogen deaminase consists of a single polypeptide with a relative molecular mass of 36-45 kDa as determined by size-exclusion chromatography and sodium dodecyl sulfate polyacrylamide gel electrophoresis. The isoelectric point of the protein is acidic. The activity of the enzyme shows different levels of sensitivity to divalent cations and is most sensitive to FE2+. The amino terminus of pea enzyme has been obtained by microsequencing and determined to bear little similarity to the amino acid sequences of porphobilinogen deaminases purified from other organisms. Polyclonal antisera elicited against the purified protein has been used to examine the abundance and cellular distribution of the enzyme.     

Excision and replication of extrachromosomal DNA of pea (Pisum sativum).

Experiments with cultured pea roots were conducted to determine (i) whether extrachromosomal DNA was produced by cells in the late S phase or in the G2 phase of the cell cycle, (ii) whether the maturation of nascent DNA replicated by these cells achieved chromosomal size, (iii) when extrachromosomal DNA was removed from the chromosomal duplex, and (iv) the replication of nascent chains by the extrachromosomal DNA after its release from the chromosomal duplex. Autoradiography and cytophotometry of cells of carbohydrate-starved root tips revealed that extrachromosomal DNA was produced by a small fraction of cells accumulated in the late S phase after they had replicated about 80% of their DNA. Velocity sedimentation of nascent chromosomal DNA in alkaline sucrose gradients indicated that the DNA of cells in the late S phase failed to achieve chromosomal size. After reaching sizes of 70 X 10(6) to 140 X 10(6) daltons, some of the nascent chromosomal molecules were broken, presumably releasing extrachromosomal DNA several hours later. Sedimentation of selectively extracted extrachromosomal DNA either from dividing cells or from those in the late S phase showed that it replicated two nascent chains, one of 3 X 10(6) daltons and another of 7 X 10(6) daltons. Larger molecules of extrachromosomal DNA were detectable after cells were labeled for 24 h. These two observations were compatible with the idea that the extrachromosomal DNA was first replicated as an integral part of the chromosomal duplex, was cut from the duplex, and then, once free of the chromosome, replicated two smaller chains of 3 X 10(6) and 7 X 10(6) daltons.     

CO2 enrichment, drought stress and growth of Alaska pea plants (Pisum sativum)

The interaction of CO₂ enrichment and drought on water status and growth of pea plants was investigated. Pisum sativum L. (cv. Alaska) plants were grown from seeds in growth chambers using 350 and 675 μl I1 CO₂, a photon flux density of 600 μmol M-2 S-1, a 16 h photoperiod and a temperature regime of 20/14°C. The drought treatment was started at the beginning of branch initiation and lasted for 9 or 11 days. The water status of the plants was monitored daily by measuring total leaf water potential and stomatal conductance. The total leaf water potential of well-watered plants was not affected by the CO₂ level. Under draughting conditions total leaf water potential decreased, with a slower decrease under the high CO₂ regime, due, at least in part, to reduced stomatal conductance. Upon rewatering, total leaf water potential and stomatal conductance recovered within one day. High CO₂ counteracted the reduction in height and, to some extent, leaf area that developed in low CO₂ unwatered plants. Additional CO₂ had no effect on branch number and did not prevent the complete inhibition of branch development that resulted from drought stress. Removing the drought conditions resulted in a rapid recovery of the internal water status and also a rapid recovery of most, but not all, plant growth parameters.     

Induction of hydrotropism in clinorotated seedling roots of Alaska pea, Pisum sativum L

Roots of the agravitropic pea (Pisum sativum L.) mutant ageotropum show positive hydrotopism, whereas roots of Alaska peas are hydrotropically almost non-responsive. When the gravitropic response was nullified by rotation on clinostats, however, roots of Alaska peas showed unequivocal positive hydrotropism in response to a water potential gradient. These results suggest that roots of Alaska peas possess normal ability to respond hydrotropicallly and their weak hydrotropic response results from a counteracting effect of gravitropism.     

Nucleotide sequence of an arginine transfer ribonucleic acid from bacteriophage T4.

The nucleotide sequence of a phage T4-coded low molecular weight RNA, previously designated polyacrylamide gel band epsilon, has been determined. This RNA can be arranged in the cloverleaf configuration common to tRNAs, with an anticodon sequence, U-C-U, which corresponds to the arginine-specific codons A-G-A and A-G-G; it is therefore assumed to be an arginine tRNA. The complete nucleotide sequence of this RNA species is: pG-U-C-C-C-G-C-U-G-G-U-G-U-A-A-U-Gm2'-G-A-D-A-G-C-A-U-A-C-G-A-U-C-C-U-U-C-U-A-A-G-psi-U-U-G-C-G-G-U-C-C-U-G-G-T-psi-C-G-A-U-C-C-C-A-G-G-G-C-G-G-G-A-U-A-C-C-AOH. The nucleotide sequence was determined by analysis of RNA, uniformly labeled in vivo, according to the conventional techniques. In addition, RNA synthesized in vitro in the presence of alpha-32P-labeled nucleoside triphosphates was analyzed through the use of nearest neighbor sequencing techniques. Although a unique sequence could not be determined by this latter analysis, restrictions on the sequence imposed by nearest neighbor data and secondary structure common to tRNA molecules allowed prediction of the correct nucleotide sequence.     

Induction of hydrotropism in clinorotated seedling roots of Alaska pea,Pisum sativum L.

Roots of the agravitropic pea (Pisum sativum L.) mutantageotropum show positive hydrotropism, whereas roots of Alaska peas are hydrotropically almost non-responsive. When the gravitropic response was nullified by rotation on clinostats, however, roots of Alaska peas showed unequivocal positive hydrotropism in response to a water potential gradlent. These results suggest that roots of Alaska peas possess normal ability to respond hydrotropically and their weak hydrotropic response results from a counteracting effect of gravitropism.     

Cloning and characterization of the P subunit of glycine decarboxylase from pea (Pisum sativum).

A pea leaf cDNA library constructed in lambda gt11 was screened with an antibody raised to the P subunit of glycine decarboxylase. One of the positive clones isolated was sequenced and shown to contain an open reading frame, which encoded the entire P subunit polypeptide. Aligning the deduced amino acid sequence with the amino acid sequence determined directly from the NH2 terminus of the mature P subunit shows the presence of a putative 86 amino acid leader sequence, presumably required for import into the mitochondria, and gives a Mr of the mature protein of 105,000. Comparison of this deduced amino acid sequence with the sequence of a pyridoxal phosphate-containing peptide isolated from the P subunit of chicken liver glycine decarboxylase shows remarkable conservation. The P subunit, however, shows little sequence homology with other published amino acid decarboxylases. Expression of the P subunit mRNA shows a pattern very similar to that of the corresponding polypeptide: it is strongly light induced and is expressed at a much higher level in leaves than in other tissues. Southern blot analysis suggests that the P subunit is encoded by a small multigene family.     

Nucleotide sequence of wheat germ cytoplasmic initiator methionine transfer ribonucleic acid

The primary sequence of wheat germ initiator tRNA has been determined using in vitro labelling techniques. The sequence is: pAUCAGAGUm1Gm2GCGCAG CGGAAGCGUm2GG psi GGGCCCAUt6AACCCACAGm7GDm5Cm5CCAGGA psi CGm1AAACCUG*GCUCUGAUACCAOH. As in other eukaryotic initiator tRNAs, the sequence -T psi CG(A)- present in loop IV of virtually all tRNA active in protein synthesis is absent and is replaced by -A psi CG-. The base pair G2:C71 present in all other initiator tRNAs recognized by E. coli Met-tRNA transformylase is absent and is replaced by U2:A71. Since wheat germ initiator tRNA is not formylated by E. coli Met-tRNA transformylase this implies a possible role of the G2:C71 base pair present in other initiator tRNAs in formylation of initiator tRNA species.     

Hollow heart of pea (Pisum sativum)

Book reviewed in this article: The Way Ahead in Plant Breeding. Proceedings of the Sixth Congress of Eucarpia. Edited by F. G. H. Lupton , G. Jenkins and R. Johnson . Basic Electron Microscope Techniques. By M. A. Hayat . The Logit Transformation (with special reference to its uses in bioassay). By W. D. Ashton . Families of Frequency Distributions. By J. K. Ord .