Characterization of a Novel Protein Induced by Progressive or Rapid Drought and Salinity in Brassica napus Leaves.

Under progressive drought stress, Brassica napus displays differential leaf modifications. The oldest leaves, developed before the onset of water deficit, wilt gradually, whereas the youngest leaves harden. Hardening was distinguished by leaf turgor and bluish wax bloom when the shoot water potential was below -3 MPa and the leaf water saturation deficit was about 60%. This adaptive change was accompanied by modifications in two-dimensional protein profiles. Ten percent of the polypeptides had altered abundance or were unique to drought-stressed plants. Two-dimensional analysis of in vitro translation products did not reveal a general decrease in mRNA population. A 22-kD double polypeptide was increased by progressive or rapid water stress and salinity and disappeared upon rehydration. These polypeptides have a common N-terminal sequence, which does not reveal homology with any known water-stress protein but which contains the signature motif of soybean Künitz trypsin inhibitors. Immunoprecipitation allowed these polypeptides to be identified on two-dimensional gels of in vitro translation products. They appeared to be synthesized as a 24-kD precursor, and their transcript was present in the control well-watered leaves, where the polypeptides were never detected, indicating a possible translational regulation. A putative function of this protein, named BnD22, in the retardation of drought-induced leaf senescence is discussed.

Variation of the polypeptide composition of mitochondria isolated from different potato tissues.

The protein contents of mitochondria from different potato (Solanum tuberosum L.) tissues (tubers, dark-grown shoots, and green leaves) grown in a greenhouse or in vitro were compared by two-dimensional polyacrylamide gel electrophoresis. Two different methods were used: using the method that gave the highest resolution, an average number of 360 polypeptides was revealed on the mitochondrial patterns after silver staining. The mitochondrial protein patterns of etiolated tissues (tubers, dark-grown shoots) are roughly similar but distinct from those of green leaves. The four subunits of the glycine decarboxylase complex (involved in photorespiration) and a few other polypeptides are very abundant in green tissues, compared with nonphotosynthetic tissues. Conversely, some other polypeptides that are abundant in tubers and dark-grown shoots are hardly detectable in green leaf mitochondria. A rabbit antiserum was raised against a 40 kilodalton polypeptide that is among the most characteristic of these nonphotosynthetic tissue-specific polypeptides, and the N-terminal sequence of this polypeptide was determined. No effect of in vitro culture was observed on the protein composition of mitochondria isolated from differentiated tissues. However, the protein patterns of callus and cell suspension mitochondria are distinct from those of any differentiated tissues, although their basic pattern is clearly mitochondrial.

Primary structure of sorghum malate dehydrogenase (NADP) deduced from cDNA sequence. Homology with malate dehydrogenase (NAD).

Malate dehydrogenase (NADP) (NADP-MDH) is an important enzyme of the photosynthetic CO2 fixation pathway of C4 plants. We have isolated two clones from a sorghum lambda gt11 cDNA library (CM3, 932 bp, and CM7, 1441 bp). Nucleotide sequence analysis of the cDNAs CM3 and CM7 showed the existence of two NADP-MDH mRNA species encoding different enzyme subunits. Microsequencing of the N-terminus of the mature protein indicated that a specific cleavage of 13 amino acids occurred during the purification steps of the enzyme. The full-length cDNA CM7 contains a large open reading frame encoding an NH2-terminal transit peptide of 40 amino acids and a mature protein of 389 amino acids (42.207 kDa). Alignment of the NADP-MDH sequence with those of several malate dehydrogenases revealed some similarities with NAD-MDHs.

Reassessment of commercially available molecular weight standards for peptide sodium dodecyl sulfate-polyacrylamide gel electrophoresis using electroblotting and microsequencing.

Myoglobin CNBr peptides, constituting the commercially available molecular weight calibration kits for sodium dodecyl sulfate-polyacrylamide gel electrophoresis, were analyzed by microsequencing after electroblotting on polyvinylidene difluoride (Immobilon) membranes. An obvious disagreement was found between peptide identification and the data provided by the manufacturers. We observed 6 peptides from Mr 2500 to 17,000 corresponding, in increasing size order, to the 3 peptides resulting from the total CNBr digestion, to 2 incompletely cleaved peptides and to the intact myoglobin. Using a corrected calibration curve, a linear relationship was established from Mr 6000 to 43,000 and a second one for shorter peptides. This method of electrophoresis and electroblotting, easily adapted for peptides, is a powerful tool for peptide identification correlated with size determination. It is especially useful for CNBr-cleaved peptides.

Structure and activity of proteins from pathogenic fungi Phytophthora eliciting necrosis and acquired resistance in tobacco.

The phytopathogenic fungi Phytophthora cryptogea and Phytophthora capsici cause systemic leaf necrosis on their non-host tobacco; in culture they release proteins, called cryptogein and capsicein, which elicit similar necrosis. In addition, both proteins protect tobacco against invasion by the pathogen Phytophthora nicotianac, the agent of the tobacco black shank, that is unable to produce such an elicitor. Cryptogein causes visible leaf necrosis starting at about 1 microgram/plant, whereas 50-fold as much capsicein is required for the same reaction. Capsicein induces protection even in near absence of leaf necrosis. The activities of both elicitors are eliminated upon pronase digestion. They are proteins of similar Mr (respectively 10,323 and 10,155) and their complete amino acid sequences were determined. They consist of 98 residues, with some internal repetitions of hexapeptides and heptapeptides. 85% identity was observed between both sequences: only two short terminal regions are heterologous, while the central core is entirely conserved. Secondary structure predictions, hydropathy and flexibility profiles differ only around position 15 and at the C-terminus; these modifications could play a role in the modulation of their biological activities. After a search of the sequence data bases, they appear to be novel proteins.

N-terminal sequences of oat avenins compared to other cereal prolamins.

Like the alcohol-soluble seed storage proteins (also called prolamins) of other cereals, avenins, the oat prolamins, are a series of polymorphic molecules belonging to a multigenic family stored within the protein bodies of the starchy endosperm. Nevertheless, they exhibit some pecularities: among the seed storage proteins, their proportion is low compared to prolamins from other cereal species; their net charge is higher; the amount of Gln + Pro only reaches 49 mol%; they are less polymorphic. We have isolated and purified several avenins and sequenced their N-terminal end. The microheterogeneity and the pecularity of avenins are revealed by the comparison of the N-terminal sequences. Like other prolamins, they exhibit tandem repeats; these repetitive peptides are slightly different from those of other prolamins of the Festucoideae, and the repetition begins earlier in the sequence. As for prolamins from other species, their predicted secondary structure reveals successive beta-turns which might be arranged in a pseudo-helix structure.