Behavioral and electrophysiological responses of the parasitic wasp Psyttalia concolor (Szépligeti) (Hymenoptera: Braconidae) to Ceratitis capitata-induced fruit volatiles

Psyttalia concolor (Szépligeti) is a koinobiont larval-pupal endoparasitoid of many Tephritidae of great economic importance, such as the medfly, Ceratitis capitata (Wiedemann). In several species of parasitoids it has been demonstrated that the mated females are strongly attracted by specific volatiles from insect-damaged plants. Yet the role of olfactory cues deriving from C. capitata-infested fruits on the female’s decision during the P. concolor host location was poorly investigated. In the present study, the responses of P. concolor females to either healthy or C. capitata-infested fruits was studied through behavioral assays. Volatiles emitted by healthy and infested fruits were SPME-sampled and analyzed by gas chromatography–mass spectrometry (GC–MS). The attractiveness of the identified volatiles was assessed and their electrophysiological activity was analyzed through gas-chromatography coupled with electroantennography (GC-EAD). P. concolor preferred infested peaches and apples over healthy ones, either when visual and olfactory or only olfactory cues were given. Nine compounds were found as exclusive of infested peaches, with respect to healthy ones, and seven of them evoked electrophysiological responses. In apples only quantitative changes in volatile emissions were observed after the medfly infestation. The emissions of 1-butyl butylate, 1-hexyl acetate and 1-butyl esanoate increased in infested apples, whereas 1-hexyl (E)-2-methyl butenoate decreased significantly. Among apple volatiles, 1-butyl butylate, 2-methyl-1-butyl acetate, 1-hexyl acetate, 2-methyl-1-butyl 2-methylbutanoate, 1-butyl hexanoate and 1-hexyl (E)-2-methyl butenoate elicited responses in female antennae. Synthetic blends reproducing the odors emitted by infested peaches and apples elicited strong attraction towards P. concolor females. For both fruits, the blend attractiveness was mainly due to some specific electrophysiological active chemicals: ethyl octanoate, decanal and 4-decanolide for peach, and 1-butyl butylate and 1-butyl hexanoate for apple. The responses induced by the identified fruit volatiles to P. concolor females allow us to suppose that they play a role as short-range attractants during host location.     

The MUR3 gene of Arabidopsis encodes a xyloglucan galactosyltransferase that is evolutionarily related to animal exostosins

Xyloglucans are the principal glycans that interlace cellulose microfibrils in most flowering plants. The mur3 mutant of Arabidopsis contains a severely altered structure of this polysaccharide because of the absence of a conserved alpha-L-fucosyl-(1-->2)-beta-D-galactosyl side chain and excessive galactosylation at an alternative xylose residue. Despite this severe structural alteration, mur3 plants were phenotypically normal and exhibited tensile strength in their inflorescence stems comparable to that of wild-type plants. The MUR3 gene was cloned positionally and shown to encode a xyloglucan galactosyltransferase that acts specifically on the third xylose residue within the XXXG core structure of xyloglucan. MUR3 belongs to a large family of type-II membrane proteins that is evolutionarily conserved among higher plants. The enzyme shows sequence similarities to the glucuronosyltransferase domain of exostosins, a class of animal glycosyltransferases that catalyze the synthesis of heparan sulfate, a glycosaminoglycan with numerous roles in cell differentiation and development. This finding suggests that components of the plant cell wall and of the animal extracellular matrix are synthesized by evolutionarily related enzymes even though the structures of the corresponding polysaccharides are entirely different from each other.     

β-D-Glycan synthases and the CesA gene family: lessons to be learned from the mixed-linkage (1→3),(1→4)β-D-glucan synthase

Cellulose synthase genes (CesAs) encode a broad range of processive glycosyltransferases that synthesize (14)-D-glycosyl units. The proteins predicted to be encoded by these genes contain up to eight membrane-spanning domains and four `U-motifs' with conserved aspartate residues and a QxxRW motif that are essential for substrate binding and catalysis. In higher plants, the domain structure includes two plant-specific regions, one that is relatively conserved and a second, so-called `hypervariable region' (HVR). Analysis of the phylogenetic relationships among members of the CesA multi-gene families from two grass species,Oryza sativa and Zea mays, with Arabidopsis thaliana and other dicotyledonous species reveals that the CesA genes cluster into several distinct sub-classes. Whereas some sub-classes are populated by CesAs from all species, two sub-classes are populated solely by CesAs from grass species. The sub-class identity is primarily defined by the HVR, and the sequence in this region does not vary substantially among members of the same sub-class. Hence, we suggest that the region is more aptly termed a `class-specific region' (CSR). Several motifs containing cysteine, basic, acidic and aromatic residues indicate that the CSR may function in substrate binding specificity and catalysis. Similar motifs are conserved in bacterial cellulose synthases, the Dictyostelium discoideum cellulose synthase, and other processive glycosyltransferases involved in the synthesis of non-cellulosic polymers with (14)-linked backbones, including chitin, heparan, and hyaluronan. These analyses re-open the question whether all the CesA genes encode cellulose synthases or whether some of the sub-class members may encode other non-cellulosic (14)-glycan synthases in plants. For example, the mixed-linkage (13)(14)-D-glucan synthase is found specifically in grasses and possesses many features more similar to those of cellulose synthase than to those of other -linked cross-linking glycans. In this respect, the enzymatic properties of the mixed-linkage -glucan synthases not only provide special insight into the mechanisms of (14)-glycan synthesis but may also uncover the genes that encode the synthases themselves.     

Approaches to understanding the functional architecture of the plant cell wall.

Cell wall polysaccharides are some of the most complex biopolymers known, and yet their functions remain largely mysterious. Advances in imaging methods permit direct visualisation of the molecular architecture of cell walls and the modifications that occur to polymers during growth and development. To address the structural and functional relationships of individual cell wall components, we need to better characterise a broad range of structural and architectural alterations in cell walls, appearing as a consequence of developmental regulation, environmental adaptation or genetic modification. We have developed a rapid method to screen large numbers of plants for a broad range of cell wall phenotypes using Fourier transform infrared microspectroscopy and Principal Component Analysis. We are using model systems to uncover the genes that encode some of the cell-wall-related biosynthetic and hydrolytic enzymes, and structural proteins.     

Fructosyl Transfer between 1-Kestose and Sucrose in Wheat Leaves

The labeling pattern of the sugar moieties of 1-kestose after in vivo pulse labeling with ¹⁴CO₂ was not the same as that after in vitro labeling with ¹⁴C-sucrose. The two fructosyl residues of 1-kestose had similar specific radioactivities after in vitro synthesis, but after in vivo radiolabeling the specific radioactivity of the terminal fructosyl moiety was significantly less than the internal fructosyl moiety. Evidence is presented that the uneven specific radioactivity of in vivo radiolabeling results from enzymatic transfer of terminal fructosyl residue from 1-kestose to sucrose.     

Incorporation of proline and aromatic amino acids into cell walls of maize coleoptiles

Sections excised from maize coleoptiles incorporated radioactivity from proline, tyrosine, and phenylalanine into structural components of the cell wall. Only about 2% of radioactivity from proline taken up by sections was incorporated into cell wall; about 24% of that incorporated was in hydroxyproline and the rest remained in proline. In contrast, as much as 40% of the radioactivity from phenylalanine and 30% from tyrosine was incorporated into cell wall material. Most of this radioactivity was in saponifiable ferulic acid. Small amounts of p-coumaric and diferulic acid were found, but only a small fraction of the hemicellulose can possibly be immobilized directly through cross-linking of diferulic esters. Substantial amounts of radioactivity from aromatic amino acids remained insoluble after strong alkali extractions of wall material, and a large fraction of polysaccharide was solubilized by dilute alkali following oxidation of phenolics by acidic NaClO₂. Hence, hemicellulosic material in the cell walls of maize coleoptiles may be organized and cross-linked primarily through alkali-resistant etherified aromatics.     

The growth physics and water relations of red-light-induced germination in lettuce seeds

Using lettuce (Lactuca sativa L., cv. Grand Rapids) embryos in osmotica, we have demonstrated that when the growth rates of the embryonic axes of seeds treated with red (R) or far-red (FR) light are equalized, the axes of R-treated seeds develop a 3.4-bar decrease in water potential (paper No. III).As axial growth begins, reserve protein and phytin decrease rapidly, concomitant with increases in reducing sugars, -amino nitrogen, and inorganic and esterified soluble phosphates. However, no differences between the axes of R-and FR-treated seeds are found with respect to the changes in these compounds, indicating that these changes arise as a result of growth and are not under immediate phytochrome control. Little change in the total lipid content is found in either treatment. The axes of FR-treated seeds hydrolyze endogenous sucrose at a greater rate thant those of R-treated seeds. Axes of R-treated seeds accumulate K⁺ and Na⁺ to a greater extent than those of FR-treated seeds. When potassium salts are added to the incubation medium, R induces increased K⁺ uptake by the axis and greater medium acidification by the axis. Malate and other organic acids and acidic amino acids increase at equal rates in both treatments, indicating that inorganic anions may also be taken up to balance the ionic charges. The results are compatible with the assumption that changes in the osmotic and pressure potentials of the embryonic axes of R-treated seeds are the result of a phytochrome-stimulated proton pump which, in whole dormant seeds, would initiate water-potential changes allowing the embryos to overcome the mechanical restraint of the surrounding seed layers, resulting in germination.Abbreviations FR far-red light - PEG polyethylene glyeol 4000 - Pfr far-red-absorbing form of phytochrome - R red light III=Carpita et al. 1979     

The influence of plant growth regulators on the growth of the embryonic axes of red- and far-red-treated lettuce seeds

The influence of several plant growth regulators on the growth of the embryonic axes from red- and far-red-(R- and FR-)treated lettuce (Lactuca sativa L., cv. Grand Rapids) seeds was examined; as shown previously, the water potential of the axes from R-treated seeds has been lowered by 3.5–5.6 bars compared to that in axes from FR-treated ones. Kinetin and abscisic acid (ABA), when included in the incubation medium, reduced the elongation of the axes whereas fusicoccin stimulated it; however, these effects were the same in axes of both R- and FR-treated seeds. In contrast, elongation of axes from FR-treated seeds was stimulated by gibberellic acid (GA₃, but elongation of axes from R-treated ones was not affected by this hormone. This latter result indicates that gibberellins may be involved in the phytochrome-mediated growth responses in lettuce axes.When the root caps of the embryos were removed prior to light treatment, R was still able to induce a water-potential decrease in the embryonic axes, indicating that at least a portion of the active Pfr resides in the axis and not the root cap.Abbreviations ABA abscisic acid - FR far red light - GA₃ gibberellic acid - PEG polyethylene glycol - Pfr far-red-absorbing form of phytochrome - R red light     

Dynamic changes in cell surface molecules are very early events in the differentiation of mesophyll cells from Zinnia elegans into tracheary elements

The Zinnia mesophyll cell system consists of isolated leaf mesophyll cells in culture that can be induced, by auxin and cytokinin, to transdifferentiate semi-synchronously into tracheary elements (TEs). This system has been used to establish the precise time point at which the TE cell fate becomes determined, and then changes have been looked for in cell-wall composition and architecture that are associated with the establishment of competence, determination, and differentiation with the transition from primary to secondary cell wall formation. At very early stages in this time course, changes in the repertoire of proteins and polysaccharides both in the cell wall and secreted into the culture medium were found. Changes in the secretion of pectic polysaccharides, xyloglucans and arabinogalactan proteins (AGPs) have been detected using the monoclonal antibodies JIM 7, CCRC-M1 and JIM 13, that recognize these three classes of cell-wall molecule, respectively. Twenty-four hours before secondary thickenings are visible, an AGP is present in the primary walls of a subpopulation of cells, and is secreted into the culture medium. This molecule is present in the secondary thickenings of mature TEs but not in their surrounding primary walls. Methyl-esterified pectic polysaccharides are present in all cell walls and are secreted into the culture medium throughout the time course of differentiation, though at an increased rate in inductive medium. However, sugar and linkage analysis of culture media shows that a relatively unbranched rhamnogalacturonan is enriched in inductive medium around the time of determination and increases rapidly in concentration. The amount of fucosylated xyloglucan in cell walls increases during the time course, but appears in inductive medium 24 h earlier than in control medium and may have a subtly different structure. The fucose-containing epitope on the xyloglucan disappears abruptly and entirely from inductive medium 6 h before any secondary thickenings are visible in the cells. The disappearance of the epitope is correlated with secretion of several hydrolytic enzyme activities. In Zinnia leaves, the mesophyll cell walls contain neither the fucosylated xyloglucan nor the AGP, although methylesterified pectin is present. All three epitopes are expressed in the vascular bundles, and the AGP is specifically localized in the xylem cells. Fucosylated xyloglucan is also present in the epidermal tissue, and the AGP is present in guard cells. The dynamic behaviour of these specific cell-wall molecules is tightly correlated with differentiation events in vitro, and can be clearly distinguished from the production of new wall material found in expanding and elongating cells. The precise timing of the appearance and disappearance of these proteins and polysaccharides compared with the point of cell-fate determination provides us with a series of cell-surface markers for cell states at very early times in the transdifferentiation pathway.