D.A. Baker

The effect of water stress on the activities of key regulatory enzymes of the sucrose to starch pathway in wheat

Developmental changes in the starch and sucrose content of grains andthe activities of enzymes of starch synthesis in wheat were studied under waterstress conditions. Water stress caused a marked reduction in the sucrose andstarch content of the grains. Sucrose synthase (SS) and UDP-glucosepyrophosphorylase (UDP-Gppase), showed higher catalytic activity and moreresistance to water stress compared with amyloplastic enzymes. ADP-glucosepyrophosphorylase (ADP-Gppase) activity was reduced to a low level under bothin situ and osmotic stress conditions in which grainsfailed to accumulate dry matter in vivo. Granule-boundstarch synthase (GBSS) also responded rapidly to in situwater stress treatments as did ADP-Gppase. Reduction in GBSS activity at thetime of growth cessation in situ was less than that ofADP-Gppase and the enzyme did not respond to severe osmotic stress. Solublestarch synthase (SSS) was the enzyme most sensitive to water stress in that itresponded earlier, and to a greater extent, than the other enzymes. However,under severe dehydration conditions, leading to cessation of growth, thedeclinein SSS activity was less than that for ADP-Gppase. SSS showed the lowestin vitro activity followed by GBSS. These results suggestthat SSS is the site of response to water stress by which the rate of graingrowth can be affected, whereas growth cessation is due mainly to theinactivation of ADP-Gppase.

Effects of abscisic acid (ABA) on grain filling processes in wheat

The effect of in situ water stress on the endogenous abscisic acid (ABA) content of the endosperm and the in vitro application of ABA on some important yield regulating processes in wheat have been studied. Water stress resulted in a marked increase in the ABA content of the endosperm at the time close to cessation of growth. Application of ABA to the culture medium of detached ears reduced grain weight. Exogenously applied ABA, at the highest concentration (0.1 mM) reduced transport of sucrose into the grains and lowered the starch synthesis ability of intact grains. In vitro sucrose uptake and conversion by isolated grains was stimulated by low ABA concentrations (0.001 mM) in the medium but was inhibited by higher concentrations. ABA application had no effect on sucrose synthase (SS) and uridine diphosphate glucose pyrophosphorylase (UDP-Gppase) activities, whereas adenosine diphosphate glucose pyrophosphorylase (ADP-Gppase), soluble starch synthase (SSS), and granule-bound starch synthase (GBSS) activities were reduced. These results raise the possibility that water stress-induced elevated levels of endogenous ABA contribute to reduced grain growth.

GC-MS-SIM analysis of abscisic acid and indole-3-acetic acid in shoot bark of apple rootstocks

Concentrations of abscisic acid and indole-3-acetic acid were measured by GC-MS-SIM in the shoot bark of clonal apple rootstocks (M.27, M.9, MM.106 and MM.111) when the rootstocks were growing actively in the UK. These rootstocks are known to exhibit a wide range of control of tree size when grafted to a common scion. Shoot bark of the dwarfing rootstocks (M.27 and M.9) contained higher concentrations than the more vigorous rootstocks (MM.106 and MM.111) of ABA. Concentrations of ABA increased from May to July, followed by a decline in August. Only the month of sampling showed any significant influence on the concentration of IAA in shoot bark; however, there was a general increase, although not significant statistically, in IAA concentration with the increasing invigoration-capacity of the rootstock. At each sampling date the dwarfing rootstocks showed greater ratios of ABA:IAA than the invigorating rootstocks and generally the ratio for each rootstock increased from May to July, except for M.27 which showed the smallest ratio in June and the largest ratio in August. The results are discussed in relation to the generally accepted control exerted by the rootstocks on tree size and the possible influence of ABA on polar auxin transport.

Vascular transport of auxins and cytokinins in Ricinus

Analyses of vascular saps supplying source and sink organs havedemonstrated the presence of major endogenous hormones and/or theirprecursors. Indol-3yl-acetic acid, a number of gibberellins, cytokininsand abscisic acid, as well as the precursor for ethylene production havebeen found in these vascular saps, allowing the sites of hormonalsynthesis and putative target tissues to be deduced. Exogenously appliedhormones are also readily loaded into these vascular pathways and may betranslocated over considerable distances from a point of application.Observations such as these indicate a possible co-ordination systembetween source and sink regulated by the synthesis and transport ofendogenous hormones. It is widely accepted that the partitioning ofassimilates between photosynthetic source organs and utilising sinkorgans is regulated by endogenous plant hormones. The key intermediatesteps involved in assimilate transport, such as phloem loading andunloading, have been shown to be responsive to applied hormones,although the role of endogenous hormones in these processes remainsessentially unresolved. Results of the analyses of vascular saps fromRicinus communis, which have been obtained using a range ofphysicochemical methods, are compared and contrasted with those obtainedby the application of exogenous hormones or their precursors. Theseresults are evaluated critically and interpreted in the light of currentmodels of source:sink regulatory processes and the long-distancetransport of auxins and cytokinins in higher plants.

Shoot regeneration in response to carbon source on internodal explants of Annona muricata L.

Adventitious shoot regeneration from internodal explants of mature plants of Annona muricata L. was obtained on Nitsch media. Meristems were induced with sorbitol as the sole carbon source supplemented with 2 mg l−1 of benzylaminopurine and 0.5 mg l−1 naphthaleneacetic acid. Adventitious shoots were developed only when the explants were transferred onto growth regulator-free media containing sucrose, galactose, or glucose. A hypothesis is proposed for the involvement of sorbitol in the induction and development of de novo shoots from internodal explants of mature trees of A. muricata.

LONG-DISTANCE VASCULAR TRANSPORT OF ENDOGENOUS HORMONES IN PLANTS AND THEIR ROLE IN SOURCE:SINK REGULATION

Analyses of phloem and xylem saps from a wide variety of plants have demonstrated the presence of the major endogenous plant hormones. The auxin 3-indole-aceticacid, a number of gibberellins, cytokinins, and abscisic acid have been found in one or the other or both of these vascular saps, allowing the sites of hormonal synthesis and putative target tissues within the plant to be deduced. Exogenously applied hormones can also be readily taken up into these vascular pathways and may be trans located over considerable distances from a point of application. Observations such as these indicate a potential coordination system between root and shoot, regulated by the synthesis and transport of endogenous hormones initially through the vascular system followed by extra vascular transport. The partitioning of assimilates between photosynthetic or storage source organs and utilizing sink organs is widely accepted to be regulated by endogenous plant hormones. The key intermediate steps, phloem loading and unloading, are responsive to exogenously applied hormones. Vascular saps from different plants have been analyzed by various investigators using a range of physicochemical methods. Their observations are evaluated and interpreted here in the light of current models of source: sink regulatory processes and the long-distance transport of endogenous hormones in higher plants.

Phloem mobility of xenobiotics: tabular review of physicochemical properties governing the output of the Kleier model

The Kleier model of phloem-mobility of xenobiotics combines the intermediate permeability hypothesis with the acid trap mechanism for weak acids. The output of the model is dependent on the lipophilicity of a compound, for which octanol/water partition coefficients (log Kow) have been used as a measure. The membrane permeability of xenobiotics is predicted from these partition coefficients, and the nature of the sieve tube membranes has been modelled using regressions derived from Nitella or potato permeability data. A wide range of log Kow values for herbicides, fungicides, insecticides and experimental compounds (≈400) have been tabulated along with the model output for various membrane parameters. The application of the model is in broad agreement with literature and experimental observations on many of the known phloem mobile herbicides and predicts low phloem mobility for the fungicides and insecticides considered here, again in agreement with the literature. The behaviour of herbicides representative of the main chemical families and modes of action are reviewed, along with examples of the few phloem-mobile fungicides and insecticides identified.

Cytokinins in the vascular saps of Ricinus communis

Roots are recognised as the major sites of cytokinin synthesis and shoots receive a continuous supply of cytokinins from the roots. Although reports are available on the xylem mobility of putative free bases and their ribosides, relatively few studies on the phloem mobility of cytokinins have been reported. The origin of phloem-mobile cytokinins is uncertain but there is evidence which implicates a recirculation from the root source. This study is the first report in which zeatin and zeatin riboside from the root pressure exudate and phloem sap of Ricinus have been identified by full-scan GC-MS and quantified by GC-MS selective-ion-monitoring. In this study, the concentration of cytokinins in root pressure exudate was similar, but lower, and in the phloem sap higher than that reported previously. The concentration of cytokinins quantified in the phloem sap confirms their transport in the sieve tubes. The relatively high concentration of zeatin riboside detected in the root pressure exudate and of zeatin detected in the phloem sap indicate a possible vascular recirculation of these hormones.

The biosynthesis and translocation of 14C-IAA in Ricinus communis

The biosynthesis of 14C-IAA from 14C-tryptophan applied to abraded leaves of Ricinus communis and its subsequent export through the phloem were studied. Phloem sap was collected at intervals from incisions made in the stem below the IAA fed leaf. Any upward movement of label through the phloem or downward movement of phloem mobile compounds from leaves above the treated one were restricted by bark-ringing the plants.TLC and HPLC analyses of the collected sap indicate that some conversion of 14C-tryptophan to 14C-IAA had occurred. Subsequent GC-MS analysis of the HPLC purified samples of phloem sap revealed high levels of endogenous IAA transported from the fed leaf. The high ratio of unlabelled/labelled IAA in the phloem sap makes unequivocal confirmation by GC-MS of the predicted biosynthesis of 14C-IAA impossible. It is postulated that IAA is synthesised from tryptophan in mature leaves and exported to developing sink tissues with the flow of photoassimilates in the phloem.

Identification and quantification of the major endogenous cytokinins in pistachio seedlings.

The major endogenous cytokinins, Z, ZR, DHZ, DHZR, iP and iPR in pistachio seedlings (Pistacia vera L. cv. Ohadi) were purified by HPLC and their identities confirmed using GC-MS. The aerial parts of two-year old pistachio seedlings including mature leaves, young leaves, lateral buds, debarked stems and bark were subjected to analysis. All of the above mentioned cytokinins were identified in the aerial parts except DHZ which was only present in mature leaves. Z-type cytokinins contributed almost 43% of the total cytokinins. ZR and DHZR were identified as the major ribosides and iP as the main base. The greatest concentration of ZR was detected in the bark, amounting to about 48%. DHZR and ZR constituted the major portion of the total cytokinins detected in both young and mature leaves while Z was detected as a minor cytokinin in leaves. The sharp increase of iP concentration during leaf maturation indicates that mature leaves are probably capable of de novo biosynthesis of cytokinins. The absence of DHZ (except in mature leaves) and the presence of considerable concentrations of DHZR in pistachio stems suggest that these tissues are able to metabolize DHZ to DHZR. The large amount of ZR in pistachio leaves suggests that root-derived ZR is transported into the leaves after loading into the xylem. The presence of high amounts of iP in pistachio lateral buds indicates that iP has been accumulated in these parts. The occurrence of a totally different cytokinin distribution pattern in buds, as compared with the other aerial parts, possibly results from their different metabolism.