David T. Clarkson scite author profile

A population of 96 doubled haploid lines (DHLs) was prepared from F1 plants of the hexaploid wheat cross Chinese Spring x SQ1 (a high abscisic acid-expressing breeding line) and was mapped with 567 RFLP, AFLP, SSR, morphological and biochemical markers covering all 21 chromosomes, with a total map length of 3,522 cM. Although the map lengths for each genome were very similar, the D genome had only half the markers of the other two genomes. The map was used to identify quantitative trait loci (QTLs) for yield and yield components from a combination of 24 site x treatment x year combinations, including nutrient stress, drought stress and salt stress treatments. Although yield QTLs were widely distributed around the genome, 17 clusters of yield QTLs from five or more trials were identified: two on group 1 chromosomes, one each on group 2 and group 3, five on group 4, four on group 5, one on group 6 and three on group 7. The strongest yield QTL effects were on chromosomes 7AL and 7BL, due mainly to variation in grain numbers per ear. Three of the yield QTL clusters were largely site-specific, while four clusters were largely associated with one or other of the stress treatments. Three of the yield QTL clusters were coincident with the dwarfing gene Rht-B1 on 4BS and with the vernalisation genes Vrn-A1 on 5AL and Vrn-D1 on 5DL. Yields of each DHL were calculated for trial mean yields of 6 g plant(-1) and 2 g plant(-1) (equivalent to about 8 t ha(-1) and 2.5 t ha(-1), respectively), representing optimum and moderately stressed conditions. Analyses of these yield estimates using interval mapping confirmed the group-7 effects on yield and, at 2 g plant(-1), identified two additional major yield QTLs on chromosomes 1D and 5A. Many of the yield QTL clusters corresponded with QTLs already reported in wheat and, on the basis of comparative genetics, also in rice. The implications of these results for improving wheat yield stability are discussed.

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Plant members of a family of sulfate transporters reveal functional subtypes.

Smith¹,

Ealing²,

Hawkesford³

et al. 1995

Proc. Natl. Acad. Sci. U.S.A.

332

277

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Three plant sulfate transporter cDNAs have been isolated by complementation of a yeast mutant with a cDNA library derived from the tropical forage legume Stylosanthes hamata. Two of these cDNAs, shstl and shst2, encode high-affinity H+/sulfate cotransporters that mediate the uptake of sulfate by plant roots from low concentrations of sulfate in the soil solution. The third, shst3, represents a different subtype encoding a lower affinity H+/sulfate cotransporter, which may be involved in the internal transport of sulfate between cellular or subcellular compartments within the plant. The steady-state level of mRNA corresponding to both subtypes is subject to regulation by signals that ultimately respond to the external sulfate supply. These cDNAs represent the identification of plant members of a family of related sulfate transporter proteins whose sequences exhibit significant amino acid conservation in filamentous fungi, yeast, plants, and mammals.All plants need to absorb essential nutrient anions against large gradients of electrochemical potential; this is true for plants in both natural and agricultural environments. Evidently, transport mechanisms of high affinity have evolved, but their precise nature remains obscure, although they have been a major research topic for decades. Despite a wealth of physiological information, the molecular nature of the transporters and the way in which they are regulated are unknown.Sulfate transport in plant roots or cultured cells has highand low-affinity components (1); the former clearly respond to the sulfur-status of the organism, being strongly derepressed by sulfur-starvation and rapidly repressed by the restoration of a sufficient sulfur supply (2-4). High rates of sulfate uptake by previously sulfur-starved cells or roots appear to depend on protein synthesis; treatment with cycloheximide decreases sulfate influx with kinetics very similar to repression by sulfate (4, 5). Such results raised the question as to whether the control of transport activity was translational, or by posttranslational modification of the transporter, rather than by transcription of the genes that encode it. Here we present results demonstrating that changes in the level of the mRNA encoding the transporter are remarkably rapid and are quite compatible with changes in transport activity.Membrane transport proteins from a wide variety of sources may be placed into distinct groups based upon primary sequence similarity or structural features (6, 7). Sequence homologies between the Neurospora crassa sulfate transporter (8) and a number of genes not previously associated with sulfate transport, including a human mucosa protein (9) and a nodulespecific protein (10), have been recognized recently (11). More recent additions to this group are a rat liver sulfate transporter (12), a human gene, DTD, a mutation in which results in diastrophic dysplasia (13), and the yeast high-affinity sulfate transporter (14). In this paper we report the cloning and analysis of plant members of this family,...

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Regulation of expression of a cDNA from barley roots encoding a high affinity sulphate transporter

et al. 1997

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Diurnal variations in hydraulic conductivity and root pressure can be correlated with the expression of putative aquaporins in the roots of Lotus japonicus

Henzler

Waterhouse

Smyth

et al. 1999

Planta

253

198

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The hydraulic conductivity of excised roots (Lp(r)) of the legume Lotus japonicus (Regel) K. Larsen grown in mist (aeroponic) and sand cultures, was found to vary over a 5-fold range during a day/night cycle. This behaviour was seen when Lp(r) was measured in roots exuding, either under root pressure (osmotic driving force), or under an applied hydrostatic pressure of 0.4 MPa which produced a rate of water flow similar to that in a transpiring plant. A similar daily pattern of variation was seen in plants grown in natural daylight or in controlled-environment rooms, in plants transpiring at ambient rates or at greatly reduced rates, and in plants grown in either aeroponic or sand culture. When detached root systems were connected to a root pressure probe, a marked diurnal variation was seen in the root pressure generated. After excision, this circadian rhythm continued for some days. The hydraulic conductivity of the plasma membrane of individual root cells was measured during the diurnal cycle using a cell pressure probe. Measurements were made on the first four cell layers of the cortex, but no evidence of any diurnal fluctuation could be found. It was concluded that the conductance of membranes of endodermal and stelar cells may be responsible for the observed diurnal rhythm in root Lp(r). When mRNAs from roots were probed with cDNA from the Arabidopsis aquaporin AthPIP1a gene, an abundant transcript was found to vary in abundance diurnally under high-stringency conditions. The pattern of fluctuations resembled closely the diurnal pattern of variation in root Lp(r). The plasma membranes of root cells were found to contain an abundant hydrophobic protein with a molecular weight of about 31 kDa which cross-reacted strongly to an antibody raised against the evolutionarily conserved N-terminal amino acid sequence of AthPIP1a.

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David T. Clarkson

The Mineral Nutrition of Higher Plants

A high-density genetic map of hexaploid wheat (Triticum aestivum L.) from the cross Chinese Spring × SQ1 and its use to compare QTLs for grain yield across a range of environments

Plant members of a family of sulfate transporters reveal functional subtypes.

Regulation of expression of a cDNA from barley roots encoding a high affinity sulphate transporter

Diurnal variations in hydraulic conductivity and root pressure can be correlated with the expression of putative aquaporins in the roots of Lotus japonicus

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