Effects of Initial Size and of Shading on the Quantitative Growth of Seedlings of the Citrus Rootstock Carrizo citrange

An 18 months' analysis of the effects of shading and of initialsize on the growth of Carrizo citrange revealed large effectson growth-rates but relatively small effects on distributionof growth to leaf, stem, thorn, and root. Shade reduced the relative growth-rate in the same proportionas the average reduction in light intensity but initial sizewas without effect. The only significant effect on proportionwas a reduction of root in shade. These effects are contrasted with species effects reported earlier.     

Dry Matter Partitioning in a Determinate and an Indeterminate Cultivar of Vicia faba L. Under Contrasting Plant Distributions and Densities

Models for root: shoot, vegetative: generative and stem: leafpartitioning are presented to quantify dry matter partitioningof two contrasting genotypes of Vicia faba, an indeterminateand a ‘topless’. A third plant type, a determinateof which two to three inflorescences had been removed, was alsoincluded but behaved similarly to the intact plant. The root:shoot partitioning model predicts linear relationships betweenroot proportion and the product of air vapour pressure deficitand relative growth rate. Data from field experiments were consistentwith model prediction and coefficients estimated were similarfor both genotypes. Partitioning into pods was modelled as proportionalto the number of actively growing pods younger than 1000°Cd. Coefficients estimated were similar in both genotypes butdifferent between densities and years. In the indeterminategenotype, stem: leaf ratio was allometric throughout, whereasleaf growth ceased but stem growth continued in the determinateafter formation of the terminal inflorescence. Relatively moredry matter was allocated to stems than to leaves in high thanin low densities. In conclusion, the main differences in drymatter partitioning between genotypes concern leaf: stem partitioningduring early pod filling and pod partitioning due to pod numberdifferences. Partitioning, root, shoot, leaf, stem, Vicia faba L.     

Effects of Salinity on Some Citrus Scion-Rootstock Combinations

Chloride and sodium concentrations, water relations and gasexchange parameters were measured on leaves of Clementine (CitrusClementine Hort. ex. Tan) and Navel orange [C. sinensis (L.)Osb] scions grafted on Cleopatra mandarin (C. reticulata Blanco)and Troyer citrange (C. sinensis x Poncirus trifoliata) rootstocksgrown at increasing levels of NaCl in the external medium. Otherparameters affected by salinity such as growth and defoliationwere also recorded. Scions on Cleopatra mandarin accumulated less Cl^- in their leavesthan did scions on Troyer citrange. Also, leaf Cl^- levels inClementine scions were lower than in Navel orange when bothwere grafted on the same rootstock. However, sodium concentrationwas lower in scions on Troyer citrange than in Cleopatra mandarin. Leaf water potential, stomatal conductance, photosynthesis andgrowth were reduced more in grafted plants of salt-treated Navelorange than those of salt-treated Clementine. However, choiceof rootstock had little effect on salt-induced changes in theseparameters. For each scion, reduction in leaf stomatal conductancewas closely correlated with decrease in leaf water potential.Also, a significant correlation between photosynthesis and stomatalconductance was found. The results indicate that reductions in gas exchange parametersand growth at increasing salinity levels depended more on thescion type than on Cl^- or Na⁺ concentration in leaves. Otherwise,leaf injury and defoliation were closely correlated with leafCl^- concentration.Copyright 1995, 1999 Academic Press Citrus, photosynthesis, salinity, water relations     

Root-Shoot Interaction in the Turnover of Reserves in Tea (Camellia sinensis L.) Roots

Root–shoot interaction in the tea plant, in relation toturnover of root reserves, following pruning and manuring, wereinvestigated by ring barking the roots or severing mature rootsin both unpruned and pruned plants. Translocation of leaf assimilatesto the root system appears to be dependent on a feeder rootstimulus, and nitrogen assimilation by the root system seemsto depend on replenishment of root reserves by leaf activity,both of which were interrupted by ring barking. Camellia sinensis, root–shoot interaction, tea, root reserves, translocation     

Genotype Affects the Morphogenic Response in vitro of Epicotyl Segments of Citrus Rootstocks

The influence of light, hormones and explant orientation onin vitro regeneration in epicotyl cuttings was compared in fourCitrus species (C. aurantium, C. macrophylla, C. reshni andC.sinensis ) and the hybrid Troyer citrange (C. sinensis x Poncirustrifoliata). In all cases, explants planted vertically regeneratedshoots at the apical end by a process of direct organogenesiswithout callus formation. When the Troyer citrange explantswere incubated horizontally, regeneration at the apical endoccurred by an indirect organogenic pathway after callus formation.This change in the pathway of regeneration did not occur inany of the Citrus species, and incubation horizontally resultedin a reduction in the number of buds and shoots formed throughthe direct organogenic pathway. Shoot formation through thedirect organogenic pathway was inhibited by darkness, and thisinhibitory effect was counteracted by the cytokinin benzyladeninein Troyer citrange and, partly, in C. sinensis, but not in C.macrophylla. A non-organogenic callus formed at the basal endof most of the cuttings of C. reshni. InC. sinensis and C. aurantium,a non-organogenic callus formed only in a low proportion ofexplants. Troyer citrange formed an organogenic callus in whichbuds or roots differentiated depending on the auxin/cytokininbalance. C. macrophylla formed callus in the dark but not inthe light. Root formation occurred both in the presence of theauxin naphthaleneacetic acid or low concentrations (2.2 to 4.4µM) of the cytokinin benzyladenine, but no buds were formed.These qualitative and quantitative differences in the organogenicresponse indicate that the conditions for regeneration mustbe optimized for each genotype. Copyright 2000 Annals of BotanyCompany Benzyladenine, citrus, Citrus aurantium, Citrus macrophylla, Citrus sinensis, Citrus sinensis x Poncirus trifoliata, naphthaleneacetic acid, organogenesis, rooting, shoot regeneration, Troyer citrange     

Arbuscular mycorrhizal fungi can alter some root characters and physiological status in trifoliate orange (<Emphasis Type="Italic">Poncirus trifoliata</Emphasis> L. Raf.) seedlings

Citrus plants strongly depend on mycorrhizal symbiosis because of less or no root hairs, but few reports have studied if their root traits and physiological status could be altered by different arbuscular mycorrhizal fungi (AMF). In a pot experiment we evaluated the effects of three AMF species, Glomus mosseae, G. versiforme and Paraglomus occultum on the root traits and physiological variables of the trifoliate orange (Poncirus trifoliata L. Raf.) seedlings. Root mycorrhizal colonization was 58–76% after 180 days of inoculation. AMF association significantly increased plant height, stem diameter, leaf number per plant, shoot and root biomass. Mycorrhizal seedlings also had higher total root length, total root projected area, total root surface area and total root volume but thinner root diameter. Among the three AMFs, greater positive effects on aboveground growth generally ranked as G. mosseae > P. occultum > G. versiforme, whilst on root traits as G. mosseae ≈ P. occultum > G. versiforme. Compared to the non-mycorrhizal seedlings, contents of chlorophyll, leaf glucose and sucrose, root soluble protein were significantly increased in the mycorrhizal seedlings. In contrast, root glucose and sucrose, leaf soluble protein, and activity of peroxidase (POD) in both leaves and roots were significantly decreased in the mycorrhizal seedlings. It suggested that the improvement of root traits could be dependent on AMF species and be related to the AMF-induced alteration of carbohydrates and POD.     

Leaf Growth in Cotton (Gossypium hirsutum L.) 2. The Influence of Temperature, Light, Water Stress and Root Restriction on the Growth and Initiation of Leaves

The rate parameters R₁, R₂, I/LI and I/t_0.5, which characterizethe growth in area of successive main-stem leaves, probablyall have the same temperature response. Temperature thereforeonly operates on the time scale. Water stress reduces both therelative growth rate and the advance of developmental age, thelatter however to a lesser extent than the former. The effectof root restriction is explained as resulting from mineral shortage. Gossypium hirsutum L., cotton, leaf growth, leaf initiation, relative growth rate, temperature, light, water stress, root restriction     

Potential Yield in Carrots (Daucus carota L.): Theory, Test, and an Application

There is little published information on the physiological behaviourof carrots at the crop level. Here we derive and test a simplemodel for the potential yield of carrot crops. The model calculatesgreen leaf area index (L) using a daily time step. Dry matterproduction is related linearly to light interception, calculatedfromL and canopy light extinction coefficient (k). Two stagesof growth are distinguished. In stage 1, leaf expansion on eachplant is unaffected by neighbouring plants. Stage 2 commenceswhen L reaches a critical value and the plants start to interact.Compared to stage 1, stage 2 has slower leaf expansion and ak which varies with plant density. Dry matter partitioning betweenshoots and the storage root depends on L. We calibrated themodel for two processing cultivars, ‘Chantenay Red Core’and ‘Red Hot’, using data from a 1997–98 plantdensity experiment in Hawke's Bay, New Zealand. The model accountedfor 72% of the observed variation in root size and 79% of thevariation in yield. We tested the model against results fromtwo experiments in 1995–96 and 1996–97. In bothexperiments the same two cultivars were sown at three differentsowing times. Overall, the model accounted for 72% of the observedvariation in root size and 66% of the variation in yield, showingthat it is portable to other environments. Finally, we appliedthe model to interpret the effects of sowing date in these twoexperiments. Previous attempts were confounded by variationin plants m^-2with sowing date. The model allowed us to separatethe effects of these factors, and indicated that early sowingsubstantially benefited yield. Copyright 2000 Annals of BotanyCompany Carrot, Daucus carota L., day-degrees, genetic algorithm, growth modelling, plant density, potential yield, thermal time     

Size-dependent Allometry of Tree Height, Diameter and Trunk-taper

The allometry of tree height with respect to trunk diameterand the allometry of trunk diameter with respect to distancefrom the top of the tree (i.e. trunk taper) were determinedfor 27 Robinia pseudoacacia trees differing in age and sizegrowing in an open field. The allometric (scaling) exponentfor height was > 1 for small and young trees and decreasedto 2/3 and then 1/2 as tree size and age increased. Similarly,the exponent for taper was > 1 near the tips of young andold trunks and converged onto values of 2/3 and 1/2 toward thebase of mature tree trunks. These observations indicate thata single 'optimal mechanical design principle' (i.e. elastic,stress or geometric self-similarity) neither holds true throughoutthe lifetime of R. pseudoacacia trees, nor does a single designprinciple govern the taper of a trunk throughout its entirelength. Rather, over the course of growth and development, theallometry of R. pseudoacacia tree height and trunk taper progressivelychanges, complying with geometric self-similarity for youngplants (and young portions of old plants) and subsequently givingthe appearance of elastic or stress self-similarity as plants(or portions of plants) get older and therefore larger. Analysesof published (and new) data suggest that the conclusions drawnfor R. pseudoacacia trees are likely to hold true for othertree species because stem growth in diameter is 'indeterminate'whereas growth in overall tree height is asymptotic and thereforeessentially 'determinate'.Copyright 1995, 1999 Academic Press Scaling, woody plants, Robinia pseudoacacia     

Leaf Characteristics and Net Gas Exchange of Diploid and Autotetraploid Citrus

The effect of tetraploidy on leaf characteristics and net gasexchange was studied in diploid (2x ) and autotetraploid (4x) ‘Valencia’ sweet orange (Citrus sinensis (L.)Osb.) and ‘Femminello’ lemon (Citrus limon (L.)Burm. f.) leaves. Comparisons between ploidy levels were madeunder high irradiance (I) in a growth chamber or low total Iin a glasshouse. Tetraploids of both species had thicker leaves,larger mesophyll cell volume and lower light transmittance thandiploids regardless of growth I. Mesophyll surface area perunit leaf area of 2x leaves was 5–15% greater than on4x leaves. Leaf thickness and mesophyll cell volume were greaterin high I leaves than low I leaves. In high I, average leafarea was similar for 2x and 4x leaves, whereas in low I it was30% greater in 4x than in 2x leaves. Nitrogen and chlorophyllconcentration per cell increased with ploidy level in both growthconditions. The ratio of chlorophyll a:b was 25% greater in2x than in 4x leaves. When net CO₂assimilation rate (A_CO2) wasbased on leaf area, 4x orange leaves had 24–35% lowerA_CO2than their diploids. There were no significant differencesin A_CO2between 2x and 4x orange or lemon leaves when expressedon a per cell basis. Overall, lower A_CO2per unit leaf area oftetraploids was related to increase in leaf thickness, largermesophyll cell volume, the decrease in mesophyll area exposedto internal air spaces, and the lower ratio between cell surfaceto cell volume. Such changes probably increased the resistanceto CO₂diffusion to the site of carboyxlation in the chloroplasts. Cell volume; chlorophyll; irradiance; leaf thickness; nitrogen; photosynthesis; ploidy; Citrus limon ; C. sinensis ; ‘Valencia’ sweet orange; ‘Femminello’ lemon     

Winter Growth of Autumn-sown White Lupin (Lupinus albus L.) Main Apex Growth Model

The winter growth of winter white lupin (cv. Lunoble) was investigated.Over three consecutive years, 1987–1989, it was sown atdifferent times at Lusignan (France) and in 1989, at nine differentlocations with various sowing times. The production of primordia,the vernalization requirements and the final number of leaveson the main stem were related to field measurements of dailymaximum and minimum temperatures. A statistical model for the main apex growth with a system oftwo equations was developed, with a threshold level for leafprimordia production at 3 °C. The number of leaf primordiaproduced by a vegetative apex (y) in terms of the cumulativesums of temperature over 3 °C (x) followed the curvilinearregression y = 4.76 + 00268x + 00000156x². The upper and lowertemperature limits for vernalization were estimated as 14 andI °C respectively. The vernalization requirements of a vegetative apex (y) decreasedwhen the number of initials produced (x) increased accordingto the negative exponential regression y = exp (7.2 + 002626.x). The two equations were used for the prediction of the finalnumber of leaves of a lupin crop. The predictive accuracy ofthe model was checked against independent data. The agreementbetween observed and predicted final leaf number was often close,but some deviations did occur with low leaf number. The modeldescribed most of the growth phenomena which occur during thephase sowing to floral initiation of the main stem of a winterlupin crop, and its possible uses are discussed. Lupinus albus L., white lupin, growth, model, vernalization, primordia, apex, thermal time     

Relationship Between the Development and Growth of Rye (Secale cereale L.) and the Potassium Concentration in Solution

The development and growth of rye (Secale cereale L. cv. Rheidol)was studied in seedlings grown hydroponically in complete nutrientsolutions containing between 10 and 600 µM K⁺. The phyllochron(defined as the interval between the appearance of successiveleaves) was used as a developmental timescale to compare plants.The pattern of both shoot and root development was strictlyordered on a phyllochron basis and was unaffected by solutionK⁺ concentration, with the exception that tillers in plantsgrown at the lowest K⁺ concentrations were occasionally eithernot initiated or aborted at an early stage of development. However,both the rate of leaf appearance on the main stem and successivetillers and the rate of tiller appearance were slower in plantsgrown at lower K⁺ concentrations. The rate of leaf appearanceon the main stem was reduced to below 90% of its maximal valueat solution concentrations below about 50 µM K⁺. Plantrelative growth rate (RGR) was also reduced by lowering theK⁺ concentration of the nutrient solution and fell to below90% of its maximal value at solution concentrations below about200 µM K⁺. There was a complex relationship between tissueK⁺ concentration and the K⁺ concentration of the nutrient solution,which differed between leaves and root. Leaf K⁺ concentrationincreased steadily from about 50 µmol g^-1 f. wt to about200 µmol g^-1 f. wt as solution K⁺ concentration was increasedfrom 10 to 400 µM. In contrast, root K⁺ concentrationexhibited a sigmoidal dependence on solution K⁺ concentration,maintaining a minimal value of approximately 20 µmol g^-1f. wt at concentration below 100 µM K⁺, then increasingprogressively to about 120 µmol g^-1 f. wt at a solutionconcentration of 600 µM K⁺. The 'critical' leaf K⁺ concentration,i.e. the concentration at which either plant RGR or plant developmentwas reduced 90% of its maximal value, was 86 µmol g^-1f. wt for plant RGR and 150 µmol g^-1 f. wt for plant development.The 'critical' root K⁺ concentration was 24 µmol g^-1 f.wt K⁺ for both RGR and development. A decline in tissue K⁺ concentrationbelow these thresholds reduced plant growth considerably. RootK⁺ concentration was a sensitive indicator of the K⁺ statusof the plant with respect to potential growth since plant growthdeclined abruptly as root K⁺ concentration approached its 'critical'value, whereas plant growth showed a less defined relationshipwith shoot K⁺ concentration.Copyright 1993, 1999 Academic Press Critical K⁺ concentration, development, potassium, relative growth rate (RGR), rye, Secale cereale L. cv. Rheidol     

The role of apical development around the time of leaf initiation in determining leaf width at maturity in wheat seedlings (Triticum aestivum L.) with impeded roots

High soil resistance to root penetration (measured as penetrometerresistance, R_s slows down leaf growth and reduces mature leafsize in wheat seedlings {Triticum aestivum L.). Underlying changesin the kinetics of cell partitioning and expansion and in thesize and organization of mature cells were reported in companionpapers (Beemster and Masle, 1996; Beemster et al., 1996). Inthe present study, the relationships between apex growth, primordiuminitiation and expansion were analysed for plants grown at contrastingR_s, focusing on a leaf whose whole development proceeded afterthe onset of root impedance (leaf 5). High R_s reduced the rates of apex and leaf development, butdid not appear to have immediate effects on the pattern of developmentof the newly initiated phytomers. During an initial short period,the rate of development of a leaf primordium and associatednode were related to plastochronic age, according to similarrelationships (slopes) at the two R_s. Effects on developmentalpatterns were first detected on phytomer radial expansion duringplastochron 2. The ontogenetic pattern of leaf elongation wasaffected later, during the next few plastochrons preceding leafemergence (‘post-primordial stage’). It is concludedthat a reduction in the number of formative divisions and inthe number of proliferative cells along the intercalary mer-istemreported earlier (Beemster and Masle, 1996; Beemster et al.,1996) is not related to the size of the apical dome at leafinitiation nor to the size and number of meristematic cellsinitially recruited to the leaf primordium, which were all unaffectedby R_s. Rather they are generated at the primordial and post-primordialstages. Key words: Wheat, apex development, leaf primodium development, mature leaf width, root impedance     

Winter Growth of Autumn-sown White Lupin (Lupinus albus L.) Main Apex Growth Model

The winter growth of winter white lupin (cv. Lunoble) was investigated.Over three consecutive years, 1987–1989, it was sown atdifferent times at Lusignan (France) and in 1989, at nine differentlocations with various sowing times. The production of primordia,the vernalization requirements and the final number of leaveson the main stem were related to field measurements of dailymaximum and minimum temperatures. A statistical model for the main apex growth with a system oftwo equations was developed, with a threshold level for leafprimordia production at 3°C. The number of leaf primordiaproduced by a vegetative apex (y) in terms of the cumulativesums of temperature over 3°C (x) followed the curvilinearregression y = 4.76+ 0.0268x + 0000015 6x². The upper and lowertemperature limits for vernalization were estimated as 14 and1°C respectively. The vernalization requirements of a vegetative apex (y) decreasedwhen the number of initials produced (x) increased accordingto the negative exponential regression y = exp (7.2— 0.02626.x). The two equations were used for the prediction of the finalnumber of leaves of a lupin crop. The predictive accuracy ofthe model was checked against independent data. The agreementbetween observed and predicted final leaf number was often close,but some deviations did occur with low leaf number. The modeldescribed most of the growth phenomena which occur during thephase sowing to floral initiation of the main stem of a winterlupin crop, and its possible uses are discussed Lupinus albus L, white lupin, growth, model, vernalization, primordia, apex, thermal time     

Growth Rate and Water Relations of Citrus Leaf Flushes

Growth rates of seasonal leaf flushes of ‘Valencia’orange [Citrus sinensis (L.) Osbeck] were measured and waterrelations characteristics of young (new) and over-wintered (old)citrus leaves were compared. New flush leaves had lower specificleaf weights and lower midday leaf water potentials than comparablyexposed old leaves. Spring and summer flush new leaves had higherosmotic potentials than old leaves. These differences becamenon-significant as the new leaves matured. During summer conditions,water-stressed new leaves reached zero turgor and stomatal conductancealso began to decrease in them at higher leaf water potentialsthan in old leaves. Old leaves were capable of maintaining openstomata at lower leaf water potentials. Opened flowers and newflush leaves lost more water, on a dry weight basis, than flowerbuds, fruit or mature leaves. The results illustrate differencesin leaf water potential and stomatal conductance which can beattributed to the maintenance of leaf turgor by decreases inleaf osmotic potentials as leaves mature. These changes in citrusleaf water relations are especially important since water stressresulting from high water loss rates of new tissues could reduceflowering and fruit set. Citrus sinensis (L.) Osbeck, orange, Citrus paradisi Macf., grapefruit, growth rate, leaf water relations, osmotic potential, water potential, stomatal conductance     

Quantitative trait loci analysis of morphological traits in Citrus

The objectives of this study were to understand the genetic basis of morphological variation observed in the genus Citrus and its relatives and to identify genomic regions associated with certain morphological traits using genetic linkage mapping and quantitative trait loci (QTLs) analysis with random amplified polymorphic DNA (RAPD) markers. First, a genetic linkage map was constructed with RAPD markers obtained by screening 98 progeny plants from a {Citrus grandis × [C. paradisi × Poncirus trifoliata]} × {[(C. paradisi × P. trifoliata) × C. reticulata] × [(C. paradisi × Poncirus trifoliata) × C. sinensis]} intergeneric cross. The map contains 69 RAPD markers distributed into nine linkage groups. Then, 17 different morphological traits, including six tree and two leaf characters of 98 progeny plants and six floral and three fruit characters of about half of the same progeny plants were evaluated for 2 years and statistically analyzed for variation. Statistical analysis of individual traits indicated that trunk diameter and growth, tree height, canopy width, tree vigor and growth, leaf length and width, petal and anther numbers, petal length and width, length of pistil and style, fruit length and diameter, and fruit segment number showed normal or close to normal distribution, suggesting that these traits may be inherited quantitatively. Quantitative data from the morphological traits were analyzed to detect markers and putative QTLs associated with these traits using interval mapping method. QTL analysis revealed 18 putative QTLs of LOD > 3.0 associated with 13 of the morphological traits analyzed. The putative QTLs were distributed in several different linkage groups, and QTLs associated with similar traits were mostly mapped to the same LG or similar locations in the linkage group, indicating that the same genomic region is involved in the inheritance of some of the morphological traits.     

Comparative Effects of Soil Moisture Stress and Restricted Root Zone Volume on Morphogenetic and Physiological Responses of Soybean [Glycine max (L.) Merr.]

Significant differences in response to soil moisture stress(SMS) and restricted root zone volume (RRZV) were found in twocultivars of soybean [Glycine max (L.) Merr.] (‘Forrest’and ‘Williams’) plants grown under controlled-environmentconditions. Leaf water potentials of SMS-treated plants were0·4-0·6 MPa lower than those of controls and stomata1conductances 23-56% lower. In the case of RRZV treatment, however,there were no differences in either parameter. Initiation ofnew leaves as reflected in the plastochron index was stronglyreduced by SMS but was unaffected by RRZV. Photosynthetic rates(CO₂ fixation dm² of leaf) of plants given SMS were reducedby 11-21% while those of RRZV-treated plants were unaffected.SMS caused a strong preferential allocation of dry matter tothe root at the expense of the shoot in both cultivars. RRZV,however, had no effect on assimilate distribution in ‘Forrest’and only slightly favoured root growth in ‘Williams.’Carbohydrate concentrations of both alcohol-soluble and insolublefractions were increased significantly by SMS, especially inthe leaves, but were little affected by RRZV. Nitrogen concentrationin the root fraction was reduced by 22-24% and that in the leafand stem fractions by 7-14% under SMS but was not affected appreciablyby RRZV. Phosphorus concentration in the leaf, stem, and rootfractions was reduced by 45-65% under SMS but was relativelyunaffected by RRZV. These findings suggest that SMS and RRZVare basically different in their mechanism of action and thatthe impairment of growth resulting from these two stresses mayinvolve different physiological processes. Our results alsoindicate that the suppressive effects of small containers onplant growth do not necessarily result from inadvertent SMS. Key words: Drought, Container effects, Glycine max (L.) Merr     

Saturation Deficit, Canopy Formation and Function in Sorghum bicolor (L.)

Hamdi, Q. A., Harris, D. and Clark, J. A. 1987. Saturation deficit,canopy formation and function in Sorghum bicolor (L.).—J.exp. Bot. 38: 1272–1283. Stands of two sorghum genotypes, SPV 354 and MK. 35-1, weregrown in controlled-environment glasshouses at three levelsof saturation vapour pressure deficit (SD), at the same temperatureand with unrestricted soil moisture. Vegetative growth was monitoredby growth analysis and non-destructive measurements were madeof leaf appearance, leaf extension and final size, and fractionallight interception. Rates of leaf appearance were reduced athigh SD in both genotypes, although this may have been an artefactof the method of measurement, and MK 35-1 produced leaves moreslowly than SPV 354. Leaf extension was also slowed as SD increasedand, since the duration of extension for individual leaves ofa given age remained constant, resulted in smaller leaf areaindices (L) in dry air than in humid air. The cumulative interceptionof radiation and the dry matter/radiation quotient (e) bothdecreased as SD increased. Key words: Sorghum, saturation deficit, canopy formation     

Episodic Growth and Relative Shoot: Root Balance in Loblolly Pine Seedlings

Leaf, root and stem systems of loblolly pine seedlings are characterizedby a seasonal periodicity in growth, during which they alternatein spurts of activity. Despite this periodicity, the allometriccoefficient describing the ratio of the relative growth ratesof leaf to root remains constant for at least the first twoyears of development. In part, constancy results from the inabilityof variation in the allocation of growth increment during briefperiods to change a pre-existing structure accumulated overthe life of the seedling. In addition, alternating periods ofleaf, root and stem growth may represent the action of feedbackmechanisms which operate to maintain an adaptive balance betweenorgan systems. Pinus taeda L., loblolly pine, allometric coefficient, homeostatic control of growth     

Cation and Chloride Partitioning through Xylem and Phloem within the Whole Plant of Ricinus communis L. under Conditions of Salt Stress

Uptake and partitioning through the xylem and phloem of K⁺,Na⁺, Mg²⁺ , Ca²⁺ and Cl^– were studied over a 9 d intervalduring late vegetative growth of castor bean (Ricinus communisL.) plants exposed to a mean salinity stress of 128 mol m^–3NaCl. Empirically based models of flow and utilization of eachion within the whole plant were constructed using informationon ion increments of plant parts, molar ratios of ions to carbonin phloem sap sampled from petioles and stem internodes andpreviously derived information on carbon flow between plantsparts in xylem and phloem in identical plant material. Salientfeatures of the plant budget for K⁺ were prominent depositionin leaves, high mobility of K⁺ in phloem, high rates of cyclingthrough leaves and downward translocation of K⁺ providing theroot with a large excess of K⁺ . Corresponding data for Na⁺showed marked retention in the root, lateral uptake from xylemby hypocotyl, stem internodes and petioles leading to low intakeby young leaf laminae and substantial cycling from older leavesback to the root. The partitioning of the anionic componentof NaCl salinity, Cl^–, contrasted to that of Na⁺ in thatit was not substantially retained in the root, but depositedmore or less uniformly in stem, petiole and leaf lamina tissues.The flow pattern for Mg²⁺ showed relatively even depositionthrough the plant but some preferential uptake by young leaves,generally lesser export than import by leaf laminae, and a returnflow of Mg²⁺ from shoot to root considerably less than the recordedincrement of the root. Ca²⁺ partitioning contrasted with thatof the other ions in showing extremely poor phloem mobility,leading to progressive preferential accumulation in leaf laminaeand negligible cycling of the element through leaves or root.Features of the response of Ricinus to salinity shown in thepresent study were discussed with data from similar modellingstudies on white lupin (Lupinus albus L.) and barley (Hordeumvulgare L.) Key words: Ricinus communis L, potassium, sodium, chloride, calcium, magnesium, phloem, xylem, transport, partitioning, salinity