Developmental control of xylem hydraulic resistances and vulnerability to embolism in Fraxinus excelsior L.: impacts on water relations

The freezing tolerance of many plants, such as pea (Pisum sativum),is increased by exposure to low temperature or abscisic acidtreatment, although the physiological basis of this phenomenonis poorly understood. The freezing tolerance of pea shoot tips,root tips, and epicotyl tissue was tested after cold acclimationat 2C, dehydration/rehydration, applications of 10^–4M abscisic acid (ABA), and deacclimation at 25C. Tests wereconducted using the cultivar ‘Alaska’, an ABA-deficientmutant ‘wil’, and its ‘wildtype’. Freezinginjury was determined graphically as the temperature that caused50% injury (T₅₀) from electrical conductivity. Endogenous ABAwas measured using an indirect enzyme-linked immunosorbant assay,and novel proteins were detected using 2-dimensional polyacrylamidegel electrophoresis. The maximum decrease in T₅₀ for root tissuewas 1C for all genotypes, regardless of treatment. For ‘Alaska’shoot tips and epicotyl tissue, exogenous ABA increased thefreezing tolerance by –1.5 to –4.0C, while coldtreatment increased the freezing tolerance by –7.5 to–14.8C. Cold treatment increased the freezing toleranceof shoot tips by –9 and –15C for ‘wil’and ‘wild-type’, respectively. Cold acclimationincreased endogenous ABA concentrations in ‘Alaska’shoot tips and epicotyls 3- to 4-fold. Immunogold labeling increasednoticeably in the nucleus and cytoplasm of the epicotyl after7 d at 2C and was greatest after 30 d at the time of maximumfreezing tolerance and soluble ABA concentration. Cold treatmentinduced the production of seven, three, and two proteins inshoot, epicotyl, and root tissue of ‘Alaska’, respectively.In ‘Alaska’ shoot tissue, five out of seven novelproteins accumulated in response to both ABA and cold treatment.However, only a 24 kDa protein was produced in ‘wil’and ‘wild-type’ shoot and epicotyl tissues aftercold treatment. Abscisic acid and cold treatment additivelyincreased the freezing tolerance of pea epicotyl and shoot tissuesthrough apparently independent mechanisms that both resultedin the production of a 24 kDa protein. Key words: Pisum sativum, cold acclimation, immuno-localization     

Freezing tolerance, protein composition, and abscisic acid localization and content of pea epicotyl, shoot, and root tissue 3

The freezing tolerance of many plants, such as pea (Pisum sativum),is increased by exposure to low temperature or abscisic acidtreatment, although the physiological basis of this phenomenonis poorly understood. The freezing tolerance of pea shoot tips,root tips, and epicotyl tissue was tested after cold acclimationat 2C, dehydration/rehydration, applications of 10^–4M abscisic acid (ABA), and deacclimation at 25C. Tests wereconducted using the cultivar ‘Alaska’, an ABA-deficientmutant ‘wil’, and its ‘wildtype’. Freezinginjury was determined graphically as the temperature that caused50% injury (T₅₀) from electrical conductivity. Endogenous ABAwas measured using an indirect enzyme-linked immunosorbant assay,and novel proteins were detected using 2-dimensional polyacrylamidegel electrophoresis. The maximum decrease in T₅₀ for root tissuewas 1C for all genotypes, regardless of treatment. For ‘Alaska’shoot tips and epicotyl tissue, exogenous ABA increased thefreezing tolerance by –1.5 to –4.0C, while coldtreatment increased the freezing tolerance by –7.5 to–14.8C. Cold treatment increased the freezing toleranceof shoot tips by –9 and –15C for ‘wil’and ‘wild-type’, respectively. Cold acclimationincreased endogenous ABA concentrations in ‘Alaska’shoot tips and epicotyls 3- to 4-fold. Immunogold labeling increasednoticeably in the nucleus and cytoplasm of the epicotyl after7 d at 2C and was greatest after 30 d at the time of maximumfreezing tolerance and soluble ABA concentration. Cold treatmentinduced the production of seven, three, and two proteins inshoot, epicotyl, and root tissue of ‘Alaska’, respectively.In ‘Alaska’ shoot tissue, five out of seven novelproteins accumulated in response to both ABA and cold treatment.However, only a 24 kDa protein was produced in ‘wil’and ‘wild-type’ shoot and epicotyl tissues aftercold treatment. Abscisic acid and cold treatment additivelyincreased the freezing tolerance of pea epicotyl and shoot tissuesthrough apparently independent mechanisms that both resultedin the production of a 24 kDa protein. Key words: Pisum sativum, cold acclimation, immuno-localization     

High-frequency Organogenesis from Direct Seed Culture in Lathyrus

Culture conditions were developed for inducing a high frequencyof direct shoot morphogenesis and whole plant regeneration incultures of intact seedlings of Lathyrus cicera L., L. ochrus(L.) DC., L. sativus L., and L. tingitanus L. The procedureof shoot regeneration involved culturing of whole, mature seedson MS medium containing cytokinins, or thidiazuron (TDZ), asubstituted phenylurea with cytokinin-like activity. Differentiationof shoots occurred without an intervening callus phase fromthe cotyledonary node and surrounding tissues of the intactseedlings developed from seeds germinated on media containingkinetin, BAP or TDZ. An average of 19·0, 15·8,28·8 and 43·0 shoots were regenerated at optimalconcentrations of 50·0, 50·0 and 80·0 µMBAP in L. cicera, L. tingitanus, L. ochrus and L. sativus, respectively.TDZ enhanced the shoot formation at the concentration of 10µM to an average of 33·1 and 33·7 shootsper seedling in L. cicera and L. tingitanus and at 50 µM,to 57·4 shoots per seedling in L. sativus. Regeneratedshoots developed roots on a modified MS medium containing 2·5µM NAA and the surviving plantlets were transferred tosoil. Histological studies revealed de novo formation of shoot budsfrom the epidermal or subepidermal cells of the basal and nodalregion of multiple epicotyls. Several meristematic centres consistingof actively-dividing cells developed in the subepidermal celllayer of the nodal tissue and adjacent areas within 7 d of seedculture on a cytokinin- or TDZ-supplemented medium. The patternof the development of these meristematic centres and shoot developmentwas similar in all four species.Copyright 1993, 1999 AcademicPress Seed culture, direct shoot morphogenesis, Lathyrus, thidiazuron, grass pea, vetch ochrus     

Embryo Morphogenesis in the Stem Parasite Scurrula pulverulenta

Seeds of Scurrula pulverulenta, a leafy mistletoe, germinatedon a simple nutrient medium, and addition of casein hydrolysate(CH) supported better growth of the seedlings. In either casethe seedlings developed haustoria which were comparable to thehaustoria formed in vivo inside the host tissue. On White'smedium (WM)+CH+indole-3yl-acetic acid (IAA) the embryo callusedand, subsequently, differentiated shoot buds and/or haustoria.On WM+CH+IAA+ kinetin the callused embryo did not differentiatehaustoria or shoot buds. However, on this medium, ‘embryoids’developed up to the heart-shaped stage. The effects of somecytokinins, coconut milk, and water-melon juice, on germination,proliferation of embryo, and differentiation of shoot buds fromthe callus were also studied.     

Direct Organogenesis and Plant Regeneration in Preconditioned Tissue Cultures of Lathyrus cicera L., L. ochrus (L.)DC. and L. sativus L.

This study demonstrates the importance of preconditioning ofsource tissue in regeneration of multiple shoot buds from severalspecies of Lathyrus. Preconditioned multiple shoots of Lathyruscicera L., L. ochrus (L.) DC. and L. sativus L. were obtainedby germinating seeds on Murashige and Skoog (MS) medium containing50 µM N⁵-benzylaminopurine (BAP) for 2 to 3 weeks. Multipleshoot bud formation occurred when epicotyl explants of preconditionedshoots were cultured on MS medium containing 5–50 µMBAP. No shoot regeneration was observed from epicotyl explantswhich were obtained from non-preconditioned shoots. Shoot budswere formed directly on explants without an intervening callusphase after 2 to 3 weeks of culture. Regenerated shoot budsformed healthy shoots which developed prolific and strong rootswhen transferred to MS medium supplemented with 2.5 µMnaphthaleneacetic acid (NAA). Lathyrus cicera L., L. ochrus (L.) DC., Ochrus Vetch, L. sativus L., Lathyrus pea, de novo differentiation, epicotyl, preconditioning with BAP     

Gibberellin does not accelerate rates of cell division in the dwarf pea shoot apical meristem

Although GA₃ doubled the numbers of cells in dwarf pea internodes,it caused no significant acceleration of cell division ratesin the apical meristem, estimated using cell doubling times,mitotic indices, or percentage labelled mitoses data. Increasedcell numbers in GA₃-treated pea stems must be generated withinthe extending internodes. Key words: Cell division cycle, gibberellin, pea, Pisum, shoot apical meristem     

Cell Cycle Patterns in the Shoot Apex of Lolium temulentum L. cv. Ceres During the Transition to Flowering Following a Single Long Day

Six-week-old Lolium temulentum cv. Ceres plants were inducedto flower by a single long day (day 1). The ‘double ridge’stage was reached on days 4/5. A detailed analysis of apicesevery 4 h on days 3 to 5 demonstrated synchronized cell divisionin the apex. However, this synchronized cell division occurredonly in the apical summit and axillary bud sites, i.e. onlyin those regions of the apex which give rise to the spikelets.This indicates a specific activation of the cells in these regions,rather than a general activation of the whole apex. Key words: Cell cycle, flowering, Lolium, shoot apex, spikelet     

Establishment, Structure and Morphology of the Tuber of Balanophora

During germination of the ‘seed’ of Balanophora,endosperm cells at the radicular pole grow out as tubular structuresand anchor the ‘seed’ to the host rootlet. The radiculartier of cells of the embryo elongate as primary haustorial tubesand establish contact with the host root vasculature. A secondaryhaustorium arises from a meristem adjoining the primary haustorium.The remainder of the embryo contributes to the tuber proper. Host parenchyma in the immediate vicinity of the primary haustoriumreverts to meristematic activity. Some of the derivatives matureas perforate tracheary cells. The remainder, retaining meristematicactivity, squeeze themselves between secondary haustorial cellsand together initiate a composite conducting strand, which repeatedlydichotomizes as the tuber grows. The conducting strand of Balanophora is looked upon as the equivalentof combined adventitious root system of parasite and host. Theremaining part of the tuber is equivalent to the shoot. Balanophora, tuber, morphology, host-parasite relations, parasite     

Cell Cycle Changes in the Shoot Apex of Silene coeli-rosa During the Second and Third Days of Floral Induction

The cell cycle in Silene coeli-rosa shoot apices was measuredto test whether or not early components of the floral stimulus,produced during the 2nd and 3rd long days (LD) of an inductiveLD treatment, resulted in an increase in the duration of G₂phase in constant 20–24 h cell cycles. Plants were grownat 20°C in short days (SD) of 8 h light and 16 h darknessfor 28 d (day 0). Starting on day 0, plants were given SD or3 LD each comprising an identical 8 h day and 16 h photo-extension,or 3 dark-interrupted (d.i.) non-inductive LD, interrupted at1700 h of each day with 1 h of darkness. The cell cycle (percentagelabelled mitoses method) and changes in cell number were determinedin the shoot apical meristem. During days 1–2 of the SDtreatment, the cell cycle and mean cell generation time (MCGT)was 18 and 32 h, respectively, giving a growth fraction of 56%.During days 2–3, the cell cycle and MCGT shortened to15 and 23 h, respectively (growth fraction = 65%). During days1–2 of the LD and d.i. LD treatments, cell cycles andMCGTs were 9–10 and 27–29 h, respectively, resultingin smaller growth fractions (about 33%). Thus, shortened cellcycles and altered growth fractions occurred regardless of whetheror not the treatment was inductive. The LD treatment resultedin a marked shortening of G₁ and, to a lesser extent, S-phase,whilst G₂ remained constant. These changes were consistent withincreases in the proportion of cells in G₂ during the photoextensionof each LD which were suppressed during the comparable periodsof the d.i. LD treatment. The latter treatment resulted in eachphase occupying virtually identical proportions of the cellcycle as in the SD treatment. Thus, the unique cell cycle responsesto the initial part of the inductive LD treatment were increasesin the proportion of cells in G₂ coupled with G₁ and G₂ beingof similar duration. Cell cycle, mean cell generation time, shoot apex, Silene coeli-rosa     

Changes in Ultrastructure and Abscisic Acid Level, and Response to Applied Gibberellins inTaxus maireiSeeds Treated With Warm and Cold Stratification

Seeds ofTaxus maireiare known for their deep dormancy whichcan only be broken by a procedure involving warm stratificationfollowed by cold stratification. Treatments with alternatingtemperatures of 25/15 or 23/11 °C (12 h light) for 6 monthsfollowed by 5 °C for 3 months were successful in overcomingseed dormancy. After 6 months of warm stratification, cytologicalchanges observed included: enlargement of the embryo; a decreasein the number of lipid bodies; appearance of ER; and increasesin mitochondria, plastids, dictyosomes, vacuoles and microbodiesin the shoot apical meristem. Cold stratification followingthe warm treatment induced cell division, and one or two distinctnucleoli in the shoot apical meristem cells were observed. Bothwarm and cold stratification reduced endogenous ABA concentrationsfrom the original 8888 pg per freshly harvested seed to 392and 536 pg, respectively. Treatment with exogenous gibberellinsafter seeds had been warm-stratified showed that GA₄and GA₇wereeffective at promoting seed germination, but GA₃was not. Theseresults suggest that the strong seed dormancy ofT. maireicouldbe caused by a high ABA content and underdevelopment of theembryos in freshly shed seeds. We conclude that warm stratificationwith alternating temperatures increases the growth of embryosby cell expansion and enlargement and decreases ABA content,but seeds still remain ungerminated. Cold stratification mayinduce the response to GAs and initiate cell division resultingin release from physiological dormancy and subsequent germinationofT. maireiseeds.Copyright 1998 Annals of Botany Company Taxus mairei; ultrastructure; abscisic acid; gibberellin; seed dormancy; stratification; germination.     

The Establishments of Tissue 4

Callus cultures of 12 temperate grasses were established, somefor the first time, by incubating detached roots or whole seedlingson a Linsmaier and Skoog basal medium which contained 2, 4-dichlorophenoxyaceticacid (2, 4-D) at 1.0 mg 1^–1 as the only growth hormone.The callus, which developed in the pericycle of the roots andon the embryo of the seeds, was subcultured on the same medium;further growth of the callus varied from good in the case ofDactylis glomeraia, Agrostis tennis, Cynosurus cristatus, andPoa trivialis, to poor in several Lolium species and varieties.Most cultures developed root primordia which sometimes grewinto visible roots, but shoot primordia, none of which grewinto shoots, were found only in the callus of Lolium multiflorumvar. westerwoldicum. Cell suspension cultures were also readily established and maintainedusing the same culture medium. Most cultures contained a highproportion of round or oval cells, which ranged from 18 to 77µm in diameter or length, while many also had a significantproportion of larger, more elongated cells which varied in lengthfrom 46 to 182 µm. The cells of Dactylis glomerata werecharacteristically larger and more convoluted than the cellsof other grass species that were examined. The addition of kinetinat 0.1 mg 1^–1 to the 2, 4-D-containing culture mediumincreased the proportion of irregular-shaped cells and reducedthe dispersion of the cells, perhaps by improving cellular contactand adhesion; in some species, such as Agrostis tenuis and Phleumpratense, the presence of kinetin promoted the deposition ofstarch granules in cells.     

In Vitro Multiplication of Sesame (Sesamum indicum) through Tissue Culture

Tissue cultures were established from different parts of sesame(Sesamum indicum L. cv. PT) seedlings. A callus tissue derivedfrom hypocotyl segments produced embryo like structures. Shoottips with cotyledons excised from 8 to 10-d-old seedlings producedmultiple shoot buds on a cytokinin-enriched medium. Presoakingand germination of seeds in BA or 2iP (8 mg l–1) enhancedthe development of shoot buds. Upon isolation and culture theshoots buds formed rooted plantlets in a charcoal-enriched medium. Sesamum, multiple buds, plantlets     

Influence of Bud Position and Plant Ontogeny on the Morphology of Branch Shoots in Pea (Pisum sativum L. cv. Alaska)

The morphology of axillary shoots of pea plants (Pisum sativumL. cv. Alaska) was analysed as a function of the position ofthe bud on the plant axis and the stage of plant developmentwhen the buds began to grow. Buds from the three most basalnodes were stimulated to develop by decapitating the main shootwhen buds were still growing (4 d plants), shortly after budsbecame dormant (7 d plants) or after the initiation of floweringon the main shoot (post-flowering plants, about 21 d after sowing).Branch shoots were scored for node of floral initiation (NFI),shoot length, and node of multiple leaflets (NML), a measureof leaf complexity. Shoots that developed spontaneously fromupper nodes (nodes 5-9) on intact post-flowering plants werescored for NFI. NFI for basal buds on 4 and 7 d plants variedas a function of nodal position and ranged from 5 to 6·7nodes. NFI on these plants was not influenced by bud size orwhether a bud was growing or dormant when the plant was decapitated.NFI for shoots derived from basal buds on decapitated post-floweringplants and upper nodes on intact post-flowering plants was about4. Reduced NFI on post-flowering plants may be due to depletionof a cotyledon-derived floral inhibitor. Basal axillary shootson 4 d plants were about 20% longer than those on 7 d plantsand about five times longer than those on post-flowering plants.These differences may be due to depletion of gibberellic acidsfrom the cotyledons. NFI and NML for the main shoot and forbasal axillary shoots were similar under some experimental conditionsbut different under other conditions, so it is likely that eachdevelopmental transition is regulated independently.Copyright1995, 1999 Academic Press Apical dominance, bud development, garden pea, initiation of flowering, Pisum sativum L., shoot morphology     

Histology of the Morphogenic Response in Thin Cell Layer Explants from Vegetative Tobacco Plants

The morphogenic response of thin cell layers (TCLs) from vegetativetobacco (Nicotiana tabacum L.) plants can be directed very preciselyby varying the concentrations of benzyladenine (BA) and -naphthaleneacetic acid (NAA) in the culture medium. Medium containing 1·6µM BA and 0·5 µM NAA was optimal for shootformation, concentrations of 0·5 µM BA and 1·6µM NAA were optimal for the induction of shoots and rootson the same explant, whereas concentrations of NAA higher than16 µM resulted in callus proliferation only. Polarityin the distribution of the shoot buds was observed, i.e. a switchfrom basal to apical shoot formation occurred with increasingNAA concentrations, suggesting basipetal transport of NAA. Histologicalexamination of TCLs on shoot induction medium revealed thatfirst cell divisions occurred within 2 d in cortical cells whichwere directly in contact with the medium along the longitudinalcut surface, and after 2 d in subepidermal cells along the lateraledges of the explants. Individual lateral buds originated fromone subepidermal and one or more epidermal cells, while apicalbuds originated from single subepidermal or cortical cells locateddirectly at the apical end of the explant. After culture ofTCLs for 2-3 d on root/shoot induction medium cells in the regeneration-competentsubepidermis elongated, while on callus induction medium subepidermalcells elongated and dedifferentiated. The regeneration systemas described in this study will be used to identify cells competentfor regeneration as well as for transformation.Copyright 1994,1999 Academic Press Nicotiana tabacum L., tobacco, thin cell layer explants, cell competence, shoot development, polarity     

Leaf Primordium Initiation and Expanded Leaf Production are Co-ordinated through Similar Response to Air Temperature in Pea (Pisum sativumL.)

Accurate prediction of the timing of leaf area development isessential to analyse and predict the responses of crops to theenvironment. In this paper, we analyse the two processes determiningthe chronology of leaf development—initiation of leafprimordia by the shoot meristem and production of expanded leavesout of the shoot tip—in several pea (Pisum sativumL.)cultivars in response to air temperature and plant growth rate.Contrasting levels of air temperature and plant growth rateduring leaf development were induced by a wide range of sowingdates and plant densities in glasshouse or field experiments.Full leaf expansion was found to occur one phyllochron afterfull leaf unfolding, whatever the leaf nodal position. Primordiuminitiation and expanded leaf production rates presented similarquantitative responses to air temperature (linear response andcommonx-intercept), whatever the plant growth rate, cultivaror period of cycle. As a consequence, they were co-ordinatedand the numbers of initiated primordia or expanded leaves wereeasily deduced from simple visual observation of leaf unfolding.The change, over time, of the numbers of initiated leaf primordiaand fully expanded leaves correlated with cumulated degree-days,with stable relationships in a wide range of environmental conditions.Two phases, with different production rates, had to be considered.These results allowed us to predict accurately the beginningand the end of individual leaf development from daily mean airtemperatures. The relationships obtained here provide an effectiveway of analysing and predicting leaf development responses tothe environment. Pisum sativumL.; pea; number of leaf primordia; number of leaves; temperature; modelling     

The Rate of Morphogenesis of Embryos and Seeds in Four Species of Grain Legumes

Comparative embryo development has been studied histologicallyin Lupinus albus, Lupinus mutabilis, Vicia faba, Pisum sativumand Latkyrus latifolius. The detailed histology of the stagesof embryo formation up to the early differentiation of tissuesof the seed is reported. The rate of embryogenesis has beentimed through 15 stages of development from anthesis and comparativerates of tissue formation established between the species. Themain observation was the slow rate of morphogenesis of embryosand seeds in Lupinus albus in comparison with the very rapidrate observed in Pisum sativum. A long period at the globularembryo stage, when embryo morphogenesis was inactive contributedto the extended development time of embryos and seeds in Lupinusalbus. Slow differentiation of reproductive tissues in L. albusdetermines late maturity in seeds and pods. Lupinus albus, white lupin, L. mutabilis, tarwi, Vicia faba, faba bean, Pisum sativum, pea, Lathyrus latifolius, everlasting pea, embryo development     

Endogenous cis,trans-Abscisic Acid and Pea Seed Development: Evidence for a Role in Seed Growth from Changes Induced by Temperature

Measurements were made using GC/MS SIM¹ of the effects of temperatureon cis,trans-ABA levels in developing ovules and embryos oftwo pea genotypes contrasted in seed size. These effects werethen related to differences in the growth of the pods, seeds,embryos, and testae. In both genotypes high temperatures hastenedthe onset and rate of logarithmic and then linear growth, greatlyshortening the duration of pod and seed development but withoutgreatly altering seed size. Cis,trans-ABA was most concentratedxin the ovules immediately after fertilization. It also accumulatedin the embryo, more rapidly in the larger-seeded line, duringseed maturation. The stage when accumulation in the embryo beganwas the same irrespective of temperature. Accumulation ceasedwhen the pods started to desiccate. The effects of differentconstant temperatures on the maximum levels of embryo cis,trans-ABAwere relatively small and confounded in one genotype by variationin ovule abortion and in the other by differences in the stagewhen cis,trans-ABA accumulation ceased. However, when plantswere transferred from 13 °C to 29 °C at two differentstages during seed maturation, further seed growth was greatlyinhibited coincident with a substantial increase in embryo cis-trans-ABA.The results suggested a role for cis,trans-ABA in the controlof cotyledon enlargement during the linear phase of seed growth.     

The Effect of Root Temperature on Growth and Uptake of Ammonium and Nitrate by Brassica napus L. in Flowing Solution Culture: I. GROWTH

Macduff, J. H., Hopper, M. J. and Wild, A. 1987. The effectof root temperature on growth and uptake of ammonium and nitrateby Brassica napus L. in flowing solution culture. I. Growth.—J.exp. Bot. 38: 42–52 Oilseed rape (Brassica napus L. cv. Bien venu) was grown for49 d in flowing nutrient solution at pH 6?0 with root temperaturedecrementally reduced from 20?C to 5?C; and then exposed todifferent root temperatures (3, 5, 7, 9, 11, 13,17 or 25?C)held constant for 14 d. The air temperature was 20/15?C day/nightand nitrogen was supplied automatically to maintain 10 mmolm^–3 NH₄NO₃ in solution. Total dry matter production wasexponential with time and similar at all root temperatures givinga specific growth rate of 0?0784 g g^–1 d^–1. Partitioningof dry matter was influenced by root temperature; shoot: rootratios increased during treatment at 17?C and 25?C but decreasedafter 5 d at 3?C and 5?C. The ratio of shoot specific growthrate: root specific growth rate increased with the ratio ofwater soluble carbohydrates (shoot: root). Concentrations ofwater soluble carbohydrates in shoot and root were inverselyrelated to root temperature; at 3, 5 and 7?C they increasedin stem + petioles throughout treatment, coinciding with a decreasein the weight of tissue water per unit dry matter. These resultssuggest that the accumulation of soluble carbohydrates at lowtemperature is the result of metabolic imbalance and of osmoticadjustment to water stress. Key words: Brassica napus, oilseed rape, root temperature, specific growth rate     

TheAfGene Regulates Timing and Direction of Major Developmental Events during Leaf Morphogenesis in Garden Pea (Pisum sativum)

The wildtype leaf of the garden pea possesses proximal pairsof leaflets and distal pairs of tendrils in the blade region.Theafila (af) mutation causes leaflets to be replaced by compound(branched) tendrils. We characterized the morphological variationin leaf form along the plant axis and leaf development in earlyand late postembryonic leaves onafilaplants to infer the roleof theAfgene. Leaf forms are more diverse early in shoot ontogenyonafilaplants.Afinfluences pinna length and pinna branchingin addition to pinna type. Pinna initiation in the proximalregion ofafilaleaf primordia is basipetal and delayed comparedto wildtype plants. In addition, pinna development in the proximalregion ofafilaleaves occurs for a longer period of time thanon wildtype leaf primordia. Therefore,Afregulates the timingand direction of leaf developmental processes in the proximalregion of the leaf, but has little effect on the distal region.These data support the heterochronic model of pea leaf morphogenesisproposed by Luet al. (International Journal of Plant Science157:311–355, 1996).Copyright 1999 Annals of Botany Company. afila,Fabaceae, garden pea, heterochrony, leaf morphogenesis,Pisum sativum.