The role of the storage carbon of cotyledons in the establishment of seedlings of Hymenaea courbaril under different light conditions

BACKGROUND AND AIMS: Hymenaea courbaril (Leguminosae-Caesalpinioideae) is a tree species with wide distribution through all of the Neotropics. It has large seeds (approx. 5 g) with non-photosynthetic storage cotyledons rich (40 %) in a cell wall polysaccharide (xyloglucan) as a carbon reserve. Because it is found in the understorey of tropical forests, it has been considered as a shade-tolerant, late-secondary species. However, the physiological mechanisms involved in seedling establishment, especially regarding the interplay between storage and light intensity, are not understood. In this work, the ecophysiological role of this carbon cotyledon reserve (xyloglucan) is characterized, emphasizing its effects on seedling growth and development during the transition from heterotrophy to autotrophy under different light conditions. METHODS: Seedlings of H. courbaril were grown in environments with different light intensities, and with or without cotyledons detached before xyloglucan mobilization. Development, growth, photosynthesis and carbon partitioning (dry mass and [14C]sucrose) were analysed in each treatment. KEY RESULTS: The detachment of cotyledons was not important for seedling survival, but resulted in a strong restriction (50 % less) of shoot growth, which was the main sink for the cotyledon carbon reserves. Carbon restriction promoted an early maturation of the photosynthetic apparatus without changes in the net CO2 fixation per unit area. The reduced surface area of the first leaves in seedlings without cotyledons was evidence of limited growth and development of seedlings in low light conditions (22 micromol m(-2) s(-1) photon flux). CONCLUSIONS: There is an increase in the importance of storage xyloglucan in cotyledons for H. courbaril seedling development as light intensity decreases, confirming that this polymer plays a key role in the adaptation of this species to establish successfully in the shadowed understorey of the forest.     

Importance of Photosynthetic Cotyledons for Early Growth of Woody Angiosperms

At various times after seed germination, epigeous cotyledons were excised or treated with DCMU (3-(3,4-dichlorophenyl)-1,1-dimethylurea) to inhibit cotyledon photosynthesis of seedlings of Acer negundo L., Ailanthus altissima (Mill.) Swingle, Eucalyptus globulus Labill., Fraxinus pennsylvanica Marsh., Robinia pseudacacia L., and Ulmus americana L. In all species, DCMU inhibited expansion of cotyledons, elongation of roots, initiation of lateral roots, and expansion of foliage leaves. During the first 10 days after radicle emergence decotylization also variously inhibited growth of plant parts. Photosynthetic rates per cotyledon varied among species in the following order: Robinia pseudacacia > Ailanthus altissima≥Fraxinus pennsylvanica > Ulmus americana. The length of time that cotyledon photosynthesis contributed to growth of axial parts varied widely among species.     

Growth Analysis of Soybean Seedlings During the Lifespan of the Cotyledons

Patterns of seedling growth of Glycine max in light and darknesswere compared during the period from germination to cotyledonabscission. Fitted growth curves and the derived functions,relative growth rate, unit leaf rate, leaf area ratio and specificleaf area, were used to assess the relative importance in seedlinggrowth of cotyledon storage reserves, cotyledon photosynthesisand leaf photosynthesis. The cotyledons are of an intermediatetype with a predominant storage and a minimal photosyntheticfunction. Cotyledon reserves support seedling growth until theprimary leaves expand, after which growth depends on leaf photosynthesis. Glycine max (L.) Merr., soybean, cotyledons, growth analysis, seedling development     

Does osmotic regulation of amylase activity in bean cotyledons exist?

The hypothesis that the promotive effect of the embryo axis of the germinating bean seed on amylase activity in the cotyledons is mediated by an osmoregulative mechanism was examined. After 2 days of germination the action of the axis on amylolytic activity was already clearly revealed, whereas at the same time it did not have any influence on osmotic pressure in the cotyledons. When the axis was attached to one cotyledon during 4 days of incubation, osmotic pressure in the cotyledon was lower than its value in the cotyledons of the intact seedling, whereas amylolytic activity was similar in both treatments. It was concluded that the tested hypothesis is not valid in the case of the bean seedling. External osmotic agents brought about a decrease in the level of amylase in the cotyledons, but this does not prove that osmotic changes which are brought about by production of internal metabolites are involved in the regulation of amylase synthesis.     

COTYLEDON PHOTOSYNTHESIS DURING SEEDLING GROWTH OF COTTON,GOSSYPIUM HIRSUTUM L.

Respiration and net photosynthetic O₂ production by cotton cotyledons were determined from an early age through the senescent stage. Various treatments were applied to cotyledons to assess the importance of current photosynthesis as compared to translocation of reserves to seedling development. Rates of respiration and net photosynthesis per cm² were high on 1-day-old cotyledons, but the rates decreased sharply with rapid expansion to reach a fairly stable rate. Respiration per cotyledon decreased linearly with age until the onset of senescence, then exhibited a distinct climacteric rise followed by a sharp decrease. Net photosynthesis per cotyledon increased until expansion was completed and then decreased linearly and steeply with age. Excision of cotyledons, inhibition of photosynthesis either chemically or by covering, and removal of the terminal bud indicated that current photosynthesis is a potent force behind early epicotyl growth.     

A study of seed lots of peas (Pisum sativum L.) differing in predisposition to pre-emergence mortality in soil

In three seed lots the condition of the cotyledons was found to be important in denning seeds predisposed to pre-emergence mortality. Such seeds readily exuded materials into seed-steep water, were rapidly infected by Pythium spp. and showed intensely stained cotyledons after being in solutions of tetrazolium chloride. In soil, infection of the cotyledons was found to occur before infection of the seedling axis and occurred in normal seed if disks of cotyledon material were placed in the soil next to the seed.
It is suggested that cotyledons influence predisposition by either increasing exudation around the seed and stimulating the fungal pathogen or by acting as a food base for the fungal hyphae which infect and kill the seedling axis.     

Response of Faidherbia albida (Del.) A. Chev., Acacia nigrescens Oliver. and Acacia nilotica (L.) Willd ex Del. seedlings to simulated cotyledon and shoot herbivory in a semi‐arid savanna in Zimbabwe

Woody plant seedling establishment is constrained by herbivory in many semi‐arid savannas. We clipped shoots and cotyledons of three woody species 5‐day (=‘early’) or 28‐day (= ‘late’) post‐emergence to simulate herbivory. Seedlings had shoot apex, one or two cotyledon(s) removed, or were retained intact. Survival rates were ≥80%, ≥40% and ≥20% for Acacia nilotica, Acacia nigrescens and Faidherbia albida respectively. F. albida mobilized stored cotyledon reserves faster and consequently shed the cotyledons earlier than the two Acacia species. Cotyledons were shed off as late as 70 days post‐emergence with 5‐day shedding earlier than 28‐day and cotyledon life‐span decreasing with intensity of defoliation. Shoot apex removal 28‐day resulted in higher compensatory growth than 5‐day in all three species. Cotyledon removal had no effect on shoot length, while shoot apex removal reduced shoot length. In F. albida root growth was stimulated by shoot apex removal. We conclude that potential tolerance to herbivory in terms of seedling survival was of the order A. nilotica > A. nigrescens > F. albida, timing of shoot apex and cotyledon removal influenced seedling growth in terms of biomass and that shoot apex removal stimulated compensatory growth which is critical to seedling survival.     

Wirkungsspektren der Anthocyansynthese in Gewebekulturen und Keimlingen von Haplopappus gracilis

Summary The biosynthesis of anthocyanin in tissue cultures and intact seedlings of Haplopappus gracilis is a light-dependent reaction which can be induced by blue light only. Anthocyanin appeared in all organs of the seedling.Wounding of the plant led to an increase in the content of anthocyanin due to increased anthocyanin synthesis in the cotyledons.The action spectra of anthocyanin formation in tissue cultures and intact seedlings have two peaks, one at 438 nm and the other at 372 nm. The limit of activity in the direction of longer wavelengths lies between 474 and 493 nm. Red light of short and long wavelength is ineffective in the induction of pigment synthesis. The photoreceptor of the light reaction is supposed to be a yellow pigment (flavoprotein or carotinoid). In contrast to the intact plants, isolated cotyledons and wounded seedlings are able to form anthocyanin not only in the blue region but also during irradiation with red light of high intensity. The action spectrum of anthocyanin synthesis in the isolated cotyledons has a marked maximum at about 440 nm and a second one at about 660 nm. A little activity can be observed throughout the visible spectrum. The pigment synthesis induced by red light can be completely suppressed by DCMU, an inhibitor of photosynthesis. This indicates that in the case of the activity in the red light caused by wounding chlorophyll serves as photoreceptor.The anthocyanin synthesis in tissue cultures and seedlings could not be influenced by low energy radiation in the red or in the far red region, even after induction of anthocyanin synthesis by blue light of high intensity. Therefore it seems that the phytochrome system is not involved in anthocyanin synthesis in Haplopappus gracilis.     

The effects of fluid drilling and seed covering medium on early carrot production under polyethylene mulch

Ungerminated seeds, fluid-drilled germinating seeds and fluid-drilled uniformly-germinated seeds were sown in furrows that were either uncovered or covered by soil and left unmulch ed or mulched with polyethylene sheet. The effects of these treatments on the emergence and growth of carrots for early harvest were examined. Leaving seeds uncovered or mulching them with polyethylene advanced seedling emergence and increased the percentage that emerged; leaving seeds uncovered also reduced the spread of emergence times and produced seedlings with larger cotyledons. Uniformly-germinated seeds emerged before germinating seeds and both emerged before ungerminated seeds. The best combination of treatments (i.e. mulched, uncovered uniformly-germinated seeds) reduced the mean number of days for emergence from the 52 required by traditionally sown seeds to 29. There was a more variable effect of seed treatments on the spread of emergence times and the percentage emergence. Earlier emergence generally led to roots reaching a marketable size earlier and more uniform emergence led to less variation in root weights at harvest.     

Light-stimulated cotyledon expansion in the blu3 and hy4 mutants of Arabidopsis thaliana.

Cotyledon expansion in response to blue light was compared for wild-type Arabidopsis thaliana (L.) Heynh. and the mutants blu3 and hy4, which show reduced inhibition of hypocotyl growth in blue light. White, blue, and red light stimulated cotyledon expansion in both intact and excised cotyledons of wild-type seedlings (ecotypes No-0, WS, Co-0, La-er). Cotyledons on intact blu3 and hy4 seedlings did not grow as well as those on the wild type in response to blue light, but pretreatment of blu3 seedlings with low fluence rates of red light increased their responsiveness to blue light. Excision of cotyledons alleviated the mutant phenotype so that both mutant and wild-type cotyledons grew equally well in blue light. The loss of the mutant cotyledon phenotype upon excision indicates that the blu3 and hy4 lesions affect cotyledon expansion indirectly via a whole-plant response to light. Furthermore, the ability of excised, mutant cotyledons to grow normally in blue light shows that this growth response to blue light is mediated by a photosystem other than the ones impaired by the blu3 and hy4 lesions.     

Changes in endogenous levels of three cytokinins during development of excised watermelon cotyledons

We have determined by an immunological method the endogenous levels of three cytokinins: dihydrozeatin riboside (DHZR), transzeatin riboside (tZR) and isope-ntenyladenosine (IPA) in watermelon (Citrullus vulgaris Schrad., cv. Fairfax) cotyledons that were either attached to the seedling or excised from the seed after imbibition and then grown on water. Both seedlings and cotyledons were grown either for 5 days in continuous light or for 3 days in the dark and 2 days in light. Our aim was to verify whether endogenous cytokinin levels are lower in excised than in attached cotyledons as could be expected since excised cotyledons are much more sensitive to exogenous cytokinin application. The levels of the three cytokinins were very low immediately after imbibition, but gradually increased during the following days. They were higher in excised cotyledons after 5 days of culture in the dark than in cotyledons of the same age that had developed on the seedling. Dihydrozeatin riboside was by far the most abundant of the three cytokinins in cotyledons as well as in the hypocotyl and the root.
Irradiation reduced the level of DHZR, negating the concept that light promotes cotyledon development by increasing endogenous cytokinins. Transzeatin riboside when supplied exogenously, stimulated cotyledon development at a lower concentration than the other two cytokinins. Exogenous supply of ben-zyladenine (BA) induced a strong increase in endogenous tZR already after 24 h.     

Seedling tolerance to cotyledon removal varies with seed size: A case of five legume species

It is generally accepted that seedlings from large seeds are more tolerant to defoliation than those from small seeds due to the additional metabolic reserves present in the large seeds. However, information on the effects of amount of seed reserves (cotyledon removal) from seedlings resulting from large vs. small seeds on seedling growth and long‐term survival in the field is limited. Five legume species with different sizes of seeds were sown in the field and none, one, or both cotyledons removed 7 days after seedling emergence. Seedling biomass, relative growth rate (RGR) and survival were determined at different time. Cotyledon removal, species, and their interaction had significant effects on seedling growth and survival. During the period between 33 and 70 days, seedlings from large seeds had a significantly lower RGR than those from small seeds. Biomass, RGR, and survival of seedlings from large seeds were significantly reduced by removal one or both cotyledons, whereas those of seedlings from small seeds were not affected. Seed energy reserves are more important for the early growth of seedlings from large seeds than for those from small seeds. The overall effect of cotyledon removal on growth and survival varies with seed size (i.e., energy reserves) with seedlings from small seeds being less sensitive than those from large seeds under field conditions.     

Reserve mobilization and starch formation in soybean (Glycine max) cotyledons in relation to seedling growth

Brown, C. S. and Huber, S. C. 1988. Reserve mobilization and starch formation in soybean ( Glycine max ) cotyledons in relation to seedling growth. - Physiol. Plant. 72: 518–524.
In germinating soybean ( Glycine max [L.] Merr.) seedlings, starch accumulated in the cotyledons during the first 5 days of seedling growth. Among 10 genotypes, the amount of starch accumulated after 5 days was relatively independent of light and appeared to be primarily related to the amount of sucrose depleted from the cotyledons during the same time period. Depletion of other reserves (e.g. protein and lipid) were not closely correlated with starch formation. In addition, the differences in starch formation were not related to differences in activities of certain enzymes that may be involved in the conversion of sucrose to starch, namely starch synthase (EC 2.4.1.21), ADP-glucose pyrophosphorylase (EC 2.7.7.27), sucrose synthase (EC 2.4.1.13), neutral invertase (EC 3.2.1.26), and PPi-linked phosphofructokinase (PFP) (EC 2.7.1.90). Starch synthesis did not compete with seedling growth, because among 10 genotypes, transient starch formation was correlated positively with seedling growth and cotyledonary photosynthetic rates. We postulate that starch is derived primarily from stored sucrose in the cotyledons and is not merely a result of 'overflow' carbon from other reserves. Starch formation also appeared to have a positive relationship with both early (0 to 5 days) and later (5 to 13 days) seedling growth, the latter perhaps due to enhanced cotyledon photosynthetic rates.     

Importance of Endosperm for Nutrition of Fraxinus pennsylvanica Seedlings

Contact between endosperm and cotyledons of germinating Fraxinuspennsylvanica Marsh. seedlings was not essential for continuationof seedling growth or adaptation of cotyledons for photosynthesis.However, when cotyledons were in contact with endosperm, thecotyledons had faster rates of elongation and dry weight increase,slower depletion of reserves, and higher chlorophyll contents.Photosynthetic contributions by cotyledons may be enhanced ifenviron mental conditions support rapid emergence of cotyledonsfrom surrounding seed structures.     

Effects of Temperature on the Pattern of Anthocyanin Accumulation in Seedlings of Polygonum cuspidatum

Polygonum cuspidatum seedling. Anthocyanin accumulated first in the lower part of hypocotyls and then the site of accumulation gradually extended toward the upper part of hypocotyls when seedlings were irradiated with white light (WL) at 25 C. Etiolated seedlings accumulated anthocyanin only in the upper parts (hook and cotyledons) when the seedlings were irradiated with WL at 5 C. De-etiolated seedlings that had been pre-irradiated with WL for 1 day at 25 C accumulated anthocyanin both in upper and lower parts of the seedlings when the seedlings were irradiated with WL at 5 C. Spectral sensitivity was dependent on the temperature during irradiation. Red light (R), blue light (B), and near ultra-violet light (NUV) induced the accumulation of anthocyanin at 5 C but only NUV was effective in inducing the accumulation of anthocyanin at 25 C. Dichlorophenyl dimethylurea (DCMU) inhibited WL-induced anthocyanin accumulation but did not NUV-induced anthocyanin accumulation at 25 C. However, sucrose promoted NUV action at 25 C, indicating that photosynthesis can promote NUV-induced anthocyanin accumulation. Distribution of phytochrome in etiolated seedlings, that was examined by spectrophotometry, was similar to the distribution of anthocyanin at 5 C. Furthermore, phytochrome remained after 48 hr irradiation with WL at 5 C although phytochrome was rapidly degraded at 25 C. Received 12 July 1999/ Accepted in revised form 24 December 1999     

Seed size, seedling morphology, and response to deep shade and damage in neotropical rain forest trees

To investigate the existence of coordinated sets of seedling traits adapted to contrasting establishment conditions, we examined evolutionary convergence in seedling traits for 299 French Guianan woody plant species and the stress response in a shadehouse of species representing seed size gradients within five major cotyledon morphology types. The French Guianan woody plant community has larger seeds than other tropical forest communities and the largest proportion of hypogeal cotyledon type (59.2%) reported for tropical forests. Yet the community includes many species with intermediate size seeds that produce seedlings with different cotyledonal morphologies. A split-plot factorial design with two light levels (0.8% and 16.1% PAR) and four damage treatments (control, seed damage, leaf damage, stem damage) was used in the shadehouse experiment. Although larger-seeded species had higher survival and slower growth, these patterns were better explained by cotyledon type than by seed mass. Even larger-seeded species with foliar cotyledons grew faster than species with reserve-type cotyledons, and survival after stem grazing was five times higher in seedlings with hypogeal cotyledons than with epigeal cotyledons. Thus, to predict seedling performance using seed size, seedling morphology must also be considered.     

A Comparative Study of the Role of the Cotyledon in Seedling Development

Seedling development was studied in four species in which thecotyledons had different capacities for expansion and CO²-flxation. The highest growth-rates were shown by the two species in whichthe cotyledons showed the most expansion and also the greatest¹⁴CO²-fixation capacity. Cotyledons of these species becamevery leaf-like and retained a high proportion of the radiocarbonfixation products during their growth in contrast to the hypogealrunner-bean cotyledon which had a high percentage export valuealthough total fixation was low. Seedlings with leaf-like cotyledons which had the dual roleof storage and subsequent provision of photosynthetic organshad delayed leaf development with early growth concentratedin cotyledon, hypocotyl, and root whereas species with cotyledonsless well adapted for photosynthesis produced leaves at an earlierstage. Thus, the pattern of early seedling development was closelyrelated to the degree of photosynthetic adaptation shown bythe cotyledons. The evidence suggests that in the species studied, cotyledonsadapted for the dual role appear to provide a more efficientsystem for early seedling development.     

The role of cotyledons in the establishment of Suaeda physophora seedlings

The role of cotyledons in seedling establishment of the euhalophyte Suaeda physophora under non-saline and saline conditions (addition of 1 mM or 400 mM NaCl) was investigated. Survival and fresh and dry weights were greater for seedlings grown in the light (12-h light/12-h dark) than in the dark (24-h dark). The shading of cotyledons tended to decrease shoot height, shoot organic dry weight, number of leaves, and survival of seedlings regardless of NaCl treatment, but the effect of cotyledon shading was greater with 400 mM NaCl. Concentrations of Na⁺ were higher in cotyledons than in leaves, regardless of NaCl treatment. The K⁺/Na⁺ ratio was lower in cotyledons than in leaves for seedlings treated with 1 mM NaCl but not for seedlings treated with 400 mM NaCl. Addition of 400 mM NaCl decreased oxygen production in cotyledons but especially in leaves. These results are consistent with the hypothesis that, by generating oxygen via photosynthesis and by compartmentalizing Na⁺, cotyledons are crucial for the establishment of S. physophora seedlings in saline environments.     

A Comparative Study of Cotyledons as Assimilatory Organs

Cotyledons of 11 species were studied at a number of stagesof germination. The hypogeal pea and runner bean cotyledonsdid not expand, lost weight, and survived for a relatively shorttime only. They also produced little chlorophyll on exposureto light, possessed no stomata, and had a very low capacityfor ¹⁴CO₂ fixation. The epigeal french bean had cotyledons thatwere basically of the hypogeal type. Although both white andblue lupin cotyledons showed a progressive weight loss, theyunderwent limited expansion and were more persistent than eitherpea or bean. They also produced considerable amounts of chlorophyll,had stomata on both upper and lower surfaces, and fixed restrictedquantities of ¹⁴CO₂. The cotyledons of the other epigeal speciesstudied showed varying degrees of expansion, up to almost fifty-foldin cucumber, and generally maintained or increased in totaldry weight for at least a restricted period. Stomata occurredon both upper and lower surfaces, extensive chlorophyll productiontook place, and ¹⁴CO₂ fixation values were high. Expansion was determined by increase in cell size, and not incell number except in the case of cucumber where both factorswere involved. In species where cotyledon cells were large initiallylittle or no expansion occurred, whereas initial cell size wassmall in cotyledons which expanded to a large extent. Epigeal cotyledons with a high expansion factor possessed othercharacteristics which made them adapted for photosynthesis,whereas epigeal species with lower cotyledon expansion togetherwith hypogeal species were less well adapted. This was not unexpectedin the case of pea and runner bean, but led to the conclusionthat french bean cotyledons are ‘accidentally epigeal’in that they showed virtually no adaptation to an aerial existence.The different capacities of the cotyledons studied suggeststhat they have differing roles in the control of seedling growth.     

Cowpea ribonuclease: properties and effect of NaCl-salinity on its activation during seed germination and seedling establishment

Pitiúba cowpea [Vigna unguiculata (L.) Walp] seeds were germinated in distilled water (control treatment) or in 100 mM NaCl solution (salt treatment), and RNase was purified from different parts of the seedlings. Seedling growth was reduced by the NaCl treatment. RNase activity was low in cotyledons of quiescent seeds, but the enzyme was activated during germination and seedling establishment. Salinity reduced cotyledon RNase activity, and this effect appeared to be due to a delay in its activation. The RNases from roots, stems, and leaves were immunologically identical to that found in cotyledons. Partially purified RNase fractions from the different parts of the seedling showed some activity with DNA as substrate. However, this DNA hydrolyzing activity was much lower than that of RNA hydrolyzing activity. The DNA hydrolyzing activity was strongly inhibited by Cu²⁺, Hg²⁺, and Zn²⁺ ions, stimulated by MgCl₂, and slowly inhibited by EDTA. This activity from the most purified fraction was inhibited by increasing concentrations of RNA in the reaction medium. It is suggested that the major biological role of this cotyledon RNase would be to hydrolyze seed storage RNA during germination and seedling establishment, and it was discussed that it might have a protective role against abiotic stress during later part of seedling establishment.