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.     

Effects of Potassium Deficiency on Cotyledon Photosynthesis and Seedling Development in Cucumis sativus L.

Seedlings of Cucumis sativus L. grew much less vigorously whencultured in potassium-deficient nutrient solution than in fullnutrients. The poorer growth was attributed to reduced CO₂ fixationby the cotyledons, which form the bulk of the photosyntheticsurface at this stage, and to a much lower level of export ofphotosynthetic products from the cotyledons. The magnitude ofthese effects increased as the seedlings aged and they werea major factor in the poorer development of the plumule in potassium-deficientplants. Electron microscopic examination of the cotyledons shows thatthe lower ¹⁴CO₂ fixation in potassiumstarved seedlings is associatedwith poorly-defined granal stacks and a proliferation of intergranalthylakoids. In plants grown in full nutrients the incorporationof radiocarbon into a cell wall fraction and into other insolublecomponents of the cell increased with cotyledon age whereasin potassium-deficient seedlings there was an increase in thepercentage of the total radiocarbon in the soluble fraction.This suggests either that the incorporation of photosyntheticproducts into cellular components was inhibited or that theability of the cotyledon to translocate photosynthetic productsto the rest of the seedling was reduced in plants grown in potassium-deficientconditions.     

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.     

Some Effects of Potassium Deficiency on Seedling Development

Seedlings with leaf-like photosynthetic cotyledons such as Cucumissativus, Sinapis alba and Trifolium pratense have higher growthrates and a greater requirement for an external supply of potassiumthan hypogeal species (Pisum sativum, Vicia faba) or epigealspecies with very fleshy cotyledons (Phaseolus vulgaris, Lupinusalbus, Lupinus angustifolius). The initial stages of seedlingdevelopment in the latter two groups involve mainly transferof reserves from cotyledons to axis and a relatively small increasein total seedling dry weight takes place during the first 2to 3 weeks. Potassium may be drawn either from the supply already presentin the cotyledons or from an external source. Species with expandingphotosynthetic cotyledons utilize the reserve potassium duringcotyledon development and it is not transported to the epicotyl.Thus, in these species an external supply of potassium is essentialfor full development of the photosynthetic system and the roots.In species whose cotyledons are not major photosynthetic organsthe reserve potassium is transported from the cotyledons tothe developing axis. In these species culture in a nutrientsolution deficient in potassium or in distilled water increasesroot dry weight but reduces plumule weight (although to a lesserextent than in species with leaf-like cotyledons). In general,the response of seedlings to culture in a nutrient solutiondeficient in potassium was very similar to culture in distilledwater only. Thus, although all the species studied had similar levels ofpotassium in the seed (µg potassium/mg dry weight) itssite of utilization differs. It appears that seedlings withleaf-like cotyledons are more susceptible during early seedlinggrowth to deficiencies in external factors, such as potassium,than are species with fleshy cotyledons.     

Impact of Cotyledon and Leaf Removal on Seedling Survival in Three Tree Species with Contrasting Cotyledon Functions1

The relative importance of cotyledons and leaves for seedling survival was evaluated using a factorial field experiment on three neotropical tree species with contrasting cotyledon functional morphologies (photosynthetic, epigeal reserve vs. hypogeal reserve). In all species, cotyledon and leaf removal shortly after leaf expansion had additive negative effects on seedling survival over 7 weeks. Carbon supplies from cotyledons and other carbohydrate reserves apparently enhanced ability of seedlings to cope with herbivory and disease.     

Effect of Sink-Source Manipulations on the Photosynthetic Rate and Carbohydrate Content of Cucumber Cotyledons

Mayoral, M. L., Plaut, Z. and Reinhold, L. 1985. Effect of sink-sourcemanipulations on the photosynthetic rate and carbohydrate contentof cucumber cotyledons.-J. exp. Bot. 36 1551–1558. The photosynthetic rate of cucumber cotyledons (Cucumis sativuscv. Dahla) reached a maximum value of 12 mg dm^–2 h^–1,10 d after emergence. In 12-d-old seedlings removal of one cotyledondoubled the CO₂ fixation rate of the other, as observed 3 dafter treatment. When the primary leaf was removed, the photosyntheticrate of the cotyledons was decreased by 33%. At this stage ofgrowth elimination of the roots as a sink for assimilates bygirdling the hypocotyl affected neither the photosynthetic ratenor the carbohydrate content of the cotyledons. By contrast,in 18-d-old seedlings removal of the first leaf brought abouta 42% increase in the photosynthetic rate of the cotyledons.The simultaneous removal of the first leaf and one cotyledondoubled the rate of CO₂ fixation of the remaining cotyledon.Girdling the hypocotyl lowered the photosynthetic rate of thecotyledons by 73%. In both 12- and 18-d-old seedlings a decreaseor increase in the sink-source ratio was correlated with anincrease or a decrease respectively in the carbohydrate contentof the cotyledons. The stomatal resistance of the cotyledonswas not affected by any of the treatments. The effect of sink-sourcemanipulations on photosynthesis and on the level of carbohydratespresent in the cotyledons was more evident in those seedlingsgrowing under high light intensity (580 µE m^–2 s^–1),than in those exposed to 300 µE m^–2 s^–1 Key words: Sink-source relationship, cotyledons, photosynthesis     

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.     

Photosynthesizing Tissue Development in C4 Cotyledons of Two Salsola Species (Chenopodiaceae)

The quantitative anatomy of developing cotyledons of NAD-malic enzyme species Salsola incanescens and NADP-malic enzyme species S. paulsenii (Chenopodiaceae) was studied. S. incanescens belongs to the group of species with foliar type of seedling development characterized by slowly growing cotyledons and a rosette form at juvenility. The rosette is the consequence of fast leaf formation, which was correlated with a low rate of leaf growth. S. paulsenii belongs to the group with the cotyledonous type of seedling development. A high growth rate of cotyledons, slow leaf formation, and absence of the rosette characterize this type. Slow leaf formation was correlated with a high rate of leaf growth. The Kranz–anatomy in cotyledons of S. incanescens (atriplicoid type) and S. paulsenii (salsoloid type) determines the duration of cotyledon development proceeding for 15 days after seed germination. The rate of growth changes during the developmental period was correlated with the type of seedling development. Cotyledons of a foliar species S. incanescens exhibit 2 to 5 times slower growth changes in cotyledon area, width, thickness, volume of mesophyll and bundle sheath cells, and number of chloroplasts per bundle sheath cell than the cotyledons of a cotyledonous species S. paulsenii. During cotyledon development in both species, the number of chloroplasts per mesophyll cell remained unchanged, and developmental changes in the bundle sheath occurred at higher rate than in mesophyll cells. Thus, these two indices seem to be independent of the type of Kranz–anatomy. The presence of atriplicoid type cotyledons in the species with salsoloid structure of true leaves might indicate a close genetic relationship between these two patterns of Kranz-anatomy.     

GERMINATION AND SEEDLING DEVELOPMENT OF SOYBEANS IN A CARBON DIOXIDE-DEFICIENT ATMOSPHERE

During the initial phase of germination and seedling development of soybeans, most of the increase in dry weight in the embryo axis occurred in the hypocotyl. The epicotyl did not undergo a rapid increase in size and dry weight until the 4th to 5th day of growth. From day 1 to 11 dry weights of the hypocotyls in the “CO₂-normal” and “CO₂-Iimiting” (less than 50 ppm [0.005%] atmospheric CO₂) treatments were similar. By day 13 the CO₂-normal hypocotyls had continued their rapid increase in dry weight while the dry weight of the hypocotyls grown under CO₂-limiting conditions had decreased. The parallel decrease in dry weight of the cotyledons that occurred for both CO₂ treatments (days 1 to 13) suggested that CO₂ content of the atmosphere is not a controlling factor in the digestion or hydrolysis of food reserves in the cotyledon during germination and seedling development. This is supported by the failure of the CO₂ treatments to produce significantly different patterns in utilization of lipids, total carbohydrates, or proteins in the cotyledons. The seedlings grown under either the limiting or normal CO₂ atmospheres utilized their cotyledonary carbohydrates and lipids before the proteins. Sufficient food reserves are present in the soybean cotyledon storage cells for seedling development until about day 9. Net CO₂ uptake by soybeans in a CO₂-normal environment first occurred between days 9 to 11.     

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     

Cotyledon anatomy in the Leguminosae

Cotyledon anatomy has been investigated in approximately 900 species representing all the major tribes of the Leguminosae. Four main cotyledon forms are recognized on the basis of morphological, anatomical and functional criteria. The two modal forms are a leaf-like photosynthetic cotyledon, usually borne in an endospermic seed and occurring in about 60% of species; and a fleshy, storage cotyledon, borne in a non-endospermic seed and occurring in about 30% of species. Two intermediate forms combine the structural and functional characteristics of the modal forms in varying degree. The leaf-like cotyledon is considered to be the basic form from which the others have been derived. Cotyledon anatomy shows correlations with seed size and with taxonomic grouping at the tribal and generic levels and thus provides a set of minor characters of potential taxonomic or phylogenetic value or for use in seed and seedling classification and identification.     

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.     

Gibberellin Metabolism and Transport During Germination and Young Seedling Growth of Pea (<Emphasis Type="Italic">Pisum sativum</Emphasis> L.)

The role of gibberellins (GAs) during germination and early seedling growth is examined by following the metabolism and transport of radiolabeled GAs in cotyledon, shoot, and root tissues of pea (Pisum sativum L.) using an aseptic culture system. Mature pea seeds have significant endogenous GA₂₀ levels that fall during germination and early seedling growth, a period when the seedling develops the capacity to transport GA₂₀ from the cotyledon to the shoot and root of the seedling. Even though cotyledons at 0–2 days after imbibition have appreciable amounts of GA₂₀, the cotyledons retain the ability to metabolize labeled GA₁₉ to GA₂₀ and express significant levels of PsGA20ox2 message (which encodes a GA biosynthesis enzyme, GA 20-oxidase). The large pool of cotyledonary GA₂₀ likely provides substrate for GA₁ synthesis in the cotyledons during germination, as well as for shoots and roots during early seedling growth. The shoots and roots express GA metabolism genes (PsGA3ox genes which encode GA 3-oxidases for synthesis of bioactive GA₁, and PsGA2ox genes which encode GA 2-oxidases for deactivation of GAs to GA₂₉ and GA₈), and they develop the capacity to metabolize GAs as necessary for seedling establishment. Auxins also show an interesting pattern during early seedling growth, with higher levels of 4-chloro-indole-3-acetic acid (4-Cl-IAA) in mature seeds and higher levels of indole-3-acetic acid (IAA) in young root and shoot tissues. This suggests a changing role for auxins during early seedling development.     

The Influence of Cotyledons in Axillary and Adventitious Shoot Production from Cotyledonary Nodes of Cucumis sativus L. (Cucumber)

Cucumber explants including at least part of the cotyledon,a short section of hypocotyl, and the apical bud, are capableof producing multiple axillary buds from the seedling apex andadventitious shoots from the hypocotyl base in a medium whichcontains 2·0 mg dm^–3 of kinetin. Removal of theapical bud triples the number of shoots produced from the apexof explants with two intact cotyledons but does not affect shootproduction from explants with some or all of their cotyledonsremoved. The area of intact cotyledon also influences morphogenesis,as explants with both cotyledons removed, failed to produceadventitious shoots from the hypocotyl base. Culture in continuousdarkness entirely prevents shoot development from the explantbase, but has little influence on shoot production from theapex. The influence of endogenous growth regulators and apicaldominance on the morphogenesis of shoots in cucumber seedlingsare discussed. Key words: Cucumber, cotyledons, apical dominance, morphogenesis, adventitious shoots, Cucumis sativus     

Utilization of Seed Reserves and Currently Produced Photosynthates by Embryonic Tissues of Pine Seedlings

The importance of seed reserves for growth of Pinus resinosaAit. during and shortly after seed germination was studied undercontrolled conditions. Tissues in the resting embryo were notcompletely differentiated. Many small, presumably reserve particleswere present in the embryo in addition to reserves in the megagametophyte.During seed germination, procambia in the embryo first differentiatedprotophloem 2 days after seeds were sown. The radicle beganto emerge from the seed coat at 5 days, at which time initialxylem formation was observed. Also, at approximately the sametime, primordia of primary needles were forming in the peripheralzone of the apex. Elements of the photosynthetic apparatus,including stomata and mesophyll with chloroplasts, were differentiatedfirst in the hypocotyl and then in cotyledons between 5 and8 days after seeds were sown. Photosynthetic rates of youngseedlings were correlated with rates of cotyledon expansion.During early developmental stages, reserve particles in megagametophytecells and embryo cells gradually disappeared. Surgical removalof megagametophytes at various stages of seed germination resultedin subsequent growth inhibition of the hypocotyl-radicle axis,with early removal of cotyledons suppressing most growth. Growthof primary needles appeared to be influenced indirectly by megagametophytereserves, probably by changes in amount of photosynthetic tissue.The embryo alone possessed capacity to differentiate such tissuesas primary needle primordia, stomata, and primary and secondaryvascular systems. Megagametophyte reserves appeared to contributeto growth of embryonic tissues only after the embryo itselfinitiated growth. Both current photosynthesis of seedlings andseed reserves contributed importantly to seedling development.     

Effects of the embryonic axis and exogenous growth regulators on sunflower cotyledon storage protein mobilization

Cotyledons of sunflower seedlings ( Helianthus annuus L. cv. Giant gray stripe) expand and their protein content first rises then begins to decrease during the first three days of growth. Storage protein structures, which are visible with scanning electron microscopy, undergo modification that leads to storage protein disappearance by day 4 post-imbibition. Expansion of cotyledons detached from seeds prior to imbibition is greatly reduced, total protein levels remain high, and storage protein structures remain visible in cells of these cotyledons. Incubation of excised cotyledons in 1.0 μM benzyladenine or kinetin increases the rates of cotyledon expansion and storage protein loss to levels higher than in intact seedling cotyledons, Incubation in 10 μM indole-3-acetic acid inhibits cotyledon expansion and protein mobilization. More rapid hydrolysis of storage proteins in cotyledons of intact seedlings or detached cotyledons treated with cytokinin is further indicated in day 2 specimens by SDS-polyacrylamide gel electrophoresis. These results suggest a possible mechanism for regulation of cotyledon development by interactions of the promotive effects of cytokinin and inhibitory effects of auxin.     

Metabolism of carbohydrate and lipid reserves in germinated cotton seeds

Utilization of reserve lipid and carbohydrates during germination (0–12 h) and postgerminative growth (12–48 h) was studied in cotton (Gossypium hirsutum L.) seedlings. Raffinose and stachyose were utilized during the germination period and early growth; mobilization was associated with -galactosidase (EC 3.2.1.22) activity. Results from pulse-chase experiments with [³H]raffinose supplied exogenously to 4-h soaked seeds indicated that raffinose-derived catabolites contributed to the coincident increase in cotyledon sucrose and starch, and to the small increase in axis dry weight. Starch appears to be an alternative sink for end products of hydrolysis of reserve carbohydrates prior to the onset of rapid axis growth and cotyledon expansion. Mobilization of neutral lipid commenced at about 16 h after soaking, concomitant with development of key glyoxylate-cycle and other gluconeogenesis-related enzyme activities. Axis dry weight increased three-fold between 24 and 48 h. Results from pulse-chase (3 h, 16 h) experiments in which [2-¹⁴C]acetate was supplied to cotyledons of intact 22-h-old seedlings showed that acetate-derived metabolites were not transported exclusively to the axes, but were partitioned between axes and cotyledons. Only 27% of total incorporated radioactivity was recovered in axes following the chase, 18% was evolved as CO₂, and the rest was recovered in water-soluble substances (20%) and polymers (31%) within the cotyledons. Of the polymers, 55% of the activity was in polysaccharides (Starch, pectic substances, hemicellulose, cellulose), 25% in protein, and 20% in unidentified neutral and acidic compounds. Considering these data, the amount of lipid mobilized, and various routes by which supplied [2-¹⁴C]acetate could be metabolized, it appears that lipidderived compounds contribute only 25–40% of axis dry-weight gain. Lipid-derived substances retained in the cotyledons likely are utilized for expansion and differentiation of the cotyledons into photosynthetic organs.     

Features of Photosynthesis in Haloxylon species of Chenopodiaceae that are Dominant Plants in Central Asian Deserts

Haloxylon aphyllum and H. persicum of Chenopodiaceae are dominantplants in the continental deserts of the Asian Irano-Turanianregion. The photosynthetic organs, assimilating shoots and leaf-likecotyledons of these two species were studied to characterizetheir photosynthetic types. ¹³C/¹²C isotope ratios, the cellularanatomy of as similating organs, primary photosynthetic products,and activities of carbon metabolism enzymes, RUBP carboxylase,PEP carboxylase, malic enzymes, and aspartate aminotransferase,indicate different pathways of CO₂ fixation in the photosyntheticorgans. Assimilating shoots had attributes of the C₄ photosynthesisentirely, while cotyledons lack Kranz-anatomy and incorporatedCO₂ via C₃ photosynthesis. Cotyledons and seeds had lower     

Limited evolutionary divergence of seedlings after the domestication of plant species

The most vulnerable stage in the life of plants is the seedling. The transition from wild to agricultural land that plants experienced during and after domestication implied a noticeable change in the seedlings′ environment. Building on current knowledge of seedling ecology, and on previous studies of cassava, we hypothesise that cultivation should have promoted epigeal germination of seedlings, and more exposed and photosynthetic cotyledons. To test this hypothesis, we phenotyped seedling morpho‐functional traits in a set of domesticated and wild progenitor accessions of 20 Eudicot herbaceous crop species. Qualitative traits like epi‐ versus hypogeal germination, leafy versus storage type of cotyledons, or crypto‐ versus phanerocotyledonar germination, remained conserved during the domestication of all 20 species. Lengths of hypocotyls and epicotyls, of cotyledon petioles, and indices of cotyledon exposure to the aboveground environment changed during evolution under cultivation. However, those changes occurred in diverse directions, depending on the crop species. No common seedling phenotypic convergence in response to domestication was thus detected among the group of species studied here. Also, none of the 20 crops evolved in accordance with our initial hypothesis. Our results reject the idea that strong selective filters exerted unconsciously by artificial selection should have resulted in generalised channelling of seedling morphology towards more productive and more herbivore risky phenotypes. This result opens up unexplored opportunities for directional breeding of seedling traits.