Cellular and chloroplast lipid composition of the leaves of Mimosa pudica

Cellular and chloroplast lipids of the leaves of Mimosa pudica have been analysed. Qualitatively the total lipid composition of this plant is similar to that reported for the photosynthetic tissues of other plants. Chloroplast lipids show some resemblance to those of algae. The cerebroside fraction of both leaves and chloroplasts contains a polyunsaturated fatty acid (20:4ω3) and a long chain sphingosine base whose R_f value coincides with that from ox brain cerebroside and not with that of phytosphingosine from spinach.     

Effects of UV-B radiation on soybean yield and seed quality: a 6-year field study

Two soybean [ Glycine max (L.) Merr.] cultivars, Essex and Williams, were grown in the field for 6 consecutive seasons under ambient and supplemental levels of ultravio-Set-B radiation to determine the potential for alterations in yield or seed quality with a reduction in the stratospheric ozone column. The supplemental UV-B fluences simulated a 16 or 25% ozone depletion. The data presented here represent the first field experiment conducted over multiple seasons which assesses the effects of increased UV-B radiation on seed yield. Overall, the cultivar Essex was found to be sensitive to UV-B radiation (yield reductions of 20%) while the cultivar Williams was tolerant. However, the effectiveness of UV-B radiation in altering yield was strongly influenced by the seasonal microclimate, and the 2 cultivars responded differently to these changing factors. Yield was reduced most in Essex during seasons in which water availability was high and was reduced in Williams only when water was severely limiting. The results of these experiments demonstrate the necessity for multiple-year experiments and the need to increase our understanding of the interaction between UV-B radiation and other environmental stresses in order to assess the potential consequences of stratospheric ozone depletion.     

Effects of natural shade on soybean thylakoid membrane composition

The effect of natural shade on chloroplast thylakoid membrane activity and composition was examined for soybean (Glycine Max. cv. Young) grown under field conditions. Plots with high (10 plants m^–1 row) or low (1 plant m^–1 row) plant density were established. Expanding leaves were tagged at 50, 58 and 65 days after planting (DAP). At 92 DAP, tagged leaves were used as reference points to characterize canopy light environments and isolate thylakoid membranes. Light environments ranged from a photosynthetic photon flux density (PPFD) of 87% of full sun to a PPFD of 10% of full sun. The decline in PPFD was accompanied by an increase in the far-red/red (735 nm/645 nm) ratio from 0.9 to approximately six. The major effects of shade on chloroplast thylakoid membranes were a reduction in chloroplast coupling factor and a shift in light-harvesting capacity from Photosystem I to Photosystem II. Photosynthetic electron transport capacity was not affected by differences in PPFD, but was 20 to 30% higher in the 1 plant m^–1 row treatment. The plant density effect on electron transport was associated with differences in plastocyanin concentration, suggesting that plastocyanin is a limiting factor in soybean. Shade did not have a significant effect on the concentration of Photosystem II, Cyt b₆f, or Photosystem I complexes.Abbreviations CF₁ chloroplast coupling factor - DAP days after planting - DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DCIP 2,6-dichlorophenolindophenol - FR/R far-red/red - PBS 10 mM sodium phosphate (pH 7.0), 150 mM NaCl - PPFD photosynthetic photon flux density - PS I Photosystem I - PS II Photosystem II - P700 reaction center of Photosystem I - Rubisco ribulose-1,5-bisphosphate carboxylase/oxygenase - TBS 20 mM Tris-HCl (pH 7.5), 500 mM NaCl - TTBS 20 mM Tris-HCl (pH 7.5), 500 mM NaCl, 0.05% (w/v) polyoxyethylenesorbitan monolaurate (Tween-20) The US Government right to retain a non-exclusive, royalty-free licence in and to any copyright is acknowledged.The US Government right to retain a non-exclusive, royalty-free licence in and to any copyright is acknowledged.     

The effect of methionine, ethylene and polyamine catabolic intermediates on polyamine accumulation in detached soybean leaves

In the present study we determined the effects of methionine, intermediates of polyamine catabolic pathways and inhibitors of either ethylene biosynthetic or polyamine catabolic pathways on polyamine accumulation in soybean leaves. Inhibitors to SAM decarboxylase and spermidine synthase, methylglyloxal-bis-(guanylhy-drazone) and cyclohexylamine, respectively, suggest that methionine may provide aminopropyl groups for the synthesis of polyamine via S-adenosylmethionine (SAM). Results from experiments that utilized a combination of compounds which altered either ethylene or polyamine biosynthesis, namely, aminoethoxyvinyl glycine, CoSO₄, 2,5-norbornadiene, and CuSO₄, suggest the two pathways compete for a common precursor. However, exogenous addition of ethylene (via ethephon treatments) had little or no effect on polyamine biosynthesis. Likewise, polyamine treatments had little or no effect on ethylene biosynthesis. These data suggest that there are few or no inhibitory effects from the end products of one pathway on the synthesis of the other. Data from leaves treated with metabolic intermediates in the catabolic pathway of polyamines and inhibitors of enzymes in the catabolic pathway, i.e. aminoguanidine, hydroxyethyldrazine and gabaculine, suggest that the observed increases in polyamine titers were not due to decreased catabolism of the polyamines. One catabolic intermediate, γ-aminobutyric acid (GABA), elevated putrescine, spermidine and spermine by 12-, 1.4-, and 2-fold, respectively, Ethylene levels decreased (25%) in GABA-treated leaves. This small decrease in ethylene could not account for such large increase in putrescine titers. Further analysis demonstrated that the GABA-mediated polyamine accumulation was inhibited by difluoromethylarginine, an inhibitor of arginine decarboxylase, but not by difluoromethylornithine, an inhibitor of ornithine decarboxylase. These data suggest that GABA directly or indirectly affects the biosynthesis of polyamines via arginine decarboxylase.     

Instantaneous canopy photosynthesis: analytical expressions for sun and shade leaves based on exponential light decay down the canopy and an acclimated non-rectangular hyperbola for leaf photosynthesis

Analytical expressions for the contributions of sun and shade leaves to instantaneous canopy photosynthesis are derived. The analysis is based on four assumptions. First, that the canopy is closed in the sense that it is horizontally uniform. Secondly, that there is an exponential profile of light down the canopy with the same decay constant for light from different parts of the sky. Thirdly, that the leaf photosynthetic response to incident irradiance can be described by a three-parameter non-rectangular hyperbola (NRH). And lastly, that light acclimation at the leaf level occurs in only one parameter of the NRH, that describing the light-saturated photosynthetic rate, which is assumed to be proportional to the local averaged leaf irradiance. These assumptions have been extensively researched empirically and theoretically and their limitations are quite well understood. They have been widely used when appropriate. Combining these four assumptions permits the derivation of algebraic expressions for instantaneous canopy photosynthesis which are computationally efficient because they avoid the necessity for numerical integration down the canopy. These are valuable for modelling plant and crop ecosystems, for which canopy photosynthesis is the primary driver. Ignoring the sun/shade dichotomy can result in overestimates of canopy photosynthesis of up to 20 %, but using a rectangular hyperbola instead of a non-rectangular hyperbola to estimate canopy photosynthesis taking account of sun and shade leaves can lead to a similarly sized underestimate.     

The effects of shading on kaempferol content and leaf characteristics of five soybean lines

Previous work has shown that the presence of kaempferol triglucoside (K9) in soybean ( Glycine max L. Merr.) leaves is associated with reduced numbers of stomata, especially on the upper surface. In the present test, shade was imposed on soybean plants as a means of altering the level of K9, and thus testing the relationship between quantities of K9 and stomatal density. Five lines of soybean that differ in their complement of flavonol glycosides were grown in the field unshaded and also with a 64 and 80% reduction in daylight intensity. Samples of the second, sixth and tenth trifoliate leaves were taken at 34, 53 and 77 days after planting. Shade reduced the quantities of flavonoids on a per leaf and a per unit area basis. Shade had no effect on stomatal density in lines containing K9, but reduced stomatal density in lines lacking K9. We envisage two opposing effects of shade on stomatal density: a direct effect in which shade reduces numbers, and an indirect effect in which a decrease in K9 content allows an increase in stomatal density. The net effect of shade on lines containing K9 appears to be the maintenance of a constant stomatal density. The quantity of K9 was highly correlated with stomatal density within all treatment combinations, and with all treatments combined.     

Polar lipid composition of leaves from nine typical alpine species

The fatty acids and polar lipid compositions of leaves from nine alpine species were almost identical to that of plants growing in habitats with little seasonal variation in temperature. Furthermore each polar lipid had about the same fatty acid composition in all plant species studied. It is suggested that neither the relative proportions of different lipid classes nor the degree of saturation of individual classes are directly implicated in the adaptation of plant tissues to different climates.     

Carbon dioxide concentration at night affects translocation from soybean leaves

Studies have indicated that the concentration of carbon dioxide [CO2] during the dark period may influence plant dry matter accumulation. It is often suggested that these effects on growth result from effects of [CO2] on rates of respiration, but responses of respiration to [CO2] remain controversial, and connections between changes in respiration rate and altered growth rate have not always been clear. The present experiments tested whether translocation, a major consumer of energy from respiration in exporting leaves, was sensitive to [CO2]. Nineteen-day-old soybean plants grown initially at a constant [CO2] of 350 micromol mol(-1) were exposed to three consecutive nights with a [CO2] of 220-1400 micromol mol(-1), with a daytime [CO2] of 350 micromol mol(-1). Change in dry mass of the individual second, third and fourth trifoliate leaves over the 3-d period was determined, along with rates of respiration and photosynthesis of second leaves, measured by net CO2 exchange. Translocation was determined from mass balance for second leaves. Additional experiments were conducted where the [CO2] around individual leaves was controlled separately from that of the rest of the plant. Results indicated that low [CO2] at night increased both respiration and translocation and elevated [CO2] decreased both processes, to similar relative extents. The effect of [CO2] during the dark on the change in leaf mass over 3 d was largest in second leaves, where the change in mass was about 50% greater at 1400 micromol mol(-1) CO2 than at 220 micromol mol(-1) CO2. The response of translocation to [CO2] was localized in individual leaves. Results indicated that effects of [CO2] on net carbon dioxide exchange rate in the dark either caused or reflected a change in a physiologically important process which is known to depend on energy supplied by respiration. Thus, it is unlikely that the observed effects of [CO2] on respiration were artefacts of the measurement process in this case.     

Mineral and lipid composition of Glycine - Glomus - Bradyrhizobium symbioses

Soybean [Glyeine max (L.) Merr. cv. Amsoy 71] plants were inoculated with either the vesicular-arbuscular mycorrhizal (VAM) fungus Glomus fasciculatum. with a strain of Bradyrizobobium Japonicum. or with both endophytes in combintion. Noninoculated controlplantes were fertilized with levels of N and P previously found to compensate for nutrient input following infection by Bradyhizobium or Glomus Temporal differences in N and P assimilation in nodulated or mycorrhizal plants indicated that Glomus was most effective during early vegetative growth and Bradyrhizobion was active until the mid-pod-fill stage in soybean. In general. soybeans colonized by Glomus contained more Cu but less Mn and P than corresponding P-fertilized plants. Soyubean roots infected with G. fasciculaum contained five unusual fatty acids: [16: 1 (11c): 8:3 (6c, 9c, 12c): 20:3 (8c, 11c, 14c): 20:4 (5c, 8c, 11c, 14c): 20:5 (5c, 8c, 11c, 14c, 17c)] that were absent in non-infected roots. Fatty acid 16:1 (11c) comprised 43% of total fatty acids in Glomus-infected roots at week 9 and 29% of total root fatty acids at week 15. This isomer of hexadecenoic acid was positively correlated with vesicle number (r = 0.92**). and 16:1 (11c) was probably the principalstorage fatty acid in fungal vesicles. These five unusual fatty acids were not found in the leaves. pods or seeds of either VAM or non-VAM plants. Specific leaf area increased with time in nodulated soybeans. but these plants contained lessCu than corresponding N-fertilized plants. Soybeans nodulated with Bradyrthizobium contained more total lipid and proportionately more fatty acid 16:0 than N-fertilized plants. Infection by Glomus or Bradyrhizobium also altered the fatty acid composition of above-ground plant parts, although these changes were subtle compared to the markedly different fatty acid found in Glomus-infected roots. These findings suggest that seed quality may be altered due to the physiological changes resulting from infection by N²-fixing bacteria and/or endomycorrhizal fungi. Observed differences in the plant nutrition of inoculated soybeans could not be replicated by fertilizer addition alone.     

Age-induced changes in cellular membranes of imbibed soybean seed axes

The physical and chemical properties of microsomal membranes and cellular antioxidant systems were investigated in imbibed soybean ( Glycine max L. Merr. cv. Maple Arrow) seeds following aging for 5 years at room temperature. The loss of germination capacity in aged seeds was associated with increased solute leakage during imbibition and with a loss of membrane phospholipid. Higher levels of free fatty acids were observed in the microsomal membranes from aged seeds. However, there was no change in fatty acid saturation. Wide angle X-ray diffraction studies indicated the presence of gel phase in addition to liquid-crystalline phase lipid domains in the membranes of aged seeds. Those from fresh seeds were exclusively liquid-crystalline. Fluorescence depolarization, using diphenylhexatriene, suggested that the microviscosity of the membrane bilayer was increased by aging. Aged seeds had a lower antioxidant potential in the lipid fraction, lower tocopherol content, and reduced ascorbate:dehydroxyascorbate ratio indicating that the aging process was associated with exposure to an oxidative stress.     

Effects of periodic fluctuations of photon flux density on anatomical and photosynthetic characteristics of soybean leaves

The development of soybean leaves grown at fluctuating photon flux density between 100 and 1500M m^-2s^-1 with a period of 160 sec were compared to leaves developed under continuous light with the same mean photon flux density. Number of epidermal cells and stomata, leaf area and specific leaf weight were not affected by the periodic fluctuation of photon flux density. Chloroplastic pigment concentration and chlorophyll fluorescence reveal some photoinhibitory effects of the high photon flux density phase. Stomatal and internal CO₂ conductance and the quantum yield were not affected by the light regime. In contrast ribulose 1.5 bisphosphate carboxylase/oxygenase activity before in vitro activation by CO₂ and Mg⁺⁺ was stimulated by the periodic illumination whereas the total amount of the enzyme and the internal leaf CO₂ conductance remained steady. In conclusion, there was no major difference between leaves of plant grown either under a steady or under a periodic fluctuation of the photon flux density except some photoinhibitory symptoms under fluctuating illumination, and a higher in vivo level of activation of the Rubisco.     

Photosynthesis in flashing light in soybean leaves grown in different conditions. I. Photosynthetic induction state and regulation of ribulose-1,5-bisphosphate carboxylase activity

The photosynthetic induction state under conditions of different lightfleck frequencies or durations, or different shade periods was studied in soybean leaves in order to examine how it might limit utilization of sunflecks in leaf canopies. Induction following an increase in photon flux density (PFD) from strongly limiting to saturating PFDs exhibited two phases; a fast-inducing one, requiring about 1 min and a slow one, requiring up to 60 min for completion. Transfer of fully induced leaves to low light resulted in a rapid decrease in the fast-inducing component, a slower decrease in the slow-inducing component and an even slower decrease in stomatal conductance. Therefore, the decreases in extent of induction appeared to be due to biochemical factors and not to stomatal closure. Under flashing light regimes consisting of 1-s lightflecks given at different frequencies for long periods, a constant induction state was achieved, the measure of induction state increased with the frequency of the lightflecks. This constant induction state also depended on the growth conditions, with shade leaves having a higher value than those grown at high light at any particular lightfleck frequency. The measure of induction state was mostly lower in flashing light as compared to constant light of the same mean PFD, particularly in leaves with a low light saturation point and in short lightflecks. Initial activities of ribulose-1,5-bisphosphate carboxylase (rubisco) were also higher in continuous light and were highly correlated with the measure of induction state. The rapid decrease in extent of induction of soybean leaves during shade periods is an important limitation to the ability of the leaves to respond to light increases similar to those occurring with sunflecks. At least part of the limitation on carbon assimilation during sunflecks due to photosynthetic induction is based on regulation of rubisco activity.     

Unusual regulatory properties of sucrose-phosphate synthase purified from soybean (Glycine max) leaves

Sucrose-phosphate (SPS) from source leaves of soybean ( Glycine max (L.) Merr. cv. Ransom II) was purified 74-fold to a final specific activity of 1.8 U (mg protein)¹. The partially purified preparation was free from phosphoglucoseisomerase (EC 5.3.1.9), pyrophosphatase (EC 3.6.1.1), phosphoenolpyruvate-phosphatase (EC 3.1.3.-), phosphofructokinase (EC 2.7.1.11), and uridine diphosphatase (EC 3.6.1.6), and was used for characterization of the kinetic and regulatory properties of the enzyme. The enzyme showed hyperbolic saturation kinetics for both fructose-6-phosphate (K_m=0.57 m M ) and UDPGlucose (UDPG) (K_m=4.8 m M ). The activity of SPS was inhibited by the product UDP. In vitro this inhibition could be partially overcome by the presence of Mg²⁺. Inorganic orthophosphate was only slightly inhibitory (35% inhibition at 25 m M phosphate). Glucose-6-phosphate (up to 20 m M ) had no effect on activity, and did not show any significant interaction with phosphate inhibition. A range of potential effectors was tested and had no effect on SPS activity: Glucose-1-phosphate, fructose-1, 6-bisphosphate, α-glycero-phosphate, dihydroxyacetone-phosphate, 3-phosphoglyceric acid, (all at 5 m M ), sucrose at 100 m M and pyrophosphate at 0.1 m M . The apparent lack of allosteric regulation of soybean SPS makes this enzyme markedly different from SPS previously characterized from spinach and maize.     

Growth and photosynthesis of soybean (Glycine max (L.) Merr.) in simulated vegetation shade: influence of the ratio of red to far-red radiation*

Abstract. Glycine max (L.) Merr. was grown under several light conditions to determine the role of red and far-red radiation in plant adaptation to vegetation shade. Neutral density,‘neutral’ density with elevated far-red radiation, and green shade treatments were used in a greenhouse, producing calculated phytochrome photostationary state (P_fr/P_r+P_fr) values of 0.68, 0.63 and 0.51, respectively. Cool-white fluorescent lamps either alone or in conjunction with far-red fluorescent lamps were used in a growth chamber, providing P_fr/P_r+P_fr of 0.79 and 0.61, respectively. Daily photo-synthetically active radiation was about 25% of daylight and was approximately equal for both greenhouse (2.15MJ m^?2) and growth chamber (2.57MJ m^?2). Developmental stage 4 weeks after sowing was similar for all treatments, but axillary growth and rates of leaf area and dry matter accretion differed between plants from greenhouse and growth chamber. Light conditions simulating vegetation shade (i.e. a low ratio of red to far-red radiation) significantly promoted petiole elongation and retarded the rate of stem elongation in both greenhouse and growth chamber experiments. Other aspects of growth either were not significantly altered by spectral quality or were not modified consistently in both greenhouse and growth chamber environments. Net photosynthetic rates measured under growth conditions for unifoliate and first trifoliolate (TF₁) leaves of growth chamber plants between 9 and 21 d after sowing were generally unaffected by spectral quality, but supplemental FR enhanced TF₁ leaf area expansion. The latter effect was not correlated with increased dry matter accumulation. The significance of spectral quality for adaptation of soybeans to canopy closure and intercropping is discussed.     

Inhibition of sulphur redistribution into new leaves of vegetative soybean by excision of the maturing leaf

When soybean plants are pulsed with [³⁵S]sulphate, label is subsequently redistributed from the roots to the leaves. This confounds studies to measure the redistribution of label from leaves. Accordingly, soybean plants ( Glycine max [L.] Merr. cv. Stephens) were grown in 20 μ M sulphate and a small portion of the root system (donor root) was pulsed with [³⁵S]sulphate for 24 h. After removing the donor root, the plants were transferred into unlabelled solution, either without sulphate (S20→SO) or with 20 μ M sulphate (S20→20) (intact plants). Also at this time, the expanding leaf (L3) was excised from half of the plants in each treatment (excised plants). Immediately after the pulse, only ca 15% of the label occurred in the roots and ca 40% in the expanding leaf, L3, mostly in the soluble fraction. In intact S20→20 plants, ³⁵S-label was exported from the soluble fraction of L3, mostly as sulphate, whilst L4 and L5 imported label. Similar responses occurred in S20→SO plants except that export of label from L3 was more rapid. Excision of L3 from S20→S20 plants inhibited labelling of leaves L4-L6 but not total sulphur, whereas in S20→SO plants, excision of L3 inhibited the import of both total sulphur and ³⁵S-label in leaves L4, L5 and L6. The data suggest that the soluble fraction of almost fully expanded leaves is an important reserve of sulphur for redistribution to growing leaves. The ³⁵S-label in the root system exhibited fluctuations consistent with its proposed role in the recycling of soluble sulphur from the leaves.     

Light‐induced systemic signalling down‐regulates photosynthetic performance of soybean leaves with different directional effects

• When plants are exposed to a heterogeneous environment, photosynthesis of leaves is not only determined by their local condition, but also by certain signals from other parts of the same plant, termed systemic regulation. Our present study was conducted to investigate the effects of light‐dependent systemic regulation on the photosynthetic performance of soybean (Glycine max L. Merr.) under heterogeneous light conditions.
• Soybean plants were treated with heterogeneous light. Then gas exchange characteristics were measured to evaluate the photosynthetic performance of leaves. Parameters related to photosynthetic pigments, chlorophyll fluorescence, Rubisco and photosynthates were examined to study the mechanisms of light‐dependent systemic regulation on photosynthesis.
• Light‐induced systemic signalling by illuminated leaves reduced the P_n of both upper and lower non‐illuminated leaves on the same soybean plant. The decrease in g_s and increase in C_i in these non‐illuminated leaves indicated restriction of carbon assimilation, which was further verified by the decline in content and activity of Rubisco. However, the activation state of Rubisco decreased only in upper non‐illuminated leaves. Quantum efficiency of PSII (ΦPSII) and ETR also decreased only in upper non‐illuminated leaves. Moreover, the effects of light‐induced systemic signalling on carbohydrate content were also detectable only in upper non‐illuminated leaves.
• Light‐induced systemic signalling by illuminated leaves restricts carbon assimilation and down‐regulates photosynthetic performance of non‐illuminated leaves within a soybean plant. However, effects of such systemic regulation differed when regulated in upward or downward direction.

     

Photogeneration of a bioelectric field by red and far-red irradiation in soybean hypocotyls

Abstract. Changes in the bioelectric field potential at the apical end of dark-grown soybean ( Glycine max) hypocotyls after exposure to several wavelengths of light have been monitored with an electrometer. A small dose of 660 nm radiation brings about a rapid positive rise in the potential. A following small dose at 760 nm prevents the increase, suggesting a phytochrome action. Pre-irradiation with 660 nm enables a subsequent larger dose of 760 nm, which by itself is without effect, to elicit a delayed rise in the potential.
A large dose at 710 nm induces a delayed increase in the field potential. The increase is prevented by a following dose at 550 nm, but not at 660 nm.     

Effects of two Avtemia diets with different contents of polyunsaturated fatty acids on the lipid composition of larvae of Atlantic herring (Clupea harengus

Atlantic herring larvae ( Clupea harengus ) were fed two enriched Artemia diets with different contents of (n-3) highly unsaturated fatty acids (HUFA), one containing low levels of 20: 5(n-3) and no 22: 6(n-3), the other containing substantial levels of both 20: 5(n-3) and 22: 6(n-3). After 30 days of culture, fatty acid compositions of lipid classes in the heads, bodies and eyes of the larvae were analysed. Fish fed Artemia with the low (n-3) HUFA diet lacking 22: 6(n-3) had lower amounts of total (n-3)HUFA and, in particular, of 22:6(n-3) in individual phospholipids and total neutral lipids of heads, bodies and eyes as compared to fish fed Artemia with high levels of (n-3)HUFA. The amount of 22: 6(n-3) in the fatty acids of phosphatidyl-ethanolamine of eyes was particularly susceptible to dietary depletion. The implications of these findings are discussed, particularly in relation to dietary requirements for 22: 6(n-3) during development of neural tissue in predatory fish iarvae.     

Carotenoid composition in sun and shade leaves of plants with different life forms

The carotenoid composition of sun leaves of nine species of annual crop plants (some with several varieties) was compared with sun and shade leaves of several other groups of plants, among those sun and shade leaves of several species of perennial shrubs and vines and deep-shade leaves of seven rainforest species. All sun leaves contained considerably greater amounts of the components of the xanthophyll cycle violaxanthin, antheraxanthin and zeaxanthin as well as of β-carotene than the shade leaves, as had previously been reported for a variety of other species by Thayer & Björkman (Photosynthesis Research, 1990, 23, 331–343). Therefore, high light specifically stimulated β,β-carotenoid synthesis. The sun leaves of these crop species did not contain α-carotene which was, however, present in large amounts in all shade leaves and in smaller amounts in sun leaves of three of the four species of perennial shrubs and vines. There was no difference in neoxanthin content on a chlorophyll basis between sun and shade leaves, and there was no consistent general difference in the lutein content between all sun and all shade leaves. The zeaxanthin (and antheraxanthin) content at peak irradiance and the xanthophyll cycle pool size were compared for sun leaves from the different groups of plants with different life forms and different metabolic activities. When growing in full sunlight the annual crop species and a perennial mesophyte had high rates of photosynthesis whereas the perennial shrubs and vines had relatively low photosynthesis rates. More zeaxanthin (and antheraxanthin) were accumulated at noon in full sunlight in those species with the lower photosynthesis rates. However, it was not such that those species also possessed the larger pools of violaxanthin + antheraxanthin + zeaxanthin. Instead, the xanthophyll cycle pools of sun leaves of the annual crop species and the perennial mesophyte were not smaller, and were even possibly larger, than those of sun leaves of the perennial shrubs and vines with low photosynthesis rates. This was so in spite of the fact that the crop species experienced much lesser degrees of excessive light at full sun than the shrubs and vines. Thus, many of the crop species converted only about 30–50% of their xanthophyll cycle pool to zeaxanthin at noon, whereas the shrubs and vines typically converted more than 80% of their pool into zeaxanthin. The crop species also had larger pools of β-carotene than the shrubs and vines but smaller pools of lutein than the majority of the latter species.