The effect of handling on the yield of two populations of Lolium perenne selected for differences in mature leaf respiration rate

Two populations of Lolium perenne L. S23 (perennial ryegrass), selected for differences in mature leaf dark respiration, were used in a non-destructive indexing system for individual plants, to determine growth parameters. Population GL66, selected for high respiratory rates and low yield, responded strongly to the indexing treatment, when grown at low plant density. Dry weights of all plant parts decreased strongly, as did dry matter percentages of the leaf blades. At high density this population demonstrated the same trend, but additionally allocation to the shoot increased. In contrast, GL72, selected for low respiratory rates and a high yield, responded only at a high plant density. It is argued that there might be a relation between the dissimilar response of the two populations to mechanical influences and the presence of the genotypes of the low-yielding population in the parent variety. The results also emphasize that non-destructive growth analyses can only be used when their effects on the plants are known.     

Metabolism and translocation of nitrogen in two Lolium perenne populations with contrasting rates of mature leaf respiration and yield

Barneix, A. J., Cooper, H. D., Stulen, I. and Lambers, H. 1988. Metabolism and translocation of nitrogen in two Lolium perenne populations with contrasting rates of mature leaf respiration and yield. - Physiol. Plant. 72: 631–636.
Several aspects of nitrogen metabolism and transport were investigated to determine whether these processes could account for the observed differences in the dark respiration rate of mature leaves between two populations of Lolium perenne L. cv. S23: GL72 - a slow respiring, high growth rate line, and cv. GL66 - a fast respiring, low growth rate line.
No differences were found in total nitrogen or soluble protein concentrations between the populations, but GL72 showed a higher concentration of soluble amino acids, accounted for mainly by increases in the amounts of asparagine and glutamine. There were no differences in the glutamine synthetase (EC 6.3.1.2) or nitrate reductase (EC 1.6.6.1) activities between populations, but the fast respiring GL66 line showed higher glutamate dehydrogenase (EC 1.4.1.3) and peroxidase (EC 1.11.1.7) activities than GL72. The protein turnover rate, determined from ³H disappearance from leaves labelled with [³H]-acetic anhydride, appeared to be larger in GL66, but the difference was not significant and could not account for the differences in respiration rate.
The apparent extent of ¹⁵N cycling between roots and shoots was low in Lolium compared to other grass species, and there were no differences between the two populations.
It is concluded that the differences in dark respiration rate are not due to differences in demand for ATP by nitrogen assimilatory processes, but may be related to faster leaf senescence in the GL66 population.     

Leaf and root respiration of Lolium perenne populations selected for contrasting leaf respiration rates are affected by intra- and interpopulation interactions

Autotoxicity and allelopathy affect the yield of GL66 and GL72, two populations of perennial ryegrass (Lolium perenne L. cv. S23) that were originally selected for contrasting rates of mature leaf dark respiration, but under conditions where allelopathic effects could not occur and autotoxic effects were minimal. To investigate if the respiration properties are also affected, the populations were subjected to two conditions (monoculture and mixed culture) and two treatments (grown in `renewed', i.e. solution completely replaced every week, and `replenished', i.e. nutrients added to the solution every week, to compensate for the nutrients that had been absorbed from the solution). When plants were grown in mixed culture with a `renewed' nutrient solution, the rate of mature leaf respiration in the absence of inhibitors was higher in GL66 than in GL72. In GL66, this rate was unaffected by condition or treatment, whereas in GL72 it increased in the `replenished' cultures, due to autotoxic and allelopathic effects. In contrast with GL66, for GL72 the effect of an inhibitor of the alternative path (salicylhydroxamic acid, SHAM) differed between conditions and treatments. Effects of an inhibitor of the cytochrome path (KCN) were affected by treatment in both populations. The increase in the rate of root respiration of GL66 due to autotoxic and allelopathic effects was accompanied by a higher rate of the SHAM-resistant component, i.e. maximum activity of the cytochrome path. Roots of GL72 showed a higher control respiration rate and a higher rate of the SHAM-resistant component when long-term accumulation of root exudates was allowed to occur in mixed cultures (allelopathy). We conclude that allelochemicals can modify both leaf and root respiration and that there is no consistent correlation between yield and respiration for GL66 and GL72 in the present study. This shows that selection for low rates of mature leaf respiration is not an appropriate method to select for high-yielding cultivars in perennial ryegrass.     

Respiration in mature leaves of Lolium perenne as affected by nutrient supply, cutting and competition

The rate of oxygen uptake was measured on sections of mature leaf tissue derived from two populations of Lolium perenne L. cv. S23, selected for contrasting rates of mature leaf respiration. Under conditions of sufficient nutrient supply, GL72 had a lower rate of respiration and a greater yield than GL66. The populations were exposed to important management variables to investigate their effect on the selection criterion, the two variables being nutrient supply and defoliation. Conditions of low nutrient supply were characterized by a similarity in respiration rate and a change in the regulation of respiration. Enzyme levels, rather than adenylates, controlled respiration. Weekly cutting induced activity of the otherwise latent alternative pathway.     

Regulation of Respiration in the Leaves and Roots of Two Lolium perenne Populations with Contrasting Mature Leaf Respiration Rates and Crop Yields

Measurements of O₂ uptake were made on leaves and roots of two populations of Lolium perenne L. cv S23 (GL66 and GL72), previously shown to have contrasting rates of CO₂ evolution and yields of dry matter. O₂ uptake was faster in the mature leaves of GL66 than those of GL72, but no difference was observed in the respiratory rates of meristematic leaf bases or mature roots. The growth rate of GL72 was faster than that of GL66. Cyanide resistance was substantial in mature leaves but the alternative path did not contribute to O₂ uptake in the dark. In both populations, adding malate and glycine stimulated O₂ uptake, but exogenous sucrose only stimulated when uncoupler was also present. The difference between the respiratory rates of the two populations was maintained under all investigated conditions. We conclude that the rate of mature leaf respiration in the dark in L. perenne is limited by adenylate control of glycolysis. The difference between the fast (GL66) and slow (GL72) respiring populations reflected a greater respiratory capacity and higher turnover of ATP in GL66. Alternative path capacity was also high in the roots of both and contributed substantially to O₂ uptake, as indicated by inhibition by salicylhydroxamic acid in the absence of KCN. The alternative path capacity of meristematic leaf bases was considerably less than that in mature leaves.

Transverse and cross-sections were made of mature leaves of both populations to study anatomical features which might explain the differences in ATP turnover, suggested by the biochemical experiments. Leaves of GL72 were thicker but did not show a different anatomy when compared with GL66. The increased thickness was not due to more or larger cells but entirely to a larger intercellular volume.

     

Effect of Nitrogen Supply on the Growth and Senescence of Leaves of Lolium perenne with Contrasting Rates of Leaf Respiration

Respiration rates remain high during senescence which is anenergy demanding process. Different rates of senescence mayexplain the contrasting respiration rates of mature leaves oftwo populations of perennial ryegrass cv. S23. This hypothesiswas tested by measuring the lengths of elongating and senescingleaves of plants of two populations (GL72, a slow and GL66,a fast respiring population) for 76 d following the transplantationof the seedlings into soil-filled pots in a growth room. Nitrogenwas supplied at two different rates at the beginning of theexperiment and again at day 36. At high levels of nitrogen supply the slow respiring populationhad a faster elongation rate and so a greater leaf length thanthe fast respiring population. There was no difference betweenthem in the rate of leaf senescence or in the duration of leafgrowth. Consequently, the fast respiring population is consideredprofligate in its use of carbon. By contrast, under low nitrogensupply both elongation and senescence rates were higher in thefast respiring population, although there was no differencein final leaf length. Therefore the longevity of leaves of thefast respiring population was reduced. It is argued that theleaves of the fast respiring population may turn-over mineralsmore rapidly than those of the slow, which may be more advantageousin conditions of low nitrogen supply and offset the benefitsof a more conservative use of carbon normally seen under conditionsof high nitrogen supply. Lolium perenne L., perennial ryegrass cv. S23, nitrogen supply, respiration rate, leaf senescence rate, leaf elongation rate, leaf longevity, population     

Effect of Selection for Dark Respiration Rate of Mature Leaves on Crop Yields of Lolium perenne cv. S23

Growth and nutritive quality of two polycross progeny (GL 83and GL 112) from F₁ plants of Lolium perenne ex cv. S23 showingslow dark respiration rates of mature leaves were compared inthe field with S23 in 3 years. Plots were cut either nine (simulatedgrazing) or five (conservation) times annually. In the firsttrial, sown in 1977, dry matter yields from plots of GL 83 werecompared with S23 during 1978 and 1979. A similar trial sownin 1979 compared GL 83, S23 and GL 112 during 1980. The slowrespiration populations displayed consistently greater (6–13per cent) annual dry matter yields than S23, mostly during midto late summer. In the first trial the difference in yield wasgreater in 1979 than 1978 and more under conservation than simulatedgrazing. In the second trial GL 83 and GL 112 yielded 11 and13 per cent more dry matter than S23 under simulated grazingand 5–6 per cent under conservation. There were no consistentdifferences in dry matter digestibility, water soluble carbohydratesor protein between the populations. Cellulose content of GL83 and to a much lesser extent GL 112, tended to be greaterthan that of S23 from July to September. Analysis of one harvestfrom another trial revealed no significant difference in energyvalue, as measured by adiabatic bomb calorimetry, between GL83 and S23. Thus, it appears that the greater dry matter productionof the progeny with slower mature leaf dark respiration ratesreflected a true increase in total energy yield not apparentlyassociated with any agronomically undesirable characteristics.The general significance of the results for crop improvementare discussed. Lolium perenne L., perennial ryegrass, yield of dry matter, energy value, dry matter digestibility     

Effects of Selection for Dark Respiration Rate on Enzyme Genotypes in Lolium perenne

Two lines of perennial ryegrass (Lolium perenne) that had previouslybeen selected for ‘fast’ and ‘slow’rates of leaf dark respiration were examined to determine whetherselection had differentiated allelic or genotypic frequenciesof five polymorphic enzyme loci, and determine whether respirationrates differed among genotypes. The lines were differentiatedfor genes coding for phosphoglucose isomerase (PGI) and UDP-glucosepyrophosphorylase (UDP). Respiration rates were heterogeneousamong UDP and 6-phosphogluconate dehydrogenase (6PGD) genotypes.Founder effects may have produced the genetic differentiationof lines at the PGI locus as we detected no differences amonggenotypes for respiration rates. The genetic differentiationamong lines for UDP was consistent with differences in darkrespiration among genotypes. Although we detected large differences(75%) in dark respiration rate among 6PGD genotypes in the fastrespiring line, selection did not differentiate the lines atthis locus. Lolium perenne L., perennial ryegrass, enzyme polymorphisms, dark respiration rate     

Genetic differentiation and phenotypic plasticity in Plantago major ssp major. I. The effect of differences in level of irradiance on growth, photosynthesis, respiration and chlorophyll content

Growth, root respiration, photosynthesis, dark respiration, chlorophyll content and chlorophyll alb ratio were followed in two genotypes of Plantago major L. ssp major L., originating from an exposed and a shaded habitat, respectively, at two levels of irradiance. In addition, responses of these processes to a transfer of plants from one light condition to the other were studied. Genetic differentiation between the two genotypes was reflected in growth rate, photosynthetic activity, dark respiration and chlorophyll content. Individuals of the genotype originating from a shaded habitat were less inhibited by low irradiance: growth was less depressed at low irradiance, while the genotype of the exposed habitat seemed to be more restricted to exposed conditions. The adaptive plastic response of growth and physiological parameters upon an alteration in irradiance was very small. The shoot to root ratio was a stable plant characteristic in these experiments. Plants of both genotypes were probably damaged after a transfer from the low to the high level of irradiance; the growth of these plants was not stimulated by high irradiance, and the photosynthetic activity was even decreased. Plants, which were transferred to the low level of irradiance, showed an immediate effect of the change and no adaptive response was observed. Obviously, the ability to perform adaptive plastic responses, which was demonstrated in the non-transferred plants after pretreatment, had been lost during the experiment and was confined to the seedling stage of individuals of the two genotypes.     

Assessing the relationship between respiratory acclimation to the cold and photosystem II redox poise in Arabidopsis thaliana

We examined the effect of manipulating photosystem II (PSII) redox poise on respiratory flux in leaves of Arabidopsis thaliana. Measurements were made on wild-type (WT) plants and npq4 mutant plants deficient in non-photochemical quenching (NPQ). Two experiments were carried out. In the first experiment, WT and mutant warm-grown plants were exposed to three different irradiance regimes [75, 150 and 300 micromol photosynthetically active radiation (PAR)], and leaf dark respiration was measured in conjunction with PSII redox poise. In the second experiment, WT and mutant warm-grown plants were shifted to 5 degrees C and 75, 150 or 300 micromol PAR, and dark respiration was measured alongside PSII redox poise in cold-treated and cold-developed leaves. Despite significant differences in PSII redox poise between genotypes and irradiance treatments, neither genotype nor growth irradiance had any effect upon the rate of respiration in warm-grown, cold-treated or cold-developed leaves. We conclude that changes in PSII redox poise, at least within the range experienced here, have no direct impacts on rates of leaf dark respiration, and that the respiratory cold acclimation response is unrelated to changes in chloroplast redox poise.     

The effect of photoperiod length on respiration in leaves of Saxifraga cernua L., an arctic herb

Abstract Rates of oxygen uptake were measured in leaves of Saxifraga cernua which had been exposed to an 18-h photoperiod. These rates were compared to those in plants which had been exposed to continuous light. Rates of total dark respiration and alternative pathway respiration measured at the end of the photoperiod gradually decreased over the initial 3 d of exposure to an 18-h photoperiod. Thereafter, respiratory rates were constant. Rates of total dark respiration and alternative pathway respiration decreased during the 6h dark period. Rates of normal and alternative pathway respiration are equally affected during the dark period. The respiratory rates had reached a new minimum level 3 d after the initiation of a dark period. These results suggest that respiration rates in arctic plants are high because of the long photoperiod in the arctic. The kinetics of photoperiod induced changes in respiration are slow enough to suggest the involvement of the biological clock in setting respiration rates. Indeed, total dark respiration and alternative pathway respiration show a definite circadian rhythm. Free-running experiments show that normal respiration changes much less (has a smaller amplitude of variation) than alternative pathway respiration and that alternative pathway respiration accounts for most of the rhythmicity of respiration.     

The Growth and Carbon Economy of Selection Lines of Lolium perenne cv. S23 with Differing Rates of Dark Respiration: 2. Grown as Young Plants from Seed

Young plants of two selection lines of Lolium perenne cv. S23with ‘fast’ and ‘slow’ rates of ‘maturetissue’ respiration were individually grown from seed,together with plants of S23, their common parent, in 9.2 cmpots in a controlled environment at 20/15 °C day/night temperatures. No significant differences were found between the genotypesin leaf extension and tiller production during this early stageof their growth. They did differ however, by an average of 26%,in the rate of dark respiration of fully expanded leaf laminae.The use of a simple model demonstrated that such a differencein respiration could alone account for the different rates ofdry matter production shown by the selection lines when grownas young crops from seed. Possible penalties of ‘slow’respiration are also considered. Lolium perenne L., ryegrass, respiration, maintenance respiration, stimulated swards, leaf growth, tiller production, carbon economy     

Variation in leaf respiration in relation to growth and photosynthesis of Lolium

Six Lolium genotypes with contrasting apparent photorespiration and CO_a compensation concentration, [C0₂]_c, were compared for net photosynthesis, dark respiration, leaf starch accumulation, rate of leaf expansion and shoot regrowth. Plants were grown in day/night temperatures of 15/10 and 25/20 ^oC. There were significant (P < 0–05) differences between the genotypes in all these parameters. At 25/20 ^oC apparent photorespiration was correlated with [CO₂]_c. Correlation coefficients, pooled from both temperature regimes, revealed that genotypes with high rates of net photosynthesis accumulated more leaf starch during light periods than genotypes with slow photosynthesis, but rates of leaf expansion and dry matter increase were only correlated, negatively, with dark respiration. Apparent photorespiration was negatively correlated with dark respiration. These findings suggest that attributes related to photorespiration such as [CO₂]_c and O₂ uptake from CO₂-free air in the light are unlikely to be useful selection criteria for growth of C₃ grasses, that net photosynthesis was probably not limiting growth and that maintenance respiration may have been an important determinant of genotypic differences in growth rate. Selections for slow and fast rates of dark respiration of mature leaves were therefore made at 8 and at 25 ^oC from within two different populations of L. perenne, S.23. This characteristic showed repeatabilities (broad-sense heritability) of from 0–41 to o-66. Six independent comparisons of simulated swards of the slow- and fast-respiring selections were made under periodic cutting regimes, either in a growth room at 25 ^oC or in a glasshouse from August to May. Growth of all plots of slow-respiring genotypes was consistently more rapid than that of the fast-respiring, at 25 ^oC in the growth room, and during autumn and spring in the glasshouse. There was no difference in winter growth. The implications of these results for the use of gas exchange measurements as selection criteria in plant breeding programmes are discussed.     

Response of Populations of Lolium perenne cv. S 23 with Contrasting Rates of Dark Respiration to Nitrogen Supply and Defoliation Regime: 1. Grown as Monocultures

Simulated swards of two populations of perennial ryegrass cv.S 23 selected for contrasting rates of mature leaf tissue respirationwere grown in a glasshouse. From establishment, the swards weresubject to three levels of nitrogen supply (14.5, 32 and 173.5ppm N) and from the first harvest 7 weeks after sowing, to threecutting frequencies (at intervals of 1, 3, and 6 weeks). Throughout the 18-week experiment, the herbage yield and themean tiller weight of the slow-respiring population were 10%greater on average than those of the fast-respiring population.Increasing nitrogen supply (from 14.5 to 173.5 ppm N) enhancedthe yield advantage of the slower-respiring population—moreso under infrequent cutting (from nothing to 22%) than underfrequent cutting (from 6 to 13%). Both maximum absolute yields,and the greatest yield advantage of the slow-respiring populationover the fast, were achieved when high nitrogen was combinedwith infrequent defoliation. Lolium perenne, perennial ryegrass cv. S23, respiration, nitrogen defoliation, simulated sward, dry-matter production, monoculture, population     

Direct and acclimatory responses of dark respiration and translocation to temperature

BACKGROUND AND AIMS: Accounting for the acclimation of respiration of plants to temperature remains a major problem in analysis of carbon balances of plants and ecosystems. Translocation of carbohydrates out of leaves in the dark requires energy from respiration. In this study relationships between the responses of leaf respiration and translocation to temperature are examined. METHODS: Direct and acclimatory responses to temperature of respiration and translocation in the dark were investigated in mature leaves of soybean and amaranth. In some cases translocation from leaves was prevented by heat-girdling the phloem in the leaf petiole, or photosynthesis during the previous day was altered. KEY RESULTS: In both species short-term increases in temperature early in the dark period led to exponential increases in rates of respiration. However, respiration rates decreased toward the end of the dark period at higher temperatures. Stopping translocation largely prevented this decrease in respiration, suggesting that the decrease in respiration was due to low availability of substrates. In soybean, translocation also increased with temperature, and both respiration and translocation fully acclimated to temperature. In amaranth, translocation in the dark was independent of temperature, and respiration did not acclimate to temperature. Respiration and translocation rates both decreased with lower photosynthesis during the previous day in the two species. CONCLUSIONS: Substrate supply limited total night-time respiration in both species at high temperatures and following days with low photosynthesis. This resulted in an apparent acclimation of respiration to high temperatures within one night in both species. However, after long-term exposure to different temperatures there was no evidence that lack of substrates limited respiration in either species. In amaranth, respiration did not limit translocation rates over the temperature range of 20-35 degrees C.     

Growth,sugar accumulation,and dark respiration of suspension cell cultures derived from contrasting alfalfa cultivars

Fall dormancy results in decumbent, slow shoot growth of alfalfa (Medicago sativa L.) in autumn and reduced shoot regrowth rates after herbage removal in summer. Although fall dormancy is used to predict alfalfa adaptation, we possess a poor understanding of the biological mechanisms underlying fall dormancy. Our objective was to examine growth and carbohydrate metabolism of suspension cell cultures derived from contrasting alfalfa cultivars that genetically differed in fall dormancy. Suspension cells were grown in B5h media containing 2% sucrose. Cells derived from fall non-dormant plants accumulated sugars more rapidly after transfer to fresh media and to higher concentrations than did cells derived from fall dormant alfalfa cultivars. Dark respiration rates of cells derived from non-dormant plants were similar to those derived from fall dormant plants when growth was limited at low cell sugar concentrations. However, both cell growth and dark respiration rates increased in cells derived from non-dormant cultivars in response to greater cell sugar concentrations. High growth rates of cells derived from rapid growing, fall non-dormant alfalfa cultivars were associated with rapid sugar uptake and higher cell respiration rates when compared to cells derived from dormant alfalfa cultivars.     

Dark Leaf Respiration in Light and Darkness of an Evergreen and a Deciduous Plant Species

Dark respiration in light as well as in dark was estimated for attached leaves of an evergreen (Heteromeles arbutifolia Ait.) and a deciduous (Lepechinia fragans Greene) shrub species using an open gas-exchange system. Dark respiration in light was estimated by the Laisk method. Respiration rates in the dark were always higher than in the light, indicating that light inhibited respiration in both species. The rates of respiration in the dark were higher in the leaves of the deciduous species than in the evergreen species. However, there were no significant differences in respiration rates in light between the species. Thus, the degree of inhibition of respiration by light was greater in the deciduous species (62%) than in the evergreen species (51%). Respiration in both the light and darkness decreased with increasing leaf age. However, because respiration in the light decreased faster with leaf age than respiration in darkness, the degree of inhibition of respiration by light increased with leaf age (from 36% in the youngest leaves to 81% in the mature leaves). This suggests that the rate of dark respiration in the light is related to the rate of biosynthetic processes. Dark respiration in the light decreased with increasing light intensity. Respiration both in the light and in the dark was dependent on leaf temperature. We concluded that respiration in light and respiration in darkness are tightly coupled, with variation in respiration in darkness accounting for more than 60% of the variation in respiration in light. Care must be taken when the relation between respiration in light and respiration in darkness is studied, because the relation varies with species, leaf age, and light intensity.     

Effect of cucumber mosaic virus infection on morphology,yield and phenolic contents of tomato

Ten tomato genotypes were screened for their resistance against cucumber mosaic virus (CMV) and its vector Myzus persicae under natural infection in field, using aphids M. persicae under net-house and mechanical inoculation under greenhouse. Large differences were observed among genotypes for infection percentage (IP) and severity index (SI) among the testing methods used. All genotypes showing tolerance to CMV in the field or through aphid inoculation, however, become susceptible and highly susceptible after mechanical inoculation. All the test genotypes also showed susceptibility to the aphid M. persicae population. Plants inoculated with CMV showed substantial decrease in yield and yield-contributing parameters which varied with cultivars that probably depended upon its genetic make up. All the test genotypes exhibited 0.97–30.19% decrease in plant height, 11.47–52.65% decrease in root length, 46.56–95.56% decrease in fresh plant weight, 65.78–92.84% decrease in root fresh weight, 19.97–87.65% decrease in the dry weight of plants, 75.63–95.43% decrease in dry root weight, 69.51–95.65% reduction in the number of fruits and 89.04–99.89% decrease in yield per plants. After 15 days of inoculation, the quantitative analysis using double beam spectrophotometer showed an increase in total phenolics in CMV-inoculated plants as compared to un-inoculated plants among genotypes. Similarly the thin layer chromatography (TLC) on silica gel G indicated that the number of phenolic compounds was increased in most of the inoculated genotypes while in others they were either decreased or remained same.     

Carbon dioxide exchange rates in soybeans during podfilling as a function of potassium supply

Photosynthetic and dark respiration rates of single leaflets and whole plant canopies were measured during podfilling of soybean plants that were grown under low and high K regimes. Dark respiration rates of detached seed from these plants were also determined during the latter part of seed development. The study was carried out to test the hypothesis that low oil/protein ratios of seed from K-deficient plants resulted from the reduction in carbon availability within the plant, as a result of lower carbon assimilation rates and higher rates of respiratory carbon loss. Photosynthetic rates of upper canopy leaflets during early podfilling were depressed under K deficiency but this effect did not occur with whole plant canopies. In fact, towards the latter part of the podfilling period canopy photosynthetic rates were higher in K-deficient plants as nitrogen was exported earlier from the leaves in high-K plants, resulting in earlier leaf senescence in these plants. The level of K supply had no consistent effect on dark respiration rates of single leaflets or plant canopies, and had no effect on CO₂ evolution rates from detached, developing seed. The findings do not substantiate the hypothesis that reduced photosynthetic efficiency or enhanced respiratory carbon loss are responsible for lower oil/protein ratios in seed from K-deficient soybean plants.     

The effect of phosphorus availability on the carbon economy of contrasting common bean (Phaseolus vulgaris L.) genotypes

A common response to low phosphorus availability is increased relative biomass allocation to roots. The resulting increase in root:shoot ratio presumably enhances phosphorus acquisition, but may also reduce growth rates by diverting carbon to the production of heterotrophic rather than photosynthetic tissues. To assess the importance of increased carbon allocation to roots for the adaptation of plants to low P availability, carbon budgets were constructed for four common bean genotypes with contrasting adaptation to low phosphorus availability in the field ("phosphorus efficiency"). Solid-phase-buffered silica sand provided low (1 microM), medium (10 microM), and high (30 microM) phosphorus availability. Compared to the high phosphorus treatment, plant growth was reduced by 20% by medium phosphorus availability and by more than 90% by low phosphorus availability. Low phosphorus plants utilized a significantly larger fraction of their daytime net carbon assimilation on root respiration (c. 40%) compared to medium and high phosphorus plants (c. 20%). No significant difference was found among genotypes in this respect. Genotypes also had similar rates of P absorption per unit root weight and plant growth per unit of P absorbed. However, P-efficient genotypes allocated a larger fraction of their biomass to root growth, especially under low P conditions. Efficient genotypes had lower rates of root respiration than inefficient genotypes, which enabled them to maintain greater root biomass allocation than inefficient genotypes without increasing overall root carbon costs.