Discrimination in the Dark. Resolving the Interplay between Metabolic and Physical Constraints to Phosphoenolpyruvate Carboxylase Activity during the Crassulacean Acid Metabolism Cycle

doi:10.1104/pp.106.088302

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Discrimination in the Dark. Resolving the Interplay between Metabolic and Physical Constraints to Phosphoenolpyruvate Carboxylase Activity during the Crassulacean Acid Metabolism Cycle¹

Howard Griffiths^*, Asaph B. Cousins, Murray R. Badger and Susanne von Caemmerer

Physiological Ecology Group, Department of Plant Sciences, University of Cambridge, Cambridge CB2 3EA, United Kingdom (H.G.); Molecular Plant Physiology Group (H.G., A.B.C., M.R.B., S.v.C.) and Australian Research Council Center of Excellence, Plant Energy Biology (M.R.B.), Research School of Biological Sciences, Australian National University, Canberra, Australian Capital Territory, 2601 Australia

ABSTRACT

TOP
ABSTRACT
THEORY
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

A model defining carbon isotope discrimination ( ${Delta}$ ¹³C) for crassulaceanacid metabolism (CAM) plants was experimentally validated usingKalanchoe daigremontiana. Simultaneous measurements of gas exchangeand instantaneous CO₂ discrimination (for ¹³C and ¹⁸O) weremade from late photoperiod (phase IV of CAM), throughout thedark period (phase I), and into the light (phase II). Measurementsof CO₂ response curves throughout the dark period revealed changingphosphoenolpyruvate carboxylase (PEPC) capacity. These systematicchanges in PEPC capacity were tracked by net CO₂ uptake, stomatalconductance, and online ${Delta}$ ¹³C signal; all declined at the startof the dark period, then increased to a maximum 2 h before dawn.Measurements of ${Delta}$ ¹³C were higher than predicted from the ratioof intercellular to external CO₂ (p_i/p_a) and fractionation associatedwith CO₂ hydration and PEPC carboxylations alone, such thatthe dark period mesophyll conductance, g_i, was 0.044 mol m^–2s^–1 bar^–1. A higher estimate of g_i (0.085 mol m^–2s^–1 bar^–1) was needed to account for the modeledand measured ${Delta}$ ¹⁸O discrimination throughout the dark period.The differences in estimates of g_i from the two isotope measurements,and an offset of –5.5 ${per thousand}$ between the ¹⁸O content of sourceand transpired water, suggest spatial variations in either CO₂diffusion path length and/or carbonic anhydrase activity, eitherwithin individual cells or across a succulent leaf. Our measurementssupport the model predictions to show that internal CO₂ diffusionlimitations within CAM leaves increase ${Delta}$ ¹³C discrimination duringnighttime CO₂ fixation while reducing ${Delta}$ ¹³C during phase IV. Whenevaluating the phylogenetic distribution of CAM, carbon isotopecomposition will reflect these diffusive limitations as wellas relative contributions from C₃ and C₄ biochemistry.

The metabolic and ecological plasticity associated with thecrassulacean acid metabolism (CAM) cycle has allowed the useof stable isotopes both to define the occurrence of the CAMpathway (Bender et al., 1973

; Osmond et al., 1973

) and to investigatethe interplay between activities of Rubisco (by day) and nocturnalphosphoenolpyruvate carboxylase (PEPC; O'Leary and Osmond, 1980

;Griffiths et al., 1990

; Dodd et al., 2003

). The phases of CAM,as defined by Osmond (1978)

, include phase I, when nocturnaluptake of CO₂ is mediated exclusively by PEPC, and phase III,when Rubisco operates with stomata closed in the light and CO₂is regenerated from malic acid. There are also two transientphases showing the switch between the major carboxylases, oneearly in the light period prior to stomatal closure (phase II)and the other in the late afternoon, when assimilation of atmosphericCO₂ initially occurs directly via Rubisco (phase IV). The carbonisotope signal of organic material is traditionally thoughtto reflect the balance between the magnitude of these four phases(Osmond, 1978

; Pierce et al., 2002a

; Winter and Holtum, 2002

During phase I of CAM, the fractionation of carbon isotopesduring CO₂ fixation was shown to reflect both photosyntheticbiochemistry and fractionation during diffusion of CO₂ throughstomata, as shown by comparing the isotopic composition of theC4 carbon in malate with that of atmospheric CO₂ (O'Leary andOsmond, 1980; Farquhar et al., 1982; Holtum et al., 1983; Deleenset al., 1985). Although PEPC operates without the company ofRubisco at night (in contrast to C₄ plants by day), the isotopiccomposition of malate was more depleted in ¹³C than could bepredicted from the model of discrimination proposed by O'Learyand Osmond (1980), which accounted for isotope fractionationby diffusion in air, CO₂ hydration, and PEPC carboxylation.Holtum et al. (1983) also noted that carbon isotope discrimination( ${Delta}$ ¹³C) was higher than predicted from gas exchange ratios ofinternal to external CO₂ partial pressure (p_i/p_a) and hypothesizedthat the differences might be due to a number of factors, includingadditional diffusion limitation in the liquid phase. Similarresults have been observed during real-time measurements of ${Delta}$ ¹³C concurrently with gas exchange in phase I (O'Leary et al.,1986; Griffiths et al., 1990; Griffiths, 1992; Borland et al.,1993; Roberts et al., 1997, 1998).

The initial model of discrimination during CAM was also usedto account for the activity of carbonic anhydrase (CA) in contrastingCAM plants (Holtum et al., 1984). The activity of CA was initiallythought to limit certain CAM plants, such as Kalanchoe daigremontiana(Tsuzuki et al., 1982). However, Holtum et al. (1984) elegantlyused the exchange of isotopically enriched ¹⁸O during the CA-catalyzedhydration of CO₂ to show that K. daigremontiana has a 40-foldexcess of CA activity relative to PEPC, inferring that therewould be little influence of the CO₂ hydration on ${Delta}$ ¹³C. Subsequently,the recognition that gas exchange measurements can be used todefine the flux of ¹²CO₂, while the ¹³C composition can be solvedfor specific fractionation effects, has allowed more detailedgas exchange and isotope discrimination models for C₃ and C₄plants to be developed. These have been based on CO₂ draw downand the sum of discrete fractionations across boundary layer,stomata, cell wall, and internal diffusion to carboxylation,as well as accounting for the effects of (photo) respiratoryfractionations and bundle sheath leakage for C₄ (Farquhar etal., 1982; Farquhar, 1983). For CAM plants, the integrated ¹³Cisotope signal was suggested from a theoretical model (Farquharet al., 1989) or derived directly from the proportional contributionof PEPC and Rubisco signals to isotope discrimination duringgas exchange (Griffiths et al., 1990). To date, however, nosystematic approach to modeling the changes in extent of discriminationduring specific phases of CAM has been undertaken, to our knowledge.

The recent development of a direct, real-time mass spectrometricsystem allows concurrent measurements of CO₂ uptake and ${Delta}$ ¹³Cto be made at rapid time intervals (Cousins et al., 2006a).It has also been possible to measure, in parallel, the extentof ¹⁸O discrimination, which has been used to determine boththe extent of CA equilibration and real-time evaporative fractionationduring transpiration. The extent of ¹⁸O enrichment can be measuredindirectly in CO₂ exchanging with tissue water and retrodiffusingfrom the leaf and directly in the evaporated water vapor signal(Cousins et al., 2006b). In this study, we have used the constitutiveCAM plant K. daigremontiana to measure online ¹³C and ¹⁸O discriminationthroughout the dark period, as compared to the transitionalphases II and IV. Our study was framed by the paucity of dataon the extent of nighttime (phase I) ${Delta}$ ¹³C and concomitant measurementsof p_i/p_a and the need to develop a comprehensive model to reconcileinstantaneous and organic carbon isotope signals in CAM plants(Griffiths, 1992; Roberts et al., 1997). To do this, we havedeveloped a quantitative model for ${Delta}$ ¹³C during the CAM cycle,which allows for a systematic analysis of the overall determinantsof the integrated ¹³C signal seen in the tissues of CAM plants.By analogy with the C₃ system (Evans et al., 1986), we showthat fractionation factors during nighttime CO₂ uptake for CAMreflect both biochemical and internal constraints of diffusionacross cell walls and mesophyll cytosol, leading to ${Delta}$ ¹³C varyingwith photosynthetic rate in addition to p_i/p_a. Thus, changesin PEPC carboxylation capacity (perhaps mediated by changingactivation by PEPC kinase; Dodd et al., 2003), which we demonstratefrom a series of CO₂ response curves, are important determinantsof nocturnal ${Delta}$ ¹³C. We also show that the ¹³C and ¹⁸O signalsin CO₂ allow different components of the mesophyll conductance(g_i) to be resolved, reflecting diffusive path lengths withincells and leaves.

Recently, there has been a resurgence of interest in using carbonisotopes to explore the potential contribution that CAM makesto organic material, as well as in determining the phylogeneticorigins of CAM within an array of families (e.g. Pierce et al.,2002b; Holtum and Winter, 2003; Crayn et al., 2004). The agreementbetween modeled and measured ${Delta}$ ¹³C values suggests that leaf internalCO₂ diffusion characteristics (influenced by leaf anatomy) determinethe draw down of CO₂ from intercellular airspace to sites ofPEPC (or Rubisco) carboxylations. When used to survey populationsfor CAM, carbon isotope composition should be considered toreflect both the proportion of C₃ and C₄ carboxylation as wellas the extent of internal diffusive limitations.

THEORY

TOP
ABSTRACT
THEORY
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Model of ${Delta}$ ¹³C during CAM Photosynthesis

The model was developed around the likely fractionations associatedwith the four phases of the CAM cycle described in the introductionand is designed to be used in the analysis of short-term measurementsof ${Delta}$ ¹³C during CO₂ uptake. The discrimination of the naturallyoccurring isotopes of carbon (¹²C and ¹³C) in the process ofphotosynthesis is influenced by environmental and biochemicalfactors (Vogel, 1980; O'Leary, 1981). Theory developed by Farquharet al. (1982) and Farquhar (1983) showed that net fractionationby C₃ and C₄ photosynthesis can be described by an equationhaving diffusion and biochemistry-dependent terms.

The overall isotope effect during carbon fixation in leavesin general is:

Formula 1 (1)
whereR_a, R_m, and R_p are the molar abundance ratios (¹³C to ¹²C) ofthe carbon in the atmosphere at the site of mesophyll carboxylationand of the carbon fixed. The symbols p_l, p_i, and p_m denote leafsurface, intercellular, and mesophyll CO₂ partial pressures(pCO₂). The symbol a_b is the fractionation occurring duringdiffusion in the boundary layer (2.9 x 10^–3), a is thefractionation during diffusion in air (4.4 x 10^–3), b_sis the fractionation as CO₂ enters solution (1.1 x 10^–3),and a_l is the fractionation occurring during diffusion in water(0.7 x 10^–3; Farquhar et al., 1982).

The magnitude of the isotope effects generally exceeds unityby a small amount only, so following (Farquhar and Richards,1984), our results are generally expressed as the discriminationor fractionation, ${Delta}$ , where

Formula 2 (2)

The derivation of the isotope effect, R_a/R_p, for CAM is similarto the derivations of R_a/R_p for C₃ and C₄ species outlined byFarquhar et al. (1982) and Farquhar (1983), and the same argumentsare followed using the ${Delta}$ notation.

If the boundary layer conductance is large, it is convenientto contract Formula 2 in Equation 1to , where

Formula 3 (3)
such that

Formula 4 (4)

Equation 4 can be rewritten in the ${Delta}$ notation by subtracting1 from both sides, such that

Formula 5 (5)
where

Formula 6 (6)
and ${Delta}$ _bio, the integrated net biochemicaldiscrimination, depends on the biochemistry of net CO₂ uptake,with expressions for the four phases of the CAM cycle givenbelow.

The p_m is dependent on the net CO₂ assimilation rate, A, andthe conductance to CO₂ diffusion from the intercellular airspaceto the site of carboxylation, g_i, where

Formula 7 (7)

It is useful to substitute Formula 7 for p_m in Equation 5, then

Formula 8 (8)

The influence of the internal diffusion conductance on ${Delta}$ ¹³C canbe calculated from the measured ${Delta}$ as

Formula 9 (9)
where ${Delta}$ _i is the carbon isotope predicted wheng_i is infinite.

${Delta}$ ¹³C during CAM photosynthesis has been used as a diagnostictool to estimate the biochemical fractionation. Equation 8 canalso be solved for ${Delta}$ _bio and

Formula 10 (10)

The Biochemical Fractionation, ${Delta}$ _bio, during CAM Photosynthesis

Assimilation rate during CAM photosynthesis can be written asa general equation

Formula 11 (11)
whereV_p and V_c are the rates of PEPC and Rubisco carboxylation, respectively,and F is the rate of photorespiration, M the rate of mitochondrialrespiration, and V_D is the rate of malate decarboxylation. Followingthe scheme of CAM photosynthesis outlined in Figure 1 , weused Equation 11 to derive a general expression for ${Delta}$ _bio of CAMphotosynthesis (described in "Materials and Methods"):

Formula 12 (12)
where and b₃ (29 ${per thousand}$ ; Roeske and O'Leary, 1984) and b₄are the fractionations associated with Rubisco carboxylationand the combined fractionation of CO₂ hydration and PEP carboxylation.The fractionation factor b₄ is temperature dependent becauseof the temperature dependence of the hydration and dehydrationreaction, which is given by

Formula 13 (13)
ifCA is in excess (Mook et al., 1974; Henderson et al., 1992;Cousins et al., 2006a).

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Figure 1. A diagram showing the major factors that determine ${Delta}$ ¹³C during CO₂ exchange in CAM species during the four phases of the CAM cycle according to Equations 5 and 12. The terms p_a, p_i, and p_m are the partial pressures of CO₂ in the atmosphere, the intercellular airspace, and in the mesophyll cells. PCR and PCO refer to the photosynthetic carbon reduction and oxygenation cycles, respectively. The associated fractionation factors are shown by lowercase letters and are described in the "Theory" section.

The fractionation factor f for photorespiration has been estimatedto be about 8 ${per thousand}$ (Ghashghaie et al., 2003

). The fractionation factorse and d could be intrinsic fractionations occurring during respirationand decarboxylation but could also be variable describing thefact the substrate being respired or decarboxylated has a differentisotope composition, R_p' to the current photosynthate, R_p (i.e. Formula 13

). Such a change in internal source CO₂ could be particularly important for malate decarboxylation,as the value of the fractionation factor d for malate decarboxylationis uncertain. The carbon being decarboxylated has the isotopicsignature of the previous dark period photosynthetic discriminationwith an added discrimination factor because of the fumaraserandomization of the ¹³C signal in C1 and C4 of malate (Osmondet al., 1988

). Deleens et al. (1985)

noted that the decarboxylationof malate is known to show a large fractionation (near 30 ${per thousand}$ ) butpointed out that if the release of malate from the vacuole isthe limiting step, this large fractionation would not be expressed,which was supported by their experimental data.

Equation 12 will differ for the different phases of CAM as indicatedin Figure 1. For example, during phase I, in the dark period,the fixation of inorganic carbon is mediated by cytosolic PEPC,with HCO₃^– substrate replenished by CA, and V_c, V_D, andF will be 0 and x = 1, such that

Formula 14 (14)

Phase II and IV represent transitional stages. In phase II,after-dawn PEPC is usually rapidly down-regulated, and the activityof Rubisco progressively increases in the light (Griffiths etal., 1990; Dodd et al., 2002). The extent of phase IV dependson water and light availability and primarily represents thedirect fixation of CO₂ by Rubisco, although PEPC may contributetoward the end of the light period (Griffiths et al., 1990).In both these phases, A can be described by Equation 11 and ${Delta}$ _bio by Equation 12 with the possibility that V_D = 0. In theearly part of phase IV, the equation is the one typical forC₃ photosynthesis, when V_D = 0 and PEPC carboxylation has notyet started (x = 0).

Formula 15 (15)

In phase III, the decarboxylation phase, stomata close as highlevels of internal CO₂ are regenerated from malic acid and highRubisco catalytic activities prevent excessive leakage of CO₂(Griffiths et al., 2002) and V_p = 0 (x = 0).

Formula 16 (16)
although F will be close to zero if internalpCO₂ is high. This equation is not particularly useful, becauseit is difficult, if not impossible, to make online measurementsof ${Delta}$ ¹³C during this phase when stomata are closed.

${Delta}$ ¹³C during Phase III from Malate to Fixed Carbon

The equations presented above are useful for the interpretationof measurements of online ${Delta}$ ¹³C. To help interpret the integratedsignal of dry matter ${Delta}$ ¹³C, the discrimination occurring in thesteps of malate decarboxylation and refixation by Rubisco needto be considered. In this case, we use an expression for theratio R_p'/R_p, where R_p' is the ¹³C/¹²C ratio of the malate fixedin the previous dark period and R_p that carbon fixed by Rubisco.Using the equation

Formula 17 (17)
whereL = g p_m is the leak rate of CO₂ out of the leaf, it can beshown that

Formula 18 (18)

Both photorespiration and CO₂ diffusion into the leaf have beenassumed to be negligible because of high internal pCO₂. Thisequation is similar to the one derived by Farquhar et al. (1989),where d and e were assumed to be 0. Similar to the case of Rubiscoin the bundle sheath of C₄ species, Rubisco fractionation canonly occur if there is some leakage of the decarboxylated CO₂.If there is no CO₂ leakage out of the leaf, the other potentialinfluence on dry matter carbon isotope composition, other thansecondary fractionations during remobilization and export, isthe fractionation associated with malate decarboxylation, suchas fumarase randomization of malate (as discussed above) orfractionation associated with respiration. If Formula 18 is the discrimination during the C₄ fixationin phase I, then gives the overall discrimination occurring to carbon initially fixedby PEPC.

RESULTS

TOP
ABSTRACT
THEORY
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Dark Period PEPC and Stomatal Responses to CO₂

CO₂ response curves of A to intercellular pCO₂ (A/p_i curves)were conducted from early evening (phase IV), throughout thedark period (phase I), and into the light (phase II) on differentleaves for three successive nights, having programmed the gasexchange system to undertake a CO₂ response curve every 2 h.Data are plotted as five representative, individual A/p_i curvesfrom a single leaf (Fig. 2A ), with the associated stomatalconductance (g_s) responses to p_i shown in Figure 2B. First,we note that in the light periods, A/p_i are typical for a C₃system, with a high CO₂ compensation point and a photosyntheticrate of around 25 µmol m^–2 s^–1 at high p_i(Fig. 2A; 19:00 h, 08:25 h). Second, the maximum assimilationcapacity of PEPC, as well as the maximum g_s, changed throughoutthe dark period (Fig. 2, A and B). The PEPC A/p_i response (Fig. 2A)and g_s (Fig. 2B) declined early in the dark period, then increaseduntil 2 h before dawn before again decreasing. It is interestingto note that although the maximum conductance varies, stomataare responsive to CO₂ concentration at all times in the lightand the dark. To explore change in the kinetic parameters ofPEPC in more detail for all of the leaves measured at each 2-htime interval, we plotted the initial slope of the A/p_i responsesand maximum assimilation rate (A_max) values (respectively, inFig. 3, A and B ) throughout the light-dark measurement cycle.The initial slope and A_max show a similar pattern, showing astatistically significant increase from the middle of the darkperiod. Most importantly, there was a linear relationship betweenthe initial slope and A_max during the dark period (see insetto Fig. 3A), suggesting changes in maximal activity of PEPC(V_pmax) and a role for changing PEPC capacity in regulatingnet assimilation through the night.

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Figure 2. Net CO₂ uptake (A) and g_s responses as a function of changing pCO₂ measured from late afternoon (phase IV) and throughout the dark period (phase I) and into the light (phase II; B). Representative data are plotted as individual response curves for one leaf at selected intervals during the dark period. Gas exchange measurements were made at an irradiance of 300 µmol quanta m^–2 s^–1 in the light period, with day/night temperatures of 25°C/20°C and a pCO₂ varied against a background gas mixture of 909 mbar nitrogen and 48 mbar of O₂.

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Figure 3. Initial slope of A/p_i response (A) and variation in A_max measured every 2 h from late afternoon (phase IV) and throughout the dark period (phase I) and into the light (phase II; B). Data are plotted as mean ± SEM for three replicate leaves, with inset in A showing the relationship between initial slope and A_max, with experimental details in the Figure 1 legend. Different letters indicate significant differences between plants at P < 0.05.

Gas Exchange and ${Delta}$ ¹³C

The continuous tracking of gas exchange characteristics wasalso undertaken for late phase IV, throughout the dark period,and into phase II in conjunction with the online mass spectrometricdeterminations (Fig. 4 ). The measurements, initially startedin the light, show that A, g_s, and p_i/p_a decline at the startof the dark period (Fig. 4, A–C), with A then graduallyrecovering over the next 6 h of the dark period. We note thatp_i/p_a does not immediately decline during the early part ofthe dark period, although the large relative variation in thisdata set was due to one replicate leaf showing higher conductanceearly in the dark period (Fig. 4C). Toward the middle and endof the dark period, p_i/p_a was much more tightly coupled to g_sand A, reaching a minimum 2 h before dawn, coincident with maximumA and g_s. These continuous measurements reflect the changingactivation state of PEPC, determined from the CO₂ response datashown in Figure 2.

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Figure 4. A, Net A. B, g_s. C, p_i/p_a measured from late afternoon (phase IV) and throughout the dark period (phase I) and into the light (phase II), with data (±SEM) for three replicate leaves from plants of K. daigremontiana maintained in a controlled-environment chamber on a reverse light/dark cycle. Gas exchange measurements were made at an irradiance of 300 µmol quanta m^–2 s^–1 in the light period, with day/night temperatures of 25°C/20°C and an inlet pCO₂ of 531 µbar in 909 mbar of nitrogen and 48 mbar of O₂ gas mixture.

${Delta}$ ¹³C, measured by the mass spectrometer simultaneously duringgas exchange (Fig. 5 ), showed typically high values in thelight when Rubisco is largely operating in the absence of PEPC(Griffiths et al., 1990

; Dodd et al., 2002

). There was a progressiveincrease in measured ${Delta}$ ¹³C throughout the dark period, with valueslowest (around 0%) when g_s was maximal at the start of the darkperiod (Figs. 4B and 5) and reaching a maximum of around 5.5 ${per thousand}$ at the end of the dark period (Fig. 5). The data of A and p_i/p_awere used in Equation 9 to calculate a mean g_i = 0.044 mol m^–2s^–1 bar^–1 (Fig. 5, dashed line). When using an infiniteg_i (effectively using p_i/p_a), predicted ${Delta}$ ¹³C values were consistently2 ${per thousand}$ to 3 ${per thousand}$ lower than measured data (Fig. 5, continuous line).

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Figure 5. ${Delta}$ ¹³C measured in association with gas exchange from late afternoon (phase IV) and throughout the dark period (phase I) and into the light period (phase II), with data (white circles, ±SEM) for three replicate leaves from plants of K. daigremontiana maintained in a controlled-environment chamber on a reverse light/dark cycle. Predicted ${Delta}$ ¹³C for the dark period (phase I) determined from the model developed in this article (see "Theory" section for details); dashed line is modeled ${Delta}$ ¹³C including correction for the draw down from substomatal cavity to cytoplasm calculated with g_i = 0.044 mol m^–2 s^–1 bar^–1 with Equation 8 and 14 b₄ = 6.27 ${per thousand}$ at a leaf temperature of 20°C; continuous line is modeled ${Delta}$ ¹³C using infinite g_i (effectively using p_i/p_a) to parameterize the model.

Transpiration, Evaporative Enrichment, and Determinants of ${Delta}$ C¹⁸OO

The constraints to PEPC activity in the dark (Figs. 2 and 3)will reflect the balance between the likely physical (wall andg_i) and biochemical (PEPC and CA activities) determinants. Toderive these components from the ¹⁸O signals in CO₂ and transpiredwater, we first considered how transpiration rate and leaf-to-airvapor pressure difference (VPD) responded between light anddark cycles, as modified by stomatal responses during the darkperiod (Fig. 6, A and B ; see also Fig. 4B). These factorscontribute to the derivation of ${delta}$ _e, the isotopic compositionof water at the site of evaporation calculated from the Craig-Gordon(Eq. 20 in "Materials and Methods") and are required for theinterpretation of ¹⁸O in CO₂. The higher transpiration rateand conductance in the light when leaf temperatures were higherare entirely consistent with the lower evaporative enrichmentseen in ${delta}$ _e during the late afternoon phase IV (Fig. 6C). Throughoutmost of the dark period, VPD was at steady state, and so theslight increase in conductance from the middle of the dark period(Fig. 4B) resulted in a slight but progressive decrease in ${delta}$ _e.As maximum CO₂ assimilation declined from 2 h before dawn (Fig. 4A), ${delta}$ _e then increased, driven by the increase in VPD at that time(Fig. 6, B and C). During phase II, the relatively low g_s andtranspiration rates (Figs. 4B and 6B) resulted in a relativelyconstant ${delta}$ _e (Fig. 6C). However, we note that the predicted ${delta}$ _eis always higher than the ¹⁸O isotope composition measured directlyin transpired water vapor ( ${delta}$ _t), which was trapped at 2-h intervalsthroughout the dark period (Fig. 6C).

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Figure 6. A, Transpiration rate. B, Leaf to air VPD. C, The ¹⁸O isotopic composition of ${delta}$ _t and at the ${delta}$ _e calculated from the Craig-Gordon model (Eq. 18), measured from late afternoon (phase IV) and throughout the dark period (phase I) and into the light (phase II) with data (±SEM) for three replicate leaves from plants of K. daigremontiana that had been maintained in a controlled-environment chamber on a reverse light/dark cycle. The source water used for irrigation of plants had an isotopic composition of ${delta}$ ¹⁸O_VSMOW = –5.5 ${per thousand}$ .

The predicted evaporative site enrichment, ${delta}$ _e, is needed forthe comparison with measured values of oxygen isotope discrimination( ${Delta}$ ¹⁸O; Fig. 7 ). The latter values are measured by the massspectrometer in the air flow downstream of the leaf cuvetteon CO₂, which has retrodiffused from the leaf (Farquhar andCernusak, 2005

). The CO₂ has first equilibrated with the cell-water¹⁸O signal, catalyzed by the action of CA. It is interestingthat ${Delta}$ ¹⁸O increases sharply at the start of the dark period (Fig. 7;around 50 ${per thousand}$ ) when it is strongly regulated by g_s; the wide variationin discrimination values is entirely consistent with the rangeof p_i/p_a calculated from gas exchange (Fig. 4, B and C). WhenPEPC activity reaches a maximum toward the end of the dark period(Figs. 2 and 3), ${Delta}$ ¹⁸O values are lower (around 20 ${per thousand}$ ) and more tightlyconstrained (Fig. 7), consistent with g_s and evaporation rateat this time (Figs. 4B and 6A).

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Figure 7. ${Delta}$ ¹⁸O measured in CO₂ and in association with gas exchange, from late afternoon (phase IV) and throughout the dark period (phase I) and into the light period (phase II), with data (white circles, ± SEM) for three replicate leaves from plants of K. daigremontiana maintained in a controlled-environment chamber on a reverse light/dark cycle.

The values of ${Delta}$ ¹⁸O increased with p_i/p_a and p_m/p_a, as predictedfrom Equation 23 ("Materials and Methods"; Fig. 8 ). The twomodeled curves in each part of Figure 8 relate the predictedisotopic discrimination when in equilibrium with either sourcewater ( ${delta}$ _s, –5.5 ${per thousand}$ ± 0.3 ${per thousand}$ versus the Vienna StandardMean Oceanic Water [VSMOW] standard, dotted line) or measured ${delta}$ _t (mean measured value, –12.2 ${per thousand}$ ± 1.1 ${per thousand}$ ; see individualdata in Fig. 6C), showing that the impact of changing between ${delta}$ _s and ${delta}$ _t on each plot is relatively minor. The measured valueswere always lower than predicted for full isotopic equilibrium,with an assumed constant ${Delta}$ _ea of 45 ${per thousand}$ or 51 ${per thousand}$ for either ${delta}$ _t or ${delta}$ _s values,respectively, when used in Equation 23 with an infinite walland cytoplasmic conductance assumed (i.e. there is no draw downfrom p_i to p_m; Fig. 8A). The offset in ${Delta}$ ¹⁸O as a function ofmesophyll pCO₂ depended on the magnitude of the wall conductanceand cytoplasmic g_i used to calculate p_m for Equation 23 ("Materialsand Methods"; Fig. 8, A–C). Measurements made in boththe light and the dark show a much better fit when the walland cytoplasmic g_i is estimated as 0.085 mol m^–2 s^–1bar^–1 (Fig. 8B), whereas the lower internal conductance,which provided a good predictor of ${Delta}$ ¹³C (0.044 mol m^–2s^–1 bar^–1), overestimated the ${Delta}$ ¹⁸O signal acrossthe board (Fig. 8C).

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Figure 8. ${Delta}$ ¹⁸O as a function of p_i/p_a (A) and p_m/p_a (B and C). In A, no correction was made for g_i, whereas in B and C, p_m was derived by assuming a g_i of 0.0.85 or 0.044 mol m^–2 s^–1 bar, respectively. The lines are not fitted to the data but represent the theoretical relationship of ${Delta}$ ¹⁸O and p_i/p_a or p_m/p_a at full isotopic equilibrium, where a = 7.7 ${per thousand}$ and ${Delta}$ _ea = 45 ${per thousand}$ or 51 ${per thousand}$ using either the average ${delta}$ _t or ${delta}$ _s values, respectively, in Equation 24. The value of g_i = 0.085 in B was estimated from minimizing the variance between measured and theoretical ${Delta}$ ¹⁸O calculated with the average ${delta}$ _t. The CO₂ supplied to the leaf had a ${Delta}$ ¹⁸O of 24 ${per thousand}$ relative to VSMOW. Data points in each section represent the individual samples collected during light (white circles) and dark (black circles) from three replicate leaves of K. daigremontiana (for details, see Figs. 2 and 5, legends above).

	DISCUSSION

TOP ABSTRACT THEORY RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

${Delta}$ ¹³C by the CAM pathway has traditionally been used to partitionthe extent of C₃ and C₄ carboxylation during the contrastingphases of CAM (Osmond, 1978

; Griffiths et al., 1990

; Griffiths,1992

; Roberts et al., 1997

). A lack of consistency between theoreticaland measured ${Delta}$ ¹³C suggested a need to reevaluate these approaches(Griffiths, 1992

) and was highlighted by the difficulties ofinferring the proportion of CAM species in various plant communitiesfrom carbon isotope composition (Pierce et al., 2002a

; Holtumand Winter, 2003

). In this study, we derived a model to evaluateinstantaneous measurements of ${Delta}$ ¹³C in the contrasting CAM phasesbased on biochemical and diffusional constraints to carboxylationfor both Rubisco and PEPC. Experimentally, we have focused oncarbon uptake during the dark period to explore the actual variationsin ${Delta}$ ¹³C in relation to the theoretical predictions from the model.

The interplay between g_s and PEPC activity were previously shownto regulate inorganic carbon supply, CA activity, and metabolicpartitioning in determining carbon isotope composition of malatesynthesized in the dark period (O'Leary and Osmond, 1980; Holtumet al., 1984; Osmond et al., 1988; Kalt et al., 1990). The opportunityto couple a gas exchange system directly to a mass spectrometerallowed us to explore instantaneous discrimination against ¹³Cduring the dark period. Concomitant measurements of ¹⁸O discriminationin CO₂ were used to highlight the internal diffusive constraintsto Rubisco and PEPC carboxylation (in chloroplast and cytoplasm,respectively) and the potential interplay between CA activity,evaporation, and leaf water turnover (for the analogy with C₄pathway see Cousins et al., 2006a, 2006b). For online gas exchangeand mass spectrometric measurements, partial pressures of CO₂and O₂ were typical for those used to optimize the system inprevious studies (Cousins et al., 2006a, 2006b).

Gas Exchange and PEPC Carboxylation Capacity during the Dark Period

The systematic changes in A during the dark period were associatedwith changes in PEPC carboxylation capacity (Figs. 2–5 ).Continuous measurements of gas exchange throughout the darkperiod, as well as the individual A/p_i responses and the correlationbetween initial slope and A_max, confirm this observation. Inparticular, it seemed that PEPC activity was driving assimilation,because proportionally, there was a more modest stomatal responsethroughout the middle of the dark period, when p_i/p_a declinedto a minimum (Fig. 4).

One question remains, however, as to the nature of the regulationunderlying the shifts in PEPC capacity and A_max seen in ourdata. The low CO₂ assimilation at the start of the dark period(Fig. 4), and subsequent recovery during the middle of the night,was tracked by catalytic capacity of PEPC (Figs. 2 and 3). Thisis consistent with the need to activate PEPC via PEPC kinaseas malic acid accumulates, because high malic acid concentrationsare likely to inhibit PEPC (Nimmo et al., 2001; Dodd et al.,2002), and PEPC kinase expression tends to occur rather latein the dark period in K. daigremontiana (Borland and Griffiths,1997).

g_i and Determinants of Instantaneous ${Delta}$ ¹³C at Night

Previously, estimates of carbon isotope composition have inferredthe extent of daytime (Rubisco) and nighttime PEPC carboxylation,together with the varying contribution during phases II andIV, to overall organic material (Osmond, 1978; Griffiths, 1992;Roberts et al., 1997). Estimates of ${Delta}$ ¹³C for PEPC (without thecompany of Rubisco, as in C₄ plants) have resulted in measured ${delta}$ ¹³C for newly fixed C in malate closer to theoretical predictionsfrom p_i/p_a (Holtum et al., 1984; Deleens et al., 1985; Robertset al., 1997). By including conductance for CO₂ diffusion fromintercellular airspace to the cytosol (g_i), the model presentedin this article provides a more effective representation of ${Delta}$ ¹³C during the CAM cycle, particularly across the dark period.Experimentally, by tracking gas exchange and real-time ${Delta}$ ¹³C throughoutthe dark period with measurable g_s (Figs. 2 and 4), we couldderive mesophyll limitations, which proved to dominate overall ${Delta}$ ¹³C.

Diffusion limitation from intercellular airspace to the chloroplaststroma was shown to reduce ${Delta}$ ¹³C in C₃ species (see Eq. 8; Evanset al., 1986) This is because the large value of ${Delta}$ _bio, whichis the result of a large Rubisco fractionation, is temperedby the diffusive draw down to carboxylation site. In C₄ species,the internal CO₂ diffusion limitation has very little influenceon ${Delta}$ ¹³C, because the ${Delta}$ _bio is close to 0 as the fractionation associatedwith Rubisco counter balances the fractionation associated withthe hydration and PEPC carboxylation of CO₂. Our theory showsthat the internal diffusion limitation in CAM species can leadto a decrease in discrimination during phase II and IV, whereRubisco is active and stomata are open, but will increase discriminationduring nighttime PEPC carboxylation. In our experiments, leaftemperatures were 20°C and ${Delta}$ _bio = –6.27 ${per thousand}$ , and we couldpartition approximately 3.5 ${per thousand}$ to the internal diffusion limitationat high assimilation rates. The mean value for the g_i to PEPCderived from our measurements of ${Delta}$ ¹³C during the dark phase broughtconvergence between measured and modeled ${Delta}$ ¹³C throughout thenight (Fig. 5; 0.044 mol m^–2 s^–1 bar^–1). Thisvalue will be important for modeling the isotopic correlatesof the C₄ pathway. In Figure 9 , we show that, depending onassimilation rate, as the value of the g_i decreases, there isa predictable increase in ${Delta}$ ¹³C with values of 6 ${per thousand}$ to 8 ${per thousand}$ potentiallyassociated with PEPC activity alone when constrained internallyby CO₂ diffusion. Accurate estimates of g_i are also importantif online measurements of ${Delta}$ ¹³C are to be used to partition CO₂uptake between Rubisco and PEPC carboxylations in phase II andIV. A low g_i will decrease ${Delta}$ ¹³C during these phases, and if nottaken into account, the contribution from PEPC is overestimated(see Eqs. 10 and 12).

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Figure 9. Modeled predictions (Eqs. 8 and 14) of ${Delta}$ ¹³C for two contrasting assimilation rates and a p_i/p_a = 0.45 using b₄ = 6.27 ${per thousand}$ at a leaf temperature of 20°C plotted as a function of varying g_i during phase I.

The model provides a consistent explanation for the rather highvalues of ${Delta}$ ¹³C often found in many constitutive CAM plants, whichhave traditionally been used to infer the contribution fromdaytime Rubisco processes. One remaining question, however,relates to the effective path length through which CO₂ diffusesto PEPC, which maybe distinguishable by the offset of cytoplasmicdiffusion and effective wall conductance as determined by ${Delta}$ ¹³Cand ${Delta}$ ¹⁸O seen in retrodiffusing CO₂.

Evaporation, Isotopic Exchange, and CA Equilibrium at Night

The ${Delta}$ ¹⁸O data provided an additional insight into diffusionalconstraints to CO₂ fixation during the dark period. The ¹⁸Oin CO₂ exchanging across the leaf surface, carrying the adoptedevaporative signal, was primarily controlled by g_s (compareFig. 7 with Fig. 4, B and C) unlike ${Delta}$ ¹³C (Fig. 5). However, aswell as providing the extent of evaporative enrichment in relationto the exchange of CO₂, the ¹⁸O signal can be used to inferthe extent of CA equilibration (Cousins et al., 2006b). It isintriguing that we needed to use a higher value of g_m to model¹⁸O exchange, and in general terms, the ${Delta}$ ¹⁸O signal clearly trackedp_i/p_a. While ${Delta}$ ¹³C was somewhat independent of p_i/p_a early inthe dark period, a lower value g_i was needed throughout, perhapsimplying that PEPC is limited for CO₂/HCO₃ supply deep withincells or succulent tissues or perhaps that there is spatialvariation in CA distribution and activity (Cousins et al., 2006a,2006b). In contrast, the ¹⁸O signal of CO₂ could reflect thosesites closer to airspaces that are in evaporative equilibrium.Finally, the –5.5 ${per thousand}$ offset between ${delta}$ _s and ${delta}$ _t (measured directly;Fig. 6) implied that evaporated water is not in equilibriumwith source water, which occurs during isotopic steady state.This may be due to the large capacitance of succulent leaves(Smith et al., 1987) or the isotopic exchange of the water vaporsignal that can occur at high humidities (Farquhar and Cernusak,2005). While this is extremely important for CAM plants andtheir nocturnal stomatal opening under natural conditions (Hellikerand Griffiths, 2007), it was precluded by our measurements atlow ambient humidity.

Implications for Carbon Isotope Signals in Natural Vegetation

The model of ${Delta}$ ¹³C presented in this article can account for muchhigher values of discrimination than are normally associatedwith dark CO₂ uptake and fixation by PEPC during the CAM cycle(Fig. 9). Previously, low values of ${Delta}$ ¹³C have been associatedwith CO₂ uptake only at night or the C4 of malate accumulatedduring the dark period (Nalborczyk et al., 1975; Deleens etal., 1985). In the Clusiaceae, a rather unusual family of hemiepiphyticstranglers that show a range of CAM characteristics (Borlandet al., 1993; Roberts et al., 1998), measured instantaneousvalues of online ${Delta}$ ¹³C were extremely low (–4 ${per thousand}$ to –6 ${per thousand}$ )under high g_s (with p_i/p_a of 0.7 and above; Roberts et al.,1997). Why, then, are measured ${Delta}$ ¹³C values in organic materialso consistently higher than these measurements might predict?Holtum et al. (1984) invoked a number of responses, includingthe rate of dark respiration and refixation (accounted for inour model by Eq. 18). Rubisco operating in the light can leadto substantial fractionation being expressed, but on a smallproportion of CO₂ in phase III (Griffiths et al., 1990), orcan contribute significantly to carbon gain and productivityduring phase IV (Borland and Dodd, 2002; Dodd et al., 2002),which would lead to higher overall ${Delta}$ ¹³C in organic material.However, in this article, we have shown that the internal diffusionconstraints from intercellular airspace to mesophyll cytosolincrease ${Delta}$ ¹³C throughout the dark period in K. daigremontiana(Figs. 5 and 9) compared to the discrimination that would bepredicted from the PEPC-mediated ${Delta}$ ¹³C alone. This will help theunderstanding of observed organic material signals.

Thus, the data presented in this article go some way to explainingtwo phenomena that arise when evaluating the distribution ofCAM from ${Delta}$ ¹³C measurements of entire plant populations. First,even plants fully committed to dark CO₂ fixation can show relativelyhigh ${Delta}$ ¹³C values because of internal constraints to diffusionduring the dark phase (Pierce et al., 2002a; Holtum and Winter,2003). Second, variations in ${Delta}$ ¹³C have traditionally been thoughtto be dominated by the extent of direct Rubisco carboxylationduring phases II and IV. We have now shown that internal constraintsto diffusion can both decrease Rubisco-mediated discriminationin phases II and IV and increase PEPC-mediated discriminationin phase I, with both responses tending to stabilize organicmaterial isotope signals and values tending to be intermediatebetween C₃ and CAM ranges. This may be one of the reasons whyorganic ${Delta}$ ¹³C signals tend to be relatively constant across awide range of habitats, as noted in a number of field studiesand experimental manipulations (Griffiths et al., 1986; Griffiths,1992).

MATERIALS AND METHODS

TOP
ABSTRACT
THEORY
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Growth Conditions

Kalanchoe daigremontiana plants were grown from vegetative plantlets,with material initially grown during the summer months in aglass house under natural light conditions (27°C day and18°C night temperatures). Two weeks prior to experimentation,plants were acclimated within two controlled-environment, walk-ingrowth rooms under a photosynthetic photon flux density of 300µmol quanta m^–2 s^–1 at plant height and airtemperature of 25°C during the day and 18°C at nightwith a photoperiod of 12 h/d. One of the rooms was set to rununder a reverse light/dark cycle to provide plant material forreal-time isotope determinations for periods immediately before,during, and after the dark period. Plants were grown in 5-Lpots in garden mix with 2.4 to 4.0 g Osmocote/L soil (15:4.8:10.8:1.2N:P:K:Mg + trace elements: B, Cu, Fe, Mn, Mo, Zn; Scotts Australia)and watered daily.

Online Gas Exchange Measurements

The uppermost fully expanded leaves were placed into the leafchamber of the LI-6400 2 h prior to the dark period and allowedto acclimate at 300 µmol photons m^–2 s^–1,25°C leaf temperature, and a pCO₂ of 531 µbar for1 h. The pCO₂ was elevated to reflect conditions in the growthfacility. Subsequently, one to three online measurements (seebelow) were made prior to changing to the corresponding nighttimeconditions (0 µmol photons m^–2 s^–1, 20°Cleaf temperature, and pCO₂ of 531 µbar). Throughout thenight period, online measurements were made approximately every20 min as described below. In coordination with the plants'day/night cycle, after the 12-h dark period, the leaf cuvettewas returned to the corresponding daytime conditions, and severalmore measurements were made prior to stomatal closure.

Air entering the leaf chamber was prepared by using mass flowcontrollers (MKS Instruments) to obtain a gas mix of 909 mbardry N₂ and 48 mbar O₂ (Cousins et al., 2006a, 2006b). A portionof the nitrogen/oxygen air was used to zero the mass spectrometerto correct for N₂O and other contaminates contributing to the44, 45, and 46 peaks. Pure CO₂ ( ${delta}$ ¹³C_VPDB = –29 ${per thousand}$ , and ${delta}$ ¹⁸O_VSMOW= 24 ${per thousand}$ ) was added to the remaining air stream to obtain a pCO₂of approximately 531 µbar. Low oxygen (48 mbar) was usedto minimize contamination of the 46 (mass-to-charge ratio [m/z])signal caused by the interaction of O₂ and N₂ to produce NO₂with the mass spectrometer source and also to minimize the biologicalimpact of secondary fractionations due to photorespiration duringdaytime gas exchange.

The gas mixtures were fed to the inlet of the LI-6400 console,and a flow rate of 200 µmol s^–1 was maintained overthe leaf. The remaining air stream was vented or used to determinethe isotopic composition of air entering the leaf chamber (Cousinset al., 2006a, 2006b). The efflux from the leaf chamber wasmeasured by replacing the match valve line with a line connecteddirectly to the mass spectrometer. Gas exchange parameters weredetermined by the LI-6400, and pCO₂ leaving the chamber wassubsequently corrected for the dilution of CO₂ by water vapor(von Caemmerer and Farquhar, 1981).

The efflux from the leaf chamber and the gas mix supplied tothe LI-6400 system were linked to a mass spectrometer throughan ethanol/dry ice water trap and a thin, gas-permeable siliconemembrane that was housed in a temperature-controlled cuvette.Initially, the masses (m/z) 44 and 45 were monitored continuously,and the ${Delta}$ ¹³C during CO₂ exchange was calculated from the ratioof mass 45 to 44 in the reference air, determined before andafter each sample measurement, entering the chamber (R_e) andthe composition of the sample air leaving the leaf chamber (R_o),as described in (Evans et al., 1986):

Formula 19 (19)
where ${xi}$ = p_e/(p_e – p_o), and p_e and p_oare the pCO₂ of dry air entering and leaving the leaf chamber,respectively. At the end of the ${Delta}$ ¹³C measurements, the acceleratingvoltage of the mass spectrometer was adjusted to continuouslymonitor masses (m/z) 44 and 46 to determine the ${Delta}$ ¹⁸O, as describedabove. Zero values for the 44, 45, and 46 peaks were determinedbefore and after the sample measurements were subtracted fromboth the sample and reference measurements prior to determiningthe mass ratios.

CO₂ Response Curves

Using the same background air stream as above, the LI-6400 gasexchange system was programmed (using the 6400-01 CO₂ injector)to run eight automated A/p_i curves (measured as A and g_s asa function of increasing p_a, external pCO₂) before (1x), during(6x), and after (1x) the dark period. The leaf was maintainedat steady-state conditions (300 µmol photons m^–2s^–1, 25°C leaf temperature, and a pCO₂ of 383 µbaror 0 µmol quanta m^–2 s^–1, 20°C leaf temperature,and pCO₂ of 383 µbar) for 1 h before the initiation ofeach A/p_i curve. The A/p_i curves were measured from low to highpCO₂ at the leaf temperature and photon flux density correspondingto the appropriate times in relation to the growth conditions.Measurement of an A/p_i curve took approximately 35 min.

Collection and ¹⁸O Isotopic Measurements of Water Vapor

A line connected directly to the exhaust port of the LI-6400was used to cryogenically trap transpired water in a modifiedglass collection line submerged in an ethanol-dry ice bath,as described in detail by Cousins et al. (2006b). Water vaporwas collected for 1 to 2 h before (1x), during (6x), and after(1x) the dark period. Because of the low volumes collected (usuallyless than 50 µL of water), the water was transferred fromthe collection tubes via a cryogenic trapping line in a streamof dry N₂ gas and subsequently sealed with a gas torch undervacuum in 6-mm-o.d. silica glass vials attached via a Cajonultra-torr fitting. The glass vials were subsequently scored,and where possible, 25 µL of liquid water was removedwith a gas tight microsyringe (SGE) and injected into 10-mLhead space vials with crimped tops containing butyl septa (Alltech),which had been previously flushed with 20 mbar CO₂ (in a N₂background) at atmospheric pressure levels (Cousins et al.,2006b). Water and CO₂ samples were left to equilibrate at roomtemperature for 48 h.

Prior to the isotopic measurements, the vials were placed fora minimum of 2.5 h on a temperature block set at 25°C. TheCO₂ samples were analyzed by injecting 200 µL of the headspacegas into a 500-µL N₂ purged, gas tight, temperature-controlledcuvette containing a Teflon gas permeable membrane linked tothe ISOPRIME mass spectrometer (Cousins et al., 2006b). Masses44 and 46 were monitored continuously, and the zero values,determined before and after the sample measurements, were subtractedfrom the values prior to determining the mass ratios. The zerovalues were typically 3% to 4% of the 44 and 46 peak. Two standardlaboratory waters were measured during each measurement to calibrateour measured values against known standards (Cousins et al.,2006b). Our standard waters (S1 = –6.44 ${per thousand}$ and S2 = –22.83 ${per thousand}$ as compared to the international VSMOW standard at 0 ${per thousand}$ ) were calibratedby the Stable Isotope Facilities in the Earth Environment Groupwithin the Research School of Earth Sciences at The AustralianNational University. The measured ${delta}$ ¹⁸O value was corrected forthe contribution of oxygen from the CO₂ used for equilibrationand normalized against VSMOW, as described in Cousins et al.(2006b; see also Scrimgeour, 1995). The precision of analyses,based on the repeated measurements of gas samples sealed invials, was 0.1 ${per thousand}$ (1 SD, n = 8).

Water at the Site of Evaporation and ${Delta}$ ¹⁸O

The ${delta}$ ¹⁸O of water at the sites of evaporation within a leaf ( ${delta}$ _e)can be estimated from the Craig and Gordon model of evaporativeenrichment (Craig and Gordon, 1965; Farquhar and Lloyd, 1993):

Formula 20 (20)
where e_a and e_i are the vaporpressures in the atmosphere and the leaf intercellular spaces. ${delta}$ _a is the isotopic composition of water vapor in the air. Thekinetic fractionation during diffusion of water from leaf intercellularair spaces to the atmosphere ( ${varepsilon}$ _k) can be calculated as in Cernusaket al. (2004):

(21)
wherer_s and r_b are the stomatal and boundary layer resistance, and32 and 21 are the fractionation factors in parts per mille.The equilibrium fractionation between liquid water and watervapor ( ${varepsilon}$ ⁺) is calculated as in Cernusak et al. (2004):

(22)
where T is leaf temperature in degreesKelvin. Under steady-state conditions, the value of ${delta}$ _t is equalto the isotopic composition of ${delta}$ _s, the water taken up by theplant (Harwood et al., 1998).

Discrimination against C¹⁸OO ( ${Delta}$ ¹⁸O) when water at the site ofexchange and CO₂ are at full isotopic equilibrium ( ${theta}$ = 1) canbe predicted (Farquhar and Lloyd, 1993) as:

Formula 23 (23)
where a is the diffusional discrimination(7.7 ${per thousand}$ ) and ${varepsilon}$ is calculated as p_m/(p_a – p_m). The ¹⁸O enrichmentof CO₂ compared to the atmosphere at the site of exchange infull oxygen isotope equilibrium with the water was calculatedas in Cernusak et al. (2004):

Formula 24 (24)
where the equilibrium fractionation between waterand CO₂ ( ${varepsilon}$ _w) can be calculated as in Cernusak et al. (2004):

(25)
where T is leaf temperature in degreesKelvin.

Derivation of an Expression for the Biochemical Fractionation, ${Delta}$ _bio, during CAM Photosynthesis

Assimilation rate during CAM photosynthesis can be written asa general equation

Formula 26 (26)

In phase I:

Formula 27 (27)
Inphase II and IV:

Formula 28 (28)
Inphase III:

Formula 29 (29)

Equation 26 can also be written for the assimilation of ¹³CO₂

Formula 30 (30)
and

Formula 31 (31)

Formula 32 (32)

Formula 33 (33)

Formula 34 (34)

Formula 35 (35)
and

Formula 36 (36)

The various fractionation factors have been defined in the theorysection. Using Equations 26 and 30 to 36, it can be shown that:

Formula 37 (37)
and

Formula 38 (38)

Using the fact that 1/(1 + x) approximately (1 – x) whenx < 1, Equation 38 can be rearranged such that

Formula 39 (39)
if

Formula 40 (40)

Dividing numerator and denominator by V_c + V_p gives

Formula 41 (41)

Multiplying out and ignoring small terms, one can derive thegeneral expression for ${Delta}$ _bio:

Formula 42 (42)
andthis is Equation 12 in the "Theory" section.

To derive the expression for the discrimination that occursbetween malate decarboxylation and Rubisco refixation in phaseIII, one uses Equation 17 and

Formula 43 (43)
substituting for V_c using Equation 17, dividingboth sides of Equation 43 by R_p, and using the fact that V_c'= V_cR_p and R_m/R_p = (1 + b₃) and rearranging gives

Formula 44 (44)
where ${phi}$ = L/V_D = g_sp_m/V_D is thefraction of CO₂ decarboxylated that leaks out of the leaf.

Statistical Analysis

ANOVA was conducted using repeated measures ANOVA in STATISTICA(version 6.0 StatSoft) on the measurements made during the darkperiod. Fisher LSD test was used for post hoc comparisons.

ACKNOWLEDGMENTS

We thank Chin Wong for helpful advice on collecting transpiredwater, Hillary Stuart for analyzing the oxygen isotope compositionof our CO₂ tank, and Graham Farquhar for his support and helpfuldiscussions.

Received August 14, 2006; accepted November 8, 2006; published December 1, 2006.

FOOTNOTES

¹ This work was supported by the Molecular Plant Physiology andEnvironmental Biology Groups at the Research School of BiologicalSciences, Australian National University (visiting fellowshipto H.G.), and by the National Science Foundation (internationalpostdoctoral fellowship to A.B.C.).

The author responsible for distribution of materials integralto the findings presented in this article in accordance withthe policy described in the Instructions for Authors (www.plantphysiol.org)is: Howard Griffiths (hg230{at}cam.ac.uk).

www.plantphysiol.org/cgi/doi/10.1104/pp.106.088302

^{^*} Corresponding author; e-mail hg230{at}cam.ac.uk; fax 44–1223–333953.

LITERATURE CITED

TOP
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RESULTS
DISCUSSION
MATERIALS AND METHODS
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