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Changes in the Responses of Leaf Gas Exchange to Temperature and Photosynthesis Model Parameters After a Few Days of Contrasting Temperatures in Four C3 Species in the Field

A peer-reviewed version of this preprint was published in:
Plants 2025, 14(4), 550. https://doi.org/10.3390/plants14040550

Submitted:

09 December 2024

Posted:

10 December 2024

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Abstract
Substantial variation in the temperature dependence of parameters of the Farquhar, von Caemmerer, and Berry C3 photosynthesis model, as well as of in vitro Rubisco kinetic characteristics have been observed in controlled conditions, but have seldom been systematically examined in the field. In this work, A vs. Ci curves were measured over a 15 or 20 oC range of temperatures in four C3 species growing outdoors, on two occasions about three weeks apart during one growing season. The two occasions were chosen for having contrasting temperatures for 3 to 4 days preceding the measurements. Low temperatures (mean maximum/minimum temperatures of 19/11 oC) resulted in higher values of the VCmax of Rubisco and Jmax at a given measurement temperature in most species compared with higher temperatures (max/min 31/25 oC). The apparent activation energy of VCmax of Rubisco ranged from 56 to 82 kJ mol-1, and that of electron transport (Jmax) ranged from 28 to 56 kJ mol-1 across species and prior temperatures. In three of the four species the activation energy of VCmax decreased and that of Jmax increased after the cooler temperatures. Stomatal conductance measured at 20 and 25 oC increased strongly with the prior warm temperatures in all species. Photosynthesis at air levels of CO2 was substantially decreased by the prior warmer temperatures in one species, but little changed in the three other species.
Keywords: 
photosynthesis
;  
temperature
;  
acclimation
;  
Rubisco
;  
C3 metabolism
Subject: 
Biology and Life Sciences  -   Plant Sciences

1. Introduction

The biochemical C3 photosynthesis model developed by Farquhar, von Caemmerer and Berry [1], coupled with empirical stomatal conductance models, is very widely used to describe and predict photosynthesis from the individual leaf level to the global carbon cycle. However, the temperature dependencies generally used in the model [2] were taken from limited data, and new information suggests considerable variation among species and growth temperatures. For example, a recent study of temperature dependent aspects of Rubisco biochemistry measured in vitro in many crop species [3] grown in a single temperature regime indicated substantial variation in several kinetic parameters important to the FvCB photosynthesis model. This suggests that the temperature dependence of parameters of the FvCB model may vary more among species and growth temperatures than is often incorporated into other analyses utilizing the model. This is recognized to be important in global carbon budget models [4,5]
A few in vivo estimates of FvCB model parameters have also indicated changes in the thermal responses of model parameters in response to different growth temperatures [6]. Seasonal variation in the temperature dependence of model parameters has been reported [7,8], although the seasonal variation was not always clearly associated with the temperature regime, and does not occur in all species [9,10]. The review by Hikosaka et al. [11] suggested that the activation energy of the maximum carboxylation capacity of Rubisco (VCmax) generally increased with growth temperature, in contrast with the review by Kattge and Knoor [12], which found no correlation with growth temperature. Work in indoor controlled environment chambers indicated an increase in the activation energy of the maximum carboxylation capacity of Rubisco (VCmax) at higher growth temperatures in collards [13], quinoa [14] and also in two of three soybean cultivars studied [15], but not in wheat or alfalfa [14]. Prins et al. [16] and Sharwood et al. [17] have found substantial variation in the temperature dependence of photosynthetic model parameters in wheat and other grasses. If the temperature dependencies of photosynthetic model parameters often change seasonally, or within a season, in response to temperature changes, this would be important information for users of photosynthesis models. Models of stomatal conductance, which are required for predicting photosynthesis in the field are still entirely empirical, based on photosynthesis, external CO2, and humidity or water vapor pressure deficit [18,19]. How well such models cope with any day-to-day variation in photosynthesis caused by changes in photosynthesis model parameters, or other more direct effects of prior environment is unknown. In this paper the absolute values of the VCmax of Rubsico, Jmax, photosynthesis and stomatal conductance (gs) at air levels of CO2, and the temperature dependencies of VCmax and the maximum photosynthetic electron transport rate (Jmax) were compared after a few days of above normal, and a few days of below normal temperatures within about a three-week period, in four C3 species. The hypothesis was that no differences would be found among measurement days within species in any leaf gas exchange parameters. These experiments relied on the ability to develop complete A vs. Ci curves rapidly (about 5 minutes per leaf at each temperature), using a programmed linear ramping of CO2 [20,21].

2. Results

In all four of these species, assimilation rates measured at 20 to 30 oC at 400 mmol mol-1 CO2 differed with pre-measurement temperature regimes (Figure 1). This contradicts the hypothesis of no differences among the pretreatment conditions. In all four species, assimilation rates measured at 20 oC were higher for plants after cool temperatures than after higher temperatures (Figure 1), but the opposite was true for two species when measured at 25 and 30 oC (Figure 1, Figure 2, Figure 3 and Figure 4).
In contrast to the differences for CO2 assimilation rates among the measurement periods, stomatal conductances at 20 to 30 oC at 400 mmol mol-1 CO2 were lowest after the days with cool temperatures in all four species (Figure 1, Figure 2, Figure 3 and Figure 4). VPD was controlled between 1.0 and 1.5 kPa for all stomatal conductance measurements. In many cases these changes in stomatal conductance between the cool and warm periods exceeded a factor of two between the cool and warm periods at a given measurement temperature (Figure1-4). Because of these large differences in stomatal conductance after the two different ambient temperature periods, the observed differences in assimilation rates did not necessarily reflect differences in photosynthetic biochemistry as assessed by photosynthesis model parameters.
Values of VCmax were higher in all four species at 20 to 30 oC measurement temperatures after the cool temperature period (Figure 1, Figure 2, Figure 3 and Figure 4), sometimes by a factor of two or more. Values of Jmax were also often higher after the cool temperature period (Figure 1, Figure 2, Figure 3 and Figure 4), although the changes in Jmax were in some cases relatively smaller than for VCmax.
The apparent activation energies of VCmax and Jmax also changed with the prior temperature regimes in most species (Figure 5). These responses are presented here as a function of mean maximum temperature of the 3-4 days prior to the measurement, although this is an arbitrary choice, since the controlling temperature feature (e.g maximum, minimum, mean) is not known. There was no significant change in activation energy of VCmax in P. crispum, but an increase with exposure temperature in the other three species (Figure 5). The apparent activation energies of Jmax decreased with exposure temperature in three of the species, with no change in S. lycopersicum (Figure5). Clearly, there was no correlation between the response of the activation energy of VCmax and that of Jmax to prior temperature in any species. Apparent activation energies for VCmax ranged from 56 to 82 kJ mol-1 across species and prior temperatures, and from 28 to 56 kJ mol-1 for Jmax.

4. Discussion

Physiological models serve many purposes, but one major use of the FVCB photosynthesis model has been to allow extrapolation of leaf photosynthesis rates beyond the condition of measurement. Using the photosynthesis model in this way also requires an estimate of stomatal conductance, to provide a value of intercellular CO2 concentration (Ci) for input into the photosynthesis model, but some stomatal conductance models can be solved iteratively with the photosynthesis model. Mesophyll conductance to CO2 movement inside the leaf can be included in the FVCB model, but often is not because of lack of information about mesophyll conductance and its response to environment in a particular application. Generally, the error involved in photosynthesis estimates caused by not including mesophyll conductance is acceptably small. However, it is often assumed that the temperature dependencies of the FVCB model parameters VCmax and Jmax are the same for all species [22]. There is now considerable experimental data to indicate that this assumption is incorrect, at least for VCmax, and that also seems to be the case for Jmax.
The observed variation in the temperature dependencies (summarized as activation energy) of VCmax have very substantial effects on estimates of photosynthetic responses to temperature. As an example, for values of the activation energy of VCmax of 60 and 85 kJ mol-1, the same rate of photosynthesis at Ci = 250 mmol mol-1 at 20 oC would extrapolate to a rate of photosynthesis at 30 oC at Ci = 250 which is 1.4 times higher for the higher value of the activation energy than for the lower value of the activation energy. How rapidly changes in the activation energy of VCmax and Jmax may change with exposure temperature is currently unknown, but a rapid response was apparent in this study. It was found that large changes in activation energies of both VCmax and Jmax could occur after 3 or 4 days of abnormal temperatures.
The trend of increasing activation energy of VCmax with increased growth temperature observed here in three of the four species studied is similar to the pattern found in two cultivars of soybean [15], and also in quinoa [14] and collard [13] grown at controlled temperatures, and in several other species [11]. However, a third cultivar of soybean, and wheat and alfalfa all showed no changes in activation energy of VCmax with growth temperature in the same studies as the other soybean cultivars and the quinoa study. Smith and Dukes [23] found very little change in the temperature dependence of VCmax below 35 oC measurement temperature for species acclimated for seven days to a range of temperatures. I am not aware of other studies reporting responses of the activation energy of Jmax, which limits photosynthesis at high CO2 concentrations, although changes in the optimum temperature of Jmax during temperature acclimation are commonly reported [e.g. 23]. Also, Smith and Dukes [23] showed higher initial slopes of Jmax responses to temperature after acclimation to warm temperatures, although activation energies were not reported. Whittemann et al [24] found no change in the activation energy of either VCmax or Jmax in the range of 15 to 30 oC in four tropical tree species acclimated to different temperatures. Based on the four species examined here and those studied by Smith and Dukes [23], Jmax certainly may respond independently of the response of VCmax, and sometimes oppositely. How Jmax responds to pre-treatment temperature may become increasingly important as the atmospheric CO2 concentration continues to increase and photosynthetic limitation shifts from VCmax to Jmax.
The large range of values of stomatal conductance within each species found in this study are not predictable from the often-used stomatal conductance models [18,19], which relate stomatal conductance directly to photosynthesis, and either directly to relative humidity or inversely to leaf to air water vapor pressure difference. The very large differences in stomatal conductance between the prior temperature regimes observed in all species here fit neither stomatal conductance model. The different patterns of response of stomatal conductance to the pre-treatment temperatures among species studied rule out any systematic measurement errors. While chilling temperatures may sometimes “lock” stomata open, that pattern does not describe the results found here, where prior cool temperatures resulted in lower stomatal conductances at 20 and 25 oC in all species.

5. Materials and Methods

Leaf gas exchange measurements were made on Solanum lycopersicum cv. Big Boy, Cucurbita pepo L. var. recticollis , Petroselinum crispum (Mill.) Fuss, var. neopolitanum, and Lireodendron tulipifera L. The three herbaceous species (C. pepo, P. crispum, and S. lycopersicum) were grown in Annapolis, Maryland in an unshaded plot with a sandy loam soil. There were six plants per species, and three per species were randomly selected for measurement on each measurement date. Plants were grown from seed, with 1 m spacing, planted in April 2021. The plot was fertilized with a complete fertilizer containing 12% N, 4% P, and 8% K at 200g of fertilizer per m2, and did not experience soil water stress. Leaves of three L. tulipifera trees were measured. These plants were about 8 years old, growing on the southern edge of a forested plot in Annapolis Maryland, and received full sunlight about 6 hours per day. The soil was an unfertilized sandy loam.
Air temperatures were obtained from a weather station in an open field at the U.S. Naval Academy, about 3 km from the research site, at the same elevation. Leaf gas exchange data were collected after three or four days of below normal air temperatures, on May 14 and 15, 2021, and after three or four days of above normal air temperatures, on June 7 and 8. The 4-day mean maximum/minimum temperatures for these three periods were 19/11, and 31/25 oC, respectively. For several days before May 11 and between the measurement days, air temperatures were nearly normal for this time of year, with maximum/minimum temperatures averaging 25/18 oC. Three leaves on different plants of S. lycopersicum and C. pepo were measured on a single day, and three leaves on different plants of each of P. crispus and L. tulipifera were measured on the next day.
On each measurement day, recently fully expanded leaves which had been in full sunlight for about an hour were first measured at the lowest leaf temperature to be used (either 15 or 20 oC). 15 oC was used as the initial leaf temperature for the measurements after the period of below normal temperatures, and 20 oC was used as the initial leaf temperature for measurements made after the period of above normal temperatures. These starting leaf temperatures were the lowest that could be obtained, given the ambient temperature and the cooling capacity of the instrument, a Ciras-3 portable photosynthesis system with a PLC3 leaf chamber and lamp (PP Systems, Amesbury, Massachusetts, USA). The leaves measured at the lowest temperature were then labelled and later the same morning measurements were made on the same leaves at 5 and 10 oC warmer leaf temperatures, or at 5, 10 and 15 oC warmer temperatures for those that were first measured at 15 oC. The maximum temperature of measurements was chosen to be 30 oC in order to avoid temperatures which might cause a gradual decrease in photosynthesis over the measurement period. For each leaf, an initial measurement was made of steady-state gas exchange at 400 + 10 mmol mol-1 CO2 and 1500 mmol m-2 s-1 PPFD. At each leaf temperature, the humidity of air entering the leaf chamber was adjusted such that a VPD of 1 to 1.5 kPa occurred at all leaf temperatures. The CO2 concentration was then reduced to 100 mmol mol-1 for two minutes, and then the CO2 concentration was linearly ramped up until leaf assimilation rate no longer increased with CO2, with gas exchange parameters recorded about every 2 s. CO2 saturation of A was reached within 5 minutes of the beginning of ramping, in all leaves. The photosynthetic photon flux density was held at 1500 mmol m-2 s-1 throughout all measurements. Stomatal conductance and VPD did not change substantially during the CO2 ramping in any leaves. Comparison with CO2 differentials for an empty leaf chamber were used to calculate A and Ci values at each CO2 level [18], using the measured gs values. The rapid ramping of CO2 allowed measurements for six leaves on a given day to be completed at least two hours prior to solar noon, thereby avoiding any “mid-day” depression of leaf gas exchange.
For each CO2 response curve, the Sharkey et al. utility [25] was used to estimate, VCmax and Jmax. Because the CO2 response curves started at about 100 mmol mol-1 external CO2, information on the mesophyll conductance and dark respiration were not considered reliable, and were not analyzed. Trisose phosphate utilization rate was calculated, but is not presented, since it has been shown to probably never limit photosynthesis at ambient CO2 [26]. Because both VCmax and Jmax increased approximately exponentially with measurement temperature, activation energies were calculated for both of these model parameters. Activation energies were calculated separately for each leaf from the slope of linear regressions of the reciprocal of VCmax or Jmax on the reciprocal of the absolute temperature [10,12].

Funding

This research received no external funding.

Data Availability Statement

Data are available from the author upon request.

Conflicts of Interest

The author declares no conflicts of interest.

References

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Figure 1. Values of A, gs, VCmax, and Jmax over a range of measurement temperatures for Cucurbita pepo after 3-4 days of exposure to cool temperatures (solid symbols) or warm temperatures (open symbols). Bars indicate SE, for n =3.
Figure 1. Values of A, gs, VCmax, and Jmax over a range of measurement temperatures for Cucurbita pepo after 3-4 days of exposure to cool temperatures (solid symbols) or warm temperatures (open symbols). Bars indicate SE, for n =3.
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Figure 2. Values of A, gs, VCmax, and Jmax over a range of measurement temperatures for Lireodendron tulipifera after 3-4 days of exposure to cool temperatures (solid symbols) or warm temperatures (open symbols). Bars indicate SE, for n =3.
Figure 2. Values of A, gs, VCmax, and Jmax over a range of measurement temperatures for Lireodendron tulipifera after 3-4 days of exposure to cool temperatures (solid symbols) or warm temperatures (open symbols). Bars indicate SE, for n =3.
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Figure 3. Values of A, gs, VCmax, and Jmax over a range of measurement temperatures for Petroselinum crispum after 3-4 days of exposure to cool temperatures (solid symbols) or warm temperatures (open symbols).
Figure 3. Values of A, gs, VCmax, and Jmax over a range of measurement temperatures for Petroselinum crispum after 3-4 days of exposure to cool temperatures (solid symbols) or warm temperatures (open symbols).
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Figure 4. Values of A, gs, VCmax, and Jmax over a range of measurement temperatures for Solanum lycopersicum after 3-4 days of exposure to cool temperatures (solid symbols) or warm temperatures (open symbols). Bars indicate SE, for n =3.
Figure 4. Values of A, gs, VCmax, and Jmax over a range of measurement temperatures for Solanum lycopersicum after 3-4 days of exposure to cool temperatures (solid symbols) or warm temperatures (open symbols). Bars indicate SE, for n =3.
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Figure 5. Activation energies (Ea) for VCmax and Jmax calculated over the range of 15 or 20 to 30 oC for four species after 3-4 days of exposure to cool temperatures or warm temperatures. Species were S. lycopersicum (S.l.), C. pepo (C.p.), P. crispum (P,c,) and L. tulipifera (L.t.).
Figure 5. Activation energies (Ea) for VCmax and Jmax calculated over the range of 15 or 20 to 30 oC for four species after 3-4 days of exposure to cool temperatures or warm temperatures. Species were S. lycopersicum (S.l.), C. pepo (C.p.), P. crispum (P,c,) and L. tulipifera (L.t.).
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