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1. Leaf nitrogen affects photosynthesis and water use efficiency similarly in nitrogen‐fixing and non‐fixing trees

   https://doi.org/10.1111/1365-2745.14194  

   Bytnerowicz, Thomas A. ; Funk, Jennifer L. ; Menge, Duncan N. L. ; Perakis, Steven S. ; Wolf, Amelia A. ( September 2023 , Journal of Ecology)

   Nitrogen (N)‐fixing trees are thought to break a basic rule of leaf economics: higher leaf N concentrations do not translate into higher rates of carbon assimilation. Understanding how leaf N affects photosynthesis and water use efficiency (WUE) in this ecologically important group is critical.

   We grew six N‐fixing and four non‐fixing tree species for 4–5 years at four fertilization treatments in field experiments in temperate and tropical regions to assess how functional type (N fixer vs. non‐fixer) and N limitation affected leaf N and how leaf N affected light‐saturated photosynthesis (A_sat), stomatal conductance (g_sw) and WUE (WUE_iand δ¹³C).

   A_sat, WUE_iand δ¹³C, but notg_sw, increased with higher leaf N. Surprisingly, N‐fixing and non‐fixing trees displayed similar scaling between leaf N and these physiological variables, and this finding was supported by reanalysis of a global dataset. N fixers generally had higher leaf N than non‐fixers, even when non‐fixers were not N‐limited at the leaf level. Leaf‐level N limitation did not alter the relationship ofA_sat,g_sw, WUE_iand δ¹³C with leaf N, although it did affect the photosynthetic N use efficiency. Higher WUE was associated with higher productivity, whereas higherA_satwas not.

   Synthesis: The ecological success of N‐fixing trees depends on the effect of leaf N on carbon gain and water loss. Using a field fertilization experiment and reanalysis of a global dataset, we show that high leaf‐level photosynthesis and WUE in N fixers stems from their higher average leaf N, rather than a difference between N fixers and non‐fixers in the scaling of photosynthesis and WUE with leaf N. By clarifying the mechanism by which N fixers achieve and benefit from high WUE, our results further the understanding of global N fixer distributions.

    

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2. Nitrogen fixation responds to soil nitrogen at low but not high light in two invasive understory species

   https://doi.org/10.1111/1365-2745.14071  

   Schmidt, Colleen B. ; Funk, Jennifer L. ; Wolf, Amelia A. ; Akana, Palani R. ; Palmer, Matthew I. ; Menge, Duncan N. L. ( February 2023 , Journal of Ecology)

   Light and soil nitrogen availability can be strong controls of plant nitrogen (N) fixation, but data on how understory N‐fixing plants respond to these drivers are limited despite their important role in ecosystem N cycling. Furthermore, ecosystem N cycling can be altered by the introduction of species with nutrient use patterns that differ from natives. We assessed how N fixation of two exotic, understory species responded to varying light and soil N environments.

   We sampled leaf tissue fromMimosa pudicaL.,Desmodium triflorum(L.) DC., and a nonfixing reference plant (Axonopus) growing in control and two N fertilization treatments under either N‐fixing or non‐N‐fixing trees, which may alter local soil nutrient cycling, across a range of light conditions. We measured N fixation with¹⁵N isotope dilution, and ensured that N‐fixing neighbour trees were in fact fixing N. All understory plants were wild‐growing species not native to the study location.

   DesmodiumandMimosaacquired 82.6% and 71.6% of their nitrogen from fixation (%N_dfa) in the control, compared to 66.8% and 58.1% in the +10 g N m⁻² year⁻¹treatment and 73.1% and 64.7% in the +15 g N m⁻² year⁻¹treatment. These subtle %N_dfadifferences across fertilization treatments were more apparent at low light availability and disappeared at high light availability. The amount of N fixed by neighbouring trees did not influence %N_dfain the understory species.

   Synthesis. Our study shows some differences in N fixation across different nutrient environments at low light for two N‐fixing species, though the changes were small, and both species derived most of their N from fixation. These findings imply that introduced N‐fixing species could exacerbate ecosystem N enrichment, particularly under high soil N conditions.

    

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3. Climate warming alters photosynthetic responses to elevated CO 2 in prairie plants

   https://doi.org/10.1002/ajb2.1532  

   Sage, Emma ; Heisler‐White, Jana ; Morgan, Jack ; Pendall, Elise ; Williams, David G. ( September 2020 , American Journal of Botany)

   The impact of elevated CO₂concentration ([CO₂]) and climate warming on plant productivity in dryland ecosystems is influenced strongly by soil moisture availability. We predicted that the influence of warming on the stimulation of photosynthesis by elevated [CO₂] in prairie plants would operate primarily through direct and indirect effects on soil water.

   We measured light‐saturated photosynthesis (A_net), stomatal conductance (g_s), maximum Rubisco carboxylation rate (V_cmax), maximum electron transport capacity (J_max) and related variables in four C₃plant species in the Prairie Heating and CO₂Enrichment (PHACE) experiment in southeastern Wyoming. Measurements were conducted over two growing seasons that differed in the amount of precipitation and soil moisture content.

   A_netin the C₃subshrubArtemisia frigidaand the C₃forbSphaeralcea coccineawas stimulated by elevated [CO₂] under ambient and warmed temperature treatments. Warming by itself reducedA_netin all species during the dry year, but stimulated photosynthesis inS. coccineain the wet year. In contrast,A_netin the C₃grassPascopyrum smithiiwas not stimulated by elevated [CO₂] or warming under wet or dry conditions. Photosynthetic downregulation under elevated [CO₂] in this species countered the potential stimulatory effect under improved water relations. Warming also reduced the magnitude of CO₂‐induced down‐regulation in this grass, possibly by sustaining high levels of carbon utilization.

   Direct and indirect effects of elevated [CO₂] and warming on soil water was an overriding factor influencing patterns ofA_netin this semi‐arid temperate grassland, emphasizing the important role of water relations in driving grassland responses to global change.

    

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4. Patterns of physical, chemical, and metabolic characteristics of sugar maple leaves with depth in the crown and in response to nitrogen and phosphorus addition

   https://doi.org/10.1093/treephys/tpad043  

   Young, Alexander R. ; Minocha, Rakesh ; Long, Stephanie ; Drake, John E. ; Yanai, Ruth D. ; Mock, ed., Hans-Peter ( April 2023 , Tree Physiology)

   Few previous studies have described the patterns of leaf characteristics in response to nutrient availability and depth in the crown. Sugar maple has been studied for both sensitivity to light, as a shade-tolerant species, and sensitivity to soil nutrient availability, as a species in decline due to acid rain. To explore leaf characteristics from the top to bottom of the canopy, we collected leaves along a vertical gradient within mature sugar maple crowns in a full-factorial nitrogen (N) by phosphorus (P) addition experiment in three forest stands in central New Hampshire, USA. Thirty-two of the 44 leaf characteristics had significant relationships with depth in the crown, with the effect of depth in the crown strongest for leaf area, photosynthetic pigments and polyamines. Nitrogen addition had a strong impact on the concentration of foliar N, chlorophyll, carotenoids, alanine and glutamate. For several other elements and amino acids, N addition changed patterns with depth in the crown. Phosphorus addition increased foliar P and boron (B); it also caused a steeper increase of P and B with depth in the crown. Since most of these leaf characteristics play a direct or indirect role in photosynthesis, metabolic regulation or cell division, studies that ignore the vertical gradient may not accurately represent whole-canopy performance.

    

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5. Photosynthetic modulation during the diurnal cycle in a unicellular diazotrophic cyanobacterium grown under nitrogen-replete and nitrogen-fixing conditions

   https://doi.org/10.1038/s41598-022-21829-6  

   Liberton, Michelle ; Biswas, Sandeep ; Pakrasi, Himadri B. ( November 2022 , Scientific Reports)

   Cyanobacteria are the only oxygenic photosynthetic organisms that can fix nitrogen. In diazotrophic cyanobacteria, the regulation of photosynthesis during the diurnal cycle is hypothesized to be linked with nitrogen fixation and involve the D1 protein isoform PsbA4. The amount of bioavailable nitrogen has a major impact on productivity in aqueous environments. In contrast to low- or nitrogen-fixing (−N) conditions, little data on photosynthetic regulation under nitrogen-replete (+ N) conditions are available. We compared the regulation of photosynthesis under −N and + N conditions during the diurnal cycle in wild type and apsbA4deletion strain of the unicellular diazotrophic cyanobacteriumCyanothecesp. ATCC 51142. We observed common changes to light harvesting and photosynthetic electron transport during the dark in + N and −N conditions and found that these modifications occur in both diazotrophic and non-diazotrophic cyanobacteria. Nitrogen availability increased PSII titer when cells transitioned from dark to light and promoted growth. Under −N conditions, deletion of PsbA4 modified charge recombination in dark and regulation of PSII titer during dark to light transition. We conclude that darkness impacts the acceptor-side modifications to PSII and photosynthetic electron transport in cyanobacteria independently of the nitrogen-fixing status and the presence of PsbA4.

    

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