Your search keyword '"Juan C. Baca Cabrera"' showing total 2 results

1. Atmospheric CO 2 and VPD alter the diel oscillation of leaf elongation in perennial ryegrass: compensation of hydraulic limitation by stored‐growth

Author

Jianjun Zhu, Hans Schnyder, Juan C. Baca Cabrera, Rudi Schäufele, and Regina T. Hirl

Subjects

0106 biological sciences, 0301 basic medicine, Stomatal conductance, Perennial plant, Physiology, Chemistry, Vapour Pressure Deficit, fungi, Turgor pressure, food and beverages, Plant Science, 01 natural sciences, ddc, 03 medical and health sciences, Horticulture, 030104 developmental biology, Osmotic pressure, Elongation, Diel vertical migration, 010606 plant biology & botany, Transpiration

Abstract

We explored the effects of atmospheric CO2 concentration (Ca ) and vapor pressure deficit (VPD) on putative mechanisms controlling leaf elongation in perennial ryegrass. Plants were grown in stands at a Ca of 200, 400 or 800 μmol mol-1 combined with high (1.17 kPa) or low (0.59 kPa) VPD during the 16 h-day in well-watered conditions with reduced nitrogen supply. We measured day : night-variation of leaf elongation rate (LERday : LERnight ), final leaf length and width, epidermal cell number and length, stomatal conductance, transpiration, leaf water potential and water-soluble carbohydrates and osmotic potential in the leaf growth-and-differentiation zone (LGDZ). Daily mean LER or morphometric parameters did not differ between treatments, but LERnight strongly exceeded LERday , particularly at low Ca and high VPD. Across treatments LERday was negatively related to transpiration (R2 = 0.75) and leaf water potential (R2 = 0.81), while LERnight was independent of leaf water potential or turgor. Enhancement of LERnight over LERday was proportional to the turgor-change between day and night (R2 = 0.93). LGDZ sugar concentration was high throughout diel cycles, providing no evidence of source limitation in any treatment. Our data indicate a mechanism of diel cycling between daytime hydraulic and night-time stored-growth controls of LER, buffering Ca and daytime VPD effects on leaf elongation.

Published

2019

2. Temperature‐sensitive biochemical 18 O‐fractionation and humidity‐dependent attenuation factor are needed to predict δ 18 O of cellulose from leaf water in a grassland ecosystem

Author

Jianjun Zhu, Juan C. Baca Cabrera, Inga Schleip, Lisa Wingate, Ulrike Ostler, Jérôme Ogée, Hans Schnyder, Rudi Schäufele, Regina T. Hirl, Technische Universität Munchen - Université Technique de Munich [Munich, Allemagne] (TUM), Interactions Sol Plante Atmosphère (UMR ISPA), Ecole Nationale Supérieure des Sciences Agronomiques de Bordeaux-Aquitaine (Bordeaux Sciences Agro)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), and Karlsruher Institut für Technologie (KIT)

Subjects

0106 biological sciences, 0301 basic medicine, Materials science, Physiology, isotope‐enabled soil–vegetation–atmosphere transfer model (MuSICA), perennial ryegrass (Lolium perenne), Analytical chemistry, enrichment of cellulose oxygen isotope composition of cellulose, Plant Science, Leaf water, Fractionation, relative humidity, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, vegetation&#8211, enabled soil&#8211, isotope&#8208, Attenuation factor, ddc:550, Relative humidity, Cellulose, relative humidity temperature, 2. Zero hunger, Humidity, food and beverages, temperature, 18O‐enrichment of cellulose oxygen isotope composition of cellulose, 15. Life on land, Canopy conductance, O-18&#8208, atmosphere transfer model (MuSICA), ddc, Earth sciences, 030104 developmental biology, chemistry, [SDE]Environmental Sciences, Temperature sensitive, canopy conductance, grassland, 010606 plant biology & botany

Abstract

We explore here our mechanistic understanding of the environmental and physiological processes that determine the oxygen isotope composition of leaf cellulose (δ$^{18}$O$_{cellulose}$) in a drought‐prone, temperate grassland ecosystem. A new allocation‐and‐growth model was designed and added to an $^{18}$O‐enabled soil–vegetation–atmosphere transfer model (MuSICA) to predict seasonal (April–October) and multi‐annual (2007–2012) variation of δ$^{18}$O$_{cellulose}$ and $^{18}$O‐enrichment of leaf cellulose (Δ$^{18}$O$_{cellulose}$) based on the Barbour–Farquhar model. Modelled δ$^{18}$O$_{cellulose}$ agreed best with observations when integrated over c. 400 growing‐degree‐days, similar to the average leaf lifespan observed at the site. Over the integration time, air temperature ranged from 7 to 22°C and midday relative humidity from 47 to 73%. Model agreement with observations of δ$^{18}$O$_{cellulose}$ (R$^{2}$ = 0.57) and Δ$^{18}$O$_{cellulose}$ (R$^{2}$ = 0.74), and their negative relationship with canopy conductance, was improved significantly when both the biochemical $^{18}$O‐fractionation between water and substrate for cellulose synthesis (ε$_{bio}$, range 26–30‰) was temperature‐sensitive, as previously reported for aquatic plants and heterotrophically grown wheat seedlings, and the proportion of oxygen in cellulose reflecting leaf water $^{18}$O‐enrichment (1 – p$_{ex}$p$_{x}$, range 0.23–0.63) was dependent on air relative humidity, as observed in independent controlled experiments with grasses. Understanding physiological information in δ$^{18}$O$_{cellulose}$ requires quantitative knowledge of climatic effects on p$_{ex}$p$_{x}$ and ε$_{bio}$.

Published

2019