Your search keyword '"Youping Zhou"' showing total 6 results

1. Initiation of efficient <scp> C 4 </scp> pathway in response to low ambient <scp> CO 2 </scp> during the bloom period of a marine dinoflagellate

Author

Da-Zhi Wang, Xi-Jie Yin, Youping Zhou, Lin Lin, Qiang Lin, Hao Zhang, and Tian-Qi Liu

Subjects

0303 health sciences, 030306 microbiology, ved/biology, fungi, ved/biology.organism_classification_rank.species, Carbon fixation, RuBisCO, Dinoflagellate, Prorocentrum donghaiense, Biology, Photosynthesis, biology.organism_classification, Microbiology, Algal bloom, 03 medical and health sciences, Botany, biology.protein, Phosphoenolpyruvate carboxykinase, Phosphoenolpyruvate carboxylase, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology

Abstract

Dinoflagellates are important primary producers and major causative agents of harmful algal blooms in the global ocean. Despite the great ecological significance, the photosynthetic carbon acquisition by dinoflagellates is still poorly understood. The pathways of photosynthetic carbon assimilation in a marine dinoflagellate Prorocentrum donghaiense under both in situ and laboratory-simulated bloom conditions were investigated using a combination of metaproteomics, qPCR, stable carbon isotope and targeted metabolomics approaches. A rapid consumption of dissolved CO2 to generate high biomass was observed as the bloom proceeded. The carbon assimilation genes and proteins including intracellular carbonic anhydrase 2, phosphoenolpyruvate carboxylase, phosphoenolpyruvate carboxykinase and RubisCO as well as their enzyme activities were all highly expressed at the low CO2 level, indicating that C4 photosynthetic pathway functioned in the blooming P. donghaiense cells. Furthermore, δ13 C values and content of C4 compound (malate) significantly increased with the decreasing CO2 concentration. The transition from C3 to C4 pathway minimizes the internal CO2 leakage and guarantees efficient carbon fixation at the low CO2 level. This study demonstrates the existence of C4 photosynthetic pathway in a marine dinoflagellate and reveals its important complementary role to assist carbon assimilation for cell proliferation during the bloom period.

Published

2021

2. Leaf transition from heterotrophy to autotrophy is recorded in the intraleaf C, H and O isotope patterns of leaf organic matter

Author

Zhenyu Zhu, Xijie Yin, Qiulin Yan, Xin Song, Bo Wang, Youping Zhou, Ying Wang, Arthur Gessler, Andleeb Rani, Ran Ma, Su Jing, and Yu Zhao

Subjects

Heterotroph, 01 natural sciences, Photoheterotroph, Gas Chromatography-Mass Spectrometry, Analytical Chemistry, Isotopes, Alkanes, Botany, Organic matter, Autotroph, Photosynthesis, Isotope-ratio mass spectrometry, Cellulose, Spectroscopy, Trophic level, chemistry.chemical_classification, Autotrophic Processes, Isotope, 010401 analytical chemistry, Organic Chemistry, Water, Heterotrophic Processes, Musa, 0104 chemical sciences, Plant Leaves, chemistry, Elemental analysis, Waxes

Abstract

RATIONALE Quantitatively relating 13 C/12 C, 2 H/1 H and 18 O/16 O ratios of plant α-cellulose and 2 H/1 H of n-alkanes to environmental conditions and metabolic status should ideally be based on the leaf, the plant organ most sensitive to environmental change. The fact that leaf organic matter is composed of isotopically different heterotrophic and autotrophic components means that it is imperative that one be able to disentangle the relative heterotrophic and autotrophic contributions to leaf organic matter. METHODS We tackled this issue by two-dimensional sampling of leaf water and α-cellulose, and specific n-alkanes from greenhouse-grown immature and mature and field-grown mature banana leaves, taking advantage of their large areas and thick waxy layers. Leaf water, α-cellulose and n-alkane isotope ratios were then characterized using elemental analysis isotope ratio mass spectrometry (IRMS) or gas chromatography IRMS. A three-member (heterotrophy, autotrophy and photoheterotrophy) conceptual linear mixing model was then proposed for disentangling the relative contributions of the three trophic modes. RESULTS We discovered distinct spatial leaf water, α-cellulose and n-alkane isotope ratio patterns that varied with leaf developmental stages. We inferred from the conceptual model that, averaged over the leaf blade, only 20% of α-cellulose in banana leaf is autotrophically laid down in both greenhouse-grown and field-grown banana leaves, while approximately 60% and 100% of n-alkanes are produced autotrophically in greenhouse-grown and field-grown banana leaves, respectively. There exist distinct lateral (edge to midrib) gradients in autotrophic contributions of α-cellulose and n-alkanes. CONCLUSIONS Efforts to establish quantitative isotope-environment relationships should take into account the fact that the evaporative leaf water 18 O and 2 H enrichment signal recorded in autotrophically laid down α-cellulose is significantly diluted by the heterotrophically formed α-cellulose. The δ2 H value of field-grown mature banana leaf n-alkanes is much more sensitive than α-cellulose as a recorder of the growth environment. Quantitative isotope-environment relationship based on greenhouse-grown n-alkane δ2 H values may not be reliable.

Published

2020

3. Author response for 'Leaf Transition from Heterotrophy to Autotrophy is Recorded in the Intraleaf C, H and O Isotope Patterns of Leaf Organic Matter'

Author

Ran Ma, Xin Song, Zhenyu Zhu, Yu Zhao, Youping Zhou, Bo Wang, Andleeb Rani, Qiulin Yan, Arthur Gessler, Xijie Yin, Jing Su, and Ying Wang

Subjects

chemistry.chemical_classification, chemistry, Isotope, Environmental chemistry, Heterotroph, Organic matter, Autotroph

Published

2020

4. The effect of processing medium on the 2 H/ 1 H of carbon‐bound hydrogen in α‐cellulose extracted from higher plants

Author

Zhenyu Zhu, Fengyan Lu, Ran Ma, Bo Wang, Youping Zhou, Qiulin Yan, Ying Wang, Yi Ma, Yu Zhao, Jing Su, Charles H. Hocart, and Xijie Yin

Subjects

Hydrogen, Isotope, 010401 analytical chemistry, Organic Chemistry, Inorganic chemistry, Extraction (chemistry), chemistry.chemical_element, 01 natural sciences, 0104 chemical sciences, Analytical Chemistry, chemistry.chemical_compound, chemistry, Kinetic isotope effect, Lignin, Cellulose, Isotope-ratio mass spectrometry, Carbon, Spectroscopy

Abstract

RATIONALE Although the 2 H/1 H ratio of the carbon-bound hydrogens (C-Hs) in α-cellulose extracted from higher plants has long been used successfully for climate, environmental and metabolic studies, the assumption that bleaching with acidified NaClO2 to remove lignin before pure α-cellulose can be obtained does not alter the 2 H/1 H ratio of α-cellulose C-Hs has nonetheless not been tested. METHODS For reliable application of the 2 H/1 H ratio of α-cellulose C-H, we processed plant materials representing different phytochemistries and photosynthetic carbon assimilation modes in isotopically contrasting bleaching media (with an isotopic difference of 273 mUr). All the isotope ratios were measured by elemental analyzer/isotope ratio mass spectrometry (EA/IRMS). RESULTS Our results show that H from the bleaching medium does appear in the final pure α-cellulose product, although the isotopic alteration to the C-H in α-cellulose due to the incorporation of processing H from the medium is small if isotopically "natural" water is used to prepare the processing medium. However, under prolonged bleaching such an isotope effect can be significant, implying that standardizing the bleaching process is necessary for reliable 2 H/1 H measurement. CONCLUSIONS The currently adopted method for removing lignin for α-cellulose extraction from higher plant materials with acidified NaClO2 bleaching is considered acceptable in terms of preserving the isotopic fidelity if isotopically "natural" water is used to prepare the bleaching solution.

Published

2020

5. Hydrogen isotopic differences between C3and C4land plant lipids: consequences of compartmentation in C4photosynthetic chemistry and C3photorespiration

Author

Hilary Stuart-Williams, Charles H. Hocart, Arthur Gessler, Kliti Grice, Youping Zhou, and Graham D. Farquhar

Subjects

0106 biological sciences, Physiology, Chemistry, Cellular respiration, Carbon fixation, food and beverages, Plant Science, Metabolism, Mevalonic acid, 010502 geochemistry & geophysics, Photosynthesis, 01 natural sciences, Chloroplast, chemistry.chemical_compound, Biochemistry, Lipid biosynthesis, Photorespiration, 010606 plant biology & botany, 0105 earth and related environmental sciences

Abstract

The 2 H/1 H ratio of carbon-bound H in biolipids holds potential for probing plant lipid biosynthesis and metabolism. The biochemical mechanism underlying the isotopic differences between lipids from C3 and C4 plants is still poorly understood. GC-pyrolysis-IRMS (gas chromatography-pyrolysis-isotope ratio mass spectrometry) measurement of the 2 H/1 H ratio of leaf lipids from controlled and field grown plants indicates that the biochemical isotopic fractionation (e2 Hlipid_biochem ) differed between C3 and C4 plants in a pathway-dependent manner: e2 HC4 > e2 HC3 for the acetogenic pathway, e2 HC4

Published

2016

6. Effects of GC temperature and carrier gas flow rate on on-line oxygen isotope measurement as studied by on-column CO injection

Author

Xi-Jie Yin, Youping Zhou, and Zhigang Chen

Subjects

Volume (thermodynamics), chemistry, Yield (chemistry), Analytical chemistry, chemistry.chemical_element, Zeolite, Oxygen, Spectroscopy, Intensity (heat transfer), Ion source, Isotopes of oxygen, Volumetric flow rate

Abstract

Although deemed important to δ 18 O measurement by on-line high-temperature conversion techniques, how the GC conditions affect δ 18 Omeasurement israrelyexaminedadequately.WethereforedirectlyinjecteddifferentvolumesofCOorCO–N2mixonto the GC column by a six-port valve and examined the CO yield, CO peak shape, CO–N2 separation, and δ 18 O value under different GC temperatures and carrier gas flow rates. The results show the CO peak area decreases when the carrier gas flow rate increases. The GC temperature has no effect on peak area. The peak width increases with the increase of CO injection volume but decreases with the increase of GC temperature and carrier gas flow rate. The peak intensity increases with the increase of GC temperature and CO injection volume but decreases with the increase of carrier gas flow rate. The peak separation time between N2 and CO decreases with an increase of GC temperature and carrier gas flow rate. δ 18 O value decreases with the increase of CO injection volume (when half m/z 28 intensity is

Published

2015