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22 results on '"Yu Ya-Chi"'

1. Synchrotron X-ray phase-contrast imaging of ultrasonic drop atomization

Author

Prasanna, Anunay, Biasiori-Poulanges, Luc, Yu, Ya-Chi, El-Rabii, Hazem, Lukić, Bratislav, and Supponen, Outi

Subjects
Physics - Fluid Dynamics
Abstract

Ultrasonic atomization is employed to generate size-controllable droplets for a variety of applications. Here, we minimize the number of parameters dictating the process by studying the atomization of a single drop pending from an ultrasonic horn. Spatiotemporally resolved X-ray phase-contrast imaging measurements show that the number-median sizes of the ejected droplets can be predicted by the linear Navier-Stokes equations, signifying that the size distribution is controlled by the fluid properties and the driving frequency. Experiments with larger pendant water drops indicate that the fluid-structure interaction plays a pivotal role in determining the ejection onset of the pendant drop. The atomization of viscoelastic drops is dictated by extended ligament formation, entrainment of air, and ejection of drop-encapsulated bubbles. Existing scaling laws are used to explain the required higher input amplitudes for the complete atomization of viscoelastic drops as compared to inviscid drops. Finally, we elucidate the differences between capillary wave-based and cavitation-based atomization and show that inducing cavitation and strong bubble oscillations quickens the onset of daughter drop ejection but impedes their size control., Comment: 36 pages, 11 figures

Published
2023

13. Simultaneous changes in seed size, oil content and protein content driven by selection of SWEET homologues during soybean domestication

Author

Wang, Shoudong, Liu, Shulin, Wang, Jie, Yokosho, Kengo, Zhou, Bin, Yu, Ya-Chi, Liu, Zhi, Frommer, Wolf B., Ma, Jian Feng, Chen, Li-Qing, Guan, Yuefeng, Shou, Huixia, Tian, Zhixi, Wang, Shoudong, Liu, Shulin, Wang, Jie, Yokosho, Kengo, Zhou, Bin, Yu, Ya-Chi, Liu, Zhi, Frommer, Wolf B., Ma, Jian Feng, Chen, Li-Qing, Guan, Yuefeng, Shou, Huixia, and Tian, Zhixi

Abstract

Soybean accounts for more than half of the global production of oilseed and more than a quarter of the protein used globally for human food and animal feed. Soybean domestication involved parallel increases in seed size and oil content, and a concomitant decrease in protein content. However, science has not yet discovered whether these effects were due to selective pressure on a single gene or multiple genes. Here, re-sequencing data from >800 genotypes revealed a strong selection during soybean domestication on GmSWEET10a. The selection of GmSWEET10a conferred simultaneous increases in soybean-seed size and oil content as well as a reduction in the protein content. The result was validated using both near-isogenic lines carrying substitution of haplotype chromosomal segments and transgenic soybeans. Moreover, GmSWEET10b was found to be functionally redundant with its homologue GmSWEET10a and to be undergoing selection in current breeding, leading the the elite allele GmSWEET10b, a potential target for present-day soybean breeding. Both GmSWEET10a and GmSWEET10b were shown to transport sucrose and hexose, contributing to sugar allocation from seed coat to embryo, which consequently determines oil and protein contents and seed size in soybean. We conclude that past selection of optimal GmSWEET10a alleles drove the initial domestication of multiple soybean-seed traits and that targeted selection of the elite allele GmSWEET10b may further improve the yield and seed quality of modem soybean cultivars.

Published
2020

14. Simultaneous changes in seed size, oil content and protein content driven by selection of SWEET homologues during soybean domestication

Author

Wang, Shoudong, primary, Liu, Shulin, additional, Wang, Jie, additional, Yokosho, Kengo, additional, Zhou, Bin, additional, Yu, Ya-Chi, additional, Liu, Zhi, additional, Frommer, Wolf B, additional, Ma, Jian Feng, additional, Chen, Li-Qing, additional, Guan, Yuefeng, additional, Shou, Huixia, additional, and Tian, Zhixi, additional

Published
2020
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17. A Subsidiary Cell-Localized Glucose Transporter Promotes Stomatal Conductance and Photosynthesis

Author

Wang, Hai, primary, Yan, Shijuan, additional, Xin, Hongjia, additional, Huang, Wenjie, additional, Zhang, Hao, additional, Teng, Shouzhen, additional, Yu, Ya-Chi, additional, Fernie, Alisdair R., additional, Lu, Xiaoduo, additional, Li, Pengcheng, additional, Li, Shengyan, additional, Zhang, Chunyi, additional, Ruan, Yong-Ling, additional, Chen, Li-Qing, additional, and Lang, Zhihong, additional

Published
2019
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19. Simultaneous changes in seed size, oil content and protein content driven by selection of SWEEThomologues during soybean domestication

Author

Wang, Shoudong, Liu, Shulin, Wang, Jie, Yokosho, Kengo, Zhou, Bin, Yu, Ya-Chi, Liu, Zhi, Frommer, Wolf B, Ma, Jian Feng, Chen, Li-Qing, Guan, Yuefeng, Shou, Huixia, and Tian, Zhixi

Abstract

Soybean accounts for more than half of the global production of oilseed and more than a quarter of the protein used globally for human food and animal feed. Soybean domestication involved parallel increases in seed size and oil content, and a concomitant decrease in protein content. However, science has not yet discovered whether these effects were due to selective pressure on a single gene or multiple genes. Here, re-sequencing data from >800 genotypes revealed a strong selection during soybean domestication on GmSWEET10a. The selection of GmSWEET10aconferred simultaneous increases in soybean-seed size and oil content as well as a reduction in the protein content. The result was validated using both near-isogenic lines carrying substitution of haplotype chromosomal segments and transgenic soybeans. Moreover, GmSWEET10bwas found to be functionally redundant with its homologue GmSWEET10aand to be undergoing selection in current breeding, leading the the elite allele GmSWEET10b, a potential target for present-day soybean breeding. Both GmSWEET10a and GmSWEET10b were shown to transport sucrose and hexose, contributing to sugar allocation from seed coat to embryo, which consequently determines oil and protein contents and seed size in soybean. We conclude that past selection of optimal GmSWEET10aalleles drove the initial domestication of multiple soybean-seed traits and that targeted selection of the elite allele GmSWEET10bmay further improve the yield and seed quality of modern soybean cultivars.

Published
2020
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22. SWEET family transporters act as water conducting carrier proteins in plants.

Author

Selvam B, Paul A, Yu YC, Chen LQ, and Shukla D

Abstract

Dedicated water channels are involved in the facilitated diffusion of water molecules across the cell membrane in plants. Transporter proteins are also known to transport water molecules along with substrates, however the molecular mechanism of water permeation is not well understood in plant transporters. Here, we show plant sugar transporters from the SWEET ( S ugar W ill E ventually be E xported T ransporter) family act as water-conducting carrier proteins via a variety of passive and active mechanisms that allow diffusion of water molecules from one side of the membrane to the other. This study provides a molecular perspective on how plant membrane transporters act as water carrier proteins, a topic that has not been extensively explored in literature. Water permeation in membrane transporters could occur via four distinct mechanisms which form our hypothesis for water transport in SWEETs. These hypothesis are tested using molecular dynamics simulations of the outward-facing, occluded, and inward-facing state of AtSWEET1 to identify the water permeation pathways and the flux associated with them. The hydrophobic gates at the center of the transport tunnel act as a barrier that restricts water permeation. We have performed in silico single and double mutations of the hydrophobic gate residues to examine the changes in the water conductivity. Surprisingly, the double mutant allows the water permeation to the intracellular half of the membrane and forms a continuous water channel. These computational results are validated by experimentally examining the transport of hydrogen peroxide molecules by the AtSWEET family of transporters. We have also shown that the transport of hydrogen peroxide follows the similar mechanism as water transport in AtSWEET1. Finally, we conclude that similar water-conduction states are also present in other SWEET transporters due to the high sequence and structure conservation exhibited by this transporter family.

Published
2024
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