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354 results on '"Cheng, Lailiang"'

1. 3D Branch Point Cloud Completion for Robotic Pruning in Apple Orchards

Author

Qiu, Tian, Zoubi, Alan, Spine, Nikolai, Cheng, Lailiang, and Jiang, Yu

Subjects
Computer Science - Robotics
Abstract

Robotic branch pruning is a significantly growing research area to cope with the shortage of labor force in the context of agriculture. One fundamental requirement in robotic pruning is the perception of detailed geometry and topology of branches. However, the point clouds obtained in agricultural settings often exhibit incompleteness due to several constraints, thereby restricting the accuracy of downstream robotic pruning. In this work, we addressed the issue of point cloud quality through a simulation-based deep neural network, leveraging a Real-to-Simulation (Real2Sim) data generation pipeline that not only eliminates the need for manual parameterization but also guarantees the realism of simulated data. The simulation-based neural network was applied to jointly perform point cloud completion and skeletonization on real-world partial branches, without additional real-world training. The Sim2Real qualitative completion and skeletonization results showed the model's remarkable capability for geometry reconstruction and topology prediction. Additionally, we quantitatively evaluated the Sim2Real performance by comparing branch-level trait characterization errors using raw incomplete data and complete data. The Mean Absolute Error (MAE) reduced by 75% and 8% for branch diameter and branch angle estimation, respectively, using the best complete data, which indicates the effectiveness of the Real2Sim data in a zero-shot generalization setting. The characterization improvements contributed to the precision and efficacy of robotic branch pruning., Comment: Accepted by IROS 2024

Published
2024

4. Sugar metabolism and accumulation in the fruit of transgenic apple trees with decreased sorbitol synthesis

Author

Li, Mingjun, Li, Pengmin, Ma, Fengwang, Dandekar, Abhaya M, and Cheng, Lailiang

Subjects
Agricultural, Veterinary and Food Sciences, Horticultural Production, Horticultural production, Plant biology
Abstract

Both sorbitol and sucrose are synthesized in source leaves and transported to fruit for supporting fruit growth in tree fruit species of the Rosaceae family. In apple (Malus domestica), antisense suppression of aldose-6-phosphate reductase, the key enzyme for sorbitol synthesis, significantly decreased the sorbitol concentration but increased the sucrose concentration in leaves, leading to a lower sorbitol but a higher sucrose supply to fruit in these plants. In response to this altered carbon supply, the transgenic fruit had lower concentration of sorbitol and much higher concentration of glucose but similar levels of fructose, sucrose, and starch throughout fruit development relative to the untransformed control. Activities of sorbitol dehydrogenase, fructokinase, and sucrose phosphate synthase were lower, whereas activities of neutral invertase, sucrose synthase, and hexokinase were higher in the transgenic fruit during fruit development. Transcript levels of MdSOT1, MdSDHs, MdFK2, and MdSPS3/6 were downregulated, whereas transcript levels of MdSUC1/4, MdSUSY1-3, MdNIV1/3, MdHKs, and MdTMT1 were upregulated in the transgenic fruit. These findings suggest that the Sucrose cycle and the sugar transport system are very effective in maintaining the level of fructose and provide insights into the roles of sorbitol and sucrose in regulating sugar metabolism and accumulation in sorbitol-synthesizing species.

Published
2018

6. A Functional InDel in the WRKY10 Promoter Controls the Degree of Flesh Red Pigmentation in Apple.

Author

Wang, Nan, Liu, Wenjun, Mei, Zhuoxin, Zhang, Shuhui, Zou, Qi, Yu, Lei, Jiang, Shenghui, Fang, Hongcheng, Zhang, Zongying, Chen, Zijing, Wu, Shujing, Cheng, Lailiang, and Chen, Xuesen

Subjects
TRANSCRIPTION factors, COLOR of plants, PROMOTERS (Genetics), GENETIC transcription, PHENOTYPES, ANTHOCYANINS
Abstract

MYB transcription factors have been linked to anthocyanin synthesis and various color phenotypes in plants. In apple, MYB10 confers a red‐flesh phenotype due to a minisatellite insertion in its R6 promoter, but R6:MYB10 genotypes exhibit various degrees of red pigmentation in the flesh, suggesting the involvement of other genetic factors. Here, it is shown that MdWRKY10, a transcription factor identified via DNA pull‐down trapping, binds to the promoter of MdMYB10 and activates its transcription. MdWRKY10 specifically interacts with the WDR protein MdTTG1 to join the apple MYB‐bHLH‐WDR (MBW) complex, which significantly enhances its transcriptional activation activity. A 163‐bp InDel detected in the promoter region of the alleles of MdWRKY10 in a hybrid population of identical heterozygous genotypes regarding R6 by structural variation analysis, contains a typical W‐box element that MdWRKY10 binds to for transactivation. This leads to increased transcript levels of MdWRKY10 and MdMYB10 and enhanced anthocyanin synthesis in the flesh, largely accounting for the various degrees of flesh red pigmentation in the R6 background. These findings reveal a novel regulatory role of the WRKY‐containing protein complex in the formation of red flesh apple phenotypes and provide broader insights into the molecular mechanism governing anthocyanin synthesis in plants. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Alternative Splicing Underpins the ALMT9 Transporter Function for Vacuolar Malic Acid Accumulation in Apple.

Author

Li, Chunlong, Krishnan, Srinivasan, Zhang, Mengxia, Hu, Dagang, Meng, Dong, Riedelsberger, Janin, Dougherty, Laura, Xu, Kenong, Piñeros, Miguel A., and Cheng, Lailiang

Subjects
ALTERNATIVE RNA splicing, MALIC acid, TRANSCRIPTION factors, PROTEIN transport, CARRIER proteins
Abstract

Vacuolar malic acid accumulation largely determines fruit acidity, a key trait for the taste and flavor of apple and other fleshy fruits. Aluminum‐activated malate transporter 9 (ALMT9/Ma1) underlies a major genetic locus, Ma, for fruit acidity in apple, but how the protein transports malate across the tonoplast is unclear. Here, it is shown that overexpression of the coding sequence of Ma1 (Ma1α) drastically decreases fruit acidity in "Royal Gala" apple, leading to uncovering alternative splicing underpins Ma1's function. Alternative splicing generates two isoforms: Ma1β is 68 amino acids shorter with much lower expression than the full‐length protein Ma1α. Ma1β does not transport malate itself but interacts with the functional Ma1α to form heterodimers, creating synergy with Ma1α for malate transport in a threshold manner (When Ma1β/Ma1α ≥ 1/8). Overexpression of Ma1α triggers feedback inhibition on the native Ma1 expression via transcription factor MYB73, decreasing the Ma1β level well below the threshold that leads to significant reductions in Ma1 function and malic acid accumulation in fruit. Overexpression of Ma1α and Ma1β or genomic Ma1 increases both isoforms proportionally and enhances fruit malic acid accumulation. These findings reveal an essential role of alternative splicing in ALMT9‐mediated malate transport underlying apple fruit acidity. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Focus on fruit crops

Author

Wu, Jun, primary, Cheng, Lailiang, additional, Espley, Richard, additional, Ma, Fengwang, additional, and Malnoy, Mickael, additional

Published
2023
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13. Carotenoid sequestration protein FIBRILLIN participates in CmOR-regulated β-carotene accumulation in melon

Author

Zhou, Xuesong, primary, Sun, Tianhu, additional, Owens, Lauren, additional, Yang, Yong, additional, Fish, Tara, additional, Wrightstone, Emalee, additional, Lui, Andy, additional, Yuan, Hui, additional, Chayut, Noam, additional, Burger, Joseph, additional, Tadmor, Yaakov, additional, Thannhauser, Theodore, additional, Guo, Wangzhen, additional, Cheng, Lailiang, additional, and Li, Li, additional

Published
2023
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32. Multi-omics approaches identify a key gene, PpTST1, for organic acid accumulation in peach

Author

Wang, Qi, primary, Cao, Ke, additional, Cheng, Lailiang, additional, Li, Yong, additional, Guo, Jian, additional, Yang, Xuanwen, additional, Wang, Jiao, additional, Khan, Irshad Ahmad, additional, Zhu, Gengrui, additional, Fang, Weichao, additional, Chen, Changwen, additional, Wang, Xinwei, additional, Wu, Jinlong, additional, Xu, Qiang, additional, and Wang, Lirong, additional

Published
2022
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43. A co-expression gene network associated with developmental regulation of apple fruit acidity

Author

Bai, Yang, Dougherty, Laura, Cheng, Lailiang, Xu, Kenong, Bai, Yang, Dougherty, Laura, Cheng, Lailiang, and Xu, Kenong

Abstract

Apple fruit acidity, which affects the fruit's overall taste and flavor to a large extent, is primarily determined by the concentration of malic acid. Previous studies demonstrated that the major QTL malic acid (Ma) on chromosome 16 is largely responsible for fruit acidity variations in apple. Recent advances suggested that a natural mutation that gives rise to a premature stop codon in one of the two aluminum-activated malate transporter (ALMT)-like genes (called Ma1) is the genetic causal element underlying Ma. However, the natural mutation does not explain the developmental changes of fruit malate levels in a given genotype. Using RNA-seq data from the fruit of ‘Golden Delicious' taken at 14 developmental stages from 1week after full-bloom (WAF01) to harvest (WAF20), we characterized their transcriptomes in groups of high (12.2±1.6mg/g fw, WAF03-WAF08), mid (7.4±0.5mg/g fw, WAF01-WAF02 and WAF10-WAF14) and low (5.4±0.4mg/g fw, WAF16-WAF20) malate concentrations. Detailed analyses showed that a set of 3,066 genes (including Ma1) were expressed not only differentially (P FDR<0.05) between the high and low malate groups (or between the early and late developmental stages) but also in significant (P<0.05) correlation with malate concentrations. The 3,066 genes fell in 648 MapMan (sub-) bins or functional classes, and 19 of them were significantly (P FDR<0.05) co-enriched or co-suppressed in a malate dependent manner. Network inferring using the 363 genes encompassed in the 19 (sub-) bins, identified a major co-expression network of 239 genes. Since the 239 genes were also differentially expressed between the early (WAF03-WAF08) and late (WAF16-WAF20) developmental stages, the major network was considered to be associated with developmental regulation of apple fruit acidity in ‘Golden Delicious'.

Published
2021

48. Soil Nitrogen Fertilization Increases Yeast Assimilable Nitrogen Concentrations in 'Golden Russet' and 'Medaille d'Or' Apples Used for Cider Production

Author

Karl, Adam D., Brown, Michael G., Ma, Sihui, Sandbrook, Ann, Stewart, Amanda C., Cheng, Lailiang, Mansfield, Anna Katharine, Peck, Gregory M., Karl, Adam D., Brown, Michael G., Ma, Sihui, Sandbrook, Ann, Stewart, Amanda C., Cheng, Lailiang, Mansfield, Anna Katharine, and Peck, Gregory M.

Abstract

The recent growth in the U.S. hard-cider industry has increased the demand for cider apples (Malus xdomestica Borkh.), but little is known about how to manage orchard soil fertility best to optimize horticultural performance and juice characteristics for these cultivars. To assess whether nitrogen fertilizer applied to the soil can improve apple juice and cider quality, calcium nitrate (CaNO3) fertilizer was applied at different rates to the soil beneath 'Golden Russet' and 'Medaille d'Or' trees over the course of three growing seasons. The experiment started when the trees were in their second leaf. The trees were cropped in their third and fourth leaf. At the end of the first growing season of the experiment, the greatest fertilizer rate increased tree trunk cross-sectional area (TCSA) by 82% relative to the control, but this difference did not persist through to the end of the study. Yield and crop load were unaffected by the nitrogen fertilization treatments. Increasing the nitrogen fertilizer rate correlated positively with more advanced harvest maturity in 'Golden Russet' fruit, which resulted in greater soluble solid concentration (SSC). Fruit from the greatest fertilizer rate treatment had an average starch pattern index (SP1) that was 1 U greater than in the control, and an SSC that was 3% greater than the control. The fertilizer treatments did not affect juice pH, titratable acidity (TA), or total polyphenol concentrations. Yeast assimilable nitrogen (YAN) concentrations were increased by nitrogen fertilization for both cultivars in both harvest years. The greatest fertilizer treatment increased juice primary amino nitrogen by 103% relative to the control. Greater nitrogen fertilization rates correlated positively with less hydrogen sulfide production during the fermentation of 'Golden Russet' juice from the first, but not the second, harvest. During the first year, cumulative hydrogen sulfide production for the 'Golden Russet' control treatment was 29.6 m

Published
2020
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49. Foliar Urea Applications Increase Yeast Assimilable Nitrogen Concentration and Alcoholic Fermentation Rate in 'Red Spy' Apples Used for Cider Production

Author

Karl, Adam D., Brown, Michael G., Ma, Sihui, Sandbrook, Ann, Stewart, Amanda C., Cheng, Lailiang, Mansfield, Anna Katharine, Peck, Gregory M., Karl, Adam D., Brown, Michael G., Ma, Sihui, Sandbrook, Ann, Stewart, Amanda C., Cheng, Lailiang, Mansfield, Anna Katharine, and Peck, Gregory M.

Abstract

Yeast assimilable nitrogen (YAN) can be a limiting nutritional factor for Saccharomyces cerevisiae yeast when fermenting apple (Maims Xdomestka Borkh.) juice into hard cider. Endogenous YAN concentrations in apples are often below the recommended thresholds to completely use all of the fermentable sugar and minimize the production of off-flavors, such as hydrogen sulfide. Cider producers supplement apple juice with exogenous nitrogen to increase YAN. Urea, commonly applied to apple orchards to increase fruit size and yields, was tested for its ability to increase endogenous apple juice YAN. Starting 6 weeks before harvest in 2017 and 2018, a 1% urea solution was applied to 'Red Spy' apple trees one, three, or five times to create low-, medium-, and high-rate treatments, respectively. Relative to the control, the high treatment increased YAN by 229% in 2017 and by 408% in 2018. More than 90% of the YAN in all juice samples was composed of primary amino nitrogen (PAN). Among all treatments, PAN mostly comprised asparagine, and as urea applications increased, the relative concentration of asparagine also increased. Aspartic acid and then glutamic acid were the second and third most abundant amino acids in all treatments, respectively, but comprised less of the total PAN as the number of urea applications increased. Soluble solid concentration, pH, titratable acidity, and total polyphenol concentration were not different among treatments. There was a positive correlation between increased urea application rate and the maximum fermentation rate, which resulted in a shorter fermentation duration. Increasing the number of urea applications was also correlated with greater hydrogen sulfide (H2S) production in juice fermented from fruit harvested in 2017 but not for fruit harvested in 2018. No residual H2S was found in the finished cider from any treatment. Increasing the number of urea applications was estimated to be less expensive than supplementing the juice with Fermaid

Published
2020
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50. Soil Nitrogen Fertilization Increases Yeast Assimilable Nitrogen Concentrations in 'Golden Russet' and 'Medaille d'Or' Apples Used for Cider Production

Author

Food Science and Technology, Karl, Adam D., Brown, Michael G., Ma, Sihui, Sandbrook, Ann, Stewart, Amanda C., Cheng, Lailiang, Mansfield, Anna Katharine, Peck, Gregory M., Food Science and Technology, Karl, Adam D., Brown, Michael G., Ma, Sihui, Sandbrook, Ann, Stewart, Amanda C., Cheng, Lailiang, Mansfield, Anna Katharine, and Peck, Gregory M.

Abstract

The recent growth in the U.S. hard-cider industry has increased the demand for cider apples (Malus xdomestica Borkh.), but little is known about how to manage orchard soil fertility best to optimize horticultural performance and juice characteristics for these cultivars. To assess whether nitrogen fertilizer applied to the soil can improve apple juice and cider quality, calcium nitrate (CaNO3) fertilizer was applied at different rates to the soil beneath 'Golden Russet' and 'Medaille d'Or' trees over the course of three growing seasons. The experiment started when the trees were in their second leaf. The trees were cropped in their third and fourth leaf. At the end of the first growing season of the experiment, the greatest fertilizer rate increased tree trunk cross-sectional area (TCSA) by 82% relative to the control, but this difference did not persist through to the end of the study. Yield and crop load were unaffected by the nitrogen fertilization treatments. Increasing the nitrogen fertilizer rate correlated positively with more advanced harvest maturity in 'Golden Russet' fruit, which resulted in greater soluble solid concentration (SSC). Fruit from the greatest fertilizer rate treatment had an average starch pattern index (SP1) that was 1 U greater than in the control, and an SSC that was 3% greater than the control. The fertilizer treatments did not affect juice pH, titratable acidity (TA), or total polyphenol concentrations. Yeast assimilable nitrogen (YAN) concentrations were increased by nitrogen fertilization for both cultivars in both harvest years. The greatest fertilizer treatment increased juice primary amino nitrogen by 103% relative to the control. Greater nitrogen fertilization rates correlated positively with less hydrogen sulfide production during the fermentation of 'Golden Russet' juice from the first, but not the second, harvest. During the first year, cumulative hydrogen sulfide production for the 'Golden Russet' control treatment was 29.6 m

Published
2020

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