Your search keyword '"Clemente, Tom E."' showing total 29 results

1. Reducing stomatal density by expression of a synthetic epidermal patterning factor increases leaf intrinsic water use efficiency and reduces plant water use in a C4 crop.

Author

Ferguson, John N, Schmuker, Peter, Dmitrieva, Anna, Quach, Truyen, Zhang, Tieling, Ge, Zhengxiang, Nersesian, Natalya, Sato, Shirley J, Clemente, Tom E, and Leakey, Andrew D B

Abstract

Enhancing crop water use efficiency (WUE) is a key target trait for climatic resilience and expanding cultivation on marginal lands. Engineering lower stomatal density to reduce stomatal conductance (g s) has improved WUE in multiple C3 crop species. However, reducing g s in C3 species often reduces photosynthetic carbon gain. A different response is expected in C4 plants because they possess specialized anatomy and biochemistry which concentrates CO2 at the site of fixation. This modifies the relationship of photosynthesis (A N) with intracellular CO2 concentration (c i), such that photosynthesis is CO2 saturated and reductions in g s are unlikely to limit A N. To test this hypothesis, genetic strategies were investigated to reduce stomatal density in the C4 crop sorghum. Constitutive expression of a synthetic epidermal patterning factor (EPF) transgenic allele in sorghum led to reduced stomatal densities, reduced g s, reduced plant water use, and avoidance of stress during a period of water deprivation. In addition, moderate reduction in stomatal density did not increase stomatal limitation to A N. However, these positive outcomes were associated with negative pleiotropic effects on reproductive development and photosynthetic capacity. Avoiding pleiotropy by targeting expression of the transgene to specific tissues could provide a pathway to improved agronomic outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

2. Greater aperture counteracts effects of reduced stomatal density on water use efficiency: a case study on sugarcane and meta-analysis.

Author

Lunn, Daniel, Kannan, Baskaran, Germon, Amandine, Leverett, Alistair, Clemente, Tom E, Altpeter, Fredy, and Leakey, Andrew D B

Abstract

Stomata regulate CO2 and water vapor exchange between leaves and the atmosphere. Stomata are a target for engineering to improve crop intrinsic water use efficiency (iWUE). One example is by expressing genes that lower stomatal density (SD) and reduce stomatal conductance (g sw). However, the quantitative relationship between reduced SD, g sw, and the mechanisms underlying it is poorly understood. We addressed this knowledge gap using low-SD sugarcane (Saccharum spp. hybrid) as a case study alongside a meta-analysis of data from 10 species. Transgenic expression of EPIDERMAL PATTERNING FACTOR 2 from Sorghum bicolor (SbEPF2) in sugarcane reduced SD by 26–38% but did not affect g sw compared with the wild type. Further, no changes occurred in stomatal complex size or proxies for photosynthetic capacity. Measurements of gas exchange at low CO2 concentrations that promote complete stomatal opening to normalize aperture size between genotypes were combined with modeling of maximum g sw from anatomical data. These data suggest that increased stomatal aperture is the only possible explanation for maintaining g sw when SD is reduced. Meta-analysis across C3 dicots, C3 monocots, and C4 monocots revealed that engineered reductions in SD are strongly correlated with lower g sw (r 2=0.60–0.98), but this response is damped relative to the change in anatomy. [ABSTRACT FROM AUTHOR]

Published

2024

3. Editing the 19 kDa alpha‐zein gene family generates non‐opaque2‐based quality protein maize.

Author

Hurst, J. Preston, Sato, Shirley, Ferris, Tyler, Yobi, Abou, Zhou, You, Angelovici, Ruthie, Clemente, Tom E., and Holding, David R.

Subjects

GENE families, AGRICULTURE, GENOME editing, PROTEINS, AMINO acids

Abstract

Summary: Maize grain is deficient in lysine. While the opaque2 mutation increases grain lysine, o2 is a transcription factor that regulates a wide network of genes beyond zeins, which leads to pleiotropic and often negative effects. Additionally, the drastic reduction in 19 kDa and 22 kDa alpha‐zeins causes a floury kernel, unsuitable for agricultural use. Quality protein maize (QPM) overcame the undesirable kernel texture through the introgression of modifying alleles. However, QPM still lacks a functional o2 transcription factor, which has a penalty on non‐lysine amino acids due to the o2 mutation. CRISPR/cas9 gives researchers the ability to directly target genes of interest. In this paper, gene editing was used to specifically target the 19 kDa alpha zein gene family. This allows for proteome rebalancing to occur without an o2 mutation and without a total alpha‐zein knockout. The results showed that editing some, but not all, of the 19 kDa zeins resulted in up to 30% more lysine. An edited line displayed an increase of 30% over the wild type. While not quite the 55% lysine increase displayed by QPM, the line had little collateral impact on other amino acid levels compared to QPM. Additionally, the edited line containing a partially reduced 19 kDa showed an advantage in kernel texture that had a complete 19 kDa knockout. These results serve as proof of concept that editing the 19 kDa alpha‐zein family alone can enhance lysine while retaining vitreous endosperm and a functional O2 transcription factor. [ABSTRACT FROM AUTHOR]

Published

2024

4. Editing the 19 kDa alpha‐zein gene family generates non‐opaque2‐based quality protein maize

Author

Hurst, J. Preston, primary, Sato, Shirley, additional, Ferris, Tyler, additional, Yobi, Abou, additional, Zhou, You, additional, Angelovici, Ruthie, additional, Clemente, Tom E., additional, and Holding, David R., additional

Published

2023

5. The OCL3 promoter from Sorghum bicolor directs gene expression to abscission and nutrient-transfer zones at the bases of floral organs

Author

Dwivedi, Krishna K., Roche, Dominique J., Clemente, Tom E., Ge, Zhengxiang, and Carman, John G.

Published

2014

6. Expression of Chlorovirus MT325 aquaglyceroporin (aqpv1) in tobacco and its role in mitigating drought stress

Author

Bihmidine, Saadia, Cao, Mingxia, Kang, Ming, Awada, Tala, Van Etten, James L., Dunigan, David D., and Clemente, Tom E.

Published

2014

7. Activity of the Arabidopsis RD29A and RD29B promoter elements in soybean under water stress

Author

Bihmidine, Saadia, Lin, Jiusheng, Stone, Julie M., Awada, Tala, Specht, James E., and Clemente, Tom E.

Published

2013

8. The Chloroplast Triggers Developmental Reprogramming When MUTS HOMOLOG1 Is Suppressed in Plants

Author

Xu, Ying-Zhi, de la Rosa Santamaria, Roberto, Virdi, Kamaldeep S., Arrieta-Montiel, Maria P., Razvi, Fareha, Li, Shaoqing, Ren, Guodong, Yu, Bin, Alexander, Danny, Guo, Lining, Feng, Xuehui, Dweikat, Ismail M., Clemente, Tom E., and Mackenzie, Sally A.

Published

2012

9. Soybean Oil: Genetic Approaches for Modification of Functionality and Total Content

Author

Clemente, Tom E. and Cahoon, Edgar B.

Published

2009

10. Fine mapping and cloning of the major seed protein quantitative trait loci on soybean chromosome 20

Author

Fliege, Christina E., primary, Ward, Russell A., additional, Vogel, Pamela, additional, Nguyen, Hanh, additional, Quach, Truyen, additional, Guo, Ming, additional, Viana, João Paulo Gomes, additional, dos Santos, Lucas Borges, additional, Specht, James E., additional, Clemente, Tom E., additional, Hudson, Matthew E., additional, and Diers, Brian W., additional

Published

2022

11. Sorghum (Sorghum bicolor)

Author

Guo, Xiaomei, primary, Ge, Zhengxiang, additional, Sato, Shirley J., additional, and Clemente, Tom E., additional

Published

2014

12. Soybeans

Author

Kinney, Anthony J., primary and Clemente, Tom E., additional

Published

2010

13. An evaluation of new and established methods to determine T‐DNA copy number and homozygosity in transgenic plants

Author

Głowacka, Katarzyna, Kromdijk, Johannes, Leonelli, Lauriebeth, Niyogi, Krishna K., Clemente, Tom E., and Long, Stephen P.

Subjects

DNA, Bacterial, segregation analysis, transformation, Homozygote, Gene Dosage, ddPCR, Reproducibility of Results, Original Articles, Plants, Genetically Modified, Real-Time Polymerase Chain Reaction, selectable marker, Southern blot, qPCR, Blotting, Southern, Genetic Loci, Chromosome Segregation, TAIL‐PCR, Tobacco, Original Article, digital droplet PCR, Crosses, Genetic

Abstract

Stable transformation of plants is a powerful tool for hypothesis testing. A rapid and reliable evaluation method of the transgenic allele for copy number and homozygosity is vital in analysing these transformations. Here the suitability of Southern blot analysis, thermal asymmetric interlaced (TAIL‐)PCR, quantitative (q)PCR and digital droplet (dd)PCR to estimate T‐DNA copy number, locus complexity and homozygosity were compared in transgenic tobacco. Southern blot analysis and ddPCR on three generations of transgenic offspring with contrasting zygosity and copy number were entirely consistent, whereas TAIL‐PCR often underestimated copy number. qPCR deviated considerably from the Southern blot results and had lower precision and higher variability than ddPCR. Comparison of segregation analyses and ddPCR of T1 progeny from 26 T0 plants showed that at least 19% of the lines carried multiple T‐DNA insertions per locus, which can lead to unstable transgene expression. Segregation analyses failed to detect these multiple copies, presumably because of their close linkage. This shows the importance of routine T‐DNA copy number estimation. Based on our results, ddPCR is the most suitable method, because it is as reliable as Southern blot analysis yet much faster. A protocol for this application of ddPCR to large plant genomes is provided., Genetic transformation is being used increasingly in the public domain to test a range of hypotheses concerning gene action, not only in Arabidopsis, but now in a broad range of plants. A major challenge though, particularly with species with relatively long life cycles, is in identifying individuals that are homozygous for the insert or DNA modification at T2, which is necessary to provide homozygous lines. Southern blotting has been the traditional approach, but it is slow and requires considerable skill. Various PCR methods have been used to accelerate testing, but have not been as reliable. However, we show here that the recently developed digital droplet PCR is as effective as Southern blotting, yet faster and capable of high‐throughput. A protocol for application of ddPCR is provided together with evidence of its efficacy.

Published

2016

14. Enhancing soybean photosynthetic CO2 assimilation using a cyanobacterial membrane protein, ictB

Author

Hay, William T., Bihmidine, Saadia, Mutlu, Nedim, Hoang, Khang Le, Awada, Tala, Weeks, Donald P., Clemente, Tom E., Long, Stephen P., Hay, William T., Bihmidine, Saadia, Mutlu, Nedim, Hoang, Khang Le, Awada, Tala, Weeks, Donald P., Clemente, Tom E., and Long, Stephen P.

Abstract

Soybean C3 photosynthesis can suffer a severe loss in efficiency due to photorespiration and the lack of a carbon concentrating mechanism (CCM) such as those present in other plant species or cyanobacteria. Transgenic soybean (Glycine max cv. Thorne) plants constitutively expressing cyanobacterial ictB (inorganic carbon transporter B) gene were generated using Agrobacterium-mediated transformation. Although more recent data suggest that ictB does not actively transport HCO3-/CO2, there is nevertheless mounting evidence that transformation with this gene can increase higher plant photosynthesis. The hypothesis that expression of the ictB gene would improve photosynthesis, biomass production and seed yield in soybean was tested, in two independent replicated greenhouse and field trials. Results showed significant increases in photosynthetic CO2 uptake (Anet) and dry mass in transgenic relative to wild type (WT) control plants in both the greenhouse and field trials. Transgenic plants also showed increased photosynthetic rates and biomass production during a drought mimic study. The findings presented herein demonstrate that ictB, as a single-gene, contributes to enhancement in various yield parameters in a major commodity crop and point to the significant role that biotechnological approaches to increasing photosynthetic efficiency can play in helping to meet increased global demands for food.

Published

2017

15. A novel R3 MYB transcriptional repressor associated with the loss of floral pigmentation in Iochroma

Author

Gates, Daniel J., primary, Olson, Bradley J. S. C., additional, Clemente, Tom E., additional, and Smith, Stacey D., additional

Published

2017

16. Enhancing soybean photosynthetic CO 2 assimilation using a cyanobacterial membrane protein, ictB

Author

Hay, William T., primary, Bihmidine, Saadia, additional, Mutlu, Nedim, additional, Hoang, Khang Le, additional, Awada, Tala, additional, Weeks, Donald P., additional, Clemente, Tom E., additional, and Long, Stephen P., additional

Published

2017

17. Expression of the Maize Dof1 Transcription Factor in Wheat and Sorghum

Author

Peña, Pamela A., primary, Quach, Truyen, additional, Sato, Shirley, additional, Ge, Zhengxiang, additional, Nersesian, Natalya, additional, Changa, Taity, additional, Dweikat, Ismail, additional, Soundararajan, Madhavan, additional, and Clemente, Tom E., additional

Published

2017

18. Towards the development of a sustainable soya bean-based feedstock for aquaculture

Author

Park, Hyunwoo, primary, Weier, Steven, additional, Razvi, Fareha, additional, Peña, Pamela A., additional, Sims, Neil A., additional, Lowell, Jennica, additional, Hungate, Cory, additional, Kissinger, Karma, additional, Key, Gavin, additional, Fraser, Paul, additional, Napier, Johnathan A., additional, Cahoon, Edgar B., additional, and Clemente, Tom E., additional

Published

2016

19. A novel R3 MYB transcriptional repressor associated with the loss of floral pigmentation in <italic>Iochroma</italic>.

Author

Gates, Daniel J., Olson, Bradley J. S. C., Clemente, Tom E., and Smith, Stacey D.

Subjects

PHENOTYPES, GENETICS, RNA sequencing, PIGMENTATION disorders, HUMAN skin color, ALLELES

Abstract

Summary: Losses of floral pigmentation represent one of the most common evolutionary transitions in flower color, yet the genetic basis for these changes has been elucidated in only a handful of cases. Here we used crossing studies, bulk‐segregant RNA sequencing, phylogenetic analyses and functional tests to identify the gene(s) responsible for the transition to white flowers in Iochroma loxense. Crosses between I. loxense and its blue‐flowered sister species, I. cyaneum, suggested that a single locus controls the flower color difference and that the white allele causes a nearly complete loss of pigmentation. Examining sequence variation across phenotypic pools from the crosses, we found that alleles at a novel R3 MYB transcription factor were tightly associated with flower color variation. This gene, which we term MYBL1, falls into a class of MYB transcriptional repressors and, accordingly, higher expression of this gene is associated with downregulation of multiple anthocyanin pigment pathway genes. We confirmed the repressive function of MYBL1 through stable transformation of Nicotiana. The mechanism underlying the evolution of white flowers in I. loxense differs from that uncovered in previous studies, pointing to multiple mechanisms for achieving fixed transitions in flower color intensity. [ABSTRACT FROM AUTHOR]

Published

2018

20. Towards the development of a sustainable soya bean-based feedstock for aquaculture.

Author

Park, Hyunwoo, Weier, Steven, Razvi, Fareha, Peña, Pamela A., Sims, Neil A., Lowell, Jennica, Hungate, Cory, Kissinger, Karma, Key, Gavin, Fraser, Paul, Napier, Johnathan A., Cahoon, Edgar B., and Clemente, Tom E.

Subjects

SOYBEAN, PLANT development, FEEDSTOCK, AQUACULTURE, PLANT molecular biology, SOY proteins

Abstract

Soya bean ( Glycine max (L.) Merr.) is sought after for both its oil and protein components. Genetic approaches to add value to either component are ongoing efforts in soya bean breeding and molecular biology programmes. The former is the primary vegetable oil consumed in the world. Hence, its primary usage is in direct human consumption. As a means to increase its utility in feed applications, thereby expanding the market of soya bean coproducts, we investigated the simultaneous displacement of marine ingredients in aquafeeds with soya bean-based protein and a high Omega-3 fatty acid soya bean oil, enriched with alpha-linolenic and stearidonic acids, in both steelhead trout ( Oncorhynchus mykiss) and Kampachi ( Seriola rivoliana). Communicated herein are aquafeed formulations with major reduction in marine ingredients that translates to more total Omega-3 fatty acids in harvested flesh. Building off of these findings, subsequent efforts were directed towards a genetic strategy that would translate to a prototype design of an optimal identity-preserved soya bean-based feedstock for aquaculture, whereby a multigene stack approach for the targeted synthesis of two value-added output traits, eicosapentaenoic acid and the ketocarotenoid, astaxanthin, were introduced into the crop. To this end, the systematic introduction of seven transgenic cassettes into soya bean, and the molecular and phenotypic evaluation of the derived novel events are described. [ABSTRACT FROM AUTHOR]

Published

2017

21. Stacking of a stearoyl-ACP thioesterase with a dual-silenced palmitoyl-ACP thioesterase and ∆12 fatty acid desaturase in transgenic soybean

Author

Park, Hyunwoo, primary, Graef, George, additional, Xu, Yixiang, additional, Tenopir, Patrick, additional, and Clemente, Tom E., additional

Published

2014

22. Sorghum (Sorghum bicolor).

Author

Guo, Xiaomei, Ge, Zhengxiang, Sato, Shirley J., and Clemente, Tom E.

Published

2015

23. Activity of the Arabidopsis RD29A and RD29B promoter elements in soybean under water stress

Author

Bihmidine, Saadia, primary, Lin, Jiusheng, additional, Stone, Julie M., additional, Awada, Tala, additional, Specht, James E., additional, and Clemente, Tom E., additional

Published

2012

24. A high-oleic-acid and low-palmitic-acid soybean: agronomic performance and evaluation as a feedstock for biodiesel

Author

Graef, George, primary, LaVallee, Bradley J., additional, Tenopir, Patrick, additional, Tat, Mustafa, additional, Schweiger, Bruce, additional, Kinney, Anthony J., additional, Van Gerpen, Jon H., additional, and Clemente, Tom E., additional

Published

2009

25. The Chloroplast Triggers Developmental Reprogramming When MUTS HOMOLOG1 Is Suppressed in Plants.

Author

Ying-Zhi Xu, de la Rosa Santamaria, Roberto, Virdi, Kamaldeep S., Arrieta-Montiel, Maria P., Razvi, Fareha, Shaoqing Li, Guodong Ren, Bin Yu, Alexander, Danny, Lining Guo, Xuehui Feng, Dweikat, Ismail M., Clemente, Tom E., and Mackenzie, Sally A.

Subjects

CHLOROPLASTS, EUKARYOTES, ARABIDOPSIS thaliana, PLANT hormones, RNA interference

Abstract

Multicellular eukaryotes demonstrate nongenetic, heritable phenotypic versatility in their adaptation to environmental changes. This inclusive inheritance is composed of interacting epigenetic, maternal, and environmental factors. Yet-unidentified maternal effects can have a pronounced influence on plant phenotypic adaptation to changing environmental conditions. To explore the control of phenotypy in higher plants, we examined the effect of a single plant nuclear gene on the expression and transmission of phenotypic variability in Arabidopsis (Arabidopsis thaliana). MutS HOMOLOG1 (MSH1) is a plant-specific nuclear gene product that functions in both mitochondria and plastids to maintain genome stability. RNA interference suppression of the gene elicits strikingly similar programmed changes in plant growth pattern in six different plant species, changes subsequently heritable independent of the RNA interference transgene. The altered phenotypes reflect multiple pathways that are known to participate in adaptation, including altered phytohormone effects for dwarfed growth and reduced internode elongation, enhanced branching, reduced stomatal density, altered leaf morphology, delayed flowering, and extended juvenility, with conversion to perennial growth pattern in short days. Some of these effects are partially reversed with the application of gibberellic acid. Genetic hemicomplementation experiments show that this phenotypic plasticity derives from changes in chloroplast state. Our results suggest that suppression of MSH1, which occurs under several forms of abiotic stress, triggers a plastidial response process that involves nongenetic inheritance. [ABSTRACT FROM AUTHOR]

Published

2012

26. Soybean genomics research community strategic plan: A vision for 2024-2028.

Author

Stupar RM, Locke AM, Allen DK, Stacey MG, Ma J, Weiss J, Nelson RT, Hudson ME, Joshi T, Li Z, Song Q, Jedlicka JR, MacIntosh GC, Grant D, Parrott WA, Clemente TE, Stacey G, An YC, Aponte-Rivera J, Bhattacharyya MK, Baxter I, Bilyeu KD, Campbell JD, Cannon SB, Clough SJ, Curtin SJ, Diers BW, Dorrance AE, Gillman JD, Graef GL, Hancock CN, Hudson KA, Hyten DL, Kachroo A, Koebernick J, Libault M, Lorenz AJ, Mahan AL, Massman JM, McGinn M, Meksem K, Okamuro JK, Pedley KF, Rainey KM, Scaboo AM, Schmutz J, Song BH, Steinbrenner AD, Stewart-Brown BB, Toth K, Wang D, Weaver L, Zhang B, Graham MA, and O'Rourke JA

Abstract

This strategic plan summarizes the major accomplishments achieved in the last quinquennial by the soybean [Glycine max (L.) Merr.] genetics and genomics research community and outlines key priorities for the next 5 years (2024-2028). This work is the result of deliberations among over 50 soybean researchers during a 2-day workshop in St Louis, MO, USA, at the end of 2022. The plan is divided into seven traditional areas/disciplines: Breeding, Biotic Interactions, Physiology and Abiotic Stress, Functional Genomics, Biotechnology, Genomic Resources and Datasets, and Computational Resources. One additional section was added, Training the Next Generation of Soybean Researchers, when it was identified as a pressing issue during the workshop. This installment of the soybean genomics strategic plan provides a snapshot of recent progress while looking at future goals that will improve resources and enable innovation among the community of basic and applied soybean researchers. We hope that this work will inform our community and increase support for soybean research., (© 2024 The Author(s). The Plant Genome published by Wiley Periodicals LLC on behalf of Crop Science Society of America.)

Published

2024

27. Reducing stomatal density by expression of a synthetic epidermal patterning factor increases leaf intrinsic water use efficiency and reduces plant water use in a C4 crop.

Author

Ferguson JN, Schmuker P, Dmitrieva A, Quach T, Zhang T, Ge Z, Nersesian N, Sato SJ, Clemente TE, and Leakey ADB

Subjects

Plant Proteins metabolism, Plant Proteins genetics, Crops, Agricultural genetics, Crops, Agricultural growth & development, Crops, Agricultural physiology, Plant Leaves physiology, Plant Leaves metabolism, Plant Leaves growth & development, Plant Stomata physiology, Plant Stomata genetics, Water metabolism, Sorghum genetics, Sorghum physiology, Sorghum metabolism, Sorghum growth & development, Plants, Genetically Modified genetics, Photosynthesis

Abstract

Enhancing crop water use efficiency (WUE) is a key target trait for climatic resilience and expanding cultivation on marginal lands. Engineering lower stomatal density to reduce stomatal conductance (gs) has improved WUE in multiple C3 crop species. However, reducing gs in C3 species often reduces photosynthetic carbon gain. A different response is expected in C4 plants because they possess specialized anatomy and biochemistry which concentrates CO2 at the site of fixation. This modifies the relationship of photosynthesis (AN) with intracellular CO2 concentration (ci), such that photosynthesis is CO2 saturated and reductions in gs are unlikely to limit AN. To test this hypothesis, genetic strategies were investigated to reduce stomatal density in the C4 crop sorghum. Constitutive expression of a synthetic epidermal patterning factor (EPF) transgenic allele in sorghum led to reduced stomatal densities, reduced gs, reduced plant water use, and avoidance of stress during a period of water deprivation. In addition, moderate reduction in stomatal density did not increase stomatal limitation to AN. However, these positive outcomes were associated with negative pleiotropic effects on reproductive development and photosynthetic capacity. Avoiding pleiotropy by targeting expression of the transgene to specific tissues could provide a pathway to improved agronomic outcomes., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2024

28. A novel R3 MYB transcriptional repressor associated with the loss of floral pigmentation in Iochroma.

Author

Gates DJ, Olson BJSC, Clemente TE, and Smith SD

Subjects

Amino Acid Sequence, Anthocyanins metabolism, Bayes Theorem, Chromosome Segregation genetics, Crosses, Genetic, Flowers genetics, Gene Expression Regulation, Plant, Genetic Loci, Models, Biological, Phenotype, Phylogeny, Plant Proteins chemistry, Plant Proteins genetics, Repressor Proteins chemistry, Repressor Proteins genetics, Solanaceae genetics, Nicotiana metabolism, Flowers physiology, Pigmentation, Plant Proteins metabolism, Repressor Proteins metabolism, Solanaceae physiology

Abstract

Losses of floral pigmentation represent one of the most common evolutionary transitions in flower color, yet the genetic basis for these changes has been elucidated in only a handful of cases. Here we used crossing studies, bulk-segregant RNA sequencing, phylogenetic analyses and functional tests to identify the gene(s) responsible for the transition to white flowers in Iochroma loxense. Crosses between I. loxense and its blue-flowered sister species, I. cyaneum, suggested that a single locus controls the flower color difference and that the white allele causes a nearly complete loss of pigmentation. Examining sequence variation across phenotypic pools from the crosses, we found that alleles at a novel R3 MYB transcription factor were tightly associated with flower color variation. This gene, which we term MYBL1, falls into a class of MYB transcriptional repressors and, accordingly, higher expression of this gene is associated with downregulation of multiple anthocyanin pigment pathway genes. We confirmed the repressive function of MYBL1 through stable transformation of Nicotiana. The mechanism underlying the evolution of white flowers in I. loxense differs from that uncovered in previous studies, pointing to multiple mechanisms for achieving fixed transitions in flower color intensity., (© 2017 The Authors. New Phytologist © 2017 New Phytologist Trust.)

Published

2018

29. Sorghum (Sorghum bicolor).

Author

Guo X, Ge Z, Sato SJ, and Clemente TE

Subjects

Agriculture methods, Agrobacterium tumefaciens genetics, Coculture Techniques, Plants, Genetically Modified, Pollen genetics, Seeds genetics, Sorghum growth & development, Sterilization, Transformation, Bacterial, Genetic Techniques, Sorghum genetics

Abstract

Agrobacterium-mediated transformation of sorghum (Sorghum bicolor L. Moench) targeting immature embryo explants is a route to introduce transgenic alleles into the crop. The protocol requires maintenance of quality stock plants under greenhouse conditions for a constant supply of immature embryo explants. This is typically carried out by a regular sowing of seeds, minimal use of pesticides, and monitoring of plants to document pollen dispersal and bagging of heads. The time frame from explant inoculation to establishment of a primary transgenic event in the greenhouse typically ranges from 4 to 6 months. Seed set in the primary transformants is comparable to greenhouse-grown stock plants, with the majority of the transgenic alleles being inherited as a single functional locus.

Published

2015