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1.
Plant Cell ; 33(10): 3348-3366, 2021 10 11.
Artículo en Inglés | MEDLINE | ID: mdl-34323976

RESUMEN

Carbohydrate partitioning from leaves to sink tissues is essential for plant growth and development. The maize (Zea mays) recessive carbohydrate partitioning defective28 (cpd28) and cpd47 mutants exhibit leaf chlorosis and accumulation of starch and soluble sugars. Transport studies with 14C-sucrose (Suc) found drastically decreased export from mature leaves in cpd28 and cpd47 mutants relative to wild-type siblings. Consistent with decreased Suc export, cpd28 mutants exhibited decreased phloem pressure in mature leaves, and altered phloem cell wall ultrastructure in immature and mature leaves. We identified the causative mutations in the Brittle Stalk2-Like3 (Bk2L3) gene, a member of the COBRA family, which is involved in cell wall development across angiosperms. None of the previously characterized COBRA genes are reported to affect carbohydrate export. Consistent with other characterized COBRA members, the BK2L3 protein localized to the plasma membrane, and the mutants condition a dwarf phenotype in dark-grown shoots and primary roots, as well as the loss of anisotropic cell elongation in the root elongation zone. Likewise, both mutants exhibit a significant cellulose deficiency in mature leaves. Therefore, Bk2L3 functions in tissue growth and cell wall development, and this work elucidates a unique connection between cellulose deposition in the phloem and whole-plant carbohydrate partitioning.


Asunto(s)
Metabolismo de los Hidratos de Carbono , Pared Celular/metabolismo , Proteínas de Plantas/genética , Zea mays/genética , Proteínas de Plantas/metabolismo , Zea mays/metabolismo
2.
J Exp Bot ; 69(16): 3917-3931, 2018 07 18.
Artículo en Inglés | MEDLINE | ID: mdl-29846660

RESUMEN

Plants synthesize carbohydrates in photosynthetic tissues, with the majority of plants transporting sucrose to non-photosynthetic tissues to sustain growth and development. While the anatomical, biochemical, and physiological processes regulating sucrose long-distance transport are well characterized, little is known concerning the genes controlling whole-plant carbohydrate partitioning. To identify loci influencing carbon export from leaves, we screened mutagenized maize plants for phenotypes associated with reduced carbohydrate transport, including chlorosis and excessive starch and soluble sugars in leaves. Carbohydrate partitioning defective1 (Cpd1) was identified as a semi-dominant mutant exhibiting these phenotypes. Phloem transport experiments suggested that the hyperaccumulation of starch and soluble sugars in the Cpd1/+ mutant leaves was due to inhibited sucrose export. Interestingly, ectopic callose deposits were observed in the phloem of mutant leaves, and probably underlie the decreased transport. In addition to the carbohydrate hyperaccumulation phenotype, Cpd1/+ mutants overaccumulate benzoxazinoid defense compounds and exhibit increased tolerance when attacked by aphids. However, double mutant studies between Cpd1/+ and benzoxazinoid-less plants indicate that the ectopic callose and carbon hyperaccumulation are independent of benzoxazinoid production. Based on the formation of callose occlusions in the developing phloem, we hypothesize that the cpd1 gene functions early in phloem development, thereby impacting whole-plant carbohydrate partitioning.


Asunto(s)
Glucanos/metabolismo , Floema/metabolismo , Proteínas de Plantas/fisiología , Sacarosa/metabolismo , Zea mays/metabolismo , Animales , Áfidos/fisiología , Benzoxazinas/metabolismo , Transporte Biológico , Lepidópteros/fisiología , Lignina/metabolismo , Mutación , Pigmentos Biológicos/metabolismo , Hojas de la Planta/metabolismo , Proteínas de Plantas/genética , Zea mays/genética , Zea mays/parasitología
3.
BMC Plant Biol ; 15: 186, 2015 Jul 30.
Artículo en Inglés | MEDLINE | ID: mdl-26223524

RESUMEN

BACKGROUND: Sorghum (Sorghum bicolor L. Moench) cultivars store non-structural carbohydrates predominantly as either starch in seeds (grain sorghums) or sugars in stems (sweet sorghums). Previous research determined that sucrose accumulation in sweet sorghum stems was not correlated with the activities of enzymes functioning in sucrose metabolism, and that an apoplasmic transport step may be involved in stem sucrose accumulation. However, the sucrose unloading pathway from stem phloem to storage parenchyma cells remains unelucidated. Sucrose transporters (SUTs) transport sucrose across membranes, and have been proposed to function in sucrose partitioning differences between sweet and grain sorghums. The purpose of this study was to characterize the key differences in carbohydrate accumulation between a sweet and a grain sorghum, to define the path sucrose may follow for accumulation in sorghum stems, and to determine the roles played by sorghum SUTs in stem sucrose accumulation. RESULTS: Dye tracer studies to determine the sucrose transport route revealed that, for both the sweet sorghum cultivar Wray and grain sorghum cultivar Macia, the phloem in the stem veins was symplasmically isolated from surrounding cells, suggesting sucrose was apoplasmically unloaded. Once in the phloem apoplasm, a soluble tracer diffused from the vein to stem parenchyma cell walls, indicating the lignified mestome sheath encompassing the vein did not prevent apoplasmic flux outside of the vein. To characterize carbohydrate partitioning differences between Wray and Macia, we compared the growth, stem juice volume, solute contents, SbSUTs gene expression, and additional traits. Contrary to previous findings, we detected no significant differences in SbSUTs gene expression within stem tissues. CONCLUSIONS: Phloem sieve tubes within sweet and grain sorghum stems are symplasmically isolated from surrounding cells; hence, unloading from the phloem likely occurs apoplasmically, thereby defining the location of the previously postulated step for sucrose transport. Additionally, no changes in SbSUTs gene expression were detected in sweet vs. grain sorghum stems, suggesting alterations in SbSUT transcript levels do not account for the carbohydrate partitioning differences between cultivars. A model illustrating sucrose phloem unloading and movement to stem storage parenchyma, and highlighting roles for sucrose transport proteins in sorghum stems is discussed.


Asunto(s)
Metabolismo de los Hidratos de Carbono , Regulación de la Expresión Génica de las Plantas , Proteínas de Transporte de Membrana/genética , Proteínas de Plantas/genética , Sorghum/genética , Sacarosa/metabolismo , Transporte Biológico , Proteínas de Transporte de Membrana/metabolismo , Modelos Biológicos , Proteínas de Plantas/metabolismo , Tallos de la Planta/metabolismo , Sorghum/metabolismo
4.
Planta ; 240(1): 209-21, 2014 Jul.
Artículo en Inglés | MEDLINE | ID: mdl-24797278

RESUMEN

MAIN CONCLUSIONS: A Chlorovirus aquaglyceroporin expressed in tobacco is localized to the plastid and plasma membranes. Transgenic events display improved response to water deficit. Necrosis in adult stage plants is observed. Aquaglyceroporins are a subclass of the water channel aquaporin proteins (AQPs) that transport glycerol along with other small molecules transcellular in addition to water. In the studies communicated herein, we analyzed the expression of the aquaglyceroporin gene designated, aqpv1, from Chlorovirus MT325, in tobacco (Nicotiana tabacum), along with phenotypic changes induced by aqpv1 expression in planta. Interestingly, aqpv1 expression under control of either a constitutive or a root-preferred promoter, triggered local lesion formation in older leaves, which progressed significantly after induction of flowering. Fusion of aqpv1 with GFP suggests that the protein localized to the plasmalemma, and potentially with plastid and endoplasmic reticulum membranes. Physiological characterizations of transgenic plants during juvenile stage growth were monitored for potential mitigation to water dry-down (i.e., drought) and recovery. Phenotypic analyses on drought mimic/recovery of juvenile transgenic plants that expressed a functional aqpv1 transgene had higher photosynthetic rates, stomatal conductance, and water use efficiency, along with maximum carboxylation and electron transport rates when compared to control plants. These physiological attributes permitted the juvenile aqpv1 transgenic plants to perform better under drought-mimicked conditions and hastened recovery following re-watering. This drought mitigation effect is linked to the ability of the transgenic plants to maintain cell turgor.


Asunto(s)
Acuagliceroporinas/genética , Nicotiana/fisiología , Phycodnaviridae/genética , Estrés Fisiológico , Agua/metabolismo , Acuagliceroporinas/metabolismo , Transporte Biológico , Biomasa , Membrana Celular/metabolismo , Deshidratación , Flores/genética , Flores/crecimiento & desarrollo , Flores/fisiología , Expresión Génica , Regulación de la Expresión Génica de las Plantas , Genes Reporteros , Ósmosis , Hojas de la Planta/genética , Hojas de la Planta/crecimiento & desarrollo , Hojas de la Planta/fisiología , Raíces de Plantas/genética , Raíces de Plantas/crecimiento & desarrollo , Raíces de Plantas/fisiología , Plantas Modificadas Genéticamente , Plastidios/metabolismo , Nicotiana/genética , Nicotiana/crecimiento & desarrollo , Transgenes , Proteínas Virales/genética , Proteínas Virales/metabolismo
5.
Planta ; 237(1): 55-64, 2013 Jan.
Artículo en Inglés | MEDLINE | ID: mdl-22983672

RESUMEN

The constitutive and drought-induced activities of the Arabidopsis thaliana RD29A and RD29B promoters were monitored in soybean (Glycine max (L.) Merr.] via fusions with the visual marker gene ß-glucuronidase (GUS). Physiological responses of soybean plants were monitored over 9 days of water deprivation under greenhouse conditions. Data were used to select appropriate time points to monitor the activities of the respective promoter elements. Qualitative and quantitative assays for GUS expression were conducted in root and leaf tissues, from plants under well-watered and dry-down conditions. Both RD29A and RD29B promoters were significantly activated in soybean plants subjected to dry-down conditions. However, a low level of constitutive promoter activity was also observed in both root and leaves of plants under well-watered conditions. GUS expression was notably higher in roots than in leaves. These observations suggest that the respective drought-responsive regulatory elements present in the RD29X promoters may be useful in controlling targeted transgenes to mitigate abiotic stress in soybean, provided the transgene under control of these promoters does not invoke agronomic penalties with leaky expression when no abiotic stress is imposed.


Asunto(s)
Proteínas de Arabidopsis/genética , Regulación de la Expresión Génica de las Plantas/efectos de los fármacos , Glycine max/genética , Regiones Promotoras Genéticas/genética , Agua/farmacología , Southern Blotting , Sequías , Fluorometría , Glucuronidasa/genética , Glucuronidasa/metabolismo , Histocitoquímica , Plantas Modificadas Genéticamente , Glycine max/metabolismo
6.
Mol Plant ; 12(9): 1278-1293, 2019 09 02.
Artículo en Inglés | MEDLINE | ID: mdl-31102785

RESUMEN

To sustain plant growth, development, and crop yield, sucrose must be transported from leaves to distant parts of the plant, such as seeds and roots. To identify genes that regulate sucrose accumulation and transport in maize (Zea mays), we isolated carbohydrate partitioning defective33 (cpd33), a recessive mutant that accumulated excess starch and soluble sugars in mature leaves. The cpd33 mutants also exhibited chlorosis in the leaf blades, greatly diminished plant growth, and reduced fertility. Cpd33 encodes a protein containing multiple C2 domains and transmembrane regions. Subcellular localization experiments showed the CPD33 protein localized to plasmodesmata (PD), the plasma membrane, and the endoplasmic reticulum. We also found that a loss-of-function mutant of the CPD33 homolog in Arabidopsis, QUIRKY, had a similar carbohydrate hyperaccumulation phenotype. Radioactively labeled sucrose transport assays showed that sucrose export was significantly lower in cpd33 mutant leaves relative to wild-type leaves. However, PD transport in the adaxial-abaxial direction was unaffected in cpd33 mutant leaves. Intriguingly, transmission electron microscopy revealed fewer PD at the companion cell-sieve element interface in mutant phloem tissue, providing a possible explanation for the reduced sucrose export in mutant leaves. Collectively, our results suggest that CPD33 functions to promote symplastic transport into sieve elements.


Asunto(s)
Hojas de la Planta/metabolismo , Sacarosa/metabolismo , Zea mays/metabolismo , Transporte Biológico/genética , Transporte Biológico/fisiología , Regulación de la Expresión Génica de las Plantas/genética , Regulación de la Expresión Génica de las Plantas/fisiología , Floema/metabolismo , Plasmodesmos/metabolismo
7.
J Plant Physiol ; 212: 58-68, 2017 May.
Artículo en Inglés | MEDLINE | ID: mdl-28273517

RESUMEN

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.


Asunto(s)
Dióxido de Carbono/metabolismo , Cianobacterias/genética , Glycine max/genética , Glycine max/metabolismo , Proteínas de la Membrana/genética , Proteínas de la Membrana/farmacología , Fotosíntesis/efectos de los fármacos , Agrobacterium tumefaciens/genética , Proteínas Bacterianas/genética , Proteínas Bacterianas/metabolismo , Proteínas Bacterianas/farmacología , Biomasa , Producción de Cultivos , Cianobacterias/metabolismo , ADN de Plantas , Regulación de la Expresión Génica de las Plantas , Genes de Plantas/genética , Proteínas de la Membrana/metabolismo , Hojas de la Planta/metabolismo , Plantas Modificadas Genéticamente/genética , Plantas Modificadas Genéticamente/crecimiento & desarrollo , Plantas Modificadas Genéticamente/metabolismo , Semillas/crecimiento & desarrollo , Glycine max/crecimiento & desarrollo , Transformación Genética
8.
Plant Signal Behav ; 11(1): e1117721, 2016.
Artículo en Inglés | MEDLINE | ID: mdl-26619184

RESUMEN

Carbohydrates are differentially partitioned in sweet versus grain sorghums. While the latter preferentially accumulate starch in the grain, the former primarily store large amounts of sucrose in the stem. Previous work determined that neither sucrose metabolizing enzymes nor changes in Sucrose transporter (SUT) gene expression accounted for the carbohydrate partitioning differences. Recently, 2 additional classes of sucrose transport proteins, Tonoplast Sugar Transporters (TSTs) and SWEETs, were identified; thus, we examined whether their expression tracked sucrose accumulation in sweet sorghum stems. We determined 2 TSTs were differentially expressed in sweet vs. grain sorghum stems, likely underlying the massive difference in sucrose accumulation. A model illustrating potential roles for different classes of sugar transport proteins in sorghum sugar partitioning is discussed.


Asunto(s)
Metabolismo de los Hidratos de Carbono , Proteínas de Transporte de Membrana/metabolismo , Proteínas de Plantas/metabolismo , Tallos de la Planta/metabolismo , Sorghum/metabolismo , Sacarosa/metabolismo , Vacuolas/metabolismo , Metabolismo de los Hidratos de Carbono/genética , Regulación de la Expresión Génica de las Plantas , Genes de Plantas , Proteínas de Transporte de Membrana/genética , Modelos Biológicos , Hojas de la Planta/genética , Proteínas de Plantas/genética , Tallos de la Planta/genética , Análisis de Secuencia de ARN , Sorghum/genética
9.
PLoS One ; 10(5): e0128989, 2015.
Artículo en Inglés | MEDLINE | ID: mdl-26024520

RESUMEN

Sugars produced from photosynthesis in leaves are transported through the phloem tissues within veins and delivered to non-photosynthetic organs, such as roots, stems, flowers, and seeds, to support their growth and/or storage of carbohydrates. However, because the phloem is located internally within the veins, it is difficult to access and to study the dynamics of sugar transport. Radioactive tracers have been extensively used to study vascular transport in plants and have provided great insights into transport dynamics. To better study sucrose partitioning in vivo, a novel radioactive analog of sucrose was synthesized through a completely chemical synthesis route by substituting fluorine-18 (half-life 110 min) at the 6' position to generate 6'-deoxy-6'[(18)F]fluorosucrose ((18)FS). This radiotracer was then used to compare sucrose transport between wild-type maize plants and mutant plants lacking the Sucrose transporter1 (Sut1) gene, which has been shown to function in sucrose phloem loading. Our results demonstrate that (18)FS is transported in vivo, with the wild-type plants showing a greater rate of transport down the leaf blade than the sut1 mutant plants. A similar transport pattern was also observed for universally labeled [U-(14)C]sucrose ([U-(14)C]suc). Our findings support the proposed sucrose phloem loading function of the Sut1 gene in maize, and additionally demonstrate that the (18)FS analog is a valuable, new tool that offers imaging advantages over [U-(14)C]suc for studying phloem transport in plants.


Asunto(s)
Radioisótopos de Flúor , Hidrocarburos Fluorados , Marcaje Isotópico , Hojas de la Planta/metabolismo , Sacarosa/análogos & derivados , Zea mays/metabolismo , Transporte Biológico Activo/fisiología , Radioisótopos de Flúor/farmacocinética , Radioisótopos de Flúor/farmacología , Hidrocarburos Fluorados/síntesis química , Hidrocarburos Fluorados/química , Hidrocarburos Fluorados/farmacocinética , Hidrocarburos Fluorados/farmacología , Proteínas de Transporte de Monosacáridos/metabolismo , Proteínas de Plantas/metabolismo , Sacarosa/síntesis química , Sacarosa/química , Sacarosa/farmacocinética , Sacarosa/farmacología
10.
G3 (Bethesda) ; 4(6): 1143-5, 2014 Apr 17.
Artículo en Inglés | MEDLINE | ID: mdl-24747759

RESUMEN

Positional cloning in maize (Zea mays) requires development of markers in the region of interest. We found that primers designed to amplify annotated insertion-deletion polymorphisms of seven base pairs or greater between B73 and Mo17 produce polymorphic markers at a 97% frequency with 49% of the products showing co-dominant fragment length polymorphisms. When the same polymorphisms are used to develop markers for B73 and W22 or Mo17 and W22 mapping populations, 22% and 31% of markers are co-dominant, respectively. There are 38,223 Indel polymorphisms that can be converted to markers providing high-density coverage throughout the maize genome. This strategy significantly increases the efficiency of marker development for fine-mapping in maize.


Asunto(s)
Marcadores Genéticos , Mutación INDEL , Polimorfismo de Nucleótido Simple , Zea mays/genética , Mapeo Cromosómico , Cromosomas de las Plantas , Bases de Datos de Ácidos Nucleicos , Sitios Genéticos
11.
Front Plant Sci ; 4: 177, 2013.
Artículo en Inglés | MEDLINE | ID: mdl-23761804

RESUMEN

Recent developments have altered our view of molecular mechanisms that determine sink strength, defined here as the capacity of non-photosynthetic structures to compete for import of photoassimilates. We review new findings from diverse systems, including stems, seeds, flowers, and fruits. An important advance has been the identification of new transporters and facilitators with major roles in the accumulation and equilibration of sugars at a cellular level. Exactly where each exerts its effect varies among systems. Sugarcane and sweet sorghum stems, for example, both accumulate high levels of sucrose, but may do so via different paths. The distinction is central to strategies for targeted manipulation of sink strength using transporter genes, and shows the importance of system-specific analyses. Another major advance has been the identification of deep hypoxia as a feature of normal grain development. This means that molecular drivers of sink strength in endosperm operate in very low oxygen levels, and under metabolic conditions quite different than previously assumed. Successful enhancement of sink strength has nonetheless been achieved in grains by up-regulating genes for starch biosynthesis. Additionally, our understanding of sink strength is enhanced by awareness of the dual roles played by invertases (INVs), not only in sucrose metabolism, but also in production of the hexose sugar signals that regulate cell cycle and cell division programs. These contributions of INV to cell expansion and division prove to be vital for establishment of young sinks ranging from flowers to fruit. Since INV genes are themselves sugar-responsive "feast genes," they can mediate a feed-forward enhancement of sink strength when assimilates are abundant. Greater overall productivity and yield have thus been attained in key instances, indicating that even broader enhancements may be achievable as we discover the detailed molecular mechanisms that drive sink strength in diverse systems.

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