The sorghum SWEET gene family: stem sucrose accumulation as revealed through transcriptome profiling

Mizuno, Hiroshi; Kasuga, Shigemitsu; Kawahigashi, Hiroyuki

doi:10.1186/s13068-016-0546-6

Cited by 104 publications

(89 citation statements)

References 54 publications

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“…Of those 41 aquaporins the expression of 16, primarily NIPs and TIPs, was relatively low. However, PIP1;2, PIP2;1 , and NIP2;2 homologs were all highly expressed in pith and rind of sorghum plants after heading, which is consistent with our findings for the S. viridis homologs of these genes ( Figure 2 ; Mizuno et al, 2016). Comparisons with other gene expression studies for C 4 grass stem tissues were not possible as in most studies the internode tissue has not been separated into different developmental zones or the study has not reported aquaporin expression (Carson and Botha, 2000, 2002; Casu et al, 2007).…”

Section: Discussionsupporting

confidence: 91%

“…In mature S. viridis internode tissues, the transcript levels of TIPs and NIPs was generally low with the exception of SvNIP2;2, SvTIP4;2 , and SvTIP1;2. In a sorghum stem transcriptome report investigating SWEET gene involvement in sucrose accumulation, we note that transcripts for all 41 sorghum aquaporins were detected in pith and rind tissues in 60-day-old plants (Reddy et al, 2015; Mizuno et al, 2016). Of those 41 aquaporins the expression of 16, primarily NIPs and TIPs, was relatively low.…”

Section: Discussionmentioning

confidence: 89%

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Roles of Aquaporins in Setaria viridis Stem Development and Sugar Storage

et al. 2016

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Setaria viridis is a C4 grass used as a model for bioenergy feedstocks. The elongating internodes in developing S. viridis stems grow from an intercalary meristem at the base, and progress acropetally toward fully expanded cells that store sugar. During stem development and maturation, water flow is a driver of cell expansion and sugar delivery. As aquaporin proteins are implicated in regulating water flow, we analyzed elongating and mature internode transcriptomes to identify putative aquaporin encoding genes that had particularly high transcript levels during the distinct stages of internode cell expansion and maturation. We observed that SvPIP2;1 was highly expressed in internode regions undergoing cell expansion, and SvNIP2;2 was highly expressed in mature sugar accumulating regions. Gene co-expression analysis revealed SvNIP2;2 expression was highly correlated with the expression of five putative sugar transporters expressed in the S. viridis internode. To explore the function of the proteins encoded by SvPIP2;1 and SvNIP2;2, we expressed them in Xenopus laevis oocytes and tested their permeability to water. SvPIP2;1 and SvNIP2;2 functioned as water channels in X. laevis oocytes and their permeability was gated by pH. Our results indicate that SvPIP2;1 may function as a water channel in developing stems undergoing cell expansion and SvNIP2;2 is a candidate for retrieving water and possibly a yet to be determined solute from mature internodes. Future research will investigate whether changing the function of these proteins influences stem growth and sugar yield in S. viridis.

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Section: Discussionsupporting

confidence: 91%

Section: Discussionmentioning

confidence: 89%

Roles of Aquaporins in Setaria viridis Stem Development and Sugar Storage

et al. 2016

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“…Particularly, SbTST4‐1 expression in RIO was dramatically higher than those in R9188/BTx406. Comparison of SbSUT2 and SbTST4‐1 expression patterns between the three genotypes, together with similar expression profiles in other sweet sorghum lines (Bihmidine et al ., ; Mizuno et al ., ), strongly indicated roles in sucrose import for stem storage sink (Figure S20). For SWEET s, 16 genes were expressed with Sb SWEET7‐1 (Sobic.007G191200) introgressed from BTx406 into R9188.…”

Section: Resultsmentioning

confidence: 85%

Transcriptome and metabolome reveal distinct carbon allocation patterns during internode sugar accumulation in different sorghum genotypes

Wang

Feng

et al. 2018

Plant Biotechnology Journal

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Sweet sorghum accumulates large amounts of soluble sugar in its stem. However, a system-based understanding of this carbohydrate allocation process is lacking. Here, we compared the dynamic transcriptome and metabolome between the conversion line R9188 and its two parents, sweet sorghum RIO and grain sorghum BTx406 that have contrasting sugar-accumulating phenotypes. We identified two features of sucrose metabolism, stable concentrations of sugar phosphates in RIO and opposite trend of trehalose-6-phosphate (T6P) between RIO vs R9188/BTx406. Integration of transcriptome and metabolome revealed R9188 is partially active in starch metabolism together with medium sucrose level, whereas sweet sorghum had the highest sucrose concentration and remained highly active in sucrose, starch, and cell wall metabolism post-anthesis. Similar expression pattern of genes involved in sucrose degradation decreased the pool of sugar phosphates for precursors of starch and cell wall synthesis in R9188 and BTx406. Differential T6P signal between RIO vs R9188/BTx406 is associated with introgression of T6P regulators from BTx406 into R9188, including C-group bZIP and trehalose 6-phosphate phosphatase (TPP). The inverted T6P signalling in R9188 appears to down-regulate sucrose and starch metabolism partly through transcriptome reprogramming, whereas introgressed metabolic genes could be related to reduced cell wall metabolism. Our results show that coordinated primary metabolic pathways lead to high sucrose demand and accumulation in sweet sorghum, providing us with targets for genetic improvements of carbohydrate allocation in bioenergy crops.

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“…Concomitant with the genetic and biochemical characterization of transporters, there have been correlative studies hinting at the contribution of transporter gene expression to sugar content in sink tissue. For example, transcriptomic analyses of fruit development in apple (Wei et al ., ), grape (Afoufa‐Bastien et al ., ), pear (Li et al ., ), banana (Miao et al ., ) and tomato (Reuscher et al ., ; Feng et al ., ), as well as the development of sweet sorghum stems (Mizuno et al ., ) and sugar beet roots (Jung et al ., ), all point to members of sugar transporter families in which expression patterns coincide with sugar accumulation patterns. A combined proteomic and transcriptomic study of sugar beet tonoplast membranes led to the identification and characterization of BvTST (tonoplast sugar transporter), which is likely to be responsible for the high sucrose accumulation characteristic of sugar beet roots (Jung et al ., ), and which functions in consort with the leaf phloem‐localized sucrose loading transporter BvSUT in determining a source–sink interaction influenced by respective push and pull transporters (Nieberl et al ., ).…”

Section: Discussionmentioning

confidence: 99%

Natural genetic variation for expression of a SWEET transporter among wild species of Solanum lycopersicum (tomato) determines the hexose composition of ripening tomato fruit

et al. 2018

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The sugar content of Solanum lycopersicum (tomato) fruit is a primary determinant of taste and quality. Cultivated tomato fruit are characterized by near-equimolar levels of the hexoses glucose and fructose, derived from the hydrolysis of translocated sucrose. As fructose is perceived as approximately twice as sweet as glucose, increasing its concentration at the expense of glucose can improve tomato fruit taste. Introgressions of the Fgr allele from the wild species Solanum habrochaites (LA1777) into cultivated tomato increased the fructose-to-glucose ratio of the ripe fruit by reducing glucose levels and concomitantly increasing fructose levels. In order to identify the function of the Fgr gene, we combined a fine-mapping strategy with RNAseq differential expression analysis of near-isogenic tomato lines. The results indicated that a SWEET protein was strongly upregulated in the lines with a high fructose-to-glucose ratio. Overexpressing the SWEET protein in transgenic tomato plants dramatically reduced the glucose levels and increased the fructose : glucose ratio in the developing fruit, thereby proving the function of the protein. The SWEET protein was localized to the plasma membrane and expression of the SlFgr gene in a yeast line lacking native hexose transporters complemented growth with glucose, but not with fructose. These results indicate that the SlFgr gene encodes a plasma membrane-localized glucose efflux transporter of the SWEET family, the overexpression of which reduces glucose levels and may allow for increased fructose levels. This article identifies the function of the tomato Fgr gene as a SWEET transporter, the upregulation of which leads to a modified sugar accumulation pattern in the fleshy fruit. The results point to the potential of the inedible wild species to improve fruit sugar accumulation via sugar transport mechanisms.

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The sorghum SWEET gene family: stem sucrose accumulation as revealed through transcriptome profiling

Cited by 104 publications

References 54 publications

Roles of Aquaporins in Setaria viridis Stem Development and Sugar Storage

Roles of Aquaporins in Setaria viridis Stem Development and Sugar Storage

Transcriptome and metabolome reveal distinct carbon allocation patterns during internode sugar accumulation in different sorghum genotypes

Natural genetic variation for expression of a SWEET transporter among wild species of Solanum lycopersicum (tomato) determines the hexose composition of ripening tomato fruit

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