Sugarcane genes associated with sucrose content

Papini-Terzi, Flávia Stal; Rocha, Flávia Riso; Vêncio, Ricardo Z. N.; Felix, Juliana M.; Branco, Diana S.; Waclawovsky, Alessandro Jaquiel; Del-Bem, Luiz-Eduardo; Lembke, Carolina Gimiliani; Costa, Maximiller D. L.; Nishiyama, Milton Yutaka; Vicentini, Renato; Vincentz, Michel; Ulian, E. C.; Menossi, Marcelo; Souza, Gláucia Mendes

doi:10.1186/1471-2164-10-120

Cited by 142 publications

(146 citation statements)

References 91 publications

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“…The reactions were incubated at 95°C for 10 min, followed by 40 cycles at 95°C for 15 s and 60°C for 1 min as described by Varkonyi-Gasic et al (14). The sugarcane polyubiquitin gene (CA179923) was used as a reference sample (15) using the primers that are described in Table 1. The reactions were conducted with three biological replicates, each in triplicate.…”

Section: Methodsmentioning

confidence: 99%

Oligomerization, Membrane Association, and in Vivo Phosphorylation of Sugarcane UDP-glucose Pyrophosphorylase

Soares

Gentile

Scorsato

et al. 2014

Journal of Biological Chemistry

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Background: UDP-glucose pyrophosphorylase (UGPase) is a key enzyme in the biosynthesis of sucrose and the cell wall. Results: UGPase was phosphorylated in and associated with the membrane in vivo. Redox modification modulated UGPase activity by changing its oligomeric state. Conclusion: Phosphorylation, redox modification, and oligomerization regulate UGPase. Significance: Our data broaden the understanding of biomass biosynthesis in the bioenergy crop sugarcane.

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Section: Methodsmentioning

confidence: 99%

Oligomerization, Membrane Association, and in Vivo Phosphorylation of Sugarcane UDP-glucose Pyrophosphorylase

Soares

Gentile

Scorsato

et al. 2014

Journal of Biological Chemistry

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“…This question has marked the evolution of evolutionary theory ever since the rediscovery of Mendel's work at the beginning of the twentieth century, which immediately generated an apparent conflict with the Darwinian view of gradual evolution (Mayr & Provine 1998). Famously, the answer proposed by the architects of the Modern Synthesis is that genes determine phenotypes, as in the oft-cited metaphors of a 'genetic blueprint' or a 'genetic programme' (for recent examples of usage, see Cuntz et al 2008;Larsen 2008;Shoguchi et al 2008;Papini-Terzi et al 2009). This sort of answer bypasses the process of development, which is treated as an incidental blackbox with no direct causal relevance to the evolutionary process.…”

Section: Introduction: Genetic Blueprints and Genotype -Phenotype Mapmentioning

confidence: 99%

Genotype–phenotype mapping and the end of the ‘genes as blueprint’ metaphor

Pigliucci

2010

Phil. Trans. R. Soc. B

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142

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In a now classic paper published in 1991, Alberch introduced the concept of genotype -phenotype (G!P) mapping to provide a framework for a more sophisticated discussion of the integration between genetics and developmental biology that was then available. The advent of evo-devo first and of the genomic era later would seem to have superseded talk of transitions in phenotypic space and the like, central to Alberch's approach. On the contrary, this paper shows that recent empirical and theoretical advances have only sharpened the need for a different conceptual treatment of how phenotypes are produced. Old-fashioned metaphors like genetic blueprint and genetic programme are not only woefully inadequate but positively misleading about the nature of G!P, and are being replaced by an algorithmic approach emerging from the study of a variety of actual G!P maps. These include RNA folding, protein function and the study of evolvable software. Some generalities are emerging from these disparate fields of analysis, and I suggest that the concept of 'developmental encoding' (as opposed to the classical one of genetic encoding) provides a promising computational -theoretical underpinning to coherently integrate ideas on evolvability, modularity and robustness and foster a fruitful framing of the G!P mapping problem.

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“…The use of cDNA microarrays to evaluate an F 1 sugarcane population that segregates for a certain trait may provide more insight into plant signaling and gene function than classical mutagenesis studies [30]. Recently, Casu et al [7] and Papini-Terzi et al [37,38] used this strategy to identify genes associated with high sucrose accumulation in sugarcane stem. The genomics approach has been the method of choice in the search for coarse regulatory mechanisms of sugarcane sucrose accumulation and signaling [3-7, 28, 37, 38].…”

Section: Introductionmentioning

confidence: 99%

Expression Profile of Signal Transduction Components in a Sugarcane Population Segregating for Sugar Content

Felix

Papini-Terzi

Rocha

et al. 2009

Tropical Plant Biol.

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Sucrose is the major product of photosynthesis in many higher plants. It is transported from the source tissue through the phloem to various sink tissues to support plant growth, development and reproduction. Knowledge on the signal transduction pathways involved in sucrose synthesis in mature leaves is limited. Using a microarray approach, we analyzed the expression profiles of 1920 sugarcane genes encoding signal transduction elements, transcription factors and stress-related proteins. We used individuals from a population segregating for sugar content and gene expression profiles were obtained from seven individuals with highest and seven with lowest sugar content. Surprisingly, from the 24 differentially expressed genes, 19 were more expressed in plants containing low-sugar content. Three of these genes encoded 14-3-3 like proteins, which have been found to reduce sucrose phosphate synthase (SPS) activity. Another encoded an SNF1-related protein similar to a protein kinase that phosphorylates SPS in vitro making it a target for the interaction with 14-3-3 proteins. The up-regulation of eight stress related genes in the lower sugar content plants supports a view that sugar levels modulate a complex signal transduction network that seems to involve responses that are related to stress. Evidence that hormone signaling is related to the sucrose content was also found. These data reinforced the usefulness of genomic approaches to uncover how sucrose metabolism can be regulated in sugarcane.

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Sugarcane genes associated with sucrose content

Cited by 142 publications

References 91 publications

Oligomerization, Membrane Association, and in Vivo Phosphorylation of Sugarcane UDP-glucose Pyrophosphorylase

Oligomerization, Membrane Association, and in Vivo Phosphorylation of Sugarcane UDP-glucose Pyrophosphorylase

Genotype–phenotype mapping and the end of the ‘genes as blueprint’ metaphor

Expression Profile of Signal Transduction Components in a Sugarcane Population Segregating for Sugar Content

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