Physiological and transcriptional analyses of developmental stages along sugarcane leaf

Mattiello, Lúcia; Riaño-Pachón, Diego Mauricio; Martins, Marina C. M.; Cruz, Larissa Prado da; Bassi, D.; Marchiori, Paulo Eduardo Ribeiro; Ribeiro, Rafael Vasconcelos; Labate, Mônica Teresa Veneziano; Labate, Carlos Alberto; Menossi, Marcelo

doi:10.1186/s12870-015-0694-z

Cited by 61 publications

(60 citation statements)

References 203 publications

(190 reference statements)

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“…The largest collection of sugarcane ESTs was generated by the SUCEST project from cDNA libraries of different tissues from several sugarcane varieties (Vettore et al., ) and was important for sugarcane gene discovery, transcript profiling, genome exploration and transcriptome and proteome analysis. Recently, the transcriptome analysis by next‐generation sequencing technology RNA‐seq has furnished important data to identify molecular key intermediaries of cell wall biosynthetic mechanism and of biomass yield and recalcitrance (Mattiello et al., ; Singh et al., ; Vicentini et al., ; Xu et al., ). On the other hand, the genome of sugarcane due to its high polyploidy is extremely complex and has not been completely sequenced or a detailed physical map produced.…”

Section: Sugarcane Genomic and Transcriptomic Resourcesmentioning

confidence: 99%

Suberin and hemicellulose in sugarcane cell wall architecture and crop digestibility: A biotechnological perspective

Figueiredo

Araújo

Llerena

et al. 2019

Food and Energy Security

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Sugarcane is a highly efficient biomass producer used in the last decades for bioethanol and bioelectricity production, as well as for animal feeding. Together with lignin, suberin is a major factor for the low sugarcane biomass digestibility by ruminants. The lipid–phenolic biomolecular composition and the ultrastructure of suberin and associated waxes confer them extraordinary properties of hydrophobicity, flexibility, and anti‐microbial resistance, responsible for the low digestibility of suberized tissues. Additionally, hemicelluloses cross‐linked with suberin and lignin also contribute appreciably to cell wall recalcitrance. In this review, a main focus was given to suberin and secondly to hemicellulose and how they may interfere with ruminant digestibility. Suberin and hemicellulose deposition and biomolecular composition are genetically regulated, showing a close regulatory interplay with phenylpropanoid and fatty acid biosynthesis pathways, cutin disruption, and stress and defense responses. Understanding the bulk of transcription factors network and hormonal regulatory mechanisms will allow accurate biotechnological approaches to the production of more feasible forage sugarcane.

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Section: Sugarcane Genomic and Transcriptomic Resourcesmentioning

confidence: 99%

Suberin and hemicellulose in sugarcane cell wall architecture and crop digestibility: A biotechnological perspective

Figueiredo

Araújo

Llerena

et al. 2019

Food and Energy Security

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“…In contrast, the SP80-3280 chloroplast was assembled from TruSeq synthetic long reads (Table 1), using our standard assembly pipeline, except for the following changes in Mirabait parameters: -k 32 -n 150. The SP80-3280 chloroplast was also assembled from transcriptomic data (SRA: SRR1979660 and SRR1979664) (Mattiello et al, 2015). Transcriptomic assembly resulted in six contigs covering all the chloroplast apart from the ribosomal RNA region, where there were 26 overlapping contigs.…”

Section: Sugarcane Chloroplast Genome Assemblymentioning

confidence: 99%

Peer Review #1 of "The sugarcane mitochondrial genome: assembly, phylogenetics and transcriptomics (v0.1)"

2019

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Background. Chloroplast genomes provide insufficient phylogenetic information to distinguish between closely related sugarcane cultivars, due to the recent origin of many cultivars and the conserved sequence of the chloroplast. In comparison, the mitochondrial genome of plants is much larger and more plastic and could contain increased phylogenetic signals. We assembled a consensus reference mitochondrion with Illumina TruSeq synthetic long reads and Oxford Nanopore Technologies MinION long reads. Based on this assembly we also analyzed the mitochondrial transcriptomes of sugarcane and sorghum and improved the annotation of the sugarcane mitochondrion as compared with other species. Methods. Mitochondrial genomes were assembled from genomic read pools using a bait and assemble methodology. The mitogenome was exhaustively annotated using BLAST and transcript datasets were mapped with HISAT2 prior to analysis with the Integrated Genome Viewer. Results. The sugarcane mitochondrion is comprised of two independent chromosomes, for which there is no evidence of recombination. Based on the reference assembly from the sugarcane cultivar SP80-3280 the mitogenomes of four additional cultivars (R570, LCP85-384, RB72343 and SP70-1143) were assembled (with the SP70-1143 assembly utilizing both genomic and transcriptomic data). We demonstrate that the sugarcane plastome is completely transcribed and we assembled the chloroplast genome of SP80-3280 using transcriptomic data only. Phylogenomic analysis using mitogenomes allow closely related sugarcane cultivars to be distinguished and supports the discrimination between Saccharum officinarum and Saccharum cultum as modern sugarcane's female parent. From whole chloroplast comparisons, we demonstrate that modern sugarcane arose from a limited number of S. cultum female founders. Transcriptomic and spliceosomal analyses reveal that the two chromosomes of the sugarcane mitochondrion are combined at the transcript level and that splice sites occur more frequently within gene coding regions than without. We reveal one confirmed and one potential cytoplasmic male sterility factor in the sugarcane mitochondrion, both of which are transcribed Conclusion. Transcript processing in the sugarcane mitochondrion is highly complex with diverse splice events, the majority of which span the two chromosomes. PolyA baited transcripts are consistent with the use of polyadenylation for transcript degradation. For the first time we annotate two cytoplasmic male sterility factors within the sugarcane mitochondrion and demonstrate that sugarcane possesses all the

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“…Deep sequencing of transcriptome (RNA-seq) has the potential to uncover the causal variations of a desirable trait both at the genic as well as at allelic level. At the genic level, there have been a few reports in sugarcane on differentially expressed genes (DEGs) associated with to sucrose accumulation (De Setta et al 2014;Cardoso-Silva et al, 2014;Thirugnanasambandam et al 2017Thirugnanasambandam et al , 2019, lignin accumulation (Vicentini et al 2015;Kasirajan et al 2018), photosynthesis (Mattiello et al 2015), response to infections from Gluconacetobacter (Vargas et al 2014), and smut pathogen (Wu et al 2013;Que et al 2014;Su et al, 2015;Brigida et al 2016). Recently, Singh et al (2018) investigated the allele specific expressions linked to molecular mechanism behind high biomass accumulation using BSR-Seq of parents, the F1 and 20 F2 clones of sugarcane.…”

Section: Introductionmentioning

confidence: 99%

Bulked segregant RNA-Seq reveals differential genes and non-synonymous genetic variants linked to sucrose accumulation in sugarcane

Banerjee

Kumar

Annadurai

et al. 2019

Preprint

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Sucrose is the key economic trait in sugarcane which is a highly polyploid multi-species hybrid and shows a complex pattern of trait inheritance. The excessively large genome of sugarcane is comparatively less explored through Next Generation Sequencing tools for creating superior varieties. In this study, RNAseq libraries of two extreme bulks from a segregating full-sib population and its parents were used to identify 9905 conditionspecific non-synonymous genetic variants (NSVs), out of which 43 had a very high degree of differential enrichment (∆f >0.5) for contrasting sucrose accumulating conditions. The statistical model used in this study which was able to quantify the relative effect of NSVs on the trait detected highly significant positive and negative effect NSVs located in the coding regions of genes involved in sucrose metabolism, photosynthesis, mitochondrial electron transport, glycolysis and transcription. In addition, a few differential pre-mature stop codons that could result in production of truncated proteins were also detected in genes coding for aquaporin, GAPDH, aldolase, cytochrome C-oxidase, chlorophyll synthase and plant plasma membrane intrinsic proteins. Additionally, a total of 2140 differentially expressed genes (DEGs) linked to high sucrose accumulation were identified. Among the DEGs, sucrose phosphate synthase III, genes involved in transport, auxin signal transduction, etc., were upregulated, while those involved in electron transfer, cytochrome P450, etc., were downregulated in high sucrose accumulation conditions. This study was able to give finer insights in to the role of allelic heterozygosity on sucrose accumulation and the identified NSVs and DEGs could be useful as candidate markers in marker-assisted breeding for developing high sugar varieties.

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Physiological and transcriptional analyses of developmental stages along sugarcane leaf

Cited by 61 publications

References 203 publications

Suberin and hemicellulose in sugarcane cell wall architecture and crop digestibility: A biotechnological perspective

Suberin and hemicellulose in sugarcane cell wall architecture and crop digestibility: A biotechnological perspective

Peer Review #1 of "The sugarcane mitochondrial genome: assembly, phylogenetics and transcriptomics (v0.1)"

Bulked segregant RNA-Seq reveals differential genes and non-synonymous genetic variants linked to sucrose accumulation in sugarcane

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