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Recent developments in sugarcane transcriptome

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Review Paper 11/11/2024
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Recent developments in sugarcane transcriptome

Shafee Ur Rehman
Int. J. Biosci.25( 5), 252-270, November 2024.
Certificate: IJB 2024 [Generate Certificate]
Key: Illumina sequencingRNA sequencing and hybridizationSugarcane genomeTranscriptome analysis

Abstract

Hybrid sugarcane is one of the major industrially important cash crops. Cultivated in the tropical and subtropical regions, it is a C4, tall-stalked plant of the Poaceae family which provides 80% world sugar and bioethanol. The genome of hybrid represents polyploidy originating from two Saccharum species Saccharum officinarum L. and Saccharum spontaneum L. The complexity of the polyploid genome remains a challenge for researchers to analyze the whole genome sequence of sugarcane. The recent, more sophisticated DNA sequencing technologies have made studying the genomes of the closest species possible. Once the whole genome of sugarcane is available, it becomes easier to understand the hybrid. transcriptome sequencing by High Throughput Illumina sequencing technology has a great role in studying an organism’s total transcriptome at different developmental stages, in different tissues, and under environmental stimuli. Large-scale expression profiling techniques of hybrid Saccharum involving generating sequence tags or hybridizing RNA samples with nucleotide probes have been used. In this review, we mainly focused on the recent developments in the transcriptome analysis of sugarcane.

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Aitken K, Berkman P, Rae A. 2016. The first sugarcane genome assembly: How can we use it? Proceedings of the Australian Society of Sugar Cane Technology 38,193–199.

Aitken K, Jackson P, Piperidis G, McIntyre L. 2006. QTL identified for yield components in a cross between a sugarcane (Saccharum spp.) cultivar Q165A and a S. officinarum clone IJ76-514. In New directions for a diverse planet. Proceedings for the 4th International Crop Science Congress, Brisbane, 26.

Amalraj VA, Balasundaram N. 2006. On the taxonomy of the members of Saccharum complex. Genetic Resources and Crop Evolution 53, 35-41.

Anonymous. 2019. NATIONAL SUPPLY COMPANY. Brazilian crop monitoring – grain: survey, December 2018 – 2018/2019 harvest. Brasília: National Supply Company. Available at: https://www.conab.gov.br/info-agro/safras/cana.

Bedre R, Irigoyen S, Schaker PDC, Monteiro-Vitorello CB, Da Silva JA, Mandadi KK. 2019. Genome-wide alternative splicing landscapes modulated by biotrophic sugarcane smut pathogen. Scientific Reports 9, 8876. https://doi.org/10.1038/s41598-019-45184-1.

Brady SM, Long TA, Benfey PN. 2006. Unravelling the dynamic transcriptome. Plant Cell 18,  2101–2111.

Burner DM, Webster RD. 1994. Cytological studies on North American species of Saccharum (Poaceae: Andropogoneae). SIDA 16, 233-244.

Buzacott JH. 1965. Cane varieties and breeding. In: Kim NJ, Mungomery RW, Hughes CG, eds. Manual of cane growing. Sydney, Australia, 220-253.

Camargo SR, Cançado GM, Ulian EC, Menossi M. 2007. Identification of genes responsive to the application of ethanol on sugarcane leaves. Plant Cell Report 26(12), 2119–2128.

Cardoso-Silva CB, Costa EA, Mancini MC, Balsalobre TWA, Canesin LEC. 2014. De Novo Assembly and Transcriptome Analysis of Contrasting Sugarcane Varieties. PLoS ONE 9(2), e88462. https://doi.org/10.1371/journal.pone.0088462.

Carson DL, Huckett BI, Botha FC, van Staden J. 2002. Differential gene expression in sugarcane leaf and internodal tissues of varying maturity. South African Journal of Botany 68(4), 434–442.

Casu RE, Jarmey JM, Bonnett GD, Manners JM. 2007. Identification of transcripts associated with cell wall metabolism and development in the stem of sugarcane by Affymetrix GeneChip Sugarcane Genome Array expression profiling. Functional & Integrative Genomics 7(2), 153–167.

Casu RE, Rae AL, Nielsen JM, Perroux JM, Bonnett GD, Manners JM. 2015. Tissue-specific transcriptome analysis within the maturing sugarcane stalk reveals spatial regulation in the expression of cellulose synthase and sucrose transporter gene families. Plant Molecular Biology 89(6), 607-628.

Crovella S, Benko-Iseppon AM. 2012. New insights in the sugarcane transcriptome responding to drought stress as revealed by supersage. The Scientific World Journal.

D’Hont A, Glaszmann JC. 2001. Sugarcane genome analysis with molecular markers: a first decade of research. Proceedings of the International Society for Sugarcane Technologist 24, 556–559.

D’Hont A, Ison D, Alix K, Roux C, Glaszmann JC. 1998. Determination of basic chromosome numbers in the genus Saccharum by physical mapping of ribosomal RNA genes. Genome 41, 221-225.

da Silva JA, Honeycutt RJ, Burnquist W, Al-Janabi SA, Sorrels ME, Tanksley SD, Sobral BW. 1995. Saccharum spontaneum L. ‘SES 208’ genetic linkage map combining RFLP- and CR-based markers. Molecular Breeding 1, 165–179.

Dahlia L, Anggakusuma D, Kurniawan I, Roshetko JM. 2010. Consumer preference for indigenous vegetables. World Agroforestry Centre.

Damaj MB, Kumpatla SP, Emani C, Beremand PD, Reddy AS, Rathore KS, Buenrostro-Nava MT, Curtis IS, Thomas TL, Erik Mirkov T. 2010. Sugarcane DIRIGENT and O-methyltransferase promoters confer stem-regulated gene expression in diverse monocots. Planta 231, 1439–1458.

Daniels C, Menzies NK. 1996. Needham, Joseph (ed.). Science and Civilisation in China: Volume 6, Biology and Biological Technology, Part 3, Agro-Industries and Forestry. Cambridge University Press, 177–185p.

Daniels J, Roach BT. 1987. Taxonomy and evolution. In: Heinz DJ, ed. Sugarcane Improvement through Breeding. Amsterdam: Elsevier Press, 7-84p.

de Maria Felix J, Papini-Terzi FS, Rocha FR, Vêncio RZ, Vicentini R, Nishiyama MY, Ulian EC, Souza GM, Menossi M. 2009. Expression profile of signal transduction components in a sugarcane population segregating for sugar content. Tropical Plant Biology 2, 98–109.

De Souza AP, Gaspar M, Da Silva EA, Ulian EC, Waclawovsky AJ, Dos Santos RV, Teixeira MM, Souza GM, Buckeridge MS. 2008. Elevated CO2 increases photosynthesis, biomass and productivity, and modifies gene expression in sugarcane. Plant Cell Environ 31(8),1116–1127.

Dharshini S, Chakravarthi M, Manoj VM, Naveenarani M, Kumar R, Meena M, Ram B, Appunu C. 2016. De novo sequencing and transcriptome analysis of a low-temperature tolerant Saccharum spontaneum clone IND 00-1037. Journal of Biotechnology 231, 280–294.

D’Hont A, Grivet L, Feldmann P, Rao S, Berding N, Glaszmann JC. 1996. Characterization of the double genome structure of modern sugarcane cultivars (Saccharum spp.) by molecular cytogenetics. Molecular and General Genetics 250, 405-413.

Dos Santos PB, Soares-Cavalcanti NM, Vieira-de-Melo GS, Benko-Iseppon AM. 2011. Osmoprotectants in the sugarcane (Saccharum spp.) transcriptome revealed by in silico evaluation. Computational Intelligence Methods for Bioinformatics and Biostatistics 6685, 44–58.

Ferreira SS, Hotta CT, de Carli Poelking VG, Leite DC, Buckeridge MS, Loureiro ME, Barbosa MH, Carneiro MS, Souza GM. 2016. Co-expression network analysis reveals transcription factors associated with cell wall biosynthesis in sugarcane. Plant Molecular Biology 2, 15–35.

Galbraith DW. 2006. DNA microarray analyses in higher plants. OMICS 10, 455–473.

Garsmeur O, Aitken KS, Potier B, Grimwood J, Charron C, Droc G. 2017. A reference sequence of the monoploid genome of sugarcane [W889], in Proceedings of the Plant and Animal Genome Conference, San Diego, CA.

Grivet L, Arruda P. 2002. Sugarcane genomics: depicting the complex genome of an important tropical crop. 5, 122–127.

Ha S, Moore PH, Heinz D, Kato S, Ohmido N, Fukui K. 1999. Quantitative chromosome map of the polyploid Saccharum spontaneum by multicolor fluorescence in situ hybridization and imaging methods. Plant Molecular Biology 39, 1165–1173.

Heinz DJ. 1987. Amsterdam: Elsevier.

Hoang NV, Furtado A, McQualter RB, Henry RJ. 2015. Next-generation sequencing of total DNA from sugarcane provides no evidence for chloroplast heteroplasmy. New Negatives in Plant Science 1(2), 33–45.

Huang DL, Gao YJ, Gui YY, Chen ZL, Qin CX, Wang M, Liao Q, Yang LT, Li YR. 2016. Transcriptome of high-sucrose sugarcane variety GT35. Sugar Tech 18(5), 520–528.

Huang N, Ling H, Su Y, Liu F, Xu L, Su W, Wu Q, Guo J, Gao S, Que YX. 2018. Transcriptional analysis identifies major pathways as response components to Sporisorium scitamineum stress in sugarcane. Gene 678, 207–218.

Irvine JE. 1999. Saccharum species as horticultural classes. TAG Theoretical and Applied Genetics 98,186–194.

Kai-Chao W, Li-Ping W, Cheng-Mei H, Yuan-Wen W, Hui-Qing C, Lin X, Hai-Bin L, Sheng-Li J, Zhi-Nian D, Yang-Rui L. 2018. Transcriptome reveals differentially expressed genes in Saccharum spontaneum GX83-10 leaf under drought stress. Sugar Tech 20(6), 756–764. https://doi.org/10.1007/s12355-018-0608-0.

Kido EA, Ferreira Neto JR, Silva RL, Pandolfi V, Guimaraes AC, Veiga DT, Chabregas SM, Crovella S, Benko-Iseppon AM. 2012. New insights in the sugarcane transcriptome responding to drought stress as revealed by supersage. The Scientific World Journal 2012(1), 821062.

Le Cunff L, Garsmeur O, Raboin LM, Pauquet J, Telismart H, Selvi A, Grivet L, Philippe R, Begum D, Deu M, Costet L. 2008. Diploid/Polyploid syntenic shuttle mapping and haplotype-specific chromosome walking toward a rust resistance gene (Bru1) in highly polyploid sugarcane (2n∼12x∼115). Genetics 180(1), 649-660.

Ling H, Huang N, Wu QB, Su YC, Peng Q, Ahmad W, Gao SW, Su WH, Que YX, Xu LP. 2018. Transcriptional insights into the sugarcane-Sorghum mosaic virus interaction. Tropical Plant Biology 11(3-4), 163–176.

Manners JM, Casu RE. 2011. Transcriptome analysis and functional genomics of sugarcane. Tropical Plant Biology 4, 9–21.

Meng D, Guangyuan C, Lei P, Qian X, Yongqing Y, Jingsheng X. 2017. Transcriptome analysis of sugarcane response to the infection by Sugarcane Streak Mosaic Virus (SCSMV). Tropical Plant Biology 10(1), 45–55.

Nam VH, Agnelo F, Patrick JM, Annelie M, Lakshmi K, Prathima P, Thirugnanasambandam, Frederik CB, Robert JH. 2017. A survey of the complex transcriptome from the highly polyploid sugarcane genome using full-length isoform sequencing and de novo assembly from short read sequencing. BMC Genomics 18, 395.

Nogueira FT, De Rosa VE, Menossi M, Ulian EC, Arruda P. 2003. RNA expression profiles and data mining of sugarcane response to low temperature. Plant Physiology 132(4), 1811–1824.

Oloriz MI, Gil V, Rojas L, Portal O, Izquierdo Y, Jimenez E, Hofte M. 2012. Sugarcane genes differentially expressed in response to Puccinia melanocephala infection: identification and transcript profiling. Plant Cell Report 31(5), 955–969.

Panje R, Babu C. 1960. Studies in Saccharum spontaneum distribution and geographical association of chromosome numbers. Cytologia 25, 152–172.

Papini-Terzi FS, Rocha FR, Vêncio RZ, Oliveira KC, de Maria Felix J, Vicentini R, de Souza Rocha C, Simoes AC, Ulian EC, di Mauro SM, Da Silva AM. 2005. Transcription profiling of signal transduction-related genes in sugarcane tissues. DNA Research 12(1), 27–38.

Park JW, Benatti TR, Marconi T, Yu Q, Solis-Gracia N, Mora V, da Silva JA. 2015. Cold responsive gene expression profiling of sugarcane and Saccharum spontaneum with functional analysis of a cold-inducible Saccharum homolog of NOD26-like intrinsic protein to salt and water stress. PLoS ONE 10(5), e0125810.

Patade VY, Bhargava S, Suprasanna P. 2012. Transcript expression profiling of stress-responsive genes in response to short-term salt or PEG stress in sugarcane leaves. Molecular Biology Reports 39, 3311–3318.

Perez R. 1997. Chapter 3: Sugar cane. Feeding pigs in the tropics. Food and Agriculture Organization of the United Nations. Archived from the original on 21 February 2018. Retrieved 2 September 2018.

Piperidis G, Piperidis N, D’Hont A. 2010. Molecular cytogenetic investigation of chromosome composition and transmission in sugarcane. Molecular Genetics and Genomics 284, 65–73.

Piriyapongsa J, Kaewprommal P, Vaiwsri S, Anuntakarun S, Wirojsirasak W, Punpee P, Klomsa-ard P, Shaw PJ, Pootakham W, Yoocha T, Sangsrakru D, Tangphatsornruang S, Tongsima S, Tragoonrung S. 2018. Uncovering full-length transcript isoforms of sugarcane cultivar Khon Kaen 3 using single-molecule long-read sequencing. PeerJ 6, e5818.

Purseglove JW. 1972. Tropical Crops: Monocotyledons. Longman Scientific and Technical, New York.

Que YX, Su YC, Guo JL, Wu QB, Xu LP. 2014. A global view of transcriptome dynamics during Sporisorium scitamineum challenge in sugarcane by RNA-seq. PLoS ONE 9(8), e106476.

Rehman SU, Muhammad K, Novaes E, Que Y, Din A, Islam M, Porto AC, Inamullah, Sajid M, Ullah N, Iqsa S. 2021. Expression analysis of transcription factors in sugarcane during cold stress. Brazilian Journal of Biology 83, e242603.

Rehman SU, Muhammad K, Sher H, Que Y, Ali R, Ali S, Hassan I, Rahat MA. 2023. Molecular analysis of cold responsive (COR) genes in selected sugarcane and Saccharum spontaneum L. Advancements in Life Sciences 9(4), 547-551.

Rossi M, Araujo PG, Paulet F, Garsmeur O, Dias VM, Chen H. 2003. Genomic distribution and characterization of EST-derived resistance gene analogs (RGAs) in sugarcane. Genome 269, 406–419.

Santa Brigida AB, Rojas CA, Grativol C, de Armas EM, Entenza JO, Thiebaut F, Lima MD, Farrinelli L, Hemerly AS, Lifschitz S, Ferreira PC. 2016. Sugarcane transcriptome analysis in response to infection caused by Acidovorax avenae subsp. avenae. PLoS ONE 11(12), e0166473.

Schnable PS, Hochholdinger F, Nakazono M. 2004. Global expression profiling applied to plant development. Current Opinion in Plant Biology 7, 50–56.

Shearman JR, Sonthirod C, Naktang C, Pootakham W, Yoocha T, Sangsrakru D. 2016. The two chromosomes of the mitochondrial genome of a sugarcane cultivar: assembly and recombination analysis using long PacBio reads. Scientific Reports 6, 31533.

Shiqiang X, Jihua W, Heyang S, Youzong H, Wei Y, Baoshan C, Muqing Z. 2018. Transcriptomic characterization and potential marker development of contrasting sugarcane cultivars. Scientific Reports 8, 1683.

Sidney M. 1986. Sweetness and power: the place of sugar in modern history. Penguin, ISBN 978-0-14-009233-2.

Simmonds NW. 1979. Principles of crop improvement. Longmans, London.

Souza GM, Berges H, Bocs S, Casu R, D’Hont A, Ferreira JE, Henry R, Ming R, Potier B, Sluys MV, Vincentz M, Paterson AH. 2011. Tropical Plant Biology 4, 145. https://doi.org/10.1007/s12042-011-9079-0.

Sreenivasan TV, Ahloowalia BS, Heinz DJ. 1987. Cytogenetics. In: Heinz DJ, ed. Sugarcane Improvement through Breeding. Elsevier, Amsterdam, p. 211-253.

Sternes PR, Moyle RL. 2015. Deep sequencing reveals divergent expression patterns within the small RNA transcriptomes of cultured and vegetative tissues of sugarcane. Plant Molecular Biology Reporter 33(4), 931–951.

Su Y, Xu L, Wang S, Wang Z, Yang Y, Chen Y, Que Y. 2015. Identification, phylogeny, and transcript of chitinase family genes in sugarcane. Scientific Reports 2(5), 10708.

Tang S, Yang L, Li Y. 2018. Transcriptome comparison of different sugarcane varieties under low-temperature stress. Biotechnology Bulletin 34(12), 116-124.

The National Archives, Government of the United Kingdom. 2010.

Vicentini R, Bottcher A, dos Santos Brito M, dos Santos AB, Creste S, de Andrade Landell MG, Cesarino I, Mazzafera P. 2015. Large-scale transcriptome analysis of two sugarcane genotypes contrasting for lignin content. PLoS ONE 10(8), e0134909.

Vilela MM, Del BLE, Van SMA, de Setta N, Kitajima JP, Cruz GM, Sforça DA, de Souza AP, Ferreira PC, Grativol C, Cardoso-Silva CB, Vicentini R, Vincentz M. 2017. Analysis of three sugarcane homo/homeologous regions suggests independent polyploidization events of Saccharum officinarum and Saccharum spontaneum. Genome Biology and Evolution 9(2), 266–278.

Wei J, Xiu Z, Ou H, Chen J, Jiang H, Zhang X, Zhang R, Zhou H, Gui Y, Li H, Li Y. 2019. Transcriptome profile analysis of twisted leaf disease response in susceptible sugarcane with Narenga porphyrocoma genetic background. Tropical Plant Biology 12, 293–303.

Wu Q, Xu L, Guo J, Su Y, Que Y. 2013. Transcriptome profile analysis of sugarcane responses to Sporisorium scitaminea infection using Solexa sequencing technology. BioMed Research International 2013, 298920.

Yang Y, Zhang X, Su Y, Zou J, Wang Z, Xu L, Que Y. 2017. miRNA alteration is an important mechanism in sugarcane response to low-temperature environment. BMC Genomics 18, 1–8.

Zeng Q, Ling Q, Fan L, Li Y, Hu F, Chen J, Huang Z, Deng H, Li Q, Qi Y. 2015. Transcriptome profiling of sugarcane roots in response to low potassium stress. PLoS ONE 10(5), e0126306.

Zhang J, Nagai C, Yu Q, Pan YB, Ayala-Silva T, Schnell RJ, Comstock JC, Arumuganathan AK, Ming R. 2012. Genome size variation in three Saccharum species. Euphytica 185, 511–519.

Zhang J, Zhang X, Tang H, Zhang Q, Hua X, Ma X, Zhu F, Jones T, Zhu X, Bowers J, Wai CM. 2018. Allele-defined genome of the autopolyploid sugarcane Saccharum spontaneum L. Nature Genetics 50(11), 1565–1573.

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