A BAC library of the SP80-3280 sugarcane variety (saccharum sp.) and its inferred microsynteny with the sorghum genome
© Figueira et al; licensee BioMed Central Ltd. 2012
- Received: 10 January 2012
- Accepted: 23 April 2012
- Published: 23 April 2012
Sugarcane breeding has significantly progressed in the last 30 years, but achieving additional yield gains has been difficult because of the constraints imposed by the complex ploidy of this crop. Sugarcane cultivars are interspecific hybrids between Saccharum officinarum and Saccharum spontaneum. S. officinarum is an octoploid with 2n = 80 chromosomes while S. spontaneum has 2n = 40 to 128 chromosomes and ploidy varying from 5 to 16. The hybrid genome is composed of 70-80% S. officinaram and 5-20% S. spontaneum chromosomes and a small proportion of recombinants. Sequencing the genome of this complex crop may help identify useful genes, either per se or through comparative genomics using closely related grasses. The construction and sequencing of a bacterial artificial chromosome (BAC) library of an elite commercial variety of sugarcane could help assembly the sugarcane genome.
A BAC library designated SS_SBa was constructed with DNA isolated from the commercial sugarcane variety SP80-3280. The library contains 36,864 clones with an average insert size of 125 Kb, 88% of which has inserts larger than 90 Kb. Based on the estimated genome size of 760–930 Mb, the library exhibits 5–6 times coverage the monoploid sugarcane genome. Bidirectional BAC end sequencing (BESs) from a random sample of 192 BAC clones sampled genes and repetitive elements of the sugarcane genome. Forty-five per cent of the total BES nucleotides represents repetitive elements, 83% of which belonging to LTR retrotransposons. Alignment of BESs corresponding to 42 BACs to the genome sequence of the 10 sorghum chromosomes revealed regions of microsynteny, with expansions and contractions of sorghum genome regions relative to the sugarcane BAC clones. In general, the sampled sorghum genome regions presented an average 29% expansion in relation to the sugarcane syntenic BACs.
The SS_SBa BAC library represents a new resource for sugarcane genome sequencing. An analysis of insert size, genome coverage and orthologous alignment with the sorghum genome revealed that the library presents whole genome coverage. The comparison of syntenic regions of the sorghum genome to 42 SS_SBa BES pairs revealed that the sorghum genome is expanded in relation to the sugarcane genome.
- Sugarcane genomics
- BAC library
- Genome organization
Sugarcane is a C4 plant that stores 1/3 of its fixed carbon as sucrose in the parenchyma cells of mature stalks. The other 2/3 is stored in the leaves (1/3) and, the stalks (1/3) in the form of complex carbohydrates . Sugarcane has been grown as a sugar source for a century, but in recent years, extensive industrial plantations have demonstrated this crop’s value for the production of sustainable energy . In industrial plantations, when sugarcane is harvested, its leaves are left in the field, contributing to the improvement of soil conservation and fertility. The stalks are transported to sugarcane mills and crushed. After crushing the juice enters a first-pass sucrose crystallisation, and the sugar remaining in the molasses goes to fermenters to produce fuel ethanol . Currently, the dried bagasse resulting from the stalk crushing is used to produce bioelectricity, but it could also be used for the production of cellulosic ethanol . Sugarcane juice has also been used as a carbon source by the synthetic biology industry to produce other fuels and high value molecules . However, the worldwide use of sugarcane for sustainable energy production depends, on the development of superior varieties that are able to grow in less fertile soils, in stress-inducing biotic and abiotic conditions in a range of tropical and sub-tropical environments.
The cultivated sugarcane varieties derive from crosses performed at the beginning of the last century between S. officinarum, a species with a high sugar content in the stalk and S. spontaneum, a disease-resistant and vigorous wild relative [4, 5]. After few backcrosses of the interspecific hybrid to S. officinarum, the breeders were able to select varieties less sensitive to biotic and abiotic stress and with a high sugar content in their stalks [5, 6]. These early interspecific hybrids constitute the basic germplasm used in breeding programs around the world. However, breeding sugarcane is a complex task because of the high degree of ploidy of the ancestor species [7, 8]. S. officinarum is octoploid with a basic chromosome number of x = 10 and 2n = 80 chromosomes, while S. spontaneum has a basic chromosome number of x = 8 and 2n = 40 to 128, and a ploidy varying from 5 to 16 [9, 10]. The interspecific hybrid genome is a mixture of the genomes of both species with a ploidy varying between 2n = 100 and 2n = 130 chromosomes . Intact chromosomes from both parents coexist in the interspecific hybrid in proportion of 5-20% from S. spontaneum and 70-80% from S. officinarum, along with a variable proportion of recombinants between the parental homoeologous chromosomes . This genome architecture imposes constraints for the breeding process and prevents the use of seeds for progeny propagation because of the complex allelic segregation from the polyploidy hybrid . This has limited the achievement of genetic gains in breeding programs, despite the use of crosses between numerous selected parental varieties and evaluation of hundreds of thousands or even millions of progenies in the large-scale field trials.
Because of its complexity, the complete sugarcane genome has not yet been sequenced, mainly due to the difficulty of assigning gene-containing fragments to a specific homologous/homeologous chromosome. However, a reference genome sequence could be assembled from fragments of different homologous and homeologous chromosomes and, even though this reference sequence would be chimeric, it could be useful for comparative genome analysis with close relatives, such as sorghum .
The estimated monoploid genome size of sugarcane is approximately 760–930 Mb , which is close to the 730 Mb size observed for sorghum . A reference sugarcane genome sequence can be obtained by sequencing a representative bacterial artificial chromosome (BAC) library. Few sequenced BAC clones from the commercial Reunion Island R570 sugarcane variety has already demonstrated the viability of comparative genomics between sugarcane and sorghum [15–17].
This report describes the construction and initial analysis of a BAC library from the Brazilian sugarcane variety SP80-3280, which has been extensively cultivated during the past 18 years . This library will be made available for the scientific community, and would be useful for the establishment of a reference genome sequence for sugarcane. The library was characterised in terms of insert size and genome coverage based on the alignment of a random sample of BAC end sequences (BESs) into the sorghum genome. Gene annotation of these BESs provided an early glimpse into the sequence composition of the sugarcane genome compared to the sorghum genome.
Construction and characterisation of the SP80-3280 BAC library
The sugarcane variety SP80-3280 was chosen to construct the BAC library because it has been widely cultivated in Brazil. Around 300 thousand Ha has been cultivated with SP80-3280 along the past, recent years in different regions of the country. The superior agronomic performance in such a vast area implies that breeders have selected adaptability traits responsible for yield stability. Thus, sequencing a BAC library from this variety may reveal allelic composition involved in crop performance, and by comparing with genome sequence from other sugarcane BAC libraries may reveal genomic regions responsible for crop adaptation to different environments. The SP80-3280 has also contributed to the cDNA libraries used for EST sequencing carried out by the sugarcane EST project (SUCEST) . SUCEST sequences targeted over 70% of the expressed sugarcane genes  and have demonstrated its usefulness for genome annotation of sugarcane BAC sequences .
Summary of the SS_SBa Sugarcane BAC library
Germplasm Cloning vector
Sugarcane variety SP80-3280 pAGIBAC1
Partial digest enzyme
Number of clones
Number of 384-well plates
Number of analyzed clones
Average insert size (kb)
Minimum insert size (kb)
Maximum insert size (kb)
Number of high quality BES
Average BES read length (bp)*
Chloroplast contamination (%)
Number of monoploid genome equivalents**
BES of a clone sample of the SS_SBa BAC library
The quality of the library and its potential genome coverage were examined by bidirectional end sequencing of the randomly selected 192 BAC clones for insert size estimation and its alignment to the genome sequence of the 10 sorghum chromosomes (Additional file 1: Table S1). After trimming the BES sequence reads for low quality and vector bases, 378 sequences, with an average read length of 944 nucleotides and a minimum length of 312 bases, were recovered (Table 1).
Synteny and micro-collinearity with sorghum
Classification of SP 80–3280 BAC end sequences as related to the alignments into the sorghum chromosomes
BES per BAC
Distance Between BES (Kb)
Opposite in (> <)
20 - 300
Same (< < or > >)
20 - 300
Opposite in (> <)
Same (<< or >>)
Opposite out (< >)
Distribution of BES into the sorghum chromosomes
Difference of expanded and contracted sorghum regions syntenic to sugarcane BACs and gene and repetitive elements content of the expanded/contracted region of sorghum
Number of syntenic regions
Sum of sugarcane BAC nucleotides (bp)
Sum of nucleotides of syntenic sorghum regions (bp)
Nucleotide difference between sorghum and sugarcane syntenic regions (bp)
Gene density of the sorghum chromosomes (%)
Repetitive elements of the sorghum chromosomes (%)
Distribution of sugarcane BACs among sorghum chromosomes (%)
Repetitive elements content
Summary of repetitive sequences among the sugarcane BESs
Number of elements
% of Total Bases
Two BAC libraries from the Reunion Island sugarcane cultivar R570, one constructed with DNA isolated from the commercial variety  and, the other constructed with DNA isolated from selfed progenies of R570  are current available. These libraries have contributed with BAC sequencing for various purposes. Here, we described the construction and initial analyses of a new sugarcane BAC library prepared with genomic DNA from a Brazilian elite commercial sugarcane variety. This BAC library exhibits genome coverage of 5–6 times the monoploid chromosome set of sugarcane. The genome coverage was estimated based on a size of 760–930 Mb for the monoploid sugarcane genome . However, in a previous study, syntenic alignment of 19 sugarcane BAC sequences from the R570 BAC library into the 20 sorghum chromosome arms revealed predominant local DNA sequence expansion of the sorghum genome in the regions syntenic with the sugarcane BAC sequences . These results suggested that the monoploid sugarcane genome could be 20% smaller than the 730 Mb sorghum genome. The alignment of the 42 BES pairs into concordant syntenic regions of the sorghum genome revealed 29% expansion of sorghum in relation to the sugarcane genome. This result is in keeping with the results observed for the R570 BAC library and suggests that the size of the monoploid sugarcane genome could be on the order of 580 Mb. If this is correct, the coverage of the SS_SBa BAC library could be on the order of 8 times the sugarcane monoploid genome.
The use of the sorghum genome sequence as a template to assemble the sugarcane genome has been proposed based on the close similarity between the two species [25, 26]. The sequence of BAC clones from the R570 BAC library and comparison of its gene and repetitive element content to that of sorghum improved confidentiality with respect to these assumptions [16, 17]. Sequence analysis of 19 BAC from the R570 BAC library revealed that almost 85% of its gene-encoding sequences are syntenic with sorghum orthologs . We analysed the sorghum chromosomes for gene density as related to the distribution of the SP80-3280 BES. Sorghum chromosomes 1, 2 and 3 showed the highest gene density and had increased number of aligned sugarcane BESs (Table 3). Chromosomes 5 and 6 has reduced gene density were richer in repetitive elements and showed fewer aligned sugarcane BESs (Table 3).
The library described in this report is from an elite commercial sugarcane variety that has been cultivated on hundreds of thousands of hectares in a range of different environments, including regions of less favourable soils in terms of water and nutrient availability. This library would be useful in providing additional information regarding the allelic composition selected by breeders. The overlapping BACs in this library may represent different homeologous chromosomes from both S. officinarum and S. spontaneum parents. Since S. officinarum contributes mainly with yield and sugar alleles and, S. spontaneum contributes mainly with stress tolerance genes, the sequences of overlapping BACs representing both species could be identified by high stringency filter hybridisation with DNA from the two parents . Furthermore, their gene and allele content could be identified, and the contribution of each of the parental genes to disease resistance and sugar content could be assigned. Additionally, expression patterns obtained using next generation platforms could provide additional useful information regarding this valuable genetic resource.
Sugarcane is a main crop for both sugar and bioenergy generation. To address the projections for sugarcane production, breeding and biotechnology approaches must be developed in the next few years, to assist the selection of high sugar yield varieties adapted to tropical and sub-tropical regions. Sequencing the genome of this complex crop may help to identify agronomically useful genes, either per se or through comparative genomics, and could also assist in the development of biotechnology tools for sugarcane improvement. This report describes the construction and preliminary analyses of a sugarcane BAC library from DNA isolated from a Brazilian elite sugarcane variety. The library comprises large insert clones and possesses 5–6 times coverage of the monoploid sugarcane genome. Sequencing and alignment of BAC end sequences from a sample of this library into orthologous regions of the sorghum genome revealed that the library presents sound genome coverage. In addition, comparison of the syntenic regions of the sorghum genome with respect to BAC end sequence pairs confirmed that the sugarcane genome might be between 20% and 30% smaller than the sorghum genome. This library represents a new resource for the community interested in sugarcane breeding and biotechnology coupled with sustainable bioenergy generation.
Germplasm and plant tissue processing
Twenty 10-week-old, field-grown sugarcane plants of the SP80-3280 variety were generously provided by the Cosan company (http://www.cosan.com.br). The plants were harvested at Usina Santa Helena in Fazenda Santo Antonio (GPS coordinates −22.735657, -47.305069), Piracicaba, State of São Paulo, Brazil. The plants were subjected to a 30-hour dark treatment, after which the healthy young leaves were collected, quickly washed to remove debris and immediately frozen by submersion in liquid nitrogen. The frozen leaves were stored at −80°C until use.
Preparation of high molecular weight (HMW) sugarcane DNA in agarose plugs
The sugarcane SP-803280 BAC library was constructed in the Arizona Genomics Institute (AGI) using standard protocols [27, 28]. Fifty grams of frozen tissue were ground under liquid nitrogen with a mortar and pestle. The ground tissue was transferred to a 1-L Erlenmeyer flask containing 500 mL of pre-chilled extraction buffer (10 mM Tris–HCl, pH 8.0, 10 mM EDTA, pH 8.0, 100 mM KCl, 0.5 M sucrose, 4 mM spermidine, 1 mM spermine, 2.0% w/v PVP-40, 0.13% w/v sodium diethyldithiocarbamate trihydrate and 800 μl β-mercaptoethanol). The suspension was gently shaken for 15 min, and the homogenate was filtered into an Erlenmeyer flask containing 500 mL of pre-chilled extraction buffer with 1.7% Triton X-100. The suspension was kept on ice for 15 min and then centrifuged for 15 min at 3,250 rpm at 4°C. The resulting pellet was resuspended in pre-chilled extraction buffer, incubated for 5 min in a water bath at 45°C and gently mixed with 1/3 v/v of 1.0% low melting temperature agarose that was previously prepared in extraction buffer and held at 45°C. The mixture was transferred to plug moulds and allowed to solidify. Forty-six plugs were transferred into a 50-mL Falcon tube containing 40 mL of proteinase K solution (0.5 M EDTA pH 9.2, 1.0%N-lauroylsarcosine, 40 mg proteinase K and 2% PVP), and the tube was incubated in a hybridisation oven at 50°C with gentle rotation for 24 h. The plugs were then washed with fresh proteinase K solution for an additional 24 h. Subsequently, the plugs were washed five times for 1 h at room temperature using 40 mL T10E10 containing phenylmethylsulfonyl fluoride (PMSF; 10 mM Tris–HCl, 10 mM EDTA, 1 mM PMSF, pH 8.0) and five times for 1 h with T10E1 plus PMSF (10 mM Tris–HCl, 1 mM EDTA, 1 mM PMSF, pH 8.00). The plugs were stored in TE at 4°C.
Restriction digestion of HMW DNA and isolation of size-selected fragments
Eight DNA plugs were partially digested for 20 minutes with 0.6 U of the Hind III restriction enzyme for each half plug. The digested samples were loaded into a 1.0% agarose gel and subjected to pulsed-field gel electrophoresis (PFGE). DNA was visualised using a UV transilluminator, and fragments containing DNA ranging from 90 to 450 Kb were cut from the gel slabs. The fragments were subsequently purified through second and third PFGE runs to remove small trapped DNA fragments . The gel fractions containing sized fragments were recovered from the gel slabs and stored at 4°C.
Ligation of sized DNA fragments
High-molecular-weight genomic DNA fragments (120–200 ng) were ligated into a HindIII- linearized and dephosphorylated pAGIBAC1 plasmid vector . The ligation reactions were incubated in a water bath at 16°C for 19 h, transferred to 0.1 M glucose/1.0% agarose and allowed to desalt for 1.5 h on ice. The ligations were transferred into new microcentrifuge tubes and stored at 4°C. The ligation samples were tested to determine the transformation efficiency and cloned insert quality. For the final transformations, 2.0 μl of ligation mixture was used to electroporate 20 μl of DH10B T1 phage-resistant E. coli cells (Invitrogen). The transformed cells were transferred into 3 mL of SOC media and incubated at 37°C for 1 h in a shaker at 250 rpm, followed by the addition of an equal volume of sterile glycerol and gentle shaking for 3 min, after which the mixtures were immediately frozen by submersion into liquid nitrogen and stored at −80°C. Subsequently, the cells were thawed and plated on 22.5 x 22.5 cm plates containing solid LB medium with 12.5 μg/mL chloramphenicol, 80 μg/mL X-gal and 100 μg/mL IPTG. The plates were incubated at 37°C overnight. White recombinant colonies were transferred into liquid LB medium containing 12.5 mg/mL chloramphenicol and incubated overnight at 37°C. The transformed E. coli from ligations that contained large inserts were arrayed into 96 x 384-well plates to constitute the SS_SBa BAC library.
Quality control and BES sequencing and analysis
Two 96-wells plates were set up using two clones from each 384-well plate of the SS_SBa BAC library. BAC DNA was isolated from these two 96-well plates, digested with NotI and separated by PFGE for fragment sizing. DNA from the same 192 BAC clones was used for BAC end sequencing with an ABI 3730 sequencer at the AGI facility. The BESs were trimmed for vector and low quality sequences using the SUCEST project trimming procedure . The trimmed sequences were compared to the NCBI GenBank non-redundant protein database using BlastX (E-value cutoff of 1e-5), to NCBI GenBank nucleotide database, to sorghum, maize and rice genome sequences, sugarcane ESTs and BAC sequences and to the sugarcane chloroplast genome  and rice mitochondria genome  using BlastN. For all BlastN searches, an E-value cutoff of 1e-20 was used. Additionally, for chloroplast and mitochondria BlastN searches a cutoff of 80% coverage was used. Repeats in the sugarcane BES were masked  and identified through searches for similarity to grass sequences in the RepBase  with Censor . The BES sequences have been submitted GenBank/NCBI under ID: (dbGSS JS672894 - JS673271).
Comparative analysis and alignment of BESs into the sorghum genome
Regions of microsynteny between sorghum and sugarcane were mapped by the alignment of BESs onto sorghum genome sequences using BlastN alignments with an E-value cutoff of 1e-20. A BES was considered microsyntenic if both ends mapped within 20 Kb and 300 Kb in the opposite orientation. When the two ends were opposite oriented one to another, the region was considered collinear [33, 34]. Otherwise, the region was considered to be rearranged between the two species. The best score sum of two ends was used to select among multiple mapping possibilities. Gene density and Gene Ontology analyses of the sorghum chromosomes and syntenic regions were based on Phytozome (V7.0) and the JGI sorghum genome annotation. Repetitive elements in the sorghum chromosomes and syntenic regions were identified with Censor  using RepBase .
TRSF was supported by CAPES. PA is a recipient of a CNPq productivity fellowship.
- Goldemberg J, Coelho ST, Guardabassi P: The sustainability of ethanol production from sugarcane. Energy Policy. 2008, 36: 2086-2097. 10.1016/j.enpol.2008.02.028.View ArticleGoogle Scholar
- Matsuoka S, Ferro J, Arruda P: The Brazilian experience of sugarcane ethanol industry. In Vitro Cell Dev Biol Plant. 2009, 45: 372-381. 10.1007/s11627-009-9220-z.View ArticleGoogle Scholar
- Arruda P: Perspective of the Sugarcane Industry in Brazil. Tropical Plant Biol. 2011, 4: 3-8. 10.1007/s12042-011-9074-5.View ArticleGoogle Scholar
- Arcenaux G: Cultivated sugarcanes of the world and their botanical derivation. Proc Int Soc Sugarcane Technol. 1967, 12: 844-885.Google Scholar
- Berding N, Roach BT: Germplasm collection, maintenance, and use. Sugarcane improvement through breeding. Edited by: Heinz DJ. 1987, New York, Elsevier, 143-210.View ArticleGoogle Scholar
- Roach BT: Nobilisation of sugarcane. Proc Int Soc Sugar Cane Technol. 1972, 14: 206-216.Google Scholar
- D’Hont A, Glaszmann JC: Sugarcane genome analysis with molecular markers, a first decade of research. Proceedings of the International Society of Sugarcane Technology. 2001, 24: 556-559.Google Scholar
- Lu YH, D'Hont A, Paulet F, Grivet L, Arnaud M, Glaszmann JC: Molecular diversity and genome structure in modern sugarcane varieties. Euphytica. 1994, 78: 217-226. 10.1007/BF00027520.View ArticleGoogle Scholar
- D’Hont A, Ison D, Alix K, Roux C, Glaszmann JC: Determination of basic chromosome numbers in the genus Saccharum by physical mapping of ribosomal RNA genes. Genome. 1998, 41: 221-225.View ArticleGoogle Scholar
- Ha S, Moore PH, Heinz D, Kato S, Ohmido N, Fukui K: Quantitative chromosome map of the polyploid Saccharum spontaneum by multicolor fluorescence in situ hybridization and imaging methods. Plant Mol Biol. 1999, 39: 1165-1173. 10.1023/A:1006133804170.PubMedView ArticleGoogle Scholar
- Grivet L, Arruda P: Sugarcane genomics: depicting the complex genome of an important tropical crop. Current Opinion in Plant Biology. 2001, 5: 122-127.View ArticleGoogle Scholar
- D’Hont A, Grivet L, Feldmann P, Rao S, Berding N, Glaszmann JC: Characterisation of the double genome structure of modern sugarcane cultivars (Saccharum spp.) by molecular cytogenetics. Mol Gen Genet. 1996, 250: 405-413.PubMedGoogle Scholar
- Abrouk M, Murat F, Pont C, Messing J, Jackson S, Faraut T, Tannier E, Plomion C, Cooke R, Feuillet C, Salse J: Palaeogenomics of plants: synteny-based modelling of extinct ancestors. Trends Plant Sci. 2010, 15: 479-487. 10.1016/j.tplants.2010.06.001.PubMedView ArticleGoogle Scholar
- Paterson AH, Bowers JE, Bruggmann R, Dubchak I, Grimwood J, Gundlach H, Haberer G, Hellsten U, Mitros T, Poliakov A, Schmutz J, Spannagl M, Tang H, Wang X, Wicker T, Bharti AK, Chapman J, Feltus FA, Gowik U, Grigoriev IV, Lyons E, Maher CA, Martis M, Narechania A, Otillar RP, Penning BW, Salamov AA, Wang Y, Zhang L, Carpita NC: The sorghum bicolor genome and the diversification of grasses. Nature. 2009, 457: 551-556. 10.1038/nature07723.PubMedView ArticleGoogle Scholar
- Garsmeur O, Charron C, Bocs S, Jouffe V, Samain S, Couloux A, Droc G, Zini C, Glaszmann JC, Van Sluys MA, D’Hont A: High homologous gene conservation despite extreme autopolyploid redundancy in sugarcane. New Phytol. 2011, 189: 629-642. 10.1111/j.1469-8137.2010.03497.x.PubMedView ArticleGoogle Scholar
- Jannoo N, Grivet L, Chantret N, Garsmeur O, Glaszmann JC, Arruda P, D'Hont A: Orthologous comparison in a gene-rich region among grasses reveals stability in the sugarcane polyploid genome. The Plant Journal. 2007, 50: 574-585. 10.1111/j.1365-313X.2007.03082.x.PubMedView ArticleGoogle Scholar
- Wang J, Roe B, Macmil S, Yu Q, Murray JE, Tang H, Chen C, Najar F, Wiley G, Bowers J, Van Sluys MA, Rokhsar DS, Hudson ME, Moose SP, Paterson AH, Ming R: Microcollinearity between autopolyploid sugarcane and diploid sorghum genomes. BMC Genomics. 2010, 11: 261-10.1186/1471-2164-11-261.PubMedPubMed CentralView ArticleGoogle Scholar
- Vettore AL, da Silva FR, Kemper EL, Arruda P: The libraries that made SUCEST. Genet Mol Biol. 2001, 24: 1-4. 10.1590/S1415-47572001000100002.View ArticleGoogle Scholar
- Vettore AL, da Silva FR, Kemper EL, Souza GM, da Silva AM, Ferro MI, Henrique-Silva F, Giglioti EA, Lemos MV, Coutinho LL, Nobrega MP, Carrer H, Franca SC, Bacci Junior M, Goldman MH, Gomes SL, Nunes LR, Camargo LE, Siqueira WJ, Van Sluys MA, Thiemann OH, Kuramae EE, Santelli RV, Marino CL, Targon ML, Ferro JA, Silveira HC, Marini DC, Lemos EG, Monteiro-Vitorello CB: Analysis and functional annotation of an expressed sequence tag collection for tropical crop sugarcane. Genome Res. 2003, 13: 2725-2735. 10.1101/gr.1532103.PubMedPubMed CentralView ArticleGoogle Scholar
- Luo M, Wing RA: An improved method for plant BAC library construction. Plant Functional Genomics: Methods and Protocols. Edited by: Grotewold E. 2003, Humana Press, Totowa, NJ, USA, 3–-19.View ArticleGoogle Scholar
- Junior TC, Carraro DM, Benatti MR, Barbosa AC, Kitajima JP, Carrer H: tructural features and transcript-editing analysis of sugarcane (Saccharum officinarum L.) chloroplast genome. Curr Genet. 2004, 46: 366-373. 10.1007/s00294-004-0542-4.View ArticleGoogle Scholar
- Notsu Y, Masood S, Nishikawa T, Kubo N, Akiduki G, Nakazono M, Hirai A, Kadowaki K: The complete sequence of the rice (Oryza sativa L.) mitochondrial genome: frequent DNA sequence acquisition and loss during the evolution of flowering plants. Molecular Genetics and Genomics. 2002, 268: 434-445. 10.1007/s00438-002-0767-1.PubMedView ArticleGoogle Scholar
- Tomkins JP, Yu Y, Miller-Smith H, Frisch DA, Woo SS, Wing R: A bacterial artificial chromosome library for sugarcane. Theor Appl Genet. 1999, 99: 419-424. 10.1007/s001220051252.PubMedView ArticleGoogle Scholar
- Le Cunff L, Garsmeur O, Raboin LM, Pauquet J, Telismart H, Selvi A, Grivet L, Philippe R, Begum D, Deu M, Costet L, Wing R, Glaszmann JC, D’Hont A: Diploid ⁄ polyploid syntenic shuttle mapping and haplotype-specific chromosome walking toward a rust resistance gene (Bru1) in highly polyploid sugarcane (2n–12x - 115). Genetics. 2008, 180: 649-660. 10.1534/genetics.108.091355.PubMedPubMed CentralView ArticleGoogle Scholar
- Bowers JE, Arias MA, Asher R, Avise JA, Ball RT, Brewer GA, Buss RW, Chen AH, Edwards TM, Estill JC, Exum HE, Goff VH, Herrick KL, James Steele CL, Karunakaran S, Lafayette GK, Lemke C, Marler BS, Masters SL, McMillan JM, Nelson LK, Newsome GA, Nwakanma CC, Odeh RN, Phelps CA, Rarick EA, Rogers CJ, Ryan SP, Slaughter KA, Soderlund CA: Comparative physical mapping links conservation of microsynteny to chromosome structure and recombination in grasses. Proc Natl Acad Sci USA. 2005, 102: 13206-13211. 10.1073/pnas.0502365102.PubMedPubMed CentralView ArticleGoogle Scholar
- Ming R, Liua SC, Lina YR, da Silva J, Wilson W, Braga D, van Deynze A, Wenslaff TF, Wud KK, Mooree PH, Burnquist W, Sorrells ME, Irvine JE, Paterson AH: Detailed alignment of saccharum and sorghum chromosomes: comparative organization of closely related diploid and polyploid genomes. Genetics. 1998, 150: 1663-168.PubMedPubMed CentralGoogle Scholar
- Lin J, Kudrna D, Wing RA: Construction, characterization, and preliminary BAC-end sequence analysis of a bacterial artificial chromosome library of the tea plant (Camellia sinensis). J Biomed Biotechnol. 2011, 10.1155/ 2011/476723.Google Scholar
- Peterson DG, Tomkins JP, Frisch DA, Wing RA: PatersonAH: Construction of plant bacterial artificial chromosome (BAC) libraries: an illustrated guide. Journal of Agricultural Genomics. 2000, 5: 1-100.Google Scholar
- Telles GP, da Silva FR: Trimming and clustering sugarcane ESTs. Genet Mol Biol. 2001, 24: 17-23. 10.1590/S1415-47572001000100004.View ArticleGoogle Scholar
- Tarailo-Graovac M, Chen N: Using RepeatMasker to identify repetitive elements in genomic sequences. Curr Protoc Bioinformatics. 2009, 4: 4-10.Google Scholar
- Jurka J, Kapitonov VV, Pavlicek A, Klonowski P, Kohany O, Walichiewicz J: Repbase Update: a database of eukaryotic repetitive elements. Cytogenet Genome Res. 2005, 110: 462-467. 10.1159/000084979.PubMedView ArticleGoogle Scholar
- Kohany O, Gentles AJ, Hankus L, Jurka J: Annotation, submission and screening of repetitive elements in repbase: repbasesubmitter and censor. BMC Bioinforma. 2006, 7: 474-10.1186/1471-2105-7-474.View ArticleGoogle Scholar
- Kim H, Hurwitz B, Yu Y, Collura K, Gill N, SanMiguel P, Mullikin JC, Maher C, Nelson W, Wissotski M, Braidotti M, Kudrna D, Goicoechea JL, Stein L, Ware D, Jackson SA, Soderlund C, Wing RA: Construction, alignment and analysis of twelve framework physical maps that represent the ten genome types of the genus Oryza. Genome Biol. 2008, 9: R45-10.1186/gb-2008-9-2-r45.PubMedPubMed CentralView ArticleGoogle Scholar
- Ammiraju JSS, Luo M, Goicoechea JL, Wang W, Kudrna D, Mueller C, Talag J, Kim H, Sisneros NB, Blackmon B, Fang E, Tomkins JB, Brar D, MacKill D, McCouch S, Kurata N, Lambert G, Galbraith DW, Arumuganathan K, Rao K, Walling JG, Gill N, Yu Y, SanMiguel P, Soderlund C, Jackson S, Wing RA: The Oryza bacterial artificial chromosome library resource: construction and analysis of 12 deep-coverage large-insert BAC libraries that represent the 10 genome types of the genus Oryza. Genome Res. 2006, 16: 140-147.PubMedPubMed CentralView ArticleGoogle Scholar
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.