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RESEARCH ARTICLE

Sucrose accumulation in sugarcane stalks does not limit photosynthesis and biomass production

N. G. Inman-Bamber A B , P. A. Jackson A and M. Hewitt A
+ Author Affiliations
- Author Affiliations

A CSIRO Plant Industry, ATSIP James University Campus, Townsville, Qld 4811, Australia.

B Corresponding author. Email: geoff.inmanbamber@gmail.com

Crop and Pasture Science 62(10) 848-858 https://doi.org/10.1071/CP11128
Submitted: 17 May 2011  Accepted: 29 September 2011   Published: 6 December 2011

Abstract

Until now raw sugar has been the predominant commodity produced from sugarcane (Saccharum spp. hybrids) with the exception of Brazil where fermentable sugars are used to produce ethanol. Worldwide interest in renewable energy has focussed attention on total biomass production of ‘energy canes’ rather than sucrose yield alone. Clones selected for biomass tend to have high fibre contents derived from the wild type, S. spontaneum. It is possible that high fibre genotypes can produce higher biomass yields than high sucrose types due to feedback on photosynthesis either by sucrose or sucrose signalling compounds as proposed in several recent publications on feedback responses in sugarcane leaves.

Up to 20 sugarcane clones with either high fibre or high sucrose content were grown in one field and three pot experiments to elucidate some of the processes from source to sink that could be responsible for high rates of biomass accumulation expected in high fibre clones. We were particularly interested in the possibility that clones with high sucrose content may have reduced photosynthesis as sucrose levels increased in upper internodes due to feedback mechanisms.

Photosynthesis of whole plants and of single leaves decreased with crop development as much as 60% in some cases. Maintenance of photosynthesis was not associated with low content of sugars in leaves or in internodes. Sink strength for sucrose storage in the upper internodes was strong in both high fibre and high sucrose clones despite plants being grown for 12 months in conditions controlled to achieve high sucrose contents.

Our data supported previous conclusions about localised feedback on photosynthesis by sugars accumulating in the leaf resulting in reduced photosynthesis of small segments of individual young leaves. However, whole-plant photosynthesis did not decline through the day indicating that older leaves may compensate for reduced photosynthesis in younger leaves in the afternoon. While photosynthesis declined with crop age and sucrose content increased we found no evidence to suggest that photosynthesis declined because sucrose content increased. An increase in biomass yield through breeding and selection may not necessarily result in reduced sucrose content and increased fibre content.

Additional keywords: ageing, feedback, fibre, energy canes, photosynthesis.


References

Alexander AG (1973) ‘Sugarcane physiology. A comprehensive study of the Saccharum source-to-sink system.’ (Elsevier: Amsterdam)

Allison JCS, Williams HT, Pammenter NW (1997) Effect of specific leaf nitrogen content on photosynthesis of sugarcane. Annals of Applied Biology 131, 339–350.
Effect of specific leaf nitrogen content on photosynthesis of sugarcane.Crossref | GoogleScholarGoogle Scholar |

Amaya A, Cock JH, Hernandez A, Irvine J (1995) Bioligia. In ‘El cultivo de la Cana en la zona azucarera de Colombia’. Cali, Colombia, Cenicana. (Eds C Casselett, J Torres, C Isaacs) pp. 31–62. (FERIVA: Colombia)

Anon. (2009) ‘International sugar and sweetener report. World sugar balances.’ (FO Licht: Ratzeburg, Germany)

Botha FC (2009) Energy yield and cost in a sugarcane biomass system. Proceedings of the Australian Society of Sugar Cane Technologists 31, 1–10.

Breaux RD, Fanguy HP, Matherne RJ, Dunckelman PH (1974) Registration of CP 65–357 sugarcane (Reg. No. 35). Crop Science 14, 605–606.
Registration of CP 65–357 sugarcane (Reg. No. 35).Crossref | GoogleScholarGoogle Scholar |

Campbell JA, Hansen RW, Wilson JR (1999) Cost-effective colorimetric microtitre plate enzymatic assays for sucrose, glucose and fructose in sugarcane tissue extracts. Journal of the Science of Food and Agriculture 79, 232–236.
Cost-effective colorimetric microtitre plate enzymatic assays for sucrose, glucose and fructose in sugarcane tissue extracts.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1MXhsVSksbc%3D&md5=7800f32e611196c551210f3ce545599aCAS |

Cheesman OD (2004) ‘Environmental impacts of sugar production: the cultivation and processing of sugarcane and sugar beet.’ (CABI Publishing: Wallingford, UK)

Haines MG, Attard SJ (2010) Watersense web based irrigation scheduling and climate interpretive tool supports adaptive management strategies approach. Proceedings of the Australian Society of Sugar Cane Technologists 32, 322–332.

Inman-Bamber NG (2004) Sugarcane water stress criteria for irrigation and drying off. Field Crops Research 89, 107–122.
Sugarcane water stress criteria for irrigation and drying off.Crossref | GoogleScholarGoogle Scholar |

Inman-Bamber NG, Bonnett GD, Spillman MF, Hewitt ML, Jackson J (2008) Increasing sucrose accumulation in sugarcane by manipulating leaf extension and photosynthesis with irrigation. Australian Journal of Agricultural Research 59, 13–26.
Increasing sucrose accumulation in sugarcane by manipulating leaf extension and photosynthesis with irrigation.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXmt1Oqtg%3D%3D&md5=fc3d5a9ace4ddb0ae9bde67bc50bbe06CAS |

Inman-Bamber NG, Bonnett GD, Spillman MF, Hewitt ML, Jingsheng X (2009) Source–sink differences in genotypes and water regimes influencing sucrose accumulation in sugarcane stalks. Crop & Pasture Science 60, 316–327.
Source–sink differences in genotypes and water regimes influencing sucrose accumulation in sugarcane stalks.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXkslGis70%3D&md5=4d50260b9e8b7bf4c1f5a7770a303c27CAS |

Inman-Bamber NG, Bonnett GD, Spillman MF, Hewitt ML, Glassop D (2010) Sucrose accumulation in sugarcane is influenced by temperature and genotype through the carbon source–sink balance. Crop & Pasture Science 61, 111–121.
Sucrose accumulation in sugarcane is influenced by temperature and genotype through the carbon source–sink balance.Crossref | GoogleScholarGoogle Scholar |

Irvine JE (1975) Relations of photosynthetic rates and leaf and canopy characters to sugarcane yield. Crop Science 15, 671–676.
Relations of photosynthetic rates and leaf and canopy characters to sugarcane yield.Crossref | GoogleScholarGoogle Scholar |

Jackson PA (2005) Progress and prospects in genetic improvement in sucrose accumulation. Field Crops Research 92, 277–290.
Progress and prospects in genetic improvement in sucrose accumulation.Crossref | GoogleScholarGoogle Scholar |

Jackson PA (2007) Australian Centre for International Agricultural Research, Crop Improvement and Management. Available at: http://aciar.gov.au/project/CIM/2000/038

Kortschak HP, Forbes A (1969) The effects of shade and age on the photosynthesis rate of sugarcane. Progress in Photosynthesis Research 1, 383–387.

Leal MRLV (2007) The potential of sugarcane as an energy source. Proceedings of the International Society of Sugar Cane Technologists 26, 23–34.

McCormick AJ, Cramer MD, Watt DA (2006) Sink strength regulates photosynthesis in sugarcane. New Phytologist 171, 759–770.
Sink strength regulates photosynthesis in sugarcane.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XhtVSku7%2FP&md5=d3c0e7c1ec9429a31d6d5898cf7e95ffCAS |

McCormick AJ, Cramer MD, Watt DA (2008) Regulation of photosynthesis by sugars in sugarcane leaves. Journal of Plant Physiology 165, 1817–1829.
Regulation of photosynthesis by sugars in sugarcane leaves.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXhsVKgurbL&md5=ec4a02d868746b55cba7fc43871dbe06CAS |

McCormick AJ, Watt DA, Cramer MD (2009) Supply and demand sink regulation of sugar accumulation in sugarcane. Journal of Experimental Botany 60, 357–364.
Supply and demand sink regulation of sugar accumulation in sugarcane.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXivFSmtbw%3D&md5=612ac9d3c3929093949b8f7d9d6ada49CAS |

Moreira JR, Goldemberg J (1999) The alcohol program. Energy Policy 27, 229–245.
The alcohol program.Crossref | GoogleScholarGoogle Scholar |

Muchow RC, Wood AW, Spillman MF, Robertson MJ, Thomas MR (1993) Field techniques to quantify the yield-determining processes in sugarcane. Proceedings of the Australian Society of Sugar Cane Technologists 15, 336–343.

Papageorgiou J, Bartholomew HC, Doherty WOS (1997) HPAE-PAD: a rapid and precise method for sugar analysis. Proceedings of the Australian Society of Sugar Cane Technologists 19, 379–386.

Paul M, Pellny T, Goddijn O (2001) Enhancing photosynthesis with sugar signals. Trends in Plant Science 6, 197–200.
Enhancing photosynthesis with sugar signals.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3MXlsFKmt7s%3D&md5=6fcf74268f320c665c27a360e50b2655CAS |

Rao PS, Kennedy A (2004) ‘Genetic improvement of sugarcane for sugar, fibre and biomass’. In ‘Proceedings of the National Agricultural Conference’. Barbados. (CD-ROM) Available at: www.agriculture.gov.bb/default.asp?V_DOC_ID=1639 (accessed 2 June 2010)

RFA (Renewable Fuels Association) (2010) Ethanol industry statistics. Available at: www.ethanolrfa.org/pages/statistics (accessed 23 November 2011)

Robertson MJ, Muchow RC, Wood AW (1996) Growth of sugarcane under high input conditions in tropical Australia. I. Radiation use, biomass accumulation and partitioning. Field Crops Research 48, 11–25.
Growth of sugarcane under high input conditions in tropical Australia. I. Radiation use, biomass accumulation and partitioning.Crossref | GoogleScholarGoogle Scholar |

van Heerden PDR, Donaldson RA, Watt DA, Singels A (2010) Biomass accumulation in sugarcane: unravelling the factors underpinning reduced growth phenomena. Journal of Experimental Botany 61, 2877–2887.
Biomass accumulation in sugarcane: unravelling the factors underpinning reduced growth phenomena.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXotVWkt7s%3D&md5=a1f9985b3e14798f2351a6a8a8bd544cCAS |

Viator R, White P, Richard E (2010) Sustainable production of energycane for bio-energy in the Southeastern US. In ‘Sustainability of the Sugar and Sugar−Ethanol Industries’. ACS Symposium Series, Vol. 1058. Ch 9. (Ed. G Eggleston) pp. 147–161. (American Chemical Society)

Vu JCV, Allen LH, Gesch RW (2006) Up-regulation of photosynthesis and sucrose metabolism enzymes in young expanding leaves of sugarcane under elevated growth CO2. Plant Science 171, 123–131.
Up-regulation of photosynthesis and sucrose metabolism enzymes in young expanding leaves of sugarcane under elevated growth CO2.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XltVeltbY%3D&md5=dbcfe3503696ec9c5a9074bff2778a9eCAS |

Wang LP, Jackson PA, Lu X, Fan YH, Foreman JW, Chen XK, Deng HH, Fu C, Ma L, Aitken KS (2008) Evaluation of sugarcane × Saccharum spontaneum progeny for biomass composition and yield components. Crop Science 48, 951–961.
Evaluation of sugarcane × Saccharum spontaneum progeny for biomass composition and yield components.Crossref | GoogleScholarGoogle Scholar |

Wei X, Jackson PA, Stringer J, Cox M (2008) Relative economic genetic value (rEGV) – an improved selection index to replace net merit grade (NMG) in the Australian sugarcane variety improvement program. Proceedings of the Australian Society of Sugar Cane Technologists 30, 174–181.

Wu L, Birch RG (2007) Doubled sugar content in sugarcane plants modified to produce a sucrose isomer. Plant Biotechnology Journal 5, 109–117.
Doubled sugar content in sugarcane plants modified to produce a sucrose isomer.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2sXitV2jur8%3D&md5=3a70550ba330c141da10ca3ce4a4f097CAS |