Access the full text.
Sign up today, get DeepDyve free for 14 days.
N Aoki, T Hirose, RT Furbank (2012)
Photosynthesis: plastid biology, energy conversion, and carbon assimilation, advances in photosynthesis and respiration
A Gupta, N Kaur (2005)
Sugar signalling and gene expression in relation to carbohydrate metabolism under abiotic stresses in plantsJ Biosci, 30
KT Glasziou (1961)
Accumulation and transformation of sugars in stalks of sugar cane. Origin of glucose and fructose in the inner spacePlant Physiol, 36
K Glasziou (1958)
The physiology of sugar-cane I. Studies on the nutritional and physiological interrelationships of the germinating cuttingAust J Biol Sci, 11
MN Andersen, F Asch, Y Wu, CR Jensen, H Næsted, VO Mogensen, KE Koch (2002)
Soluble invertase expression is an early target of drought stress during the critical, abortion-sensitive phase of young ovary development in maizePlant Physiol, 130
JW Patrick, FC Botha, RG Birch (2013)
Metabolic engineering of sugars and simple sugar derivatives in plantsPlant Biotechnol J, 11
T Roitsch (1999)
Source-sink regulation by sugar and stressCurr Opin Plant Biol, 2
T Roitsch, ME Balibrea, M Hofmann (2003)
Extracellular invertase: key metabolic enzyme and PR proteinJ Exp Bot, 54
B O’Neill, M Purnell, D Anderson, L Nielsen, S Brumbley (2012)
Sucrose mobilisation in sugarcane stalk induced by heterotrophic axillary bud growthTrop Plant Biol, 5
KA Bindon, FC Botha (2002)
Carbon allocation to the insoluble fraction, respiration and triose-phosphate cycling in the sugarcane culmPhysiol Plant, 116
SE Lingle (1989)
Evidence for the uptake of sucrose intact into sugarcane internodesPlant Physiol, 90
BP O’Neill, MP Purnell, ND Kurniawan, GJ Cowin, GJ Galloway, LK Nielsen, SM Brumbley (2013)
Non-invasive monitoring of sucrose mobilization from culm storage parenchyma by magnetic resonance spectroscopyBiosci Biotechnol Biochem, 77
E Echeverria (1998)
Acid invertase (sucrose hydrolysis) is not required for sucrose mobilization from the vacuolePhysiol Plant, 104
KE Koch (1996)
Carbohydrate-modulated gene expression in plantsAnnu Rev Plant Physiol Plant Mol Biol, 47
PH Moore (1995)
Temporal and spatial regulation of sucrose metabolism in the sugarcane stemAust J Plant Physiol, 22
W Schafer, J Rohwer, F Botha (2005)
Partial purification and characterisation of sucrose synthase in sugarcaneJ Plant Physiol, 162
C Dillewijn (1952)
Botany of sugarcane
Y Wu, WT Avigne, KE Koch (1998)
Differential regulation of sugar-sensitive sucrose synthases by hypoxia and anoxia indicate complementary transcriptional and posttranscriptional responsesPlant Physiol, 116
KE Koch, Y Wu, J Xu (1996)
Sugar and metabolic regulation of genes for sucrose metabolism: potential influence of maize sucrose synthase and soluble invertase responses on carbon partitioning and sugar sensingJ Exp Bot, 47
A Whittaker, F Botha (1997)
Carbon partitioning during sucrose accumulation in sugarcane internodal tissuePlant Physiol, 115
K Koch (2004)
Sucrose metabolism: regulatory mechanisms and pivotal roles in sugar sensing and plant developmentCurr Opin Plant Biol, 7
AM Smith, M Stitt (2007)
Coordination of carbon supply and plant growthPlant Cell Environ, 30
S Bihmidine, CT Hunter, CE Johns, KE Koch, DM Braun (2013)
Regulation of assimilate import into sink organs: update on molecular drivers of sink strengthFront Plant Sci, 4
K Herbers, U Sonnewald (1998)
Molecular determinants of sink strengthCurr Opin Plant Biol, 1
B Vilhar, A Kladnik, A Blejec, PS Chourey, M Dermastia (2002)
Cytometrical evidence that the loss of seed weight in the miniature1 seed mutant of maize is associated with reduced mitotic activity in the developing endospermPlant Physiol, 129
AL Rae, CPL Grof, RE Casu, GD Bonnett (2005)
Sucrose accumulation in the sugarcane stem: pathways and control points for transport and compartmentationField Crops Res, 92
TA Bull, KT Glasziou (1963)
The evolutionary significance of sugar accumulation in saccharumAust J Biol Sci, 16
Sucrose, glucose and fructose concentrations, and sucrolytic enzyme activities were measured in the developing shoots and internodes of sprouting sugarcane setts (Saccharum spp, variety N19). The most striking change during the sink-source transition of the internode and germination of the axillary bud is a more than five-fold induction of cell wall invertase in the germinating bud. In contrast, soluble acid invertase is the main sucrose hydrolytic activity induced in the internodal tissue. A cycle of breakdown and synthesis of sucrose was evident in both the internodes and the shoots. During shoot establishment, the sucrose content decreased and the hexose content increased in the internodal tissues while both sucrose and hexoses continuously accumulated in the shoots. Over the sprouting period internode, dry mass was reduced by 25 and 30 % in plants incubated in a dark/light cycle or total darkness, respectively. Sucrose accounted for 90 % of the dry mass loss. The most significant changes in SuSy activity are in the synthesis direction in the shoots resulting in a decrease in the breakdown/synthesis ratio. In contrast the SuSy activity in the internodal tissue decrease and more so in the synthesis activity resulting in an increase in the breakdown to synthesis ratio.
Tropical Plant Biology – Springer Journals
Published: Dec 23, 2015
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.