Your search keyword '"fructans"' showing total 75 results

1. Transforming a Fructan:Fructan 6G-Fructosyltransferase from Perennial Ryegrass into a Sucrose:Sucrose 1-Fructosyltransferase.

Author

Lasseur, Bertrand, Schroeven, Lindsey, Lammens, Willen, Roy, Katrien Le, Spangeberg, German, Manduzio, Hélène, Vergauwen, Rudy, Lothier, Jérémy, Prud'homme, Marie-Pascale, and Wim Van den Ende

Subjects

*FRUCTANS, *RYEGRASSES, *SUCROSE, *GRASS physiology, *GRAIN, *FRUCTAN-containing plants

Abstract

Fructosyltransferases (FTs) synthesize fructans, fructose polymers accumulating in economically important cool-season grasses and cereals. FTs might be crucial for plant survival under stress conditions in species in which fructans represent the major form of reserve carbohydrate, such as perennial ryegrass (Lolium perenne). Two FT types can be distinguished: those using sucrose (S-type enzymes: sucrose:sucrose 1-fructosyltransferase [1-SST], sucrose:fructan 6-fructosyltransferase) and those using fructans (F-type enzymes: fructan:fructan I -fructosyltransferase [1-FFT], fructan:fructan 6G-fructosyltransferase [6G-FFT]) as preferential donor substrate. Here, we report, to our knowledge for the first time, the transformation of an F-type enzyme (6G- FFT/1-FFT) into an S-type enzyme (1-SST) using perem-tial ryegrass 6G-FFT/1-FFT (Lp6G-FFT/1-FFT) and 1-SST (Lpl-SST) as model enzymes. This transformation was accomplished by mutating three amino acids (N340D, W343R, and S415N) in the vicinity of the active site of Lp6C-FFT/1-FFT. In addition, effects of each amino acid mutation alone or in combination have been studied. Our results strongly suggest that the amino acid at position 343 (tryptophan or arginine) can greatly determine the donor substrate characteristics by influencing the position of the amino acid at position 340. Moreover, the presence of arginine-343 negatively affects the formation of neofructan-type linkages. The results are compared with recent findings on donor substrate selectivity within the group of plant cell wall invertases and fructan exohydrolases. Taken together, these insights contribute to our knowledge of structure/function relationships within plant family 32 glycosyl hydrolases and open the way to the production of tailor-made fructans on a larger scale. [ABSTRACT FROM AUTHOR]

Published

2009

2. Molecular Dissection of Variation in Carbohydrate Metabolism Related to Water-Soluble Carbohydrate Accumulation in Stems of Wheat.

Author

Gang-Ping Xue, McIntyre, C. Lynne, Jenkins, Colin L. D., Glassop, Donna, Van Herwaarden, Anthony F., and Shorter, Ray

Subjects

*CARBOHYDRATE metabolism, *WHEAT, *GRAIN, *DISSECTION, *ENZYMES, *FRUCTANS

Abstract

Water-soluble carbohydrates (WSCs; composed of mamly fructans, sucrose [Suc], glucose [Gic], and fructose) deposited in wheat (Triticum aestivum) stems are important carbon sources for grain filling. Variation in stem WSC concentrations among wheat genotypes is one of the genetic factors influencing grain weight and yield under water-limited environments. Here, we describe the molecular dissection of carbohydrate metabolism in stems, at the WSC accumulation phase, of recombinant inbred Seri/Babax lines of wheat differing in stem WSC concentrations. Affymetrix GeneChip analysis of carbohydrate metabolic enzymes revealed that the mRNA levels of two fructan synthetic enzyme families (Suc:Suc 1-fructosyltransferase and Suc:fructan 6-fructosyltransferase) in the stem were positively correlated with stem WSC and fructan concentrations, whereas the mRNA levels of enzyme families involved in Suc hydrolysis (Suc synthase and soluble acid invertase) were inversely correlated with WSC concentrations. Differential regulation of the mRNA levels of these Suc hydrolytic enzymes in Seri/Babax lines resulted in genotypic differences in these enzyme activities. Down-regulation of Suc synthase and soluble acid. invertase in high WSC lines was accompanied by significant decreases in the mRNA levels of enzyme families related to sugar catabolic pathways (fructokinase and mitochondrion pyruvate dehydrogenase complex) and enzyme families involved in diverting UDP-Glc to cell wall synthesis (UDP-Glc 6-dehydrogenase, UDP-glucuronate decarboxylase, and cellulose synthase), resulting in a reduction in cell wall polysaccharide contents (mainly hemicellulose) in the stem of high WSC lines. These data suggest that differential carbon partitioning in the wheat stem is one mechanism that contributes to genotypic variation in WSC accumulation. [ABSTRACT FROM AUTHOR]

Published

2008

3. Unraveling the Difference between Invertases and Fructan Exohydrolases: A Single Amino Acid (Asp-239) Substitution Transforms Arabidopsis Cell Wall Invertasel into a Fructan 1-Exohydrolase.

Author

Le Roy, Katrien, Lammens, Willem, Verhaest, Maureen, De Coninck, Barbara, Rabijns, Anja, Van Laere, André, and Van den Ende, Wim

Subjects

*INVERTASE, *FRUCTANS, *AMINO acids, *ARABIDOPSIS, *PLANT cell walls, *HYDROLYSIS

Abstract

Plant cell wall invertases and fructan exohydrolases (FEHs) are very closely related enzymes at the molecular and structural level (family 32 of glycoside hydrolases), but they are functionally different and are believed to fulfill distinct roles in plants. Invertases preferentially hydrolyze the glucose (Glc)-fructose (Fru) linkage in sucrose (Suc), whereas plant FEHs have no invertase activity and only split terminal Fru-Fru linkages in fructans. Recently, the three-dimensional structures of Arabidopsis (Arabidopsis thaliana) cell wall Invertasel (AtcwINVl) and chicory (Cichorium intybus) 1-FEH ha were resolved. Until now, it remained unknown which amino acid residues determine whether Suc or fructan is used as a donor substrate in the hydrolysis reaction of the glycosidic bond. In this article, we present site-directed mutagenesis-based data on AtcwINVl showing that the aspartate (Asp)-239 residue fulfills an important role in both binding and hydrolysis of Suc. Moreover, it was found that the presence of a hydrophobic zone at the rim of the active site is important for optimal and stable binding of Suc. Surprisingly, a D239A mutant acted as a l-FEH, preferentially degrading 1-kestose, indicating that plant FEHs lacking invertase activity could have evolved from a cell wall invertase-type ancestor by a few mutational changes. In general, family 32 and 68 enzymes containing an Asp-239 functional homolog have Suc as a preferential substrate, whereas enzymes lacking this homolog use fructans as a donor substrate. The presence or absence of such an Asp-239 homolog is proposed as a reliable determinant to discriminate between real invertases and defective invertases/FEHs. [ABSTRACT FROM AUTHOR]

Published

2007

4. Fructan 1–Exohydrolases. Β–(2,1)–Trimmers during Graminan Biosynthesis in Stems of Wheat? Purification, Characterization, Mass Mapping, and Cloning of Two Fructan 1–Exohydrolase Isoforms.

Author

Van den Ende, Wim, Clerens, Stefan, Vergauwen, Rudy, Van Riet, Liesbet, Van Laere, André, Yoshida, Midori, and Kawakami, Akira

Subjects

*PLANT genetic transformation, *FRUCTANS, *HYDROLASES, *PLANT stems, *WINTER wheat

Abstract

Reports on the cloning, purification and characterization of two fructan 1–exohydrolase cyclic DNA (cDNA) from winter wheat stems. Derivation of the cDNA from a special group within the cell wall-type invertases; Purification of the corresponding isoenzymes to electrophoretic homogeneity; Determination of the mass spectra.

Published

2003

5. Properties of Fructan:Fructan 1-Fructosyltransferases from Chicory and Globe Thistle, Two Asteracean Plants Storing Greatly Different Types of Inulin

Author

André Van Laere, Rudolf Vergauwen, and Wim Van den Ende

Subjects

Sucrose, food.ingredient, Physiology, Inulin, Fructose, Plant Science, Asteraceae, Biology, Models, Biological, Chicory, Substrate Specificity, chemistry.chemical_compound, food, Fructan, Cichorium, Botany, Genetics, Helianthus, Plant Proteins, Whole Plant and Ecophysiology, Cynara scolymus, Echinops Plant, biology.organism_classification, Fructans, Kinetics, Hexosyltransferases, chemistry, Thistle, Trisaccharides, Jerusalem artichoke

Abstract

Remarkably, within the Asteraceae, a species-specific fructan pattern can be observed. Some species such as artichoke (Cynara scolymus) and globe thistle (Echinops ritro) store fructans with a considerably higher degree of polymerization than the one observed in chicory (Cichorium intybus) and Jerusalem artichoke (Helianthus tuberosus). Fructan:fructan 1-fructosyltransferase (1-FFT) is the enzyme responsible for chain elongation of inulin-type fructans. 1-FFTs were purified from chicory and globe thistle. A comparison revealed that chicory 1-FFT has a high affinity for sucrose (Suc), fructose (Fru), and 1-kestose as acceptor substrate. This makes redistribution of Fru moieties from large to small fructans very likely during the period of active fructan synthesis in the root when import and concentration of Suc can be expected to be high. In globe thistle, this problem is avoided by the very low affinity of 1-FFT for Suc, Fru, and 1-kestose and the higher affinity for inulin as acceptor substrate. Therefore, the 1-kestose formed by Suc:Suc 1-fructosyltransferase is preferentially used for elongation of inulin molecules, explaining why inulins with a much higher degree of polymerization accumulate in roots of globe thistle. Inulin patterns obtained in vitro from 1-kestose and the purified 1-FFTs from both species closely resemble the in vivo inulin patterns. Therefore, we conclude that the species-specific fructan pattern within the Asteraceae can be explained by the different characteristics of their respective 1-FFTs. Although 1-FFT and bacterial levansucrases clearly differ in their ability to use Suc as a donor substrate, a kinetic analysis suggests that 1-FFT also works via a ping-pong mechanism.

Published

2003

6. Cloning and functional analysis of sucrose:sucrose 1-fructosyltransferase from tall fescue

Author

Marcel Lüscher, Virginie Galati, Roger A. Aeschbacher, Urs Hochstrasser, Thomas Boller, Andres Wiemken, C. J. Nelson, and Guido Vogel

Subjects

Sucrose, DNA, Complementary, Physiology, Molecular Sequence Data, Plant Science, Fructose, Biology, Molecular cloning, Poaceae, Pichia pastoris, Fructan, Sequence Analysis, Protein, Complementary DNA, Gene expression, Genetics, Transferase, Amino Acid Sequence, RNA, Messenger, Cloning, Molecular, Plant Proteins, chemistry.chemical_classification, Reverse Transcriptase Polymerase Chain Reaction, biology.organism_classification, Yeast, Fructans, Enzyme, Biochemistry, chemistry, Hexosyltransferases, Electrophoresis, Polyacrylamide Gel, Research Article

Abstract

Enzymes of grasses involved in fructan synthesis are of interest since they play a major role in assimilate partitioning and allocation, for instance in the leaf growth zone. Several fructosyltransferases from tall fescue (Festuca arundinacea) have previously been purified (Lüscher and Nelson, 1995). It is surprising that all of these enzyme preparations appeared to act both as sucrose (Suc):Suc 1-fructosyl transferases (1-SST) and as fructan:fructan 6G-fructosyl transferases. Here we report the cloning of a cDNA corresponding to the predominant protein in one of the fructosyl transferase preparations, its transient expression in tobacco protoplasts, and its functional analysis in the methylotrophic yeast,Pichia pastoris. When the cDNA was transiently expressed in tobacco protoplasts, the corresponding enzyme preparations produced 1-kestose from Suc, showing that the cDNA encodes a 1-SST. When the cDNA was expressed in P. pastoris, the recombinant protein had all the properties of known 1-SSTs, namely 1-kestose production, moderate nystose production, lack of 6-kestose production, and fructan exohydrolase activity with 1-kestose as the substrate. The physical properties were similar to those of the previously purified enzyme, except for its apparent lack of fructan:fructan 6G-fructosyl transferase activity. The expression pattern of the corresponding mRNA was studied in different zones of the growing leaves, and it was shown that transcript levels matched the 1-SST activity and fructan content.

Published

2000

7. Cloning, developmental, and tissue-specific expression of sucrose:sucrose 1-fructosyl transferase from Taraxacum officinale. Fructan localization in roots

Author

Wim Van den Ende, An Michiels, André Van Laere, Dominik Van Wonterghem, and Rudolf Vergauwen

Subjects

endocrine system, Sucrose, DNA, Complementary, Physiology, Molecular Sequence Data, Plant Science, Plant Roots, Gene Expression Regulation, Enzymologic, chemistry.chemical_compound, Fructan, fluids and secretions, Taraxacum officinale, Gene Expression Regulation, Plant, Cichorium, Botany, Genetics, Amino Acid Sequence, RNA, Messenger, Sieve tube element, Helianthus, Plant Proteins, biology, Base Sequence, Sequence Homology, Amino Acid, fungi, Xylem, food and beverages, Plants, biology.organism_classification, Fructans, chemistry, Biochemistry, Hexosyltransferases, Phloem, hormones, hormone substitutes, and hormone antagonists, Research Article

Abstract

Sucrose:sucrose 1-fructosyl transferase (1-SST) is the key enzyme initiating fructan synthesis in Asteraceae. Using reverse transcriptase-PCR, we isolated the cDNA for 1-SST from Taraxacum officinale. The cDNA-derived amino acid sequence showed very high homology to other Asteracean 1-SSTs (Cichorium intybus 86%, Cynara scolymus 82%,Helianthus tuberosus 80%), but homology to 1-SST fromAllium cepa (46%) and Aspergillus foetidus (18%) was much lower. Fructan concentrations, 1-SST activities, 1-SST protein, and mRNA concentrations were compared in different organs during vegetative and generative development ofT. officinale plants. Expression of 1-SST was abundant in young roots but very low in leaves. 1-SST was also expressed at the flowering stages in roots, stalks, and receptacles. A good correlation was found between northern and western blots showing transcriptional regulation of 1-SST. At the pre-flowering stage, 1-SST mRNA concentrations and 1-SST activities were higher in the root phloem than in the xylem, resulting in the higher fructan concentrations in the phloem. Fructan localization studies indicated that fructan is preferentially stored in phloem parenchyma cells in the vicinity of the secondary sieve tube elements. However, inulin-like crystals occasionally appeared in xylem vessels.

Published

2000

8. Fructan: more than a reserve carbohydrate?

Author

I, Vijn and S, Smeekens

Subjects

Bacteria, Glycoside Hydrolases, Sequence Homology, Amino Acid, beta-Fructofuranosidase, Molecular Sequence Data, Plants, Models, Biological, Update, Fructans, Evolution, Molecular, Carbohydrate Sequence, Hexosyltransferases, Carbohydrate Metabolism, Amino Acid Sequence, Biotechnology

Published

1999

9. Cloning of sucrose:sucrose 1-fructosyltransferase from onion and synthesis of structurally defined fructan molecules from sucrose

Author

I, Vijn, A, van Dijken, M, Lüscher, A, Bos, E, Smeets, P, Weisbeek, A, Wiemken, and S, Smeekens

Subjects

DNA, Complementary, Glycoside Hydrolases, Sequence Homology, Amino Acid, beta-Fructofuranosidase, Protoplasts, fungi, Molecular Sequence Data, food and beverages, Fructans, Plant Leaves, Plants, Toxic, Hexosyltransferases, Onions, Tobacco, Amino Acid Sequence, RNA, Messenger, Cloning, Molecular, Research Article

Abstract

Sucrose (Suc):Suc 1-fructosyltransferase (1-SST) is the key enzyme in plant fructan biosynthesis, since it catalyzes de novo fructan synthesis from Suc. We have cloned 1-SST from onion (Allium cepa) by screening a cDNA library using acid invertase from tulip (Tulipa gesneriana) as a probe. Expression assays in tobacco (Nicotiana plumbaginifolia) protoplasts showed the formation of 1-kestose from Suc. In addition, an onion acid invertase clone was isolated from the same cDNA library. Protein extracts of tobacco protoplasts transformed with this clone showed extensive Suc-hydrolyzing activity. Conditions that induced fructan accumulation in onion leaves also induced 1-SST mRNA accumulation, whereas the acid invertase mRNA level decreased. Structurally different fructan molecules could be produced from Suc by a combined incubation of protein extract of protoplasts transformed with 1-SST and protein extract of protoplasts transformed with either the onion fructan:fructan 6G-fructosyltransferase or the barley Suc:fructan 6-fructosyltransferase.

Published

1998

10. Properties of Fructan:Fructan 1-Fructosyltransferases from Chicory and Globe Thistle, Two Asteracean Plants Storing Greatly Different Types of Inulin

Author

Vergauwen, Rudy, Van Laere, André, and Van den Ende, Wim

Published

2003

11. Fructans, but Not the Sucrosyl-Galactosides, Raffinose and Loliose, Are Affected by Drought Stress in Perennial Ryegrass

Author

Amiard, Véronique and Keller, Felix

Published

2003

12. Rubisco Small Subunit, Chlorophyll a/b-Binding Protein and Sucrose:Fructan-6-Fructosyl Transferase Gene Expression and Sugar Status in Single Barley Leaf Cells in Situ. Cell Type Specificity and Induction by Light

Author

Lu, Chungui, Koroleva, Olga A., Farrar, John F., and Tomos, A. Deri

Published

2002

13. Defoliation Induces Fructan 1-Exohydrolase II in Witloof Chicory Roots. Cloning and Purification of Two Isoforms, Fructan 1-Exohydrolase IIa and Fructan 1-Exohydrolase IIb. Mass Fingerprint of the Fructan 1-Exohydrolase II Enzymes

Author

Van den Ende, Wim

Published

2001

14. Sucrose Metabolism in Plastids

Author

Weisbeek, Peter J.

Published

2001

15. Cloning and Functional Analysis of Sucrose:Sucrose 1-Fructosyltransferase from Tall Fescue

Author

Lüscher, Marcel, Galati, Virginie, Boller, Thomas, and Wiemken, Andres

Published

2000

16. Cloning, Developmental, and Tissue-Specific Expression of Sucrose:Sucrose 1-Fructosyl Transferase from Taraxacum officinale. Fructan Localization in Roots

Author

Van den Ende, Wim, Vergauwen, Rudy, and Van Laere, André

Published

2000

17. Disaccharide-Mediated Regulation of Sucrose:Fructan-6-Fructosyltransferase, a Key Enzyme of Fructan Synthesis in Barley Leaves

Author

Müller, Joachim, Sprenger, Norbert, Boller, Thomas, and Wiemken, Andres

Published

2000

18. Fructan: More than a Reserve Carbohydrate?

Author

Vijn, Irma and Smeekens, Sjef

Published

1999

19. Carbohydrates in Individual Cells of Epidermis, Mesophyll, and Bundle Sheath in Barley Leaves with Changed Export or Photosynthetic Rate

Author

Koroleva, Olga A., Farrar, John F., Tomos, A. Deri, and Pollock, Christopher J.

Published

1998

20. Cloning of Sucrose:Sucrose 1-Fructosyltransferase from Onion and Synthesis of Structurally Defined Fructan Molecules from Sucrose

Author

Vijn, Irma, van Dijken, Anja, Lüscher, Marcel, Weisbeek, Peter, Wiemken, Andres, and Smeekens, Sjef

Published

1998

21. Phloem Transport of Fructans in the Crassulacean Acid Metabolism Species Agave deserti

Author

Wang, Ning and Nobel, Park S.

Published

1998

22. Apoplastic Sugars, Fructans, Fructan Exohydrolase, and Invertase in Winter Oat: Responses to Second-Phase Cold Hardening

Author

Livingston, David P.

Published

1998

23. Purification and Characterization of the Enzymes of Fructan Biosynthesis in Tubers of Helianthus tuberosus Colombia: II. Purification of Sucrose:Sucrose 1-Fructosyltransferase and Reconstitution of Fructan Synthesis in vitro with Purified Sucrose:Sucrose 1-Fructosyltransferase and Fructan:Fructan 1-Fructosyltransferase

Author

Jonker, Harry H.

Published

1996

24. Purification and Characterization of an Oat Fructan Exohydrolase That Preferentially Hydrolyzes β-2,6-Fructans

Author

Livingston, David P.

Published

1996

25. Fructan Accumulation and Sucrose Metabolism in Transgenic Maize Endosperm Expressing a Bacillus amyloliquefaciens SacB Gene

Author

Klein, Theodore M.

Published

1996

26. Multiscale Metabolic Modeling: Dynamic Flux Balance Analysis on a Whole-Plant Scale

Author

Grafahrend-Belau, Eva, Junker, Astrid, Eschenröder, André, Müller, Johannes, Schreiber, Falk, and Junker, Björn H.

Published

2013

27. Understanding the Role of Defective Invertases in Plants: Tobacco Nin88 Fails to Degrade Sucrose

Author

Le Roy, Katrien, Vergauwen, Rudy, Struyf, Tom, Yuan, Shuguang, Lammens, Willem, Mátrai, Janka, De Maeyer, Marc, and Van den Ende, Wim

Published

2013

28. Ethylene and 1-Methylcyclopropene Differentially Regulate Gene Expression during Onion Sprout Suppression

Author

Cools, Katherine, Chope, Gemma A., Hammond, John P., Thompson, Andrew J., and Terry, Leon A.

Published

2011

29. Unexpected presence of Graminan- and Levan-Type Fructans in the Evergreen Frost-Hardy Eudiot Pachysandra terminalis (Buxaceae): Purification, Cloning, and Functional analysis of a 6-SST/6-SET Enzyme

Author

van den Ende, Wim, Coopman, Marlies, Clerens, Stefan, Vergauwen, Ruby, Le Roy, Katrien, Lammens, Willem, and Vam Laere, André

Published

2011

30. Advanced Data-Mining Strategies for the Analysis of Direct-Infusion Ion Trap Mass Spectrometry Data from the Association of Perennial Ryegrass with Its Endophytic Fungus, Neotyphodium lolii

Author

Cao, Mingshu, Koulman, Albert, Johnson, Linda J., Lane, Geoffrey A., and Rasmussen, Susanne

Published

2008

31. Molecular Dissection of Variation in Carbohydrate Metabolism Related to Water-Soluble Carbohydrate Accumulation in Stems of Wheat

Author

Xue, Gang-Ping, Mclntyre, C. Lynne, Jenkins, Colin L. D., Glassop, Donna, van Herwaarden, Anthony F., and Shorter, Ray

Published

2008

32. Exopolysaccharides Produced by Phytopathogenic Pseudomonas syringae Pathovars in Infected Leaves of Susceptible Hosts

Author

Fett, William F.

Published

1989

33. Localization of the Enzymes of Fructan Metabolism in Vacuoles Isolated by a Mechanical Method from Tubers of Jerusalem Artichoke (Helianthus tuberosus L.)

Author

John, Philip

Published

1989

34. Growth Rates and Assimilate Partitioning in the Elongation Zone of Tall Fescue Leaf Blades at High and Low Irradiance

Author

Schnyder, Hans

Published

1989

35. Diurnal Growth of Tall Fescue Leaf Blades: II. Dry Matter Partitioning and Carbohydrate Metabolism in the Elongation Zone and Adjacent Expanded Tissue

Author

Schnyder, Hans

Published

1988

36. Fructan Content and Synthesis in Leaf Tissues of Festuca arundinacea

Published

1988

37. Characterization of Fructan from Mature Leaf Blades and Elongation Zones of Developing Leaf Blades of Wheat, Tall Fescue, and Timothy

Published

1988

38. Uptake and Assimilation of NO₃⁻ and NH₄⁺ by Nitrogen-Deficient Perennial Ryegrass Turf

Published

1988

39. Regulation of Fructan Metabolism in Leaves of Barley (Hordeum vulgare L. cv Gerbel)

Author

Wagner, Walter, Wiemken, Andres, and Matile, Philippe

Published

1986

40. Fructan Content and Fructosyltransferase Activity during Wheat Seed Growth

Published

1987

41. Growth Rates and Carbohydrate Fluxes within the Elongation Zone of Tall Fescue Leaf Blades

Author

Schnyder, Hans

Published

1987

42. Enzymology of Fructan Synthesis in Grasses: Properties of Sucrose-Sucrose-Fructosyltransferase in Barley Leaves (Hordeum vulgare L. cv Gerbel)

Author

Wagner, Walter and Wiemken, Andres

Published

1987

43. Photosynthesis in Tall Fescue: IV. Carbon Assimilation Pattern in Two Genotypes of Tall Fescue Differing in Net Photosynthesis Rates

Author

Randall, Douglas D.

Published

1983

44. Partial Purification and Properties of Phleinase Induced in Stem Base of Orchardgrass after Defoliation

Published

1985

45. Carbohydrate Metabolism in Leaf Meristems of Tall Fescue: I. Relationship to Genetically Altered Leaf Elongation Rates

Published

1984

46. Diurnal Carbohydrate Metabolism of Barley Primary Leaves

Author

Sicher, Richard C. and Harris, William G.

Published

1984

47. Photosynthate Partitioning in Basal Zones of Tall Fescue Leaf Blades

Published

1991

48. Fructosyl Transfer between 1-Kestose and Sucrose in Wheat Leaves

Author

Kanabus, Jan, Gibeaut, David M., and Carpita, Nicholas C.

Published

1991

49. Sucrose:Fructan 6-Fructosyltransferase, a Key Enzyme for Diverting Carbon from Sucrose to Fructan in Barley Leaves

Author

Bortlik, Karlheinz, Wiemken, Andres, and Bancal, Pierre

Published

1995

50. Fructosyltransferase Activities in the Leaf Growth Zone of Tall Fescue

Author

Lüscher, Marcel

Published

1995