Cloning of a vacuolar invertase from Belgian endive leaves (Cichorium intybus)

Although a lot of vacuolar invertase (EC 3.2.1.26) cDNAs are available from a diversity of plant species, up to now no sequence information is available on invertases from any dicot fructan-containing species. Therefore, we describe the cloning of vacuolar acid invertase cDNA from etiolated Belgian endive leaves ( Cichorium intybus L. var. foliosum cv. Flash), formed throughout the forcing process of the witloof chicory roots. Full-length cDNA was obtained by a combination of RT-PCR, PCR and 5'- and 3' RACE RT-PCR, starting with primers based on conserved amino acid sequences. The cloned chicory acid invertase groups together with vacuolar type invertases and fructan biosynthetic enzymes. A putative role for vacuolar type invertases in fructan synthesizing plants is discussed.     

Fructan synthesis in transgenic tobacco and chicory plants expressing barley sucrose:fructan 6-fructosyltransferase

We have recently cloned a cDNA encoding sucrose:fructan 6-fructosyltransferase (6-SFT), a key enzyme of fructan synthesis forming the β-2,6 linkages typical of the grass fructans, graminans and phleins [Sprenger et al. (1995) Proc. Natl. Acad. Sci. USA 92, 11652–11656]. Here we report functional expression of 6-SFT from barley in transgenic tobacco and chicory. Transformants of tobacco, a plant naturally unable to form fructans, synthesized the trisaccharide kestose and a series of unbranched fructans of the phlein type (β-2,6 linkages). Transformants of chicory, a plant naturally producing only unbranched fructans of the inulin type (β-2,1 linkages), synthesized in addition branched fructans of the graminan type, particularly the tetrasaccharide bifurcose which is also a main fructan in barley leaves.     

Kinetic behaviour and specificity of β-fructosidases in the hydrolysis of plant and microbial fructans

Fructosidases, in particular exo-β-fructosidases, may act on fructans such as inulins and levans of plant and bacterial origin to produce fructose. In this paper, the kinetic properties of a commercial preparation (Fructozyme L) and a recombinant exoinulinase (BfrA) from Thermotoga maritima, were studied using fructan polymer substrates from various sources. Both enzymatic preparations preferentially hydrolyzed β2-1 linkages and low molecular weight fructans. We show that chicory inulin is degraded most efficiently by both preparations, followed by bacterial inulin, in spite of its high molecular weight and branching in β2-6 positions. All bacterial levans were more slowly hydrolyzed. Michaelis–Menten kinetics describe the hydrolysis of sucrose and low molecular weight fructans (≤8.3 kDa) by both enzyme preparations, while first order kinetics were observed with respect to bacterial fructans due to the high molecular weight and, therefore, low molar concentrations. Comparison of second order rate constants indicates that bacterial inulin (Leuconostoc citreum CW28) is hydrolyzed more slowly with both enzyme preparations than chicory inulin by approximately one order of magnitude. For Leuconostoc mesenteroides NRRL B-512F levan, the second order rate constant for Fructozyme L is 200-fold lower than for chicory inulin. However, the second order rate constant for BfrA is only 22-fold lower than for chicory inulin. Taken together, our studies characterize the kinetics of fructan hydrolysis and also suggest that the kinetic parameters may be used to differentiate between fructan structures.     

De-novo synthesis of fructans from sucrose in vitro by a combination of two purified enzymes (sucrose: sucrose 1-fructosyl transferase and fructan: fructan 1-fructosyl transferase) from chicory roots (Cichorium intybus L.)

Although fructans occur widely in several plant families and they have been a subject of investigation for decennia, the mechanism of their biosynthesis is not completely elucidated. We succeeded in purifying a fructan: fructan 1-fructosyl transferase (1-FFT; EC 2.4.1.100) from chicory roots (Cichorium intybus L. var. foliosum cv. Flash). In combination with the purified chicory root sucrose: sucrose 1-fructosyl transferase (1-SST; EC 2.4.1.99), this enzyme synthesized a range of naturally occurring chicory fructans (inulins) from sucrose as the sole substrate. Starting from physiologically relevant sucrose concentrations, inulins up to a degree of polymerization (DP) of about 20 were synthesized in vitro after 96 h at 0°C. Neither 1-SST, nor 1-FFT alone could mediate the observed fructan synthesis. Fructan synthesis in vitro was compared starting from 50, 100 and 200 mM sucrose, respectively. The initiation of (DP > 3)-fructan synthesis was found to be correlated with a certain ratio of 1 kestose to sucrose. The data presented now provide strong evidence to validate the 1-SST/1-FFT model for in-vivo fructan synthesis, at least in the Asteraceae.Abbreviations DP degree of polymerization - 1-FFT fructan: fructan 1-fructosyl transferase - 1-SST sucrose: sucrose 1-fructosyl transferase The authors thank E. Nackaerts for valuable technical assistance. W. Van den Ende is grateful to the National Fund for Scientific Research (NFSR Belgium) for giving a grant for research assistants.     

Cloning of the fructan biosynthesis pathway of Jerusalem artichoke

To study the regulation of fructan synthesis in plants, we isolated two full-size cDNA clones encoding the two enzymes responsible for fructan biosynthesis in Jerusalem artichoke ( Helianthus tuberosus ): 1-sucrose:sucrose fructosyl transferase (1-SST) and 1-fructan:fructan fructosyl transferase (1-FFT). Both enzymes have recently been purified to homogeneity from Jerusalem artichoke tubers (Koops and Jonker (1994) J. Exp. Bot. 45, 1623–1631; Koops and Jonker (1996) Plant Physiol. 110, 1167–1175) and their amino acid sequences have been partially determined. Using RT–PCR and primers based on these sequences, specific fragments of the genes were amplified from tubers of Jerusalem artichoke. These fragments were used as probes to isolate the cDNAs encoding 1-SST and 1-FFT from a tuber-specific λZAP library. The deduced amino acid sequences of both cDNAs perfectly matched the sequences of the corresponding purified proteins. At the amino acid level, the cDNA sequences showed 61% homology to each other and 59% homology to tomato vacuolar invertase. Based on characteristics of the deduced amino acid sequence, the first 150 bp of both genes encode a putative vacuolar targeting signal. Southern blot hybridization revealed that both 1-SST and 1-FFT are likely to be encoded by single-copy genes. Expression studies based on RNA blot analysis showed organ-specific and developmental expression of both genes in growing tubers. Lower expression was detected in flowers and in stem. In other organs, including leaf, roots and dormant tubers, no expression could be detected. In tubers, the spatial and developmental expression correlates with the accumulation of fructans. Using the 1-sst and 1-fft cDNAs, chimeric genes were constructed driven by the CaMV 35S promoter. Analysis of transgenic petunia plants carrying these constructs showed that both cDNAs encode functional fructosyltransferase enzymes. Plants transformed with the 35S- 1-sst construct accumulated the oligofructans 1-kestose (GF₂), 1,1-nystose (GF₃) and 1,1,1-fructosylnystose (GF₄). Plants transformed with the 35S- 1-fft construct did not accumulate fructans, probably because of the absence of suitable substrates for 1-FFT, i.e. fructans with a degree of polymerization ≥ 3 (GF₂, GF₃, etc.). Nevertheless, protein extracts from these transgenic plants were able to convert GF₃, when added as a substrate, into fructans with a higher degree of polymerization. Progeny of crosses between a 35S- 1-sst -containing plant and a 35S- 1-fft- containing plant, showed accumulation of high-molecular-weight fructans in old, senescent leaves. Based on the comparison of the predicted amino acid sequences of 1-sst and 1-fft with those of other plant fructosyl transferase genes, we postulate that both plant fructan genes have evolved from plant invertase genes.     

Fructan of the inulin neoseries is synthesized in transgenic chicory plants (Cichorium intybus L.) harbouring onion (Allium cepa L.) fructan:fructan 6G-fructosyltransferase

Fructan (polyfructosylsucrose) is an important storage carbohydrate in many plant families. fructan:fructan 6G-fructosyltransferase (6G-FFT) is a key enzyme in the formation of the inulin neoseries, a type of fructan accumulated by members of the Liliales. We have cloned the 6G-FFT from onion by screening a cDNA library using barley sucrose:fructan 6-fructosyltransferase (6-SFT) as a probe. The deduced amino acid sequence showed a high homology with plant invertases and 6-SFT. Incubation of protein extracts from transgenic tobacco plants with the trisaccharide 1-kestose and sucrose resulted in the formation of neokestose and fructans of the inulin neoseries with a degree of polymerization up to six. Introduction of the onion 6G-FFT into chicory resulted in the synthesis of fructan of the inulin neoseries, in addition to the synthesis of linear inulin.     

Molecular cloning and characterization of a high DP fructan: fructan 1-fructosyl transferase from Viguiera discolor (Asteraceae) and its heterologous expression in Pichia pastoris

Inulin-type fructans are stored in the tuberous roots of the Brazilian cerrado plant Viguiera discolor Baker (Asteraceae). In Cynara scolymus (artichoke) and Echinops ritro (globe thistle), the fructans have a considerably higher degree of polymerization (DP) than in Cichorium intybus (chicory) and Helianthus tuberosus (Jerusalem artichoke). It was shown before that the higher DP in some species can be attributed to the properties of their fructan: fructan 1-fructosyl transferases (1-FFTs; EC 2.4.1.100), enzymes responsible for chain elongation. Here, we describe the cloning of a high DP (hDP) 1-FFT cDNA from V. discolor and its heterologous expression in Pichia pastoris . Starting from 1-kestose and Neosugar P (a mixture of oligo-inulins from microbial origin) as substrates, the recombinant enzyme produces a typical hDP inulin profile in vitro, closely resembling the one observed in vivo. The enzyme shows no invertase activity and sucrose: sucrose 1-fructosyl transferase (1-SST; EC 2.4.1.99) activity in vitro. Pattern evolution during incubation suggests that inulins with DP ≥ 6 are much better substrates than sucrose or lower DP oligo-fructans. Because hDP inulin-type fructans show superior properties for specific food and non-food applications, the hDP 1-FFT gene from V. discolor has potential for the production of hDP inulin in vitro or in transgenic crops.     

Properties of fructan:fructan 1-fructosyltransferases from chicory and globe thistle,two Asteracean plants storing greatly different types of inulin

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.     

高等植物果聚糖研究进展

果聚糖是高等植物重要的贮藏碳水化合物 ,因植物种类和发育阶段而异 ,主要存在 5种类型的结构 :线型菊糖型果聚糖、菊糖型果聚糖新生系列、线型梯牧草糖型果聚糖、混合型梯牧草糖型果聚糖和梯牧草糖型果聚糖新生系列。果聚糖的代谢模型随着代谢酶—蔗糖 :蔗糖果糖基转移酶、蔗糖 :果聚糖_6_果糖基转移酶、果聚糖 :果聚糖果糖基转移酶、果聚糖 :果聚糖_6_果糖基转移酶、果聚糖外水解酶等的发现、纯化和克隆日趋清晰。此外 ,果聚糖分子生物学研究也取得了一定的进展     

高等植物果聚糖研究进展

果聚糖是高等植物重要的贮藏碳水化合物,因植物种类和发育阶段而异,主要存在5种类型的结构：线型菊糖型果聚糖、菊糖型果聚糖新生系列、线型梯牧草糖型果聚糖、混合型梯牧草糖型果聚糖和梯牧草糖型果聚糖新生系列。果聚糖的代谢模型随着代谢酶—蔗糖：蔗糖果糖基转移酶、蔗糖：果聚糖_6_果糖基转移酶、果聚糖：果聚糖果糖基转移酶、果聚糖：果聚糖_6_果糖基转移酶、果聚糖外水解酶等的发现、纯化和克隆日趋清晰。此外,果聚糖分子生物学研究也取得了一定的进展。     

Cloning and functional analysis of a high DP fructan:fructan 1-fructosyl transferase from Echinops ritro (Asteraceae): comparison of the native and recombinant enzymes

Inulin-type fructans are the simplest and most studied fructans and have become increasingly popular as prebiotic health-improving compounds. A natural variation in the degree of polymerization (DP) of inulins is observed within the family of the Asteraceae. Globe thistle (Echinops ritro), artichoke (Cynara scolymus), and Viguiera discolor biosynthesize fructans with a considerably higher DP than Cichorium intybus (chicory), Helianthus tuberosus (Jerusalem artichoke), and Dahlia variabilis. The higher DP in some species can be explained by the presence of special fructan:fructan 1-fructosyl transferases (high DP 1-FFTs), different from the classical low DP 1-FFTs. Here, the RT-PCR-based cloning of a high DP 1-FFT cDNA from Echinops ritro is described, starting from peptide sequence information derived from the purified native high DP 1-FFT enzyme. The cDNA was successfully expressed in Pichia pastoris. A comparison is made between the mass fingerprints of the native, heterodimeric enzyme and its recombinant, monomeric counterpart (mass fingerprints and kinetical analysis) showing that they have very similar properties. The recombinant enzyme is a functional 1-FFT lacking invertase and 1-SST activities, but shows a small intrinsic 1-FEH activity. The enzyme is capable of producing a high DP inulin pattern in vitro, similar to the one observed in vivo. Depending on conditions, the enzyme is able to produce fructo-oligosaccharides (FOS) as well. Therefore, the enzyme might be suitable for both FOS and high DP inulin production in bioreactors. Alternatively, introduction of the high DP 1-FFT gene in chicory, a crop widely used for inulin extraction, could lead to an increase in DP which is useful for a number of specific industrial applications. 1-FFT expression analysis correlates well with high DP fructan accumulation in vivo, suggesting that the enzyme is responsible for high DP fructan formation in planta.     

Arabidopsis AtcwINV3 and 6 are not invertases but are fructan exohydrolases (FEHs) with different substrate specificities

The genome of Arabidopsis thaliana contains six putative cell-wall type invertase genes (AtcwINV1-6). Heterologous expression of AtcwINV1, 3 and 6 cDNAs in Pichia pastoris revealed that the enzymes encoded by AtcwINV3 and 6 did not show invertase activity. Instead, AtcwINV3 is a 6-FEH and AtcwINV6 is a fructan exohydrolase (FEH) that can degrade both inulin and levan-type fructans. For AtcwINV6 it is proposed to use the term (6&1) FEH. In contrast, AtcwINV1 is a typical invertase. FEH activity was also detected in crude extracts of different parts of Arabidopsis. To verify that the FEH activity of AtcwINV3 and 6 were not artefacts of the heterologous expression system, the protein corresponding to AtcwINV3 was isolated from whole Arabidopsis plants and indeed showed only 6-FEH activity and no invertase activity. Although no fructans can be detected in Arabidopsis plants, it is shown that kestoses (trimers) can be synthesized in crude leaf extracts. The putative physiological significance of FEH in so-called non-fructan plants is discussed.     

Fructosyl transferase and hydrolase activities in rhizophores and tuberous roots upon growth of Polymnia sonchifolia (Asteraceae)

The underground reserve organs of yacon (Polymnia sonchifolia Poep. Endl.), similarly to other economically important Asteraceae, accumulate more than 60%, on a DW basis, of inulin type β(2‐1) fructans, mainly oligomers (GF2–GF16). Although sucrose:sucrose 1‐fructosyl transferase (1‐SST), fructan:fructan 1‐fructosyl transferase (1‐FFT) and fructan 1‐exohydrolase (1‐FEH) were properly described and characterized from a number of plant species, detailed information about their activities in different organs during development are rather scarce in the literature. In the present work 1‐SST, 1‐FFT and 1‐FEH activities were measured monthly in rhizophores and tuberous roots of yacon plants during their complete growth cycle under field conditions. Results showed that 1‐SST activity in rhizophores was always higher than 1‐FFT activity and increased up to 8 months of cultivation, decreasing to initial values at the end of the growth period. In the tuberous roots 1‐SST activity was also higher than 1‐FFT but varied differently. The higher values were found at the beginning of tuberization (3‐month‐old plants) and at the flowering phase (7‐month‐old plants). Results also showed that synthesizing activities in yacon plants were always higher in rhizophores than in the tuberous roots, while hydrolysing activity predominated in the latter, mainly when 1‐kestose and nystose were used as substrates. 1‐FEH from yacon plants showed low efficiency when commercial inulin from Helianthus tuberosus was utilized as substrate. The analysis of the enzymatic activities performed during growth of yacon clearly indicated the most appropriate source organ and phase of development to obtain the highest enzymatic activities for purification purposes and for the production of fructo‐oligosaccharides (FOS). Furthermore, the results suggested that the relative levels of activities of 1‐SST, 1‐FFT and 1‐FEH could be involved in the chain length distribution of the fructan molecules found in rhizophores and in tuberous roots of this species.     

Fructan:fructan 1-fructosyltransferase,a key enzyme for biosynthesis of graminan oligomers in hardened wheat

Fructans play important roles not only as a carbon source for survival under persistent snow cover but also as agents that protect against various stresses in overwintering plants. Complex fructans having both ß-(2,1)- and ß-(2,6)-linked fructosyl units accumulate in wheat (Triticum aestivum L.) during cold hardening. We detected fructan: fructan 1-fructosyltransferase (1-FFT; EC 2.4.1.100) activity for catalyzing the formation and extension of ß-(2,1)-linked fructans in hardened wheat tissues, cloned cDNAs (wft3 and wft4) of 1-FFT, and analyzed the enzymatic properties of a wft3 recombinant protein (Wft3m) produced by yeast. Wft3m transferred ß-(2,1)-linked fructosyl units to phlein, an extension of sucrose through ß-(2,6)-linked fructosyl units, as well as to inulin, an extension of sucrose through ß-(2,1)-linked fructosyl units, but could not efficiently synthesize long inulin oligomers. Incubation of a mixture of Wft3m and another recombinant protein of wheat, sucrose:fructan 6-fructosyltransferase (6-SFT), with sucrose and 1-kestotriose produced fructans similar to those that accumulated in hardened wheat tissues. The results demonstrate that 1-FFT produces branches of ß-(2,1)-linked fructosyl units to phlein and graminan oligomers synthesized by 6-SFT and contributes to accumulation of fructans containing ß-(2,1)- and ß-(2,6)-linked fructosyl units. In combination with sucrose:sucrose 1-fructosyltransferase (1-SST; EC 2.4.1.99) and 6-SFT, 1-FFT is necessary for fructan synthesis in hardened wheat.     

Effect of ethylene glycol and glycerol fructosides on the activity and product specificity of bacterial and plant fructosyltransferases

Fructosyltransferases (FTs) are key enzymes in plants and bacteria to synthesize fructans. To gain insight on the specificity of the hexose subsites in the active site of FTs, ethylene glycol fructoside (EGF) and glycerol fructoside (GF), containing fructose in the furanose configuration, were synthesized in vitro and used as substrates to study the effect on the activity of bacterial levansucrase (BsLS), chicory root sucrose:sucrose 1-fructosyltransferase (1-SST) and fructan:fructan 1-fructosyltransferase (1-FFT). The results demonstrated that EGF and GF, at physiologically relevant concentrations, were efficient acceptor substrates for BsLS and 1-FFT, but not for 1-SST. EGF and GF cannot be used as donor substrates for BsLS, 1-SST and 1-FFT. A model is proposed to explain the subsite specificity differences between the three FTs involved in this study.     

Fructan 1-exohydrolases. beta-(2,1)-trimmers during graminan biosynthesis in stems of wheat? Purification,characterization, mass mapping,and cloning of two fructan 1-exohydrolase isoforms

Graminan-type fructans are temporarily stored in wheat (Triticum aestivum) stems. Two phases can be distinguished: a phase of fructan biosynthesis (green stems) followed by a breakdown phase (stems turning yellow). So far, no plant fructan exohydrolase enzymes have been cloned from a monocotyledonous species. Here, we report on the cloning, purification, and characterization of two fructan 1-exohydrolase cDNAs (1-FEH w1 and w2) from winter wheat stems. Similar to dicot plant 1-FEHs, they are derived from a special group within the cell wall-type invertases characterized by their low isoelectric points. The corresponding isoenzymes were purified to electrophoretic homogeneity, and their mass spectra were determined by quadrupole-time-of-flight mass spectrometry. Characterization of the purified enzymes revealed that inulin-type fructans [beta-(2,1)] are much better substrates than levan-type fructans [beta-(2,6)]. Although both enzymes are highly identical (98% identity), they showed different substrate specificity toward branched wheat stem fructans. Although 1-FEH activities were found to be considerably higher during the fructan breakdown phase, it was possible to purify substantial amounts of 1-FEH w2 from young, fructan biosynthesizing wheat stems, suggesting that this isoenzyme might play a role as a beta-(2,1)-trimmer throughout the period of active graminan biosynthesis. In this way, the species and developmental stage-specific complex fructan patterns found in monocots might be determined by the relative proportions and specificities of both fructan biosynthetic and breakdown enzymes.     

Summer Meeting 2013: growth and physiology of bifidobacteria

Bifidobacteria are a minor fraction of the human colon microbiota with interesting properties for carbohydrate degradation. Monosaccharides such as glucose and fructose are degraded through the bifid shunt, a dedicated pathway involving phosphoketolase activity. Its stoechiometry learns that three moles of acetate and two moles of lactate are produced per two moles of glucose or fructose that are degraded. However, deviations from this 3 : 2 ratio occur, depending on the rate of substrate consumption. Slower growth rates favour the production of acetate and pyruvate catabolites (such as formate) at the cost of lactate. Interestingly, bifidobacteria are capable to degrade inulin‐type fructans (ITF) (oligofructose and inulin) and arabinoxylan‐oligosaccharides (AXOS). Beta‐fructofuranosidase activity enables bifidobacteria to degrade ITF. However, this property is strain‐dependent. Some strains consume both fructose and oligofructose, with different preferences and degradation rates. Small oligosaccharides (degree of polymerization or DP of 2–7) are taken up, in a sequential order, indicating intracellular degradation and as such giving these bacteria a competitive advantage towards other inulin‐type fructan degraders such as lactobacilli, bacteroides and roseburias. Other strains consume long fractions of oligofructose and inulin. Exceptionally, oligosaccharides with a DP of up to 20 (long‐chain inulin) are consumed by specific strains. Also, the degradation of AXOS by α‐arabinofuranosidase and β‐xylosidase is strain‐dependent. Particular strains consume the arabinose substituents, whether or not together with a consumption of the xylose backbones of AXOS, either up to xylotetraose or higher and either extra‐ or intracellularly. The production of high amounts of acetate that accompanies inulin‐type fructan degradation by bifidobacteria cross‐feeds other colon bacteria involved in the production of butyrate. However, bifidobacterial strain‐dependent differences in prebiotic degradation indicate the existence of niche‐specific adaptations and hence mechanisms to avoid competition among each other and to favour coexistence with other colon bacteria.     

The fructan syndrome: Evolutionary aspects and common themes among plants and microbes

Fructans are multifunctional fructose‐based water soluble carbohydrates found in all biological kingdoms but not in animals. Most research has focused on plant and microbial fructans and has received a growing interest because of their practical applications. Nevertheless, the origin of fructan production, the so‐called “fructan syndrome,” is still unknown. Why fructans only occur in a limited number of plant and microbial species remains unclear. In this review, we provide an overview of plant and microbial fructan research with a focus on fructans as an adaptation to the environment and their role in (a)biotic stress tolerance. The taxonomical and biogeographical distribution of fructans in both kingdoms is discussed and linked (where possible) to environmental factors. Overall, the fructan syndrome may be related to water scarcity and differences in physicochemical properties, for instance, water retaining characteristics, at least partially explain why different fructan types with different branching levels are found in different species. Although a close correlation between environmental stresses and fructan production is quite clear in plants, this link seems to be missing in microbes. We hypothesize that this can be at least partially explained by differential evolutionary timeframes for plants and microbes, combined with potential redundancy effects.     

Development of Bifidobacterium lactis Bb 12 on β‐(2,6)‐Linked Fructan‐Containing Substrate

β‐(2,1)‐linked fructan of plant origin (inulin) and the related oligosaccharides (FOS) as non‐digestible carbohydrates, i.e., potent prebiotics, can stimulate the growth of various probiotic lactic acid bacteria, including a number of bifidobacteria strains. The related β‐(2,6)‐linked fructans of microbial origin (levan and FOS), however, have scarcely been investigated in this respect. Therefore, the bifidogenic properties of various fructans, i.e., inulin, levan, fructooligosaccharides (FOS) and fructan syrup (FS), were tested as glucose substitutes in MRS media and were compared concerning their effect on the commercial strain Bifidobacterium lactis Bb 12. Although glucose was the preferred substrate for growth and biomass formation, FS exhibited a comparable cell growth (8.4 × 10⁷ counts/mL and 1.0 × 10⁷ counts/mL, respectively) and acidification power (84 °T and 74 °T, respectively) during 48 h of fermentation, as well as an increase in lactic acid and decrease in acetic acid formation. Bifidobacterium lactis Bb 12 did not utilize inulin as a sole carbon source as judged from the 60 % decrease in cell count and the insignificant (0.1 pH unit) acidification of the growth medium, whereas levan provided a noticeable increase in cell count and acidification (0.4 pH units) during 48 h of fermentation. FOS preparation appeared to be a satisfactory carbon source for this strain, but lower acidification power (56 °T) and cell counts were observed as compared to glucose‐ or FOS‐containing media (2.6 % and 22 %, respectively). The products obtained under conditions of mild lactic acid hydrolysis of levan (37 °C, pH 3.3, 24 h) enhanced the cell count (7–10 %) and acidification power (by a factor of 2.7) of Bifidobacterium lactis Bb 12.     

Sucrose metabolism in spring and winter wheat in response to high irradiance, cold stress and cold acclimation

Effects of low‐temperature stress, cold acclimation and growth at high irradiance in a spring (Triticum aestivum L. cv. Katepwa) and a winter wheat (Triticum aestivum L. cv. Monopol) were examined in leaves and crowns with respect to the sucrose utilisation and carbon allocation. Light‐saturated and carbon dioxide (CO₂)‐saturated rates of CO₂ assimilation were decreased by 50% in cold‐stressed spring and winter wheat cultivars. Cold‐ or high light‐acclimated Katepwa spring wheat maintained light‐saturated rates of CO₂ assimilation comparable to those of control spring wheat. In contrast, cold‐ or high light‐acclimated winter wheat maintained higher light and CO₂‐saturated rates of CO₂ assimilation than non‐acclimated controls. In leaves, during either cold stress, cold acclimation or acclimation to high irradiance, the sucrose/starch ratio increased by 5‐ to 10‐fold and neutral invertase activity increased by 2‐ to 2.5‐fold in both the spring and the winter wheat. In contrast, Monopol winter wheat, but not Katepwa spring wheat, exhibited a 3‐fold increase in leaf sucrose phosphate synthase (SPS) activity, a 4‐fold increase in sucrose:sucrose fructosyl transferase activity and a 6.6‐fold increase in acid invertase upon cold acclimation. Although leaves of cold‐stressed and high light‐grown spring and winter wheat showed 2.3‐ to 7‐fold higher sucrose levels than controls, these plants exhibited a limited capacity to adjust either sucrose phosphate synthase or sucrose synthase activity (SS[s]). In addition, the acclimation to high light resulted in a 23–31% lower starch abundance and no changes at the level of fructan accumulation in leaves of either winter or spring wheat when compared with controls. However, high light‐acclimated winter wheat exhibited a 1.8‐fold higher neutral invertase activity and high light‐acclimated spring wheat exhibited an induction of SS(d) activity when compared with controls. Crowns of Monopol showed higher fructan accumulation than Katepwa upon cold and high light acclimation. We suggest that the differential adjustment of CO₂‐saturated rates of CO₂ assimilation upon cold acclimation in Monopol winter wheat, as compared with Katepwa spring wheat, is associated with the increased capacity of Monopol for sucrose utilisation through the biosynthesis of fructans in the leaves and subsequent export to the crowns. In contrast, the differential adjustment of CO₂‐saturated rates of CO₂ assimilation upon high light acclimation of Monopol appears to be associated with both increased fructan and starch accumulation in the crowns.