Physiological Functions of Acid and Neutral Invertases in Growth and Sugar Storage in Sugar Cane

The roles of acid invertases, pH optima about 5, and neutral invenase, pH optimum 7, have been examined during growth and maturation of stalks of sugar cane (Saccharum officinarum) and hybrid cultivars. Bound acid invertases are found in the outer space which includes the cell wall. A soluble acid invertase occurs in immature, elongating internodes, and is located both in the outer space and the vacuole of storage parenchyma cells. This enzyme disappears when internode growth ceases. The outer space component appears to be the major controller for dry matter input accompanying cell extension growth. The vacuolar component appears to be concerned with regulation of both turgor pressure and internal sugar pools. The neutral invertase increases during maturation. The level of enzyme activity correlates with the level of hexoses. This enzyme appears to be part of a system controlling sugar flux in mature storage tissue.     

Genome-Wide Identification of the Invertase Gene Family in Populus

Invertase plays a crucial role in carbohydrate partitioning and plant development as it catalyses the irreversible hydrolysis of sucrose into glucose and fructose. The invertase family in plants is composed of two sub-families: acid invertases, which are targeted to the cell wall and vacuole; and neutral/alkaline invertases, which function in the cytosol. In this study, 5 cell wall invertase genes (PtCWINV1-5), 3 vacuolar invertase genes (PtVINV1-3) and 16 neutral/alkaline invertase genes (PtNINV1-16) were identified in the Populus genome and found to be distributed on 14 chromosomes. A comprehensive analysis of poplar invertase genes was performed, including structures, chromosome location, phylogeny, evolutionary pattern and expression profiles. Phylogenetic analysis indicated that the two sub-families were both divided into two clades. Segmental duplication is contributed to neutral/alkaline sub-family expansion. Furthermore, the Populus invertase genes displayed differential expression in roots, stems, leaves, leaf buds and in response to salt/cold stress and pathogen infection. In addition, the analysis of enzyme activity and sugar content revealed that invertase genes play key roles in the sucrose metabolism of various tissues and organs in poplar. This work lays the foundation for future functional analysis of the invertase genes in Populus and other woody perennials.     

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.     

Insight into the role of sugars in bud burst under light in the rose

Bud burst is a decisive process in plant architecture that requires light in Rosa sp. This light effect was correlated with stimulation of sugar transport and metabolism in favor of bud outgrowth. We investigated whether sugars could act as signaling entities in the light-mediated regulation of vacuolar invertases and bud burst. Full-length cDNAs encoding two vacuolar invertases (RhVI1 and RhVI2) were isolated from buds. Unlike RhVI2, RhVI1 was preferentially expressed in bursting buds, and was up-regulated in buds of beheaded plants exposed to light. To assess the importance of sugars in this process, the expression of RhVI1 and RhVI2 and the total vacuolar invertase activity were further characterized in buds cultured in vitro on 100 mM sucrose or mannitol under light or in darkness for 48 h. Unlike mannitol, sucrose promoted the stimulatory effect of light on both RhVI1 expression and vacuolar invertase activity. This up-regulation of RhVI1 was rapid (after 6 h incubation) and was induced by as little as 10 mM sucrose or fructose. No effect of glucose was found. Interestingly, both 30 mM palatinose (a non-metabolizable sucrose analog) and 5 mM psicose (a non-metabolizable fructose analog) promoted the light-induced expression of RhVI1 and total vacuolar invertase activity. Sucrose, fructose, palatinose and psicose all promoted bursting of in vitro cultured buds under light. These findings indicate that soluble sugars contribute to the light effect on bud burst and vacuolar invertases, and can function as signaling entities.     

Effects of Pyrocatechol on Some Metabolic Processes of Mature Sugar Beet (Beta vulgaris) Plants

Pyrocatechol (PC), 10^-2M, was applied to the foliage of mature plants of sugar beet (Beta vulgaris L.). Its effect on the activity of nitrate reductase, transaminase, invertase, phosphatases, sucrose synthetase, sucrose phosphate synthetase, and UDPG-pyrophosphorylase were determined 7, 14, and 21 days after treatment. Significant reductions in the activity of nitrate reductase, transaminase, invertase, and phosphatases (including phenyl phosphatase, glucose-1-, glucose-6-, fructose-6-phosphatase, and adenosine triphosphatase) in the treated plants occurred. On the other hand, activities of the enzymes of sucrose biosynthesis, uridine, diphosphate glucose pyrophosphorylase (UDPG-pyrophosphorylase), sucrose synthetase, and sucrose phosphate synthetase were significantly stimulated by the application of pyrocatechol. The results suggest that the growth inhibition following the application of PC to sugar beet plants may stem in part from an amino acid stress resulting from a PC-induced decrement in nitrate reductase and transaminase activity. Its application also creates an enzymatic condition favorable for sucrose biosynthesis and storage.     

Unexpected presence of fructan 6-exohydrolases (6-FEHs) in non-fructan plants: characterization, cloning, mass mapping and functional analysis of a novel "cell-wall invertase-like" specific 6-FEH from sugar beet (Beta vulgaris L.)

About 15% of flowering plant species synthesize fructans. Fructans serve mainly as reserve carbohydrates and are subject to breakdown by plant fructan exohydrolases (FEHs), among which 1-FEHs (inulinases) and 6-FEHs (levanases) can be differentiated. This paper describes the unexpected finding that 6-FEHs also occur in plants that do not synthesize fructans. The purification, characterization, cloning and functional analysis of sugar beet (Beta vulgaris L.) 6-FEH are described. Enzyme activity measurements during sugar beet development suggest a constitutive expression of the gene in sugar beet roots. Classical enzyme purification followed by in-gel trypsin digestion and mass spectrometry (quadruple-time-of-flight mass spectrometry (Q-TOF) MS) led to peptide sequence information used in subsequent RT-PCR based cloning. Levan-type fructans (beta-2,6) are the best substrates for the enzyme, while inulin-type fructans (beta-2,1) and sucrose are poorly or not degraded. Sugar beet 6-FEH is more related to cell wall invertases than to vacuolar invertases and has a low iso-electric point (pI), clearly different from typical high pI cell wall invertases. Poor sequence homology to bacterial or fungal FEHs makes an endophytic origin highly unlikely. The functionality of the 6-FEH cDNA was further demonstrated by heterologous expression in Pichia pastoris. As fructans are absent in sugar beet, the role of 6-FEH in planta is not obvious. Like chitinases and beta-glucanases hydrolysing cell-surface components of fungal plant pathogens, a straightforward working hypothesis for further research might be that plant 6-FEHs participate in hydrolysis (or prevent the formation) of levan-containing slime surrounding endophytic or phytopathogenic bacteria.     

Antisense repression of vacuolar and cell wall invertase in transgenic carrot alters early plant development and sucrose partitioning.

To unravel the functions of cell wall and vacuolar invertases in carrot, we used an antisense technique to generate transgenic carrot plants with reduced enzyme activity. Phenotypic alterations appeared at very early stages of development; indeed, the morphology of cotyledon-stage embryos was markedly changed. At the stage at which control plantlets had two to three leaves and one primary root, shoots of transgenic plantlets did not separate into individual leaves but consisted of stunted, interconnected green structures. When transgenic plantlets were grown on media containing a mixture of sucrose, glucose, and fructose rather than sucrose alone, the malformation was alleviated, and plantlets looked normal. Plantlets from hexose-containing media produced mature plants when transferred to soil. Plants expressing antisense mRNA for cell wall invertase had a bushy appearance due to the development of extra leaves, which accumulated elevated levels of sucrose and starch. Simultaneously, tap root development was markedly reduced, and the resulting smaller organs contained lower levels of carbohydrates. Compared with control plants, the dry weight leaf-to-root ratio of cell wall invertase antisense plants was shifted from 1:3 to 17:1. Plants expressing antisense mRNA for vacuolar invertase also had more leaves than did control plants, but tap roots developed normally, although they were smaller, and the leaf-to-root ratio was 1.5:1. Again, the carbohydrate content of leaves was elevated, and that of roots was reduced. Our data suggest that acid invertases play an important role in early plant development, most likely via control of sugar composition and metabolic fluxes. Later in plant development, both isoenzymes seem to have important functions in sucrose partitioning.     

Differential expression of a chlorophyll a/b binding protein gene and a proline rich protein gene in juvenile and mature phase English ivy (Hedera helix)

Two cDNA clones representing mRNAs which are differentially expressed during in vitro culture of juvenile and mature leaf petioles of English ivy ( Hedera helix L.) were isolated by differential screening. The mRNA represented by clone HW101 is expressed at a higher level in untreated juvenile than in untreated mature in-vitro-cultured petioles. Treatment of petioles with α-naphthaleneacetic acid (NAA) at the initiation of culture decreases HW101 mRNA levels in juvenile but not mature, petioles. In intact plants. HW101 mRNA is expressed at a higher level in juvenile laminae, petioles and stems than in identical tissues of mature plants. DNA sequence analysis indicates that HW1O1 cDNA is significantly similar to a light harvesting chlorophyll a/b binding protein gene ( Lhcb ) of pea. The gene represented by the second clone. HW103, is expressed at a higher level in mature than in juvenile in-vitro-cultured petisoles. Treatment of petioles with NAA at the initiation of culture decreases HW103 mRNA levels in chronologically young mature but not older mature and juvenile petioles. However, expression of the HW103 gene is not detectable in petioles, or in any other vegetative organ tested, immediately after excision. It is, however, expressed in developing seeds. In otherwise intact plants, the HW103 gene is expressed in wounded petioles of mature plants 5 days after wounding but not in wounded petioles of juvenile plants. It is also expressed at a higher level in wounded stems of mature plants than in those of juvenile plants. However, it is not expressed in wounded lamina of either juvenile or mature plants. DNA sequence analysis indicates that HW103 cDNA is similar to a cell wall proline rich protein (PRP) gene of soybean. This is the first report of differential expression of a PRP gene in tissues from juvenile and mature plants. Southern blot analysis of nuclear DNA of H. helix shows that both HW101 and HW103 are members of small gene families.     

Invertase inhibitors from red beet, sugar beet, and sweet potato roots

Invertase inhibitors have been isolated and partially purified from red beets, sugar beets, and sweet potatoes. These inhibitors are thermolabile proteins with molecular weights of 18,000 to 23,000. They do not inhibit yeast and Neurospora invertases, but they are reactive with potato tuber invertase and other plant invertases with pH optima near 4.5. There are differences in reactivity of the inhibitors with some of the plant invertases, however. For most invertases, red beet and sugar beet inhibitors are most effective at pH 4.5 while sweet potato inhibitor is most effective at pH 5.     

Sucrose uptake,invertase localization and gene expression in developing fruit of Lycopersicon esculentum and the sucrose-accumulating Lycopersicon hirsutum

By using immunolocalization and differential extraction methods we show that only apoplastic invertase, but not vacuolar invertase, was present in the mature, sucrose-accumulating L. hirsutum pericarp. In contrast, in the hexose-accumulating L. esculentum fruit, both the apoplastic and vacuolar invertase activities and protein content increase in the mature fruit. Quantitative expression studies of the soluble invertase gene (TIV1) and the apoplastic invertase genes (LINs) showed that only TIV1 gene expression could account for the species and developmental differences of both soluble and insoluble enzyme activity of the pericarp. The expression of the LIN genes encoding for apoplastic tomato invertases was unrelated to the differences in bound enzyme activity and could not account for the rise in bound invertase activity in the mature L. esculentum fruit. Evidence is presented that the bound invertase activity of tomato fruit is also the TIV1 gene product. The presence of apoplastic invertase in the mature sucrose-accumulating L. hirsutum fruit suggests a hydrolysis-resynthesis mechanism of sucrose uptake. In order to test this hypothesis, we studied short- and long-term uptakes of asymmetrically labelled ³H-fructosyl-sucrose accompanied by compartmental analysis of the sugars in attached whole fruits of L. hirsutum and L. esculentum. The results indicate that hydrolysis-resynthesis is slow in the sucrose-accumulating fruit but is not an integral part of an uptake and compartmentation mechanism.     

Developing fructan-synthesizing capability in a plant invertase via mutations in the sucrose-binding box

Fructans are fructose polymers that are synthesized from sucrose by fructosyltransferases. Fructosyltransferases are present in unrelated plant families suggesting a polyphyletic origin for their transglycosylation activity. Based on sequence comparisons and enzymatic properties, fructosyltransferases are proposed to have evolved from vacuolar invertases. Between 1% and 5% of the total activity of vacuolar invertase is transglycosylating activity. We investigated the nature of the changes that can convert a hydrolysing invertase into a transglycosylating enzyme. Remarkably, replacing 33 amino acids (amino acids 143-175) corresponding to the N-terminus of the mature onion vacuolar invertase with the corresponding region of onion fructan:fructan 6G-fructosyltransferase (6G-FFT) led to a shift in activity from hydrolysis of sucrose towards transglycosylation between two sucrose molecules. The substituted N-terminal region contains the sucrose-binding box that harbours the nucleophile involved in sucrose hydrolysis (Asp164). Subsequent research into the individual amino acids responsible for the enhanced transglycosylation activity revealed that mutations in amino acids Trp161 and Asn166, can give rise to a shift towards polymerase activity. Changing the amino acid at either of these positions in the sucrose-binding box increases the transglycosylation capacity of invertases two- to threefold compared to wild type. Combining the two mutations had an additive effect on transglycosylation ability, resulting in an approximately fourfold enhancement. The mutations generated correspond with natural variation present in the sucrose-binding boxes of vacuolar invertases and fructosyltransferases. These relatively small changes that increase the transglycosylation capacity of invertases might explain the polyphyletic origin of the fructan accumulation trait.     

Enzymes Involved in the Postharvest Degradation of Sucrose in Beta vulgaris L. Root Tissue

The reducing sugar content of sugar beet (Beta vulgaris L.) roots increased during 30 days of storage at 21 C and 160 days at 5 C as a result of an increase in acid invertase activity. Sucrose synthetase and neutral invertase activities were high at harvest but declined during storage, thus showing no relationship with postharvest reducing sugar accumulation in sugar beet roots. Acid α-glucosidase activity was detected in fresh roots but showed no activity with sucrose as a substrate.