Induction of Expression of Genes Coding for Sporamin and beta-Amylase by Polygalacturonic Acid in Leaf-Petiole Cuttings of Sweet Potato

Sporamin and β-amylase are two major proteins of tuberous storage root of sweet potato (Ipomoea batatas) and their accumulation can be induced concomitantly with the accumulation of starch in leaves and petioles by sucrose (K Nakamura, M Ohto, N Yoshida, K Nakamura [1991] Plant Physiol 96: 902-909). Although mechanical wounding of leaves of sweet potato only occasionally induced the expression of sporamin and β-amylase genes, their expression could be reproducibly induced in leaf-petiole cuttings when these explants were dipped in a solution of polygalacturonic acid or chitosan at their cut edges. Polygalacturonic acid seemed to induce expression of the same genes coding for sporamin and β-amylase that are induced by sucrose. Because polygalacturonic acid and chitosan are known to mediate the induction of wound-inducible defense reactions, these results raise an interesting possibility that β-amylase, in addition to sporamin, may have some role in the defense reaction. Expression of sporamin and β-amylase genes could also be induced by abscisic acid, and this induction by abscisic acid, as well as induction by polygalacturonic acid or sucrose, was repressed by gibberellic acid. By contrast, methyl jasmonate did not cause the significant induction of either sporamin or β-amylase mRNAs. Induction of expression of sporamin and β-amylase genes by polygalacturonic acid or sucrose was inhibited by cycloheximide, suggesting that de novo synthesis of proteins is required for both of the induction processes.     

Involvement of Ca2+ signalling in the sugar-inducible expression of genes coding for sporamin and β-amylase of sweet potato

Genes coding for sporamin and β-amylase of sweet potato are inducible not only by high levels of metabolizable sugars, such as sucrose, but also by a low concentration of polygalacturonic acid (PGA). Calmodulin inhibitors and EGTA inhibited both the PGA-inducible and the sucrose-inducible accumulation of mRNAs for sporamin and β-amylase in sweet potato. Calmodulin inhibitors, EGTA and La³⁺, also inhibited the sucrose-inducible expression, in leaves of transgenic tobacco, of a fusion gene, β-Amy:GUS, which consists of the promoter of the β-amylase gene and the coding sequence for β-glucuronidase. The sucrose-inducible expression of the β-Amy:GUS fusion gene was also inhibited by two inhibitors of Ca²⁺ channels, diltiazem and nicardipine. These results suggest that the sugar-inducible expression of genes for sporamin and β-amylase involves, at least in part, Ca²⁺-mediated signalling, and that the cytosolic free Ca²⁺ may mediate cross-talk between signals related to carbohydrate metabolism and other stimuli. Treatment of coelenterazine-loaded leaf discs of tobacco expressing a Ca²⁺-binding photoprotein, aequorin, with 0.2 M sucrose for 24 h significantly reduced the level of luminescence that could be induced by cold shock, as compared to cold shock-induced luminescence in coelenterazine-loaded leaf discs treated with water. Repression of cold shock-induced luminescence was due to the conversion of holoaequorin to apoaequorin during the treatment with sucrose. Treatment of coelenterazine-loaded leaf discs with a 0.2 M solution of glucose or fructose, but not of mannitol or sorbitol, also reduced the cold shock-induced luminescence. It is suggested that non-synchronous increases in cytosolic level of free Ca²⁺ occur in leaf discs during treatment with high levels of metabolizable sugars.     

Natural variation reveals relationships between pre-stress carbohydrate nutritional status and subsequent responses to xenobiotic and oxidative stress in Arabidopsis thaliana

Background

Soluble sugars are involved in responses to stress, and act as signalling molecules that activate specific or hormone cross-talk transduction pathways. Thus, exogenous sucrose treatment efficiently induces tolerance to the herbicide atrazine in Arabidopsis thaliana plantlets, at least partially through large-scale modifications of expression of stress-related genes.

Methods

Availability of sugars in planta for stress responses is likely to depend on complex dynamics of soluble sugar accumulation, sucrose–starch partition and organ allocation. The question of potential relationships between endogenous sugar levels and stress responses to atrazine treatment was investigated through analysis of natural genetic accessions of A. thaliana. Parallel quantitative and statistical analysis of biochemical parameters and of stress-sensitive physiological traits was carried out on a set of 11 accessions.

Key Results

Important natural variation was found between accessions of A. thaliana in pre-stress shoot endogenous sugar levels and responses of plantlets to subsequent atrazine stress. Moreover, consistent trends and statistically significant correlations were detected between specific endogenous sugar parameters, such as the pre-stress end of day sucrose level in shoots, and physiological markers of atrazine tolerance.

Conclusions

These significant relationships between endogenous carbohydrate metabolism and stress response therefore point to an important integration of carbon nutritional status and induction of stress tolerance in plants. The specific correlation between pre-stress sucrose level and greater atrazine tolerance may reflect adaptive mechanisms that link sucrose accumulation, photosynthesis-related stress and sucrose induction of stress defences.Key words: Arabidopsis thaliana, natural variation, atrazine sensitivity, carbon nutrition, endogenous soluble sugars, oxidative stress, sucrose, xenobiotic stress     

The CsSUT1 promoter from Citrus sinensis confers sink-specific expression of a downstream reporter gene in transgenic Arabidopsis

Membrane-localized H⁺-symporting sucrose transporters (SUC or SUT proteins) are involved in sucrose loading into the phloem of source tissues and sucrose uptake into sink tissues, which are essential events in the growth and development of higher plants. While many of these sucrose transporters are localized in the phloem, others function in sink tissues. In an attempt to gain insight into which class the CsSUT1 gene from Citrus sinensis falls, we isolated a 1537-bp upstream region of this gene (CsSUT1p), inserted it upstream of the ??-glucuronidase (GUS) reporter gene and transformed the resulting vector into Arabidopsis thaliana. Histochemical and semi-quantitative RT-PCR analyses indicated that the CsSUT1p conferred GUS expression in floral tissues and the roots of young seedlings, but not above ground vegetative tissues. In flowers, GUS expression was noted in young floral buds, as well as immature stamens and carpels. Deletion analyses indicated that a ?1052 to ?1 fragment (relative to the translational start codon at +1) of the CsSUT1p, but not a ?496 to ?1 fragment, was able to drive the same pattern of expression of a downstream reporter gene in transgenic Arabidopsis. Taken together, these results suggest that the CsSUT1 gene, like numerous SUC/SUT genes from other plant species, may play a role in the uptake of sucrose into sink tissues.     

Molecular characterization of the PpMADS1 gene from peach

PpMADS1, a member of the euAP1 clade of the class A genes, was previously cloned from peach. In this study, PpMADS1 was constitutively expressed in Arabidopsis thaliana to study its function in plant development. The transgenic A. thaliana plants containing 35S::PpMADS1 showed severe phenotype variation including early flowering, conversion of inflorescence branches to solitary flowers, formation of terminal flowers, production of higher number of carpels, petals, and stamens than non-transgenic plants, and prevention of pod shatter. Significantly, the transgenic plants produced more than one silique from a single flower. The results obtained by using cDNA microarray and real-time PCR analyses in the transgenic Arabidopsis indicated that PpMADS1 might play dual roles in regulating the floral meristem development by activating or repressing different sets of genes that would determine the different fate of a floral meristem. In addition, the PpMADS1 gene promoter was further cloned, and deletion analyses were conducted by using fused GUS as a reporter gene in transgenic A. thaliana. Histochemical staining of different organs from transgenic plants revealed the region between ?197 and ?454?bp was specific for GUS expression in flower primordium, and the region between ?454 and ?678?bp was specific for GUS expression in sepals and petals. In contrast, a negative regulatory element present between ?678 and ?978?bp could suppress GUS expression in filament.     

A Novel <Emphasis Type="Italic">PhLRR</Emphasis> Gene Promoter is Sufficient for Engineering Male Sterility in Petunia

Tissue-specific promoters can drive genes specifically expressed in the target organs and have been widely used in plant molecular breeding. In this study, a 1.2-kb promoter region of an anther-specific gene PhLRR from Petunia hybrida “Fantasy” was isolated and fused to the β-glucuronidase (GUS) gene. The pPhLRR::GUS vector was heterogeneously transformed into tobacco in which the GUS staining was only detected in the early development stage of anthers and no GUS expression in any other three floral whirls or vegetative organs was observed. It is very different from other well-studied anther-specific promoters which drive genes specifically expressed in the later development stage of anthers or only in the pollens. Furthermore, the pPhLRR::Barnase was introduced into petunia and induced complete male sterility without influencing the ornamental characteristics or the female fertility in transformed plants. These results indicate that PhLRR promoter is a new kind of petunia anther-specific promoter and could be taken as a valuable tool in ornamental plant breeding.     

Organ-specificity and inducibility of patatin class I promoter from potato in transgenic arabidopsis plants

Patatin class I promoter (B33 promoter) is a tissue-specific potato (Solanum tuberosum L.) promoter expressing the patatin gene mainly in tubers. However, it can be induced in other organs by sucrose or light. We compared the activity of this promoter fused with the reporter gene during heterological expression in B33::GUS transgenic arabidopsis (Arabidopsis thaliana L.) plants and homological expression of the same DNA construct in potato. Promoter activity was estimated from quantification of β-glucuronidase (GUS) activity. It was shown that, during heterological expression in arabidopsis seedlings, B33 promoter manifested a tissue-specificity and inducibility, although in a different manner than during homological expression in potato. In noninduced arabidopsis seedlings, B33 promoter was most active in the roots, whereas, after induction with sucrose treatment, it became most active in cotyledons. 10 mM sucrose was sufficient for a manifold activation of B33 promoter in intact seedlings. The degree of B33 promoter induction by sucrose in arabidopsis seedlings was strictly organ-specific and increased in the following sequence: root < hypocotyl < cotyledons. 150–200 mM sucrose enhanced B33 promoter activity in cotyledons by 200 to 300 times, i.e., much stronger than in potato organs. Glucose and fructose were less efficient than sucrose. Phytohormones affecting tuber formation in potato (gibberellins, auxins, and cytokinins) did not affect significantly B33 promoter activity in arabidopsis. A lag period of approximately 6 h preceded sucrose-induced B33 promoter activation. This indicates that the patatin promoter is not the primary target for the sucrose signal. The quantitative examination of heterological expression of patatin class I promoter further clarifies its basic functional characteristics and permits a better prognosis of its behavior after transferring into other plant species.     

Characterization of the GLP13 gene promoter in Arabidopsis thaliana

In transgenic plants, for many applications it is important that the inserted genes are expressed in a tissue-specific manner. This in turn could help better understanding their roles in plant development. Germin-like proteins (GLPs) play diverse roles in plant development and defense responses. In order to understand the functions and regulation of the GLP13 gene, its promoter (762 bp) was cloned and fused with a β-glucuronidase (GUS) reporter gene for transient expression in Arabidopsis thaliana and tobacco (Nicotiana tabacum cv. K326). Histochemical analysis of the transgenic plants showed that GUS was specifically expressed in vascular bundles predominantly in phloem tissue of all organs in Arabidopsis. Further analyses in transgenic tobacco also identified similar GUS expression in the vascular bundles.     

Sucrose-Induced Accumulation of beta-Amylase Occurs Concomitant with the Accumulation of Starch and Sporamin in Leaf-Petiole Cuttings of Sweet Potato

β-Amylase of sweet potato (Ipomoea batatas L.), which constitutes about 5% of the total soluble protein of the tuberous root, is absent or is present in only small amounts in organs other than the tuberous roots of the normal, field-grown plants. However, when leaf-petiole cuttings from such plants were supplied with a solution that contained sucrose, the accumulation of β-amylase was induced in both leaf and petiole portions of the explants. The sucrose-induced accumulation of β-amylase in leaf-petiole cuttings occurred concomitant with the accumulation of starch and of sporamin, the most abundant storage protein of the tuberous root. The accumulation of β-amylase, of sporamin and of starch in the petioles showed similar dependence on the concentration of sucrose, and a 6% solution of sucrose gave the highest levels of induction when assayed after 7 days of treatment. The induction of mRNAs for β-amylase and sporamin in the petiole could be detected after 6 hours of treatment with sucrose, and the accumulation of β-amylase and sporamin polypeptides, as well as that of starch, continued for a further 3 weeks. In addition to sucrose, glucose or fructose, but not mannitol or sorbitol, also induced the accumulation of β-amylase and sporamin, suggesting that metabolic effects of sucrose are important in the mechanism of this induction. Treatment of leaf-petiole cuttings with water under continuous light, but not in darkness, also caused the accumulation of small amounts of these components in the petioles, probably as a result of the endogenous supply of sucrose by photosynthesis. These results suggest that the expression of the gene for β-amylase is under metabolic control which is coupled with the expression of sink function of cells in the sweet potato.     

Isolation and Characterization of OsGSTL1 Promoter from Rice

OsGSTL1 gene was isolated from the rice genomic library. Semi-quantitative RT-PCR analysis demonstrated that the expression of the OsGSTL1 in rice was not induced by chlorsulfuron, ethylene, abscisic acid, salicylic acid, and methyl jasmonate. In order to investigate the cis-elements of OsGSTL1 promoter, the promoter regions with different lengths were fused to the β-glucuronidase (GUS) reporter gene. All constructs were transformed into onion epidermal cells or A. thaliana plants to detect the expression patterns. In onion epidermal cells, the 160 bp fragment and longer ones were functional for directing GUS expression. In transgenic A. thaliana, the 2?155 bp upstream region of OsGSTL1 gene directed the GUS expression only in cotyledon after germination, but not in the root of young seedlings. In the later seedling, the 2?155 bp upstream region of OsGSTL1 gene directed GUS expression in roots, stems, and leaves. However, the GUS gene directed by a 1?224 bp upstream fragment is expressed in all the checked tissues. These results suggest that the spatiotemporal expression response elements of OsGSTL1 existed in the 5′-upstream region between −2?155 and −1?224 bp.     

Efficient Agrobacterium-mediated genetic transformation method using hypocotyl explants of radish (Raphanus sativus L.)

To investigate the gene function of radish (Raphanus sativus L.), several attempts have been made to generate genetically transformed radish. However, no efficient and relatively simple method for the genetic transformation of radish has been developed to date. In this study, we established an Agrobacterium-mediated genetic transformation method using the hypocotyl-derived explants of radish cultivar “Pirabikku”. Primarily based on the Brassica transformation procedure, we optimized it for radish transformation. Using this system, the transformation efficiency of radish hypocotyl explants by Agrobacterium tumefaciens strain GV3101 harboring pIG121-Hm was 13.3%. The copy number of transfer DNA integrated into the genome was either one or two in the four independent transgenic plants. Two of the four plants exhibited male sterility and did not produce self-pollinated seeds. Examination of the expression of the β-glucuronidase (GUS) gene in T₁ plants from fertile T₀ plants showed that the GUS genes were inherited. The improvement in the genetic transformation in this study might pave the way for accelerated molecular breeding and genetic analysis of radish.     

The chalcone synthase multigene family of Petunia hybrida (V30): differential,light-regulated expression during flower development and UV light induction

We have analysed the expression of the 8–10 members of the gene family encoding the flavonoid biosynthetic enzyme chalcone synthase (CHS) from Petunia hybrida. During normal plant development only two members of the gene family (CHS-A and CHS-J) are expressed. Their expression is restricted to floral tissues mainly. About 90% of the total CHS mRNA pool is transcribed from CHS-A, wheares CHS-J delivers about 10% in flower corolla, tube and anthers. Expression of CHS-A and CHS-J during flower development is coordinated and (red) light-dependent. In young seedlings and cell suspension cultures expression of CHS-A and CHS-J can be induced with UV light. In addition to CHS-A and CHS-J, expression of another two CHS genes (CHS-B and CHS-G) is induced in young seedlings by UV light, albeit at a low level. In contrast to CHS genes from Leguminoseae, Petunia CHS genes are not inducible by phytopathogen-derived elicitors. Expression of CHS-A and CHS-J is reduced to a similar extent in a regulatory CHS mutant, Petunia hybrida Red Star, suggesting that both genes are regulated by the same trans-acting factors. Comparison of the promoter sequences of CHS-A and CHS-J reveals some striking homologies, which might represent cis-acting regulatory sequences.     

A Cascade of Sequentially Expressed Sucrose Transporters in the Seed Coat and Endosperm Provides Nutrition for the Arabidopsis Embryo

Developing plant embryos depend on nutrition from maternal tissues via the seed coat and endosperm, but the mechanisms that supply nutrients to plant embryos have remained elusive. Sucrose, the major transport form of carbohydrate in plants, is delivered via the phloem to the maternal seed coat and then secreted from the seed coat to feed the embryo. Here, we show that seed filling in Arabidopsis thaliana requires the three sucrose transporters SWEET11, 12, and 15. SWEET11, 12, and 15 exhibit specific spatiotemporal expression patterns in developing seeds, but only a sweet11;12;15 triple mutant showed severe seed defects, which include retarded embryo development, reduced seed weight, and reduced starch and lipid content, causing a “wrinkled” seed phenotype. In sweet11;12;15 triple mutants, starch accumulated in the seed coat but not the embryo, implicating SWEET-mediated sucrose efflux in the transfer of sugars from seed coat to embryo. This cascade of sequentially expressed SWEETs provides the feeding pathway for the plant embryo, an important feature for yield potential.