桃PpMADS1基因启动子的克隆及功能分析

PpMADS1基因属于一类MADS box 基因,在植物的花发育调控中起着重要的作用。通过Genome Walking的方法从桃基因组中分离了长度为1 814bp的PpMADS1基因启动子片段,序列分析表明,在此启动子上不仅含有TATA box 和CAAT box基本元件,而且含有大量的与光调节有关的调控元件,如GT-1,Sp1和as-2-box,另外存在两个CArG-box元件、一个G-box元件和一个TGA-element,说明该启动子可能受光周期和激素的调控。将该启动子通过5′端缺失,分区段与GUS报告基因连接构建表达载体,并转化拟南芥。GUS组织化学染色分析结果表明,在-197到-454bp有促使GUS在花原基中表达的花原基特异性元件,在-454到-678bp之间存在促使GUS在萼片和花瓣表达的特异性元件,在-678到-978bp存在负调控作用元件,阻遏了GUS基因在花药中的表达。     

Spatial distribution of the RABBIT EARS protein and effects of its ectopic expression in Arabidopsis thaliana flowers

In many flowering plants, flowers consist of two peripheral organs, sepals and petals, occurring in outer two whorls, and two inner reproductive organs, stamens and carpels. These organs are arranged in a concentric pattern in a floral meristem, and the organ identity is established by the combined action of floral homeotic genes expressed along the whorls. Floral organ primordia arise at fixed positions in the floral meristem within each whorl. The RABBIT EARS (RBE) gene is transcribed in the petal precursor cells and primordia, and regulates petal initiation and early growth in Arabidopsis thaliana. We investigated the spatial and temporal expression pattern of a RBE protein fused to the green fluorescent protein (GFP). Expression of the GFP:RBE fusion gene under the RBE cis-regulatory genomic fragment rescues the rbe petal defects, indicating that the fusion protein is functional. The GFP signal is located to the cells where RBE is transcribed, suggesting that RBE function is cell-autonomous. Ectopic expression of GFP:RBE under the APETALA1 promoter causes the homeotic conversion of floral organs, resulting in sterile flowers. In these plants, the class B homeotic genes APETALA3 and PISTILLATA are down-regulated, suggesting that the restriction of the RBE expression to the petal precursor cells is crucial for flower development.     

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.     

Separation of AG function in floral meristem determinacy from that in reproductive organ identity by expressing antisense AG RNA

The Arabidopsis floral homeotic gene AGAMOUS (AG) is a regulator of early flower development. The ag mutant phenotypes suggest that AG has two functions in flower development: (1) specifying the identity of stamens and carpels, and (2) controlling floral meristem determinacy. To dissect these two AG functions, we have generated transgenic Arabidopsis plants carrying an antisense AG construct. We found that all of the transgenic plants produced abnormal flowers, which can be classified into three types. Type I transgenic flowers are phenocopies of the ag-1 mutant flowers, with both floral meristem indeterminacy and floral organ conversion; type II flowers are indeterminate and have partial conversion of the reproductive organs; and type III flowers have normal stamens and carpels, but still have an indeterminate floral meristem inside the fourth whorl of fused carpels. The existence of type III flowers indicates that AG function can be perturbed to affect only floral meristem determinacy, but not floral organ identity. Furthermore, the fact that floral meristem determinacy is affected in all transformants, but floral organ identity only in a subset of them, suggests that the former may required a higher level of AG activity than the latter. This hypothesis is supported by the levels of AG'mRNA detected in different transformants with different frequencies of distinct types of abnormal antisense AG transgenic flowers. Finally, since AG inhibits the expression of another floral regulatory gene AP1, we examined AP1 expression in antisense AG flowers, and found that AP1 is expressed at a relatively high level in the center of type II flowers, but very little or below detectable levels in the inner whorls of type III flowers. These results provide further insights into the interaction of AG and AP1 and how such an interaction may control both organ identity and floral meristem determinacy.     

Isolation of the tomato AGAMOUS gene TAG1 and analysis of its homeotic role in transgenic plants.

To understand the details of the homeotic systems that govern flower development in tomato and to establish the ground rules for the judicious manipulation of this floral system, we have isolated the tomato AGAMOUS gene, designated TAG1, and examined its developmental role in antisense and sense transgenic plants. The AGAMOUS gene of Arabidopsis is necessary for the proper development of stamens and carpels and the prevention of indeterminate growth of the floral meristem. Early in flower development, TAG1 RNA accumulates uniformly in the cells fated to differentiate into stamens and carpels and later becomes restricted to specific cell types within these organs. Transgenic plants that express TAG1 antisense RNA display homeotic conversion of third whorl stamens into petaloid organs and the replacement of fourth whorl carpels with pseudocarpels bearing indeterminate floral meristems with nested perianth flowers. A complementary phenotype was observed in transgenic plants expressing the TAG1 sense RNA in that first whorl sepals were converted into mature pericarpic leaves and sterile stamens replaced the second whorl petals.     

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.     

A Role for Arabidopsis PUCHI in Floral Meristem Identity and Bract Suppression

At the onset of flowering, the Arabidopsis thaliana primary inflorescence meristem starts to produce flower meristems on its flank. Determination of floral fate is associated with changes in the growth pattern and expression of meristem identity genes and suppression of a subtending leaf called a bract. Here, we show a role in floral fate determination and bract suppression for the PUCHI gene, an AP2/EREBP family gene that has previously been reported to play roles in lateral root morphogenesis. Mutations in PUCHI cause partial conversion of flowers to inflorescences, indicating that PUCHI is required for flower meristem identity. PUCHI is transiently expressed in the early flower meristem and accelerates meristem bulging while it prevents the growth of the bract primordium. The function of PUCHI in floral fate determination and bract suppression overlaps that of the BLADE-ON-PETIOLE1 (BOP1) and BOP2 genes, which encode a pair of redundant regulatory proteins involved in various developmental processes, including leaf morphogenesis and flower patterning. We also show that PUCHI acts together with BOP1 and BOP2 to promote expression of LEAFY and APETALA1, two central regulators of floral meristem identity. Expression patterns of the PUCHI and BOP genes point to a role in spatial control of flower-specific activation of these meristem identity genes.     

Eucalypt MADS-Box Genes Expressed in Developing Flowers

Three MADS-box genes were identified from a cDNA library derived from young flowers of Eucalyptus grandis W. Hill ex Maiden. The three egm genes are single-copy genes and are expressed almost exclusively in flowers. The egm1 and egm3 genes shared strongest homology with other plant MADS-box genes, which mediate between the floral meristem and the organ-identity genes. The egm3 gene was also expressed strongly in the receptacle or floral tube, which surrounds the carpels in the eucalypt flower and bears the sepals, petals, and numerous stamens. There appeared to be a group of genes in eucalypts with strong homology with the 3′ region of the egm1 gene. The egm2 gene was expressed in eucalypt petals and stamens and was most homologous to MADS-box genes, which belong to the globosa group of genes, which regulate organogenesis of the second and third floral whorls. The possible role of these three genes in eucalypt floral development is discussed.     

Eucalyptus has a functional equivalent of the Arabidopsis floral meristem identity gene LEAFY

Two genes cloned from Eucalyptus globulus, Eucalyptus LeaFy (ELF1 and ELF2), have sequence homology to the floral meristem identity genes LEAFY from Arabidopsis and FLORICAULA from Antirrhinum. ELF1 is expressed in the developing eucalypt floral organs in a pattern similar to LEAFY while ELF2 appears to be a pseudo gene. ELF1 is expressed strongly in the early floral primordium and then successively in the primordia of sepals, petals, stamens and carpels. It is also expressed in the leaf primordia and young leaves and adult and juvenile trees.The ELF1 promoter coupled to a GUS reporter gene directs expression in transgenic Arabidopsis in a temporal and tissue-specific pattern similar to an equivalent Arabidopsis LEAFY promoter construct. Strong expression is seen in young flower buds and then later in sepals and petals. No expression was seen in rosette leaves or roots of flowering plants or in any non-flowering plants grown under long days. Furthermore, ectopic expression of the ELF1 gene in transgenic Arabidopsis causes the premature conversion of shoots into flowers, as does an equivalent 35S-LFY construct. These data suggest that ELF1 plays a similar role to LFY in flower development and that the basic mechanisms involved in flower initiation and development in Eucalyptus are similar to those in Arabidopsis.     

Pollination of <Emphasis Type="Italic">Machaerium opacum</Emphasis> (Fabaceae) by nocturnal and diurnal bees

With plants whose flowers open at night and stay open during the day, nocturnal pollinators may exploit floral resources before diurnal competitors. Moths, bats, and beetles are the most familiar nocturnal pollinators, whereas nocturnal bees as pollinators remain poorly understood. The common Cerrado tree Machaerium opacum (Fabaceae) has white and strongly scented melittophilous flowers, which first open at the night and remain open during the day and, thus, have the potential to be visited by both nocturnal and diurnal bees. We asked: (1) what is the plant’s breeding system? (2) when during the night do the flowers open? (3) what are the visual and olfactory floral cues? and (4) which nocturnal/diurnal bees visit and pollinate the flowers? We show that M. opacum is self-incompatible. Its flowers open synchronously at 03:30 h, produce nectar exclusively at night, and have an explosive mechanism of pollen presentation. The flowers have pure white petals, release strong scents during anthesis, and are pollinated by nocturnal and diurnal bees. We recorded four nocturnal and 17 diurnal species as flower visitors, with females of nocturnal species of Ptiloglossa (Colletidae) being the most abundant. After an initial pollen-releasing visit, only a minor amount of pollen remains in a flower. Several floral traits favor visits by nocturnal bees: (1) night-time flower opening, (2) nectar production at night, (3) almost complete pollen release during the first flower visit, and (4) pure white petals and strong odor production prior to sunrise, facilitating visual and olfactory detection of flowers when light is dim.     

Characterization of promoter activity of the ethylene receptor gene OgERS1 from Oncidesa in transgenic Arabidopsis

Physiological changes associated with senescence of flowers and abscission of floral parts in Oncidesa (formerly Oncidium) cv. Gower Ramsey are caused by a plant hormone ethylene which is produced by pollinia cap dislodgment during postharvest handling and transportation. The ethylene receptor gene OgERS1 of Oncidesa has been previously cloned and characterized. To analyze promoter activity of OgERS1, transgenic Arabidopsis thaliana plants were generated to express the ß-glucuronidase (GUS) reporter gene under the control of 5’-upstream sequence of OgERS1 from Oncidesa. The expression pattern of the OgERS1 promoter at the cellular level was investigated by analysis of GUS activity. This promoter can activate gene expression in both actively dividing young tissues and abscission-related aging tissues. Expression of GUS was detected in the shoot meristem uniquely in 10 to 30 d-old-plants and was found in flower buds, axillary buds, flower stems, and abscission layers during later development. In 2- to 3-week-old transgenic Arabidopsis, exogenous ethylene, glucose, lactose, and maltose enhanced promoter activity implying that crosstalk between sugar and an ethylene receptor may exist. However, indole-3-acetic acid, benzylaminopurine, abscisic acid, heat, wounding, salinity, drought, and flooding slightly suppressed promoter activity. These results demonstrate that the promoter of OgERS1 was developmentally and environmentally regulated, and imply a potential for application of this bi-functional promoter to increase branching or enhanced dwarfing.     

Ectopic expression of an orchid (Oncidium Gower Ramsey) AGL6-like gene promotes flowering by activating flowering time genes in Arabidopsis thaliana

An AP1/AGL9 group of MADS box gene, OMADS1, with extensive homology to the Arabidopsis AGAMOUS-like 6 gene (AGL6) was characterized from orchid (Oncidium Gower Ramsey). OMADS1 mRNA was detected in apical meristem and in the lip and carpel of flower. Yeast two-hybrid analysis indicated that OMADS1 is able to strongly interact with OMADS3, a TM6-like protein that was involved in flower formation and floral initiation in orchid. Transgenic Arabidopsis and tobacco ectopically expressed OMADS1 showed similar novel phenotypes by significantly reducing plant size, flowering extremely early, and losing inflorescence indeterminacy. In addition, homeotic conversion of sepals into carpel-like structures and petals into staminoid structures were also observed in flowers of 35S::OMADS1 Arabidopsis. This result indicated that OMADS1 was involved in floral formation and initiation in transgenic plants. Further analysis indicated that the expression of flowering time genes FT, SUPPRESSOR OF OVEREXPRESSION OF CO 1 (SOC1) and flower meristem identity genes LEAFY (LFY), APETALA1 (AP1) was significantly up-regulated in 35S::OMADS1 transgenic Arabidopsis plants. Furthermore, ectopic expression of OMADS1 rescued late-flowering phenotype in gi-1, co-3 but not for ft-1 and fwa-1 mutants. These results supported that ectopic expression of OMADS1 influenced flower transition and formation by acting as an activator for FT and SOC1 in Arabidopsis.     

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.     

Auxin quantification based on histochemical staining of GUS under the control of auxin-responsive promoter

To visualize phytohormone localization in plant tissues, transgenic plants comprising the GUS reporter gene are often used. However, until now only qualitative assessment of the hormone presence was available. In this work, we suggested the method for IAA quantification in transgenic DR5::GUS Arabidopsis thaliana L. plants by the analysis of digital images. An empirical quadratic dependence was established between the IAA concentration in medium and the level of GUS-dependent staining. Using this method, we demonstrated that, after A. thaliana root gravistimulation for 90 min, auxin lateral redistribution occurred. It resulted in the increase in the IAA concentration in the lower root part (in the elongation zone and apical meristem) by 200% on the average.