This invention relates to a plant gene promoter and its use.
The following references are referred to in the specification and are identified in the text by their respective numbers. Mention of the reference does not necessarily indicate that it is relevant to the patentability of the invention.
The main factor responsible for the reduction of tomato crop yields under elevated temperatures is the impairment of pollen development and germination. This factor is known as high temperature stress (HTS). The flowering phases most sensitive to high temperatures are meiosis (8-9 days before anthesis) and fertilization (1-3 days after anthesis). In Brassica, pollen from plants exposed to four days of HTS (35° C.) had lower in vitro germination rates (17.5%) than pollen from control grown plants (59.2%). The lower germination rate was regardless of whether in vitro germination was carried out at 23° C. or 35° C. Similar findings indicating that the male reproductive organs are the most sensitive to heat stress were reported for other plant species as well.
Although male sterility due to HTS has been observed in numerous plants, the biochemical or developmental pathways affected remain unknown. Similarly, while much is known about the response of vegetative tissues to environmental stress, very little information is available with respect to the pollen's ability to mount a defensive response. A comparative analysis of the global pollen protein expression profile in the presence or absence of stress is one approach that can help address these shortcomings. To date, there are still very few comprehensive analyses specific to the pollen proteome and only one such analysis deals with temperature stress [1]. In this study the global protein expression profile of rice anthers was analyzed under cold stress and 70 protein spots were found to be differentially displayed. The little evidence so far seems to indicate that pollen grains not only do not induce the proteins normally found in stressed vegetative tissues, but that the detrimental effects occur mainly at the translational and post-translational level.
Carbohydrates play a critical role in pollen development, germination and fertilization, serving as nutrients for metabolic, structural, storage and perhaps signaling functions. In many plants including tomato and Brassica, the transported sugar is mainly sucrose. An unloading pathway of sucrose via the apoplastic space is mandatory for symplastically isolated cells, such as developing pollen, that receive their carbohydrate supply from the tapetum layer and the surrounding locular fluid. The transported sucrose is released from the sieve elements of the phloem into the anther wall layers and the tapetum apoplast, probably via a sucrose transporter. The released sucrose molecules may follow either or both of the following routes: 1. Enter the cytosol of the pollen sink cells and be cleaved by sucrose synthase (SuSy) into fructose and UDP-glucose (UDPG); 2. Irreversibly hydrolyzed into glucose and fructose by an extra-cellular (apoplastic) invertase—ionically bound to the cell wall. The resulting hexose monomers, glucose and fructose, are then taken up into the sink cells by hexose transporters.
Pollen germination and tube growth are also highly dependent on the availability of sugars, since the main metabolic activity during this process is the biosynthesis of polymers that will form the elongating cell wall. While the volume of the protoplast does not change significantly during pollen tube elongation since it moves forward, the cell wall forms an immobile tube which continuously expands at the apex. Given that a single pollen tube has to achieve a total length of about a centimeter in tomato and Brassica pistils within a short time, the supply of cell wall precursors needs to be uninterrupted and extremely rapid. To support this high level of carbohydrate synthesis pollen tubes use both stored reserves which can include sucrose, starch, phytic acid and lipids, depending on the species and external sources of sugar. In in vitro growing pollen tubes, the need for external carbon sources was shown to increase with time as internal stores were depleted. Efficient sugar metabolism is therefore crucial for the success of the fertilization process.
In a number of plant species, stress-induced impairment of male gametophyte development is preceded by disturbances in carbohydrate metabolism in the anther and the developing pollen [2]. In tomato, HTS causes a reduction in both starch levels of developing immature tomato pollen and soluble sugar concentration of mature pollen grains. This was accompanied by a decrease in the number of pollen grains produced, an elevated number of non-viable pollen and a decrease in the capacity of the viable pollen to germinate [3].
Both sucrose synthase (SuSy) and invertase cleave sucrose to produce the hexose sugars, glucose and fructose, that must be phosphorylated by hexose phosphorylating enzymes (hexose kinases) before they can be further metabolized. Hexose phosphorylating enzymes are characterized by their particular affinity to various sugars. Hexokinase (HXK) phosphorylates glucose and fructose, whereas fructokinase (FRK) phosphorylates only fructose. The affinity of FRKs to fructose are one to two orders of magnitude higher than that of HXKs to fructose. The phosphorylated sugars (hexose phosphates) may enter glycolysis or the pentose phosphate pathway, or be converted and stored as starch. Uridine diphosphate glucose (UDPG), produced by cleavage of sucrose by SuSy, may also be used for cell wall, cellulose or starch synthesis.
Four HXK genes and four FRK genes (LeFRK1-4) were identified in tomato plants [4,5]. All four HXK and three of the FRK genes (LeFRK1-3) are expressed at different levels in all plant tissues [4,5]. However, the fourth recently cloned fructokinase, LeFRK4, is expressed exclusively in anthers and pollen [6] (mainly in mature and germinating pollen but also in developing pollen) at levels 100 times higher than any of the other HXK and FRK genes.
Karni, L. and Aloni, B. [7] investigated changes in fructokinase (FRK) and hexokinase activities in pepper flowers during their development, and studied the possible roles of these enzymes in determining pollen germination capacity under high temperature and under CO2 enrichment, previously shown to modify sugar concentrations in pepper pollen. Their results suggested that pollen and anther FRK may play a role in the regulation of pollen germination, possibly by providing fructose-6-phosphate for glycolysis, or through conversion to UDPG to support the biosynthesis of cell wall material for pollen tube growth.
In one aspect of the invention, there is provided an isolated polynucleotide sequence comprising one of the following: (a) the LeFRK4 promoter; and (b) a functional part thereof, being a modified LeFRK4 promoter in which one or more of the nucleotide bases have been substituted or deleted, or one or more nucleotide bases have been added thereto, wherein the specific promoter activity of the modified promoter is substantially the same as that of the LeFRK4 promoter.
The term “LeFRK4 promoter” includes the sequence consisting of nucleotides 1 to 2488 (SEQ. ID. NO:1) of the sequence shown in
The term “specific promoter activity” within the context of the LeFRK4 promoter includes at least the following features:
The term “substantially the same” within the context of a modified LeFRK4 promoter means that the modified promoter has a specific promoter activity having at least one, and preferably both of its features, defined above, at a level of at least 80%, more preferably at least 85%, still more preferably at least 90%, even more preferably at least 95%, most preferably at least 98% of the activity of the unmodified, native promoter.
Also included in the invention is a vector, preferably an expression vector, comprising the promoter of the invention. Various expression vectors active in plant cells are well known to the skilled man of the art, e.g. PVX, pJLX, pBI121, pART7/27, pRT104, etc. Various heterologous nucleic acid sequences or genes may be inserted into the vector so as to be operably linked to and under control of the promoter. In a preferred embodiment, the heterologous gene encodes a protein involved in sugar metabolism such as an invertase, a sucrose synthase or a glucose transporter. In a most preferred embodiment, the heterologous gene encodes a sugar kinase, for example hexokinase, fructokinase, fucokinase or galactokinase (GalK).
The heterologous gene may also be a variable gene having a special purpose such as a reporter gene confirming the expression of the promoter. In the case of producing a male sterile plant, the foreign gene may be a gene degrading the development or germination of the pollen.
A further embodiment of the invention includes a host cell transformed by the vector of the invention. In a preferred embodiment, the host cell is a plant cell, preferably a pollen or an anther cell. A still further embodiment of the invention is a transgenic plant comprising the host cell of the invention.
The promoter of the invention may be used in various applications in plant genetics. One of the applications is described in detail below.
Other possible applications are: (1) causing male sterility by specific expression of various genes (such as RNAses, proteases, toxins or other genes) that may disrupt pollen or anther development. Male sterility is a desirable trait for the production of hybrid seeds and may save laborious sterilization methods currently used in company seeds; and (2) elimination of pollen development to prevent or reduce allergenic pollen components or allergic effects caused by pollen.
In a second aspect of the invention, there is provided a method for protecting a plant from high temperature stress (HTS), comprising transforming the plant with a polynucleotide sequence, wherein said polynucleotide sequence comprises a nucleotide sequence encoding a sugar kinase under the control of an anther and/or pollen specific promoter, thereby producing a transformed plant having improved tolerance to HTS.
In a preferred embodiment, the specific promoter comprises the LeFRK4 promoter. In another preferred embodiment, the sugar kinase is a hexokinase or a fructokinase. In a still other preferred embodiment, the plant is tomato, cucumber, peppers, zucchini, maize, cotton, flax, wheat, rice, eggplant, melon or Brassica, or any other plant susceptible to HTS.
In a third aspect of the invention, there is provided a method for causing male sterility comprising transforming the plant with a polynucleotide sequence, wherein said polynucleotide sequence comprises a nucleotide sequence capable of disrupting pollen or anther development under the control of an anther and/or pollen specific promoter, thereby causing male sterility. In a preferred embodiment, the specific promoter comprises the LeFRK4 promoter.
In order to understand the invention and to see how it may be carried out in practice, a preferred embodiment will now be described, by way of non-limiting example only, with reference to the accompanying drawings, in which:
CaMV-Cauliflower mosaic virus
FRK-Fructokinase
Fru6p-Fructose 6-phosphate
Glc6P-Glucose 6-phosphate
HXK-Hexokinase
LeHXK1,2,3,4-L. esculentum hexokinase 1, 2, 3 and 4
LeFRK1,2,3,4-L. esculentum fructokinase 1, 2, 3 and 4
PCR-Polymerase Chain Reaction
SuSy-Sucrose Synthase
UDP-glucose-Uridyl diphosphate glucose
½×MSO: 2.3 gr/lit Murashige and Skoog (MS) salts
Do: 4.3 gr/lit MS salts
D1: 4.3 gr/lit MS salts
MSR: 4.3 gr/lit MS salts
LB: 10 gr/lit tryptone
The effect of HTS on both pollen development and germination is demonstrated in
To investigate the importance of hexose phosphorylation in determining pollen competence to germinate, pollen germination was analyzed for tomato plants over-expressing the Arabidopsis hexokinase gene (AtHXK1) under the control of the CaMV 35S promoter (35S::AtHXK1) [8]. Although previous reports claimed that this promoter had only negligible expression in tomato pollen, it was found that the 35S::AtHXK1 construct is expressed in pollen, in accordance with published results for tomato and other plant species [Duck N B, Folk W R (1994) Hsp70 heat shock protein cognate is expressed and stored in developing tomato pollen. Plant Mol Biol 26: 1031-1039], as well as in empty tomato anthers and in pollen germinating at either 23° C. or 32° C. (
Recently, a fructokinase gene, LeFRK4, was cloned which is exclusively expressed in stamens [6]. The expression of LeFRK4 was analyzed in developing and germinating pollen relative to the other three FRK genes (LeFRK1, 2 & 3), the four known HXK genes (LeHXK1-4), the 5 invertase genes (TIV1, LIN5-8) and the two SuSy genes (SuSy1-2). It was found that LeFRK4 is by far the most abundantly expressed gene in both mature and germinating tomato pollen (
The preferred promoter region of LeFRK4 (SEQ. ID. NO: 2) was isolated and joined to AtHXK1 and to LeFRK1 to obtain PLeFRK4::AtHXK1 and PLeFRK4::LeFRK1 constructs. To address the question of which of the two AtHXK1 activities, glucose or fructose phosphorylation, contributes to HTS resistance, HTS resistance of plants expressing AtHXK1 or LeFRK1 under the control of the LeFRK4 promoter should be compared. To reduce the possibility of cosuppression, LeFRK1 should be used, whose normal expression in anther and pollen is relative low. LeFRK1 should be preferred over LeFRK2 and LeFRK3 since LeFRK1, unlike the latter enzymes (but like LeFRK4), is not repressed by fructose and perhaps could further enhance fructose phosphorylation.
The PLeFRK4::AtHXK1 and PLeFRK4::LeFRK1 constructs have been used to generate about thirty transgenic tomato plants per construct. Initial analysis of To plants expressing PLeFRK4::AtHXK1 has shown that independent transgenic plants exhibit high pollen viability upon germination at high temperature (
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IL2007/000407 | 3/29/2007 | WO | 00 | 4/24/2009 |
Number | Date | Country | |
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60790777 | Apr 2006 | US |