This application is a continuation-in-part of U.S. application Ser. No. 11/119,683, filed May 2, 2005, which is a continuation of U.S. application Ser. No. 09/834,998, filed Apr. 13, 2001, which is a continuation of U.S. application Ser. No. 09/644,039, filed Aug. 22, 2000, which claims the benefit of U.S. Provisional Application No. 60/164,808, filed Nov. 10, 1999.
The entire teachings of the above applications are incorporated herein by reference.
The invention was supported, in whole or in part, by grants GM52414, DK54214, DK43495, DK51509, DK34854 and GM35010 from the National Institutes of Health, by grant MCB9317175 from the National Science Foundation, by grants from the National Research Initiative, U.S. Department of Agriculture, Cooperative State Research, Education, and Extension Service no. 2006-35304-17339, and by grants from Storrs Agricultural Experimental Station Hatch. The Government has certain rights in the invention.
The prospects for feeding humanity as we enter the new millennium are formidable. The progressive salinization of irrigated land compromises the future of agriculture in the most productive areas of our planet (Serrano et al., 1994). Arid regions offer optimal photoperiod and temperature conditions for the growth of most crops, but suboptimal rainfall. Artificial irrigation has solved the problem in the short term. However, water supplies always contain some dissolved salt, which upon evaporation gradually accumulates on the soils. To grow in saline environments, plants must maintain a much lower ratio of Na + /K + in their cytoplasm than that present in the soil. Thus, a need exists for crops having increased tolerance to salt.
In worldwide agricultural production, phosphorus is second only to nitrogen as the most limiting macronutrient. In soils, orthophosphate (Pi), the assimilated form of phosphorus, exists primarily as insoluble calcium salts or iron-aluminium oxide complexes that are inaccessible to plants (Holford, 1997). When aggressive fertilization is employed to alleviate available Pi deficiency, runoff from agricultural land represents a serious threat to aquatic and marine environments (Hammond et al., 2004). Thus, a need exists for crops having increased Pi uptake.
The present invention discloses transgenic plant cells and transgenic plants comprising transgenic plant cells, wherein the transgenic plant cells comprise an exogenous nucleic acid that causes overexpression of a plant vacuolar pyrophosphatase in the one or more transgenic plant cells, wherein the exogenous nucleic acid comprises a nucleic acid sequence encoding the plant vacuolar pyrophosphatase. The transgenic plants can have one or more enhanced phenotypic traits relative to non-transgenic wild-type plants of the same species. The present invention also discloses methods of making the transgenic plants.
According to one embodiment of the present invention, one or more transgenic plant cells comprise an exogenous nucleic acid that causes overexpression of a plant vacuolar pyrophosphatase in the one or more transgenic plant cells, wherein the exogenous nucleic acid comprises a nucleic acid sequence encoding the plant vacuolar pyrophosphatase. The transgenic plant cells can be from a plant selected from the group consisting of tomato, rice, tobacco, sorghum, cucumber, lettuce, turf grass, Arabidopsis and corn. They can be obtained from a tissue selected from the group consisting of roots, stems, leaves, flowers, fruits and seeds. The nucleic acid sequence encoding the plant vacuolar pyrophosphatase can be from a non-transgenic wild-type plant of the same species as the transgenic plant or from a non-transgenic wild-type plant of a species different from the transgenic plant. It can be obtained from a plant selected from the group consisting of Arabidopsis , tobacco, tomato and corn. It can be operably linked to at least one regulatory element that results in overexpression of the plant vacuolar pyrophosphatase. The plant vacuolar pyrophosphatase can be AVP1 or a homolog thereof.
According to another embodiment of the present invention, a transgenic plant comprises one or more transgenic plant cells comprising an exogenous nucleic acid that causes overexpression of a plant vacuolar pyrophosphatase in the one or more transgenic plant cells, wherein the exogenous nucleic acid comprises a nucleic acid sequence encoding the plant vacuolar pyrophosphatase. The transgenic plant can be selected from the group consisting of tomato, rice, tobacco, sorghum, cucumber, lettuce, turf grass, Arabidopsis and corn. The nucleic acid sequence encoding the plant vacuolar pyrophosphatase can be from a non-transgenic wild-type plant of the same species as the transgenic plant or from a non-transgenic wild-type plant of a species different from the transgenic plant. It can be obtained from a plant selected from the group consisting of Arabidopsis , tobacco, tomato and corn. It can be operably linked to at least one regulatory element that results in overexpression of the plant vacuolar pyrophosphatase. The plant vacuolar pyrophosphatase can be AVP1 or a homolog thereof. Transgenic progeny of the transgenic plant can comprise the exogenous nucleic acid. Transgenic seeds produced by the transgenic plant can comprise the exogenous nucleic acid. Transgenic progeny grown from the transgenic seeds can also comprise the exogenous nucleic acid. The transgenic plant can have one or more enhanced phenotypic traits relative to non-transgenic wild-type plants of the same species, and the enhanced phenotypic traits are selected from the group consisting of increased tolerance to one or more salts, increased yield, larger plant size and increased Pi uptake under Pi-sufficient growth conditions. It can also have one or more enhanced phenotypic traits relative to non-transgenic wild-type plants of the same species under Pi-deficient growth conditions, and the enhanced phenotypic traits are selected from the group consisting of increased root structure, increased root and shoot biomass, increased yield, increased biomass, delayed curtail of cell proliferation, increased Pi uptake, increased rhizosphere acidification, resistance to Al toxicity, increased organic acid exudates from root under Al stress, and increased root K + contents with or without Al stress.
According to yet another embodiment of the present invention, a method of making a transgenic plant with one or more enhanced phenotypic traits relative to non-transgenic wild-type plants of the same species comprises:
a) introducing an exogenous nucleic acid comprising a nucleic acid sequence encoding a plant vacuolar pyrophosphatase into one or more cells of a plant to generate transformed cells;
b) regenerating transgenic plants from the transformed cells;
c) selecting a transgenic plant with one or more enhanced phenotypic traits relative to non-transgenic wild-type plants of the same species, thereby producing the transgenic plant.
The one or more enhanced phenotypic traits can be selected from the group consisting of increased tolerance to one or more salts, increased yield, larger plant size and increased Pi uptake under Pi-sufficient growth conditions. They can also be selected from the group under Pi-deficient growth conditions consisting of increased root structure, increased root and shoot biomass, increased yield, increased biomass, delayed curtail of cell proliferation, increased Pi uptake, increased rhizosphere acidification, resistance to Al toxicity, increased organic acid exudates from root under Al stress, and increased root K + contents with or without Al stress. The transgenic plant can be selected from the group consisting of tomato, rice, tobacco, sorghum, cucumber, lettuce, turf grass, Arabidopsis and corn. The one or more cells of a plant can be obtained from a tissue selected from the group consisting of roots, stems, leaves, flowers, fruits and seeds. The nucleic acid sequence encoding the plant vacuolar pyrophosphatase can be from a non-transgenic wild-type plant of the same species as the transgenic plant or from a non-transgenic wild-type plant of a species different from the transgenic plant. It can be obtained from a plant selected from the group consisting of Arabidopsis , tobacco, tomato and corn. It can be operably linked to at least one regulatory element that results in overexpression of the plant vacuolar pyrophosphatase. The plant vacuolar pyrophosphatase can be AVP1 or a homolog thereof. The one or more salts can be selected from the group consisting of NaCl, KCl and CaCl 2 . They can have a concentration of about 0.2 M to about 0.3 M in water.
According to still another embodiment of the present invention, a transgenic rice plant comprises one or more transgenic rice plant cells comprising an exogenous nucleic acid that causes overexpression of a plant vacuolar pyrophosphatase in the one or more transgenic rice plant cells, wherein the exogenous nucleic acid comprises a nucleic acid sequence encoding the plant vacuolar pyrophosphatase, and the transgenic rice plant has one or more enhanced phenotypic traits relative to non-transgenic wild-type rice plants, said enhanced phenotypic traits selected from the group consisting of more tillers, more panicles and increased P, Fe and Zn contents. The nucleic acid sequence encoding the plant vacuolar pyrophosphatase can be from a non-transgenic wild-type plant of the same species as the transgenic plant or from a non-transgenic wild-type plant of a species different from the transgenic plant. It can be obtained from a plant selected from the group consisting of Arabidopsis , tobacco, tomato and corn. It can be operably linked to at least one regulatory element that results in overexpression of the plant vacuolar pyrophosphatase. The plant vacuolar pyrophosphatase can be AVP1 or a homolog thereof. Transgenic progeny of the transgenic rice plant can comprise the exogenous nucleic acid. Transgenic seeds produced by the transgenic rice plant can comprise the exogenous nucleic acid. Transgenic progeny grown from the transgenic seeds can also comprise the exogenous nucleic acid.
According to yet another embodiment of the present invention, a method of making a transgenic rice plant with one or more enhanced phenotypic traits relative to non-transgenic wild-type rice plants comprises:
a) introducing an exogenous nucleic acid comprising a nucleic acid sequence encoding a plant vacuolar pyrophosphatase into one or more cells of a rice plant to generate transformed cells;
b) regenerating transgenic plants from the transformed cells;
c) selecting a transgenic rice plant with one or more enhanced phenotypic traits relative to non-transgenic wild-type plants of the same species, thereby producing the transgenic rice plant.
The one or more enhanced phenotypic traits can be selected from the group consisting of more tillers, more panicles and increased P, Fe and Zn contents. The one or more cells of a plant can be obtained from a tissue selected from the group consisting of roots, stems, leaves, flowers, fruits and seeds. The nucleic acid sequence encoding the plant vacuolar pyrophosphatase can be from a non-transgenic wild-type plant of the same species as the transgenic plant or from a non-transgenic wild-type plant of a species different from the transgenic plant. It can be obtained from a plant selected from the group consisting of Arabidopsis , tobacco, tomato and corn. It can be operably linked to at least one regulatory element that results in overexpression of the plant vacuolar pyrophosphatase. The plant vacuolar pyrophosphatase can be AVP1 or a homolog thereof.
The foregoing will be apparent from the following more particular description of example embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating embodiments of the present invention.
FIGS. 1A and 1B are bar graphs showing the intracellular Na + and K + contents of wild-type yeast strains and of yeast strains carrying various mutations affecting sodium tolerance; values are the mean of two determinations, and bars represent the standard deviations.
FIG. 2 is alignment of the deduced amino acid sequences of NhX1 homologue from Arabidopsis AtNHX1 (SEQ ID NO: 1), human HsNHE-6 (SEQ ID NO: 2) and yeast ScNHX1 (SEQ ID NO:3); identical residues are in black boxes, and dashes indicate gaps in the sequence, * above alignment denote putative amiloride binding site from human NHE1 ( 163 DVF-FLFLLPPI 173 ) (SEQ ID NO: 4).
FIG. 3A is a schematic representation of a working model of the transporters involved in sodium sequestration at the yeast prevacuolar compartment; Nhx1 (Na + /H + antiporter), Vma1 (vacuolar membrane H + -adenosine triphosphatase (H + -ATPase)), Gef1 (yeast CLC chloride channel), Ena1 (plasma membrane Na + -ATPase).
FIG. 3B is a schematic representation of a working model of the transporters involved in sodium sequestration at the yeast prevacuolar compartment shown in FIG. 3A, which also includes AVP1 ( Arabidopsis thaliana vacuolar pyrophosphate-energized proton pump).
FIG. 4 depicts a nucleotide sequence of Arabidopsis thaliana cDNA encoding H + -PPase (SEQ ID NO: 6) and the predicted amino acid sequence of polypeptide (SEQ ID NO: 7) encoded by the nucleotide sequence.
FIG. 5 is a diagram of a working model of some of the genes involved in apoplastic acidification of Arabidopsis thaliana during Pi deficiency.
FIG. 6A is a graph showing quantitative RTF-PCR time points of AHA1, AHA2, AHA6, AVP1 and AtPT1 from wild-type (WT) plants grown under low Pi for 0-48 h. The relative mRNA levels were normalized to ACT2. Values are the means ±standard deviation, n=3.
FIG. 6B is a image showing immunoblot time points of membrane proteins isolated from WT plants grown under low Pi for 0-6 days and probed with antisera to H + -pyrophosphatase and P-ATPase.
FIG. 6C is a bar graph showing the relative densities of H + -pyrophosphatase and P-ATPase in FIG. 6B quantified with Bio-Rad Quantity One software. Values are the means ±standard deviation of three independent experiments.
FIG. 7A-C are bar graphs showing results of ionomic analysis of rice grains from wild-type and OsAVP1DOX plants. Rice was grown under phosphorus-sufficient conditions and harvested seeds were submitted for ICP-MS analysis of 20 elements by the Purdue-NSF Ionomics facility using their standard protocols. Shown are the profiles for phosphorus (P 31 ), iron (Fe 56 ), and zinc (Zn 66 ). Values are shown for grains with and without husks in parts per million.
A description of example embodiments of the invention follows.
The teachings of all patents, published applications and references cited herein are incorporated by reference herein in their entirety.
Producing salt-tolerant plants using genetic engineering requires the identification of the relevant genes. Physiological studies suggest that salt exclusion in the root and/or salt sequestration in the leaf cell vacuoles are critical determinants for salt tolerance (Kirsch et al., 1996). Toxic concentrations of NaCl build up first in the fully expanded leaves where NaCl is compartmentalized in the vacuoles. Only after their loading capacity is surpassed, do the cytosolic and apoplasmic concentrations reach toxic levels, ultimately leading to loss of turgor, ergo plant death. It has been suggested that hyperacidification of the vacuolar lumen via the vacuolar H + -ATPase (V-ATPase) provides the extra protons required for a Na + /H + exchange-activity leading to the detoxification of the cytosol (Tsiantis et al., 1996). Salt stress increases both ATP- and pyrophosphate (PPi)-dependent H + transport in tonoplast vesicles from sunflower seedling roots. Salt treatments also induce an amiloride-sensitive Na + /H + exchange activity (Ballesteros et al., 1997). In the halophyte Mesembryanthemum crystallinum , high NaCl stimulates the activities of both the vacuolar V-ATPase and a vacuolar Na + /H + antiporter in leaf cells. As described herein, the plant components involved in the intracellular detoxification system have been identified by complementing salt-sensitive mutants of the budding yeast Saccharomyces cerevisiae . As also described herein, Arabidopsis thaliana ( A. thaliana; Arabidopsis ) has been used as a host model plant to demonstrate that overexpression of these genes results in salt tolerance in the plant.
Accordingly, the present invention is directed to transgenic plants which are tolerant to one or more salts. As used herein, the term “salt” refers to any salt, such as NaCl, KCl, and/or CaCl 2 . In one embodiment, the transgenic plants of the present invention comprise one or more plant cells transformed with exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant. Any suitable vacuolar pyrophosphatase, several of which have been cloned, can be used in the compositions and methods of the present invention (e.g., Sarafian et al., 1992; Lerchl et al., 1995; Kim et al., 1994). A. thaliana vacuolar pyrophosphatase (AVP1) cDNA sequence and its encoded protein sequence (Sarafian et al., 1992) are shown in FIG. 4. As used herein, nucleic acid which “alters expression of vacuolar pyrophosphatase” includes nucleic acid which enhances (promotes) or inhibits expression of vacuolar pyrophosphatase in the transgenic plant. In a particular embodiment, the present invention relates to a transgenic plant which is tolerant to salt comprising an exogenous nucleic acid construct which is designed to overexpress AVP1 or designed to downregulate endogenous vacuolar pyrophosphatase. The present invention also encompasses transgenic plants which grow in a concentration of salt that inhibits growth of a corresponding non-transgenic plant. Transgenic progeny of the transgenic plants, seeds produced by the transgenic plant and progeny transgenic plants grown from the transgenic seed are also the subject of the present invention. Also described herein are plant cells comprising exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant cell.
Producing plants with increased Pi uptake using genetic engineering also requires the identification of the relevant genes. In response to limiting Pi availability, plant metabolic and developmental processes are altered to enhance Pi uptake. For example, in Arabidopsis , the coordinated induction of more than 600 genes is seen under conditions of Pi deprivation (Misson et al., 2005). Perhaps the most obvious consequence of altered gene expression in Pi-deprived plants is the expansion of their root architecture and resultant increases in absorptive surface area (Lopez-Bucio et al., 2002; Gahoonia and Nielsen, 2004). Pi-deprived roots exhibit transition of the primary root to determinate growth, greater frequency of lateral root formation and increased recruitment of trichoblasts to form root hairs (Abel et al., 2002; Poirier and Bucher, 2002; Sanchez-Calderon et al., 2006). In some species, Pi-deprived roots form specialized structures to enhance nutrient uptake, as is seen in white lupin ( Lupinus albus ), which forms clusters of short, hairy lateral roots (proteoid roots) that are specialized for Pi uptake (Yan et al., 2002). Another adaptation to low soil Pi is rhizosphere acidification, resulting from enhanced plasma membrane H + -ATPase activity in roots (Yan et al., 2002; Zhu et al., 2005; Shen et al., 2006). Increased H + extrusion results in increased displacement of Pi from insoluble soil complexes (Vance et al., 2003). The advantage of these adaptations to low-Pi conditions is evident in the apparent universality of such responses in plants that prosper in low-Pi soils. As described herein, the plant components involved in the adaptations to low-Pi conditions have been identified by quantitative real-time fluorescence-polymerase chain reaction (RTF-PCR) and western blot analysis. As also described herein, A. thaliana , tomato and rice have been used as host model plants to demonstrate that overexpression of these genes results in increased Pi uptake in the plant.
Accordingly, the present invention is also directed to transgenic plants which have increased Pi uptake. As used herein, the term “Pi uptake” refers to total Pi content per plant, irrespective of the growth conditions. In one embodiment, the transgenic plants of the present invention comprise one or more plant cells transformed with exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant. Any suitable vacuolar pyrophosphatase, several of which have been cloned, can be used in the compositions and methods of the present invention (e.g., Sarafian et al., 1992; Lerchl et al., 1995; Kim et al., 1994). A. thaliana vacuolar pyrophosphatase (AVP1) cDNA sequence and its encoded protein sequence (Sarafian et al., 1992) are shown in FIG. 4. As used herein, nucleic acid which “alters expression of vacuolar pyrophosphatase” includes nucleic acid which enhances (promotes) or inhibits expression of vacuolar pyrophosphatase in the transgenic plant. In a particular embodiment, the present invention relates to a transgenic plant which has increased Pi uptake comprising an exogenous nucleic acid construct which is designed to overexpress AVP1 or designed to downregulate endogenous vacuolar pyrophosphatase. The present invention also encompasses transgenic plants which grow in a deficiency of Pi that inhibits growth of a corresponding non-transgenic plant. Transgenic progeny of the transgenic plants, seeds produced by the transgenic plant and progeny transgenic plants grown from the transgenic seed are also the subject of the present invention. Also described herein are plant cells comprising exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant cell.
Any suitable nucleic acid molecule which alters expression of vacuolar pyrophosphatase in the plant can be used to transform the transgenic plants in accordance with the present invention. Exogenous nucleic acid is a nucleic acid from a source other than the plant cell into which it is introduced or into a plant or plant part from which the tansgenic part was produced. The exogenous nucleic acid used for transformation can be RNA or DNA (e.g., cDNA and genomic DNA). In addition, the exogenous nucleic acid can be circular or linear, double-stranded or single-stranded molecules. Single-stranded nucleic acid can be the sense strand or the anti-sense strand.
The exogenous nucleic acid can comprise nucleic acid that encodes a vacuolar pyrophosphatase protein (an exogenous vacuolar pyrophosphatase), such as AVP1, a functional portion thereof (peptide, polypeptide), or a homolog thereof, and/or nucleic acid that alters (enhances or inhibits) expression of the endogenous vacuolar pyrophosphatase of the plant into which the exogenous nucleic acid is introduced. As used herein a “functional portion” of a nucleic acid that encodes a vacuolar pyrophosphatase protein is a portion of the nucleic acid that encodes a protein or polypeptide which retains a function characteristic of a vacuolar pyrophosphatase protein. In a particular embodiment, the nucleic acid encodes AVP1, a functional portion or a homolog thereof. As used herein “a homolog” of AVP1 refers to a homologous protein of AVP1 wherein the homologous protein performs the same function as AVP1 does in Arabidopsis but is from a different plant species, i.e. a homolog of AVP1 is a vacuolar pyrophosphatase of a plant species other than Arabidopsis . There is a high degree of identity at the amino acid level between vacuolar pyrophosphatases across the plant kingdom (Maeshima, 2000; Drozdowicz and Rea, 2001), suggesting that vacuolar pyrophosphatase from one species would be functional in another species. As described herein, this is indeed the case.
Nucleic acid that alters (enhances or inhibits) expression of the endogenous vacuolar pyrophosphatase of the plant into which the exogenous nucleic acid is introduced includes regulatory sequences (e.g., inducible or constitutive) which function in plants and antisense nucleic acid. Examples of regulatory sequences include promoters, enhancers and/or suppressors of vacuolar pyrophosphatase. The nucleic acid can also include, for example, polyadenylation site, reporter gene and/or intron sequences and the like whose presence may not be necessary for function or expression of the nucleic acid but can provide improved expression and/or function of the nucleic acid by affecting, for example, transcription and/or stability (e.g., of mRNA). Such elements can be included in the nucleic acid molecule to obtain optimal performance of the nucleic acid.
The nucleic acid for use in the present invention can be obtained from a variety sources using known methods. For example, the nucleic acid encoding a vacuolar pyrophosphatase (e.g., AVP1) for use in the present invention can be derived from a natural source, such as tobacco, bacteria, tomato or corn. In one embodiment, the nucleic acid encodes a vacuolar pyrophosphatase that corresponds to a wild type of the transgenic plant. In another embodiment, the nucleic acid encodes a vacuolar pyrophosphatase that does not correspond to a wild type of the transgenic plant. Nucleic acid that alters (enhances or inhibits) expression of the endogenous vacuolar pyrophosphatase of the plant into which the exogenous nucleic acid is introduced (e.g., regulatory sequences) can also be chemically synthesized, recombinantly produced and/or obtained from commercial sources.
A variety of methods for introducing the nucleic acid of the present invention into plants are known to those of skill in the art. For example, Agrobacterium-mediated plant transformation, particle bombardment, microparticle bombardment (e.g., U.S. Pat. No. 4,945,050; U.S. Pat. No. 5,100,792) protoplast transformation, gene transfer into pollen, injection into reproductive organs and injection into immature embryos can be used. The exogenous nucleic acid can be introduced into any suitable cell(s) of the plant, such a root cell(s), stem cell(s), leaf cell(s), flower cell(s), fruit cell(s) and/or seed cell(s) of the plant.
In one embodiment, a construct comprising a vacuolar pyrophosphatase gene operably linked to a promoter designed to overexpress the vacuolar pyrophosphatase (e.g., an expression cassette) or a construct designed to downregulate endogenous pyrophosphatase is used to produce the transgenic plants of the present invention. As used herein the term “overexpression” refers to greater expression/activity than occurs in the absence of the construct. In a particular embodiment, a construct comprising an AVP1 gene operably linked to a chimeric promoter designed to overexpress the AVP1 or designed to downregulate endogenous pyrophosphatase is used to produce the transgenic plants of the present invention. More particularly, the present invention relates to a construct wherein the AVP1 gene is operably linked to a double tandem enhancer of a 35S promoter.
Any suitable plant can be used to produce the transgenic plants of the present invention. For example, tomato, corn, tobacco, rice, sorghum, cucumber, lettuce, turf grass, ornamental (e.g., larger flowers, larger leaves) and legume plants can be transformed as described herein to produce the transgenic plants of the present invention. In addition, the transgenic plants of the present invention can be grown in any medium which supports plant growth such as soil or water (hydroponically).
The present invention also encompasses methods of making a transgenic plant which is tolerant to salt. In one embodiment, the method comprises introducing into one or more cells of a plant exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant to yield transformed cells in the plant, thereby producing a transgenic plant which is tolerant to salt. In another embodiment, the method comprises introducing into one or more cells of a plant a nucleic acid construct which is designed to overexpress AVP1 to yield transformed cells, thereby producing a transgenic plant which is tolerant to salt. The methods of making a transgenic plant can further comprise regenerating plants from the transformed cells to yield transgenic plants and selecting a transgenic plant which is tolerant to salt. The transgenic plants produced by these methods are also encompassed by the present invention.
The present invention also encompasses methods of making a transgenic plant with increased Pi uptake. In one embodiment, the method comprises introducing into one or more cells of a plant exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant to yield transformed cells in the plant, thereby producing a transgenic plant with increased Pi uptake. In another embodiment, the method comprises introducing into one or more cells of a plant a nucleic acid construct which is designed to overexpress AVP1 to yield transformed cells, thereby producing a transgenic plant with increased Pi uptake. The methods of making a transgenic plant can further comprise regenerating plants from the transformed cells to yield transgenic plants and selecting a transgenic plant which with increased Pi uptake. The transgenic plants produced by these methods are also encompassed by the present invention.
The transgenic plants of the present invention are useful for a variety of purposes. As described herein, the plant components involved in an intracellular cation detoxification system have been identified by complementing salt-sensitive mutants of the budding yeast Saccharomyces cerevisiae . As also described herein, the plant components involved in the adaptations to low Pi conditions have been identified by quantitative RTF-PCR and western blot analysis. The present invention relates to a method of bioremediating soil comprising growing one or more transgenic plants and/or progeny thereof in the soil, wherein the transgenic plants and/or progeny thereof comprise exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant. In another embodiment, the present invention relates to a method of removing cations (e.g., monvalent and/or divalent cations) from a medium which can support plant growth (e.g., soil, water) comprising growing one or more transgenic plants and/or progeny thereof in the medium, wherein the transgenic plants and/or progeny thereof comprise exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant. For example, the method can be used to remove sodium (Na), lead (Pb), manganese (Mn) and/or calcium (Ca) ions from a medium which supports plant growth. In another embodiment, the present invention relates to a method of scavenging Pi from a medium which can support plant growth (e.g., soil, water) comprising growing one or more transgenic plants and/or progeny thereof in the medium, wherein the transgenic plants and/or progeny thereof comprise exogenous nucleic acid which alters expression of vacuolar pyrophosphatase in the plant. For example, the method can be used to prevent Pi runoff from agricultural land.
Furthermore, it has been shown herein that the transgenic plants of the present invention are larger than the corresponding wild type plants (Example 3). Thus, the present invention provides for a method of increasing the yield of a plant comprising introducing into one or more cells of a plant nucleic acid which alters expression of vacuolar pyrophosphatase in the plant to yield transformed cells, thereby increasing the yield of the plant. The present invention also relates to a method of making a plant which is larger than its corresponding wild type plant comprising introducing into one or more cells of a plant nucleic acid which alters expression of vacuolar pyrophosphatase in the plant to yield transformed cells, thereby producing a transgenic plant which is larger than its corresponding wild type plant. The method can further comprise regenerating plants from the transformed cells to yield transgenic plants and selecting a transgenic plant which is larger than its corresponding wild type plant, thereby producing a transgenic plant which is larger than its corresponding wild type plant. Also encompassed by the present invention is a method of making a transgenic plant (e.g., an ornamental plant) having increased flower size compared to its corresponding wild type plant comprising introducing into one or more cells of a plant nucleic acid which alters expression of vacuolar pyrophosphatase in the plant to yield transformed cells, thereby producing a transgenic plant having increased flower size compared to its corresponding wild type plant.
The present invention also provides for a method of producing a transgenic plant which grows in salt water comprising introducing into one or more cells of a plant nucleic acid which alters expression of vacuolar pyrophosphatase in the plant to yield transformed cells, thereby producing a transgenic plant which grows in salt water. As used herein, “salt water” includes water characterized by the presence of salt, and preferably wherein the concentration of salt in the water is from about 0.2M to about 0.4M. In one embodiment, salt water refers to sea water.
The present invention also provide for a method of producing a transgenic plant which grows better than wild-type in Pi deficiency comprising introducing into one or more cells of a plant nucleic acid which alters expression of vacuolar pyrophosphatase in the plant to yield transformed cells, thereby producing a transgenic plant which grows better than wild-type in Pi deficiency. As used herein, “Pi deficiency” refers to a growth medium, either natural or artificial, containing lower Pi than what is required to support full growth of a wild-type plant, i.e. under Pi deficiency, growth of a wild-type plant is limited. Because different plants require different levels of Pi to fully grow, Pi deficiency, as used herein, is a plant-specific term.
The transgenic plants of the present invention can also be used to produce double transgenic plants which are tolerant to salt wherein a plant is transformed with exogenous nucleic acid which alters expression of a vacuolar phosphatase and exogenous nucleic acid which alters expression of another protein involved in sequestration of cations and/or detoxification in plants. In one embodiment, the present invention relates to a double transgenic plant which is tolerant to salt comprising one or more plant cells transformed with exogenous nucleic acid which alters expression of a vacuolar pyrophosphatase and an Na + /H + antiporter in the plant. In one embodiment, the vacuolar pyrophosphatase is AVP1 or a homologue thereof and the Na + /H + antiporter is AtNHX1 or a homologue thereof. The present invention further relates to a transgenic progeny of the double transgenic plant, as well as seeds produced by the transgenic plant and a progeny transgenic plant grown from the seed.
The transgenic plants of the present invention can also be used to produce double transgenic plants with increased Pi uptake wherein a plant is transformed with exogenous nucleic acid which alters expression of a vacuolar phosphatase and exogenous nucleic acid which alters expression of another protein involved in the adaptations to low-Pi conditions. In one embodiment, the present invention relates to a double transgenic plant with increased Pi uptake comprising one or more plant cells transformed with exogenous nucleic acid which alters expression of a vacuolar pyrophosphatase and a plasma membrane H + -ATPase in the plant. In one embodiment, the vacuolar pyrophosphatase is AVP1 or a homologue thereof and the plasma membrane H + -ATPase is AHA2 or AHA6 or a homologue thereof. The present invention further relates to a transgenic progeny of the double transgenic plant, as well as seeds produced by the transgenic plant and a progeny transgenic plant grown from the seed.
Investigation of the role of intracellular organelles in cation homeostasis via the identification and manipulation of key transporters is described herein. Most of these intracellular organelles, including clathrin-coated vesicles, endosomes, Golgi membranes and vacuoles have acidic interiors (Xie et al., 1989). This acidification is mediated by a proton-translocating electrogenic ATPase and in plant vacuoles also via a pyrophosphate-driven proton pump V-PPase (Davies et al., 1997; Zhen et al., 1997). There exists a requirement of anion transport to maintain net electroneutrality (al-Awqati, 1995). The yeast member of the CLC voltage-gated chloride channel superfamily, Gef1, is required for copper loading in late-Golgi vesicles and for cation sequestration in the prevacuolar compartment in yeast (Gaxiola et al., 1998; Gaxiola et al., 1999; Example 1). Furthermore, it has been shown that the defects of gef1 mutants can be suppressed by the introduction of the prototype member of the CLC superfamily, the Torpedo marmorata CLC-0 or by the introduction of Arabidobsis thaliana CLC-c and CLC-d chloride channel genes (Hechenberger et al., 1996; Gaxiola et al., 1998). While not wishing to be bound by theory, two observations led to the proposal of a model for Na + sequestration in yeast described herein (FIGS. 3A and 3B). First, gef1 mutants are sensitive to high NaCl concentrations. Second, the Na + /H + exchanger Nhx1 localized to the prevacuolar compartment (Nass and Rao, 1998). This model posits that Na + sequestration by Nhx1 depends on the vacuolar H + -ATPase and Gef1, the chloride channel. Gef1-mediated anion influx allows the establishment by the vacuolar H + -ATPase of a proton gradient sufficient in magnitude to drive the uphill accumulation of Na + via Na + /H + exchange.
This model is entirely consistent with the physiological data on the role of the vacuole in cation detoxification in higher plants. As described in Example 1, to test this sequestration model, mutant yeast strains (ena1) lacking the plasma membrane sodium efflux pump, which therefore must rely on the internal detoxification system in order to grow on high salt, were constructed. In theory, increasing the influx of protons into the postulated endosomal compartment should improve Na + sequestration via the Nhx1 exchanger. In order to increase the H + availability the A. thaliana gain-of-function mutant gene AVP1-D that codes for the vacuolar pyrophosphate-energized proton pump was expressed (FIG. 3B) (Zhen, Kim and Rea, 1997). This plant pump expressed in yeast restored the Na + resistance of the test strain, but only if the strain had functional NHX1 and GEF1 genes. Furthermore, Gef1p and Nhx1p colocalize within a common organelle, the prevacuolar compartment (Gaxiola et al., 1999). These results strongly support the model in FIGS. 3A and 3B and indicate that the yeast prevacuolar compartment can be used to identify the elusive plant transporters involved intracellular sodium detoxification.
Yeast and plant cells share pathways and signals for the trafficking of vesicles from the Golgi network to the vacuole (Neuhaus et al., 1998; Paris et al., 1997; Sato et al., 1997; Vitale et al., 1999). As shown herein, intracellular Na + detoxification in yeast requires functional Na + /H + exchanger (Nhx1) and chloride channel (Gef1), and they colocalize to a prevacuolar compartment (Gaxiola et al., 1999). As described in Example 1, to further test the utility of this system, an Arabidopsis thaliana homologue of the yeast NHX1 gene (AtNHX1) was cloned and its function in the nhx 1 yeast mutant was tested. The AtNHX1 gene was able to suppress partially the cation sensitivity phenotypes of nhx 1 mutants. Further support for the role of the Arabidopsis AtNHX1 gene in salt homeostasis came from the observation that its expression is induced in salt-stressed plants (Gaxiola et al., 1999). A recent report shows that the overexpression of AtNHX1 gene in transgenic Arabidopsis thaliana promotes sustained growth in soil watered with 200 mM NaCl plus ⅛ M.S. salts under short-day cycle conditions (Apse et al., 1999). It is worth noting that every addition of ⅛ M.S. salts provides 2.5 mM potassium reducing the stringency of the NaCl stress, and that a short-day cycle reduces oxidative stress. As described in Example 2, transgenic plants that overexpress the AtNHX1 were generated (35SAtNHX1 transgenics).
In plants, most of the transport processes are energized by the primary translocation of protons. H + -translocating pumps located at the plasma membrane and tonoplast translocated H + from the cytosol to extracellular and vacuolar compartments, respectively (Rea et al., 1990). The plant tonoplast contains two H + -translocating pumps; the V-ATPase and the inorganic pyrophosphatase or V-PPase. Their action results in luminal acidification and the establishment of a H + electrochemical potential gradient across the tonoplast (Davies et al., 1997). The vacuolar membrane is implicated in a broad spectrum of physiological processes that include cytosolic pH stasis, compartmentation of regulatory Ca 2+ , sequestration of toxic ions such as Na + , turgor regulation, and nutrient storage and retrieval. The vacuole constitute 40 to 99% of the total intracellular volume of a mature plant cell. The vacuolar proton pumping pyrophosphatase is a universal and abundant component of plant tonoplast capable of generating a steady-state transtonoplast H + electrochemical potential similar or greater than the one generated by the V-ATPase (Rea et al., 1990). PPi is a by-product in the activation or polymerization steps of a wide range of biosynthetic pathways and in plants serves as an alternative energy donor to ATP for sucrose mobilization via sucrose synthase, for glycolysis via PPi: fructose-6-phosphate phosphotransferase and for tonoplast energisation via the vacuolar proton pumping pyrophosphatase (Stitt, 1998).
As described in Example 1, the overexpression of the A. Thaliana gain-of-function mutant gene AVP1-D increases the intracellular detoxification capability in yeast (Gaxiola et al., 1999). The rationale behind this approach is that an increased influx of H + into the vacuolar compartment should improve Na + sequestration via the Nhx1 exchanger. As described in Example 3, in order to test this hypothesis in plants, a transgenic Arabidopsis thaliana plant was engineered to overexpress the AVP1 wild-type gene using the double tandem enhancer of the 35S promoter (Topfer et al., 1987). AVP1 encodes the pyrophosphate-energized vacuolar membrane proton pump from Arabidopsis (Sarafian et al., 1992). Previous investigations suggest that the AVP1 gene is present in a single copy in the genome of Arabidopsis (Kim et al., 1994), however, a sequence homologous, but not identical, to AVP1 on chromosome one has been tentatively designated as ORF F9K20.2 on BAC F9K20 by the Arabidopsis Genome Initiative (AGI).
Five different lines of 35SAVP1 plants showed an enhanced salt tolerance as compared to wild-type plants in the T2 stage. However, the most dramatic phenotype was apparent in the homozygous T3 plants. These transgenic plants are larger than wild-type plants. Furthermore, homozygous 35SAVP1 plants show sustained growth in the presence of 250 mM NaCl plus ⅛ M.S. salts when grown in a 24 hours light regimen. Interestingly, when 35SAVP1 plants were grown under short-day cycle conditions sustained growth in the presence of 300 mM NaCl plus 1/8 M.S. salts was observed.
Hydroponic culture increases plant growth and provides stress-free root and shoot material (Gibeaut et al., 1997). Another important advantage of hydrophonic culture is that we can alter the ionic composition in a more accurate manner than in soil. These advantages could be important for the physiological studies of salt stress. As described in Example 4, wild type and 35SAVP1 transgenic plants were grown hydroponically. Under such conditions the size differences in root, leaves and stems among wild type and 35SAVP1 transgenic plants are dramatic. To learn about the salt tolerance of these plants under hydroponic conditions, NaCl concentration were increased stepwise by 50 mM every 4 days (Apse et al., 1999). 35SAVP1 transgenic plants appear healthy in the presence of 200 mM NaCl while wild type controls show severe deleterious effects in their leaves and stems.
Investigation of the plant components involved in the adaptations to low-Pi conditions via quantitative RTF-PCR and western blot analysis is described herein. Previous genome-wide transcriptional analysis using Arabidopsis thaliana Affymetrix gene chips identified a number of genes related to phosphate deprivation (Misson et al., 2005). However, the baseline on the gene chips could prevent the detection of relatively minor changes, resulting in false negatives. As described in Example 5, low Pi can increase transcript and protein abundance of AVP1 and H + -ATPases in A. thaliana , whose induction has never been previously observed in A. thaliana following phosphate deprivation. While not wishing to be bound by theory, two observations led to the proposal of a model for apoplastic acidification in A. thaliana in Pi deficiency described herein (FIG. 5). First, microsomal fractions from AVP1 transgenic Arabidopsis plants (AtAVP1 OX) exhibited increased plasma membrane (PM) P-type H + -ATPase (P-ATPase) protein abundance and activity (Li et al., 2005). Second, the apoplastic pH was significantly more acidic in AtAVP1OX than in wild-type plants (Li et al., 2005). This model posits that apoplastic acidification during Pi deficiency, which is the result of increased PM P-ATPase activity, at least partially depends on increased expression of AVP1 during Pi defiency. Increased AVP1 expression can lead to increased PM P-ATPase expression and activity, suggesting a mechanism that can be manipulated to produce plants that exhibit increased resilience to Pi deficiency.
This model is entirely consistent with the experimental data on the role of AVP1 in rhizosphere acidification in Arabidopsis under Pi deficiency. As described in Example 7, increased rhizosphere acidification in AtAVPOX1 under Pi deficiency was completely inhibited by 1 mM vanadate, an inhibitor of PM H + -ATPase activity, as was rhizosphere acidification in wild-type plants. This result strongly supports the model in FIG. 5 and indicate that the previously observed increased apoplastic acidification in AtAVP1OX plants was to a large part, if not entirely, via increased PM H + -ATPase activity.
Under nutrient-sufficient conditions, AVP1 transgenic plants exhibit certain enhanced phenotypic traits such as increased root structure, increased root and shoot biomass, increased yield, increased biomass and increased seed production (U.S. Patent Application Publication No. 2003-0213015 A1; U.S. Patent Application Publication No. US 2005-0278808 A1; Example 3). These enhanced phenotypic traits are also observed in AtAVP1OX as described herein. As described in Example 7, AtAVP1OX plants also exhibited enhanced growth and Pi uptake when grown in either Pi-sufficient or Pi-deficient conditions. The rationale behind this is that increased H + extrusion results in increased displacement of Pi from insoluble soil complexes, resulting in more efficient Pi scavenging.
Other AVP1 transgenic species, including AVP1 transgenic tomato (LeAVP1 OX) and AVP1 transgenic rice (OsAVP1 OX), also exhibited the aforementioned enhanced phenotypic traits under nutrient-sufficient conditions and enhanced growth and Pi uptake when grown in either Pi-sufficient or Pi-deficient conditions. Other phenotypic traits observed for AVP1 transgenic plants under Pi deficiency included, but were not limited to, increased root structure, increased root and shoot biomass, increased yield, increased biomass, delayed curtail of cell proliferation, faster and total Pi depletion, resistance to aluminum (Al) toxicity, increased organic acid exudates from root under Al stress, and increased root K + contents with or without Al stress. Mobilized A1 is known as being toxic to plants. Pi deficiency is often a problem in tropical soils in which marginal Al toxicity limits agricultural production (Kochian et al., 2004).
Importantly, AVP1 transgenic rice was found to exhibit increased biomass and seed yields when grown under nutrient-sufficient conditions. Other enhanced phenotypic traits observed for AVP1 transgenic rice include, but are not limited to, more tillers, more panicles and increased phosphorus (P), iron (Fe) and zinc (Zn) contents.
Genetic engineering promises to transform modern agriculture. Salinization of soil due to irrigation has rendered much land unusable for crop production. Low level of P in tropical/subtropical soils result in agricultural losses. Fertilizer application results in P runoff pollution of aquatic and marine environments. Described herein is a strategy using genetic and molecular biological approaches to improve the intracellular Na + detoxification and the Pi uptake capabilities of crops. The fact that genetically engineered Arabidopsis thaliana plants that overexpress either AVP1 (the pyrophosphate-energized vacuolar membrane proton pump, this work) or AtNHX1 (the Na + /H + antiporter (Apse et al., 1999, and this work) are capable of growing in the presence of 200 mM NaCl strongly supports the strategy described herein. The fact that genetically engineered Arabidopsis , tomato and rice plants have increased Pi uptake and enhanced growth in both Pi-sufficient and Pi-deficient conditions also strongly supports the strategy described herein. It is likely that a double transgenic plant will show a further enhanced salt-tolerant phenotype or an increased Pi uptake phenotype or both phenotypes. Moreover, the discovery that Arabidopsis and tomato plants over-expressing AVP1 are resistant to water deficit stress (Gaxiola et al., 2001, 2007; Park et al., 2005) further enhances the potential value of this approach, as low-Pi soils are common in developing nations where water deficits are not easily ameliorated by irrigation. Furthermore, it is shown herein that the Arabidopsis thaliana transporter AVP1 is able to perform similar function in important agricultural crops, such as tomato and rice. It is expected that AVP1 homologs from other species will be able to perform similar functions when transformed into plants. The increased size of AVP1 transgenic plants also contribute to future food security, namely potential yield increases in genetically engineered crops.
Materials and Methods
Yeast strains and Plasmids. All strains used are isogenic to W303 (ura3-1.can1-100 leu2-3, 112trp1-1 his3-11, (Gaxiola et al., 1992). Plasmids pRG52 (Δgef1::HIS3) (Gaxiola et al., 1998) and pRG197 (Anhx1::HIS3) were used to construct the deletions of GEF1 and NHX1 genes, yielding strains RGY85 and RGY296, respectively. The ena1::HIS3 mutant was obtained from Fink Lab collection (L5709). Transformation was performed by using the lithium acetate method (Gietz et al., 1992). Double mutants RGY324 (gef1::HIS3 ena1::HIS3), RGY326 (nhx1::HIS3 ena1::HIS3), and RGY343 (gef1::HIS3 nhx1::HIS3) were obtained by crossing the single-mutant strains. Double mutants were identified among the meiotic progeny by scoring for the phenotypes associated with each of the single mutants. Sporulation, tetrad dissection, and mating types were scored as described (Guthrie and Fink, 1991). Cells were grown in YPD (1% yeast/2% peptone/2% dextrose; Difco), YPGAL (1% yeast/2% peptone/2% galactose; Difco), SD (Difco; Synthetic medium with 2% Dextrose), or APG (APG is a synthetic minimal medium containing 10 mM arginine, 8 mM phosphoric acid, 2% glucose, 2 mM MgSO 4 , 1 mM KCl, 0.2 mM CaCl 2 , and trace minerals and vitamins) (Rodriguez-Navarro and Ramos, 1984). MnCl 2 (Sigma), tetramethylammonium chloride (Sigma), NaCl (Sigma), or hygromycin-B (Sigma) were added as indicated.
Wild type, L5709 (ena1::HIS3), RGY324 (gef1::HIS3 ena1::HIS3), and RGY326 (nhx1::HIS3 ena1::HIS3) strains were transformed with pYES2 vector (Invitrogen) and plasmid pYES2-AVP1-E229D described in ref. Zhen, Kim and Rea, 1997. The strain RGY343 (gef1::HIS3 nhx1::HIS3), used for histochemical analysis, was transformed with pRG151 (GEF1-GFP) (Gaxiola et al., 1998) and with pRIN73 [NHX1-(HA) 3 ] (Nass and Rao, 1998).
Wild-type and RGY296 (nhx1::HIS3) strains were transformed with vector pAD4 (Ballester et al., 1989). RGY296 (nhx1::HIS3) was transformed with pRG308 (ADH1::AtNHX1) (see Cloning of AtNHX1).
Determination of Intracellular Sodium and Potassium content. Cells were grown overnight in SD-ura medium (Difco; synthetic medium with 2% dextrose without uracil). YPGAL (1% yeast extract/2% peptone/2% galactose; Difco) media was inoculated with the overnight stocks and grow to an A 600 of 0.6. At this optical density (OD), NaCl was added to a final concentration of 0.7 M. The cells incubated for 6 h, harvested by centrifugation, washed two times with 1.1 M sorbitol and 20 mM MgCl 2 , and entracted with water for 30 min at 95° C. The amount of Na + and K + in cells was determined at the University of Georgia Chemical Analysis Laboratory by an Inductively Coupled Plasina-MS. Intracellular cation concentrations were estimated as described (Gaxiola et al., 1992) by using the intracellular water value calculated for cells grown in 1 M NaCl.
Immunofluorescence. The strain RGY343 (gef1::HIS3 nhx1::HIS3) was grown in SD-ura, -leu medium (Difco; synthetic medium with 2% dextrose without uracil and leucin) to mid-logarithmic phase, 0.1 mg/ml hygromycin B was added, and the culture was incubated for 1 h at 30° C. Cells were fixed with 3.7% formaldehyde (Sigma) for 45 min at room temperature without agitation. Spheroplast formation, permeabilization, washing, and antibody incubation was performed as described (Pringle et al., 1991). MAB HA11 used as first antibody was from Babco (Richmond, Calif.). Cy3-conjugated goat antimouse IgG was from Jackson Immunoresearch. 4′,6-Diamidino-2-phenylind-ole (Sigma) was added to mounting medium to stain mitochondrial and nuclear DNA.
Subcellular Fractionation and Western Analysis. The strain RGY343 (gef1::HIS3 nhx1::HIS3) was grown in APG medium (pH 7.0), and lysates fractioned on a 10-step sucrose density gradient as described (Nass and Rao, 1998). Aliquots of individual fractions (100 μg) were subjected to SDS/PAGE and transferred to nitrocellulose as described (Nass and Rao, 1998). Western blots were probed with monoclonal anti-GFP (green fluorescent protein) antibody (1:10,000 dilution; CLONTECH), anti-hemagglutinin antibody (1:10,000 dilution: Boehringer Mannheim), and peroxidase-coupled goat anti-mouse antibody (1:5,000;) and developed by using the ECL enhanced chemiluminescence system (Amersham Pharmacia).
Plant Strains, Growth conditions and RNA Preparation. A. thaliana plants (ecotype Columbia) were grown aseptically on unsupplemented plant nutrient agar without sucrose (Haughn and Somerville, 1986) for 15 days at 19° C. and under continuous illumination. NaCl or KCl was added to a final concentration of 250 mM, and the plants were incubated for 6 h. Total RNA from tissue of salt-treated and untreated plants was isolated (Niyogi and Fink, 1992). Hybond-N (Amersham) membranes were hybridized with a 32 P-Labeled DNA probe from plasmid pRG308. Hybridization was performed at 65° C. overnight. Washes were performed at 65° C. with 0.2% standard saline citrate (SSC)/0.1% SDS. 18S probe was used as loading control. MACBAS 2.4 program was used to quantify the relative amount of RNA.
Cloning of AtNHX1. AtNHX1 was cloned from a phage cDNA library of A. thaliana (Kieber et al., 1993) (obtained from the Arabidopsis Biological Resource Center) by probing with an expressed sequence tag (Arabidopsis Biological Resources Center, DNA Stock Center) containing a partial clone. A full-length clone (2.1 kilobase; kb) was ligated into vector pSK2 (Stratagene) at the NotI site, generating plasmid pRG293. The AtNHX1 open reading frame (ORF) was amplified via PCR by using pRG293 as template and GGCCCGGGATGGATTCTCTAGTGTCGAAACTGCCTTCG (SEQ ID NO: 5) and T7 oligonucleotides. The PCR product was then digested with XbaI and SalI and ligated into pAD4 vector generating plasmid pRG308. The AtNHX1 ORF was sequenced to verify the fidelity of the PCR product. The full-length sequence is longer than the ORF reported by the Arabidopsis Genome Initiative (A TM021B04.4), and has been deposited in GenBank (accession no. AF106324).
Results
The Arabidopsis Vacuolar H + -Pyrophosphatase (AVP1) Confers Salt Tolerance to Yeast ena1 Mutants. To determine the components of the intracellular system required for sodium detoxification, an ena1 mutant that lacks the plasma membrane sodium efflux pump and therefore must rely on the internal detoxification system to overcome sodium toxicity was used. Growth of the ena1 strain is sensitive to low concentrations of sodium (200 mM), concentrations that do not inhibit the growth of wild-type strains. The sequestration model (Nass and Rao, 1998; Gaxiola et al., 1998) predicts that the ena1 strain would become salt tolerant if one could enhance the availability of protons in the postulated endosomal compartment. With increased influx of protons, cytoplasmic Na + would be sequestered via the Nhx1 exchanger. The yeast vacuolar ATPase is a multisubunit protein, so it is difficult to increase its activity by overexpressing any one of its subunits. However, it is possible to increase the influx of protons by expressing the A. thaliana AVP1 gene in yeast. This gene encodes a single polypeptide that, when expressed in yeast, is capable of pumping protons into the lumen of the vacuole (Kim et al., 1994). To ensure maximum activity of this proton pump, the E229D gain-of-function mutant of the AVP1 gene (AVP1-D) that has enhanced H + pumping capability was expressed (Zhen, Kim and Rea., 1997).
Overexpression of AVP1-D restored salt tolerance to salt-sensitive ena1 mutants. The restoration of salt tolerance to an ena1 strain by AVP1-D requires functional NHX1 and GEF1 genes: ena1nhx1 AVP1-D and ena1 gef1 AVP1-D strains are salt sensitive.
Expression of Arabidopsis vacuolar pyrophosphatase AVP1 in ena1 mutants: Vector pYES2 (Invitrogen) was introduced into wild-type, ena1, ena1 nhx1, and ena1 gef1 mutants. Plasmid pYes2-AVP1-D (Zhen, Kim and Rea, 1997) was introduced into ena1, ena1 nhx1, and ena1 gef1 mutants. Five-fold serial dilutions (starting at 10 5 cells) of each strain were plated on YPGAL (1% yeast extract/2% peptone/2% galactose) with or without 0.5 M NaCl and incubated at 30° C. for 2 days. FIGS. 1A and 1B show intracellular concentrations of Na + and K + . Exponentially growing cells (wild-type and ena1 transformed with pYES2 vector and ena1, ena1 nhx1, and ena1 gef1 mutants carrying pYes2-AVP1-D) were exposed to 0.7 M NaCl for 6 hours. Total cell extracts were prepared (see Materials and Methods), and Na + and K + concentrations were determined. There is a consistent reduction in total cell Na + in the ena1 AVP-D strain. The reason for this reduction is unknown.
The intracellular Na + and K + contents of wild-type strains and of strains carrying various mutations affecting sodium tolerance were determined after 6 h of exposure to media supplemented with 0.7 M NaCl (FIGS. 1A and 1B). The intracellular Na + content in the ena1 mutant is 8-fold higher than in the wild-type strain. The ena1 AVP-D strain is salt-resistant, even though its intracellular Na + content is 4-fold higher than that of the wild type. In ena1AVP1-D strains lacking either gef1 or nhx1 (i.e., ena1 gef1 or ena1 nhx 1), the Na + content is not reduced to the extent that it is in GEF1 NHX1 strain. Taken together, the genetic and physiological data are consistent with the model that Nhx1, Gef1 and Avp1 cooperate to sequester sodium internally.
The intracellular K + content correlates with salt tolerance and is inversely correlated with the Na + content of our strains (FIG. 1B). The wild-type K + concentration is ≈100 mM but is reduced to 20 mM in the ena1 mutant. Interestingly, in an ena1 strain that overexpresses the AVP1-D gene, the intracellular concentration of K + is restored almost to wild-type levels (FIG. 1B). However, AVP1-D overexpression fails to restore wild-type levels of intracellular potassium unless both NHx1 and GEF1 are functional (see the double mutants ena1 nhx1 or ena1 gef1 in FIG. 1B).
The NHX1 and GEF1 genes, which have been identified as important in sodium detoxification, are also required for the detoxification of other cations. Growth of gef1 and nhx1 mutants in the presence of toxic cations: Five-fold serial dilutions (starting at 10 5 cells) of the indicated strains were grown at 30° C. for 2 days on YPD (1% yeast extract/2% peptone/2% dextrose) with the addition of either 3 mM MnCl 2 , 0.45 M tetramethylammonium (TMA), or 0.05 mg/ml hygromycin B (HYG) as indicated.
For example, gef1 mutants are sensitive to 3 mM MnCl 2 , 0.45 M tetramethylammonium chloride and to 0.05 μg/ml hygromycin-B. The nhx1 mutant is also sensitive to tetramethylammonium chloride and hygromycin. The extreme sensitivity of the nhx1 mutant to hygromycin provides an important tool for assaying nhx1 function.
Gef1p and Nhx1p Colocalize. The sequestration model postulates not only a functional connection between the anion channel Gef1 and sodium exchanger Nhx1 but also predicts that these two proteins colocalize within a common compartment. Because previous studies indicated that Nhx1 localizes to a prevacuolar compartment (Nass and Rao, 1998), two types of experiments were performed to determine whether Gef1 and Nhx1 proteins colocalize to this compartment.
Distribution of fluorescence and immunodetection of subcellular fractions in gef1 nhx1 cells transformed with two constructs: a GEF1-GFP fusion and a NHX1-(HA) 3 -tagged fusion were determined. The strain RGY419 (gef1 nhx1) was transformed with plasmids pRG151; GEF1-GFP and pRIN73; NHX1-(HA) 3 . Transformants were grown in SD (Difco; synthetic medium with 2% dextrose). When the cells reached OD 600 =0.5, hygromycin B (Sigma) was added to a final concentration of 0.1 mg/ml and the cells were incubated for 40 min at 30° C. Cells were fixed and stained with antibodies to HA epitope and 4′,6-diamidino-2-phenylindole (DAPI). Cells were viewed by charge-coupled device microscopy and optically sectioned by using a deconvolution algorithm (Scanalytics, Billerica, Mass.) (Kennedy et al., 1997); (Bar=1 μm).
It was found that hemagglutinin (HA)-tagged Nhx1 and Gef1-GFP fusion protein colocalize as shown via epifluorescence deconvolution microscopy (FIG. 3A). Persistence of signal coincidence on 90° rotation of the image further supports colocalization of the two transporter proteins in these cells.
The colocalization of Nhx1 (HA) 3 and GEF1-GFP is also supported by the comigration of the two proteins in sucrose density gradients of membrane preparations obtained from cells expressing the tagged proteins. The strain RGY419 (gef1 nhx1) transformed with plasmids pRG151; GEF1-GFP and pRIN73; NHX1-(HA) 3 was grown in APG medium (Rodriguez-Navarro and Rea, 1984), converted to spheroplasts, lysed, and fractionated on a 10-step sucrose gradient (18-54%) as described (Sorin et al, 1997; Antebi and Fink, 1992). Western blots showed the distribution of Gef1-GFP and Nhx1-HA (see Example 1, Materials and Methods).
The sedimentation behavior of the membrane fraction containing both proteins is consistent with that of a prevacuolar compartment (Nass and Rao, 1998). Gef1-GFP (but not Nhx1) is also present in Golgi fractions, consistent with previous studies (Gaxiola et al., 1998; Schwappach et al., 1998).
An A. thaliana Homologue of NHX1 Functions in Yeast. The yeast strain described herein provides an important tool for identifying genes that mediate salt tolerance in other organisms. To test the utility of this system, a sequence from Arabidopsis (See Materials and Methods) with very high homology to the S. cerevisiae NHX1 ORF was identified and used an expressed sequence tag (see Materials and Methods) to obtain a full-length clone of this Arabidopsis gene. An alignment of the amino acid sequences of Nhx1 homologues from Arabidopsis (AtNhx1), human (HsNhe6), and yeast (ScNhx1) reveals segments of amino acid identity and similarity within predicted transmembrane domains (FIG. 2). However, it is important to note that despite these relationships, neither the N-terminal nor the C-terminal regions of AtNhx1 and ScNhx1 show a high degree of homology (FIG. 2). A characteristic of mammalian Na + /H + antiporters is their inhibition by amiloride. A putative amiloride binding site ( 163 DVFFLFLLPPI 173 ) (SEQ ID NO: 4) has been defined via point mutants in the human NHE1 antiporter gene (Counillon et al., 1993). AtNhx1, HsNhe-6 and ScNhx1 have an almost identical sequence (FIG. 2). However, our attempts to inhibit the activity of either Nhx1 or AtNhx1 in yeast cultures with amiloride were unsuccessful.
The extreme sensitivity of yeast nhx1 mutants to hygromycin permitted the testing of whether the cloned Arabidopsis AtNHX1 ORF could provide Na + /H + exchange function in yeast. Vector pAD4 (Ballester et al., 1989) was introduced into wild-type and nhx1 strains. Plasmid pRG308; ADH; AtNHX1 was introduced into nhx1 mutants as indicated. Five-fold serial dilutions (starting at 10 5 cells) of the indicated strains were grown at 30° C. for 2 days on YPD (−) or on YPD supplemented with 0.05 mg/ml hygromycin (+). Serial dilutions of the same strains were grown on APG medium (see Materials and Methods) (−) or on APG supplemented with 0.4 M NaCl (Rodriguez-Navarro and Ramos, 1984).
The At NHX1 gene is capable of suppressing the hygromycin sensitivity of the nhx1 mutant. The AtNHX1 gene also suppressed the NaCl sensitivity of nhx1 mutant but only under conditions in which the K + availability was reduced. However, AtAHX1 was not capable of rescuing the Na + -sensitive growth phenotype of the double mutant ena1 nhx1 overexpressing the AVP1-D gene.
Further support for the role of the Arabidopsis AtNHX1 gene in salt homeostasis came from an analysis of its expression in salt-stressed plants. Plants were grown for 15 days under standard conditions and then exposed for 6 h to either 250 mM NaCl or KCl. The NaCl stress increased AtNHX1 mRNA levels 4.2-fold, whereas KCl promoted only a 2.8-fold increase. This increase in mRNA level produced by sodium resembles that described for the yeast NHX1 gene (Nass and Rao, 1998). RNA tissue blot hybridized with AtNHX1. Ten micrograms of total RNA from 15-day old plants exposed to 250 mM NaCl or Kcl for 6 h and a control grown without salt was subjected to electrophoresis on a denaturing formaldehyde gel. The blot was hybridized with a probe internal to AtNHX1 ORF. An 18S ribosomal probe was used as a loading control.
Discussion
The studies described herein provide evidence for the importance of the prevacuolar pH for intracellular Na + sequestration in yeast. Overexpression of the plant H + -pyrophosphatase (AVP1) confers salt tolerance to yeast only in those strains containing a functional chloride channel (Gef1) and the Na + /H + exchanger (Nhx1).
These data support a model in which the Nhx1 Na + /H + exchanger acts in concert with the vacuolar ATPase and the GEF1 anion channel to sequester cations in a prevacuolar compartment. Several studies suggest that the prevacuolar compartment may be derived both from the plasma membrane and the late Golgi. These vesicles are likely involved in the assembly of the vacuole or delivery of cargo to this organelle. It is reasonable to expect that these prevacuolar vesicles detoxify cations by sequestration, thereby lowering their concentrations in the cytoplasm and in other organelles.
The yeast system described herein permits the functional assessment of diverse heterologous proteins in salt tolerance: chloride channels, H + pumps, and Na + /H + exchangers and other cation/H + exchangers or cation/bicarbonate symporters. The system is robust and flexible. The function of the Arabidopsis chloride channels (Gaxiola et al., 1998; Hechenberger et al., 1996), H + pump, and Na + /H + exchanger can be assayed in the corresponding yeast mutant. Despite the inability of At NHX1 to suppress all the phenotypes of the yeast nhx1 mutant, the fact that it suppresses some phenotypes, coupled with the DNA homology between AtNHX1 and yeast NHX1, indicates that the plant gene carries out a similar function to that of the yeast homologue. The observation that the AtNHX1 gene suppresses the sensitivity of the nhx1 mutant to hygromycin but provides only a weak Na + detoxification phenotype could be a consequence either of differential regulation of the transporters in the two organisms or of distinct cation transport selectivities.
The regulation of AtNHX1 by salt and the ability of the plant gene to suppress the yeast nhx1 mutant suggest that the mechanism by which cations are detoxified in yeast and plants may be similar. Indeed, previous work suggested that vacuolar sodium accumulation in salt-tolerant plants may be mediated by a tonoplast Na + /H + antiporter that utilizes the proton-motive force generated by the vacuolar H + -ATPase (V-ATPase) and/or H + -translocating pyrophosphatase (V-PPase; refs. Barkla et al., 1994; Zhen, et al., 1997; Kirsch et al., 1996).
The finding described herein that both gef1 and nhx 1 mutants are hypersensitive to hygromycin indicate that the level of resistance to hygromycin depends on the function of the vacuolar and prevacuolar organelles. Yeast mutants impaired in K + uptake (trk1) are hypersensitive to hygromycin (Madrid et al., 1998); reduced K + uptake hyperpolarizes the plasma membrane potential and drives the uptake of alkali cations such as hygromycin. Mutations that reduce the H + pumping activity of the plasma membrane H + -ATPase, Pma1, depolarize the plasma membrane potential and confer resistance to hygromycin (McCusker et al., 1987). Thus, mutants such as gef1 or nhx1 that affect the pH or membrane potential of the vacuolar and prevacuolar compartments may be expected to affect hygromycin compartmentation.
Transgenic plants that overexpress the AtNHX1 were generated using Agrobacterium -mediated plant transformation. The transgenic AtNHX1 was expressed using a double tandem enhancer of the 35S promoter of CaMV (Topfer et al., 1987). T3 transgenic plants are less affected than wild type controls when watered with 300 mM NaCl.
15 wild-type plants and 15 35SAtNHX1 transgenic were grown on a 12 hours-day cycle for 20 days. During this period plants were watered every 5 days with a diluted nutrient solution (⅛ M.S. salts). 200 mM NaCl was added to the watering solution at day 21 and at day 33 plants were watered with a nutrient solution containing 300 mM NaCl. Plants were photographed 10 days after the last NaCl treatment.
Transgenic plants that overexpress AVP1 were generated using Agrobacterium -mediated plant transformation. The transgenic AVP1 was expressed using a double tandem enhancer of the 35S promoter of CaMV (Topfer et al., 1987). 15 wild-type plants and 15 35SAVP1 transgenics were grown on a 24 hours-day cycle for 16 days. During this period plants were watered every 4 days with a diluted nutrient solution (⅛ M.S. salts). 200 mM NaCl was added to the watering solution at day 17 and at day 27 plants were watered with nutrient solution containing 250 mM NaCl. Plants were photographed 10 days after the last NaCl treatment. Identical conditions and treatment as described in Example 2 were used.
These transgenic plants are larger than wild-type plants. Furthermore, homozygous 35SAVP1 plants show sustained growth in the presence of 250 mM NaCl plus ⅛ M.S. salts when grown in a 24 hours light regimen. Interestingly, when 35SAVP1 plants were grown under short-day cycle conditions (12 hour day/light cycle) sustained growth in the presence of 300 mM NaCl plus ⅛ M.S. salts was observed.
Hydroponically grown wild type and 35SAVP1 transgenic plants were generated. 65 days old wild type and 35SAVP1 transgenic plants grown in solution culture on a 12 hour light cycle.
Wild type and 35SAVP1 transgenic plants were also grown in solution culture on a 12 hours light cycle for 20 days. Starting at day 21, NaCl concentration was increased in a stepwise fashion by 50 mM increments every 4 days. Plants were photographed after 4 days in the presence of 200 mM NaCl.
Materials and Methods
Quantitative RTF-PCR. Arabidopsis thaliana plants were germinated in half-strength MS medium for 2 weeks, and then transferred to 10 μM Pi plates for 0-48 h. Total RNA was isolated from seedlings (10-15 seedlings per sample) with TRI-reagent (Molecular Research Center, Cincinnati, Ohio, USA), according to the manufacturer's manual. After being treated with DNase I (DNA-free Kit, Ambion, Austin, Tex., USA), 1 μg of each RNA sample was used to synthesize cDNA with an iSript cDNA Synthesis Kit (Bio-Rad Laboratories, Hercules, Calif., USA) in a total volume of 20 μL at 41° C. for 1h.
RTF-PCR was performed in a LightCycler 2.0 (Roche Applied Science, Mannheim, Germany), in a total volume of 25 μL containing 0.1 mL RT reaction (diluted into 5 μL) as template, using a LightCycler FastStart DNA MasterPLUS SYBR Green I Kit, according to the manufacturer's manual (Roche Applied Science). The transcription levels of AtPT1, AVP1 and AHAs genes were normalized to ACT2. The following are the specific primer pairs for the different genes designed with LightCycler Probe Design2 software (Roche Applied Science): ACT2, 5′CCCGCTATGTATGTCGC3′ (SEQ ID NO: 8) and 5′TCCAGCAAGGTCAAGACG3′ (SEQ ID NO: 9); AtPT1, 5′CCTCCTCAAGTTGACTACATT3′ (SEQ ID NO: 10) and 5′CTCGATATCTGTTTGTAAGACCT3′ (SEQ ID NO: 11); AVP1, 5′GTTTCGTCACTGAGTACTACAC3′ (SEQ ID NO: 12) and 5′TCATGATAGCAATAGCAAAGATTGGA3′ (SEQ ID NO: 13); AHA1, 5′TCCATCCCTGTTGAGGAGT3′ (SEQ ID NO: 14) and 5′ATATCTGCTTTCTTCAAAGCGG3′ (SEQ ID NO: 15); AHA2, 5 40 ATTGACGGCAGTGGTAAC3′ (SEQ ID NO: 16) and 5′CGAGCAACAGCCAACGA3′ (SEQ ID NO: 17); AHA6, 5′AGATGAGATAATTGACAAGTTTGCT3′ (SEQ ID NO: 18) and 5′TCTGCACTGTCATGTCTTGGA3′ (SEQ ID NO: 19). Their specificity was confirmed by BLASTN in the National Center for Biotechnology Information (NCBI).
Western blot analysis. Seeds of A. thaliana plants were germinated in half-strength MS medium for 2 weeks, and then transferred to 10 μM Pi plates. Samples of seedlings (1-3 g) were taken at different time points (0, 2, 4 and 6 days), and membrane protein was extracted as described elsewhere (Schumaker and Sze, 1985). The protein concentration was determined using the bicinchoninic acid (BCA) protein assay reagent (Pierce, Rockford, Ill., USA); 15 mg per sample was electrophoretically resolved in 12% Tris-HCl-sodium dodecylsulphate (SDS) gel (Bio-Rad Laboratories) and transferred to Immobilon-P transfer membrane (Millipore, Bedford, Mass., USA). Membranes were incubated for 1.5 h with an antiserum raised against a synthetic peptide corresponding to the putative hydrophilic loop IV of the AVP1 protein (Rea et al., 1992) or with a polyclonal antiserum raised against Arabidopsis P-ATPase (Bouche-Pillon et al., 1994). After 1.5 h of incubation with a secondary antibody conjugated with alkaline phosphatase, the membranes were treated with a nitroblue tetrazolium-5-bromo-4-chloroindol-3-yl phosphate (NBT/BCIP) substrate solution (Roche, Indianapolis, Ind., USA) for staining.
pAVP1:GUS construct. DNA from Bac (F7H2) containing the AVP1 promoter region was employed to amplify a 1.7-kb fragment upstream to the ATG codon using the following primers: sense, 5′GCTCTAGACGTTTACCACACCAGTCACCAC3′ (SEQ ID NO: 20) with an XbaI restriction site at the 5′ end; antisense, 5′CGGGATCCCTTCTCTCCTCCGTATAAGAGA3′ (SEQ ID NO: 21) with a BamHI restriction site at the 5′ end. The amplified ˜1.7-kb AVP1 promoter was ligated to the pGEM-T vector (Promega, Madison, Wis., USA), sequenced, and then subcloned into the XbaI/BamHI site of the pBC308 vector in front of the GUS open reading frame (Xiang et al., 1999). The vector pBC308 contains the Bar gene (phosphinothricin acetyltransferase) for selection with the herbicide phosphinothricin (BASTA).
Transformation and selection. The construct was transformed into Agrobacterium tumefaciens strain GV3101, and then introduced into A. thaliana Col-0 ecotype via the floral dip method (Clough and Bent, 1998). Plants transformed with the pAVP1:GUS cassette were seeded in soil and selected by spraying with BASTA (T1). Seeds obtained from self-pollinated transformants (T2) were scored again for herbicide resistance on soil. Complete BASTA resistance identified homozygous pAVP1::GUS plants of the T3 progeny.
Results and Discussion
The transcription and translation of AVP1 and P-ATPases (also known as “Autoinhibited H + -ATPases,” or AHAs), normally expressed in roots (Arango et al., 2003; Gaxiola et al., 2007) under limiting Pi conditions, were monitored. AVP1 and representative AHA mRNA abundance was assessed in wild-type Arabidopsis plants transferred to limiting Pi conditions by quantitative RTF-PCR. AVP1 mRNA induction peaked 12 h after the transfer of the seedlings to limiting Pi, AHA1 showed no change, and both AHA2 and AHA6 expression peaked 12 h after AVP1 (FIG. 6A). Transcription of the phosphate transporter AtPT1, which is induced under low-phosphate conditions (Muchhal et al., 1996), was up-regulated within 3 h of limiting Pi conditions (FIG. 6A). The induction of AVP1 expression by limiting Pi was confirmed with an AVP1 promoter-β-glucuronidase (AVP1::GUS) reporter transformant. This behavior is consistent with the presence of potential cis regulatory Pi response elements in the 1.7-kb promoter region used to generate the AVP1::GUS reporter (i.e. one PRH1 element at position −540; two TC elements at positions −79 and −103). These elements are present in genes whose expression has been shown to be up-regulated under limiting Pi conditions (reviewed in Hammond et al., 2004). Western blots of microsomal fractions probed with polyclonal antibodies raised against AVP1 and H + -ATPase (FIG. 6B), and the relative densities of each confirmed expression (FIG. 6C), showed that the abundance of both H + pumps was increased fourfold and twofold, respectively, by Pi starvation. These results suggest that increased AVP1 expression precedes an increase in the abundance of AHA2 and AHA6H + -ATPases.
Materials and Methods
Arabidopsis growing conditions. The control Arabidopsis plants and AVP1OX plants (Gaxiola et al., 2001) used in this work were of the Col-0 ecotype. Seeds were surface sterilized and imbibed overnight at 4° C. before being sown on agar medium, or soil, or rock wool for hydroponic growth. For plants grown on agar, half-strength Murashige and Skoog (MS) medium (Murashige and Skoog, 1962) and Pi-free medium (Estelle and Somerville, 1987; Hartel et al., 2000) were used with 1% sucrose and 0.8% or 1% agar (Micropropagation/Plant Tissue Culture Grade, PhytoTechnology Laboratories, Shawnee Mission, Kans., USA). Pi-free medium contains 20 mM 2-(N-morpholino) ethanesulphonic acid (MES) (pH 5.8), 5.0 mM KNO 3 , 2.0 mM MgSO 4 , 2.0 mM Ca(NO 3 ) 2 , 50 μM iron ethylenediaminetetraacetate (Fe-EDTA), 70 μM H 3 BO 3 , 14 μM MnCl 2 , 0.5 μM CuSO 4 , 1.0 μM ZnSO 4 , 0.2 μM NaMoO 4 , 10 μM NaCl and 0.01 μM CoCl 2 . The Pi concentration was adjusted with KH 2 PO 4 . All experiments were performed with agar (PhytoTechnology Laboratories) that had no detectable trace Pi contamination, as determined by the method of Murphy and Riley (1962).
Lateral root, root length and root hair measurements. Root lengths were measured directly with a ruler. The lateral root number and the root hair number were counted under an Olympus SZ40 stereomicroscope (Tokyo, Japan). Root hair photographs were taken and printed, and the root hair lengths on the photographs were measured with a ruler. The final values were converted to the actual size of the root hair.
Results and Discussion
To examine whether the root systems of AtAVP1 OX plants were capable of responding to low Pi, control and AtAVP1 OX seeds were germinated under Pi-deficient (10 μM) conditions and their root development was analyzed. AtAVP1 OX seedlings developed more robust root systems than wildtype controls under Pi limitation. At 20 days, AtAVP1 OX roots were longer and had developed an average of seven more lateral roots than controls (P<0.01). Root hairs were also 2.5-fold larger and 1.5-fold denser than those of controls under Pi-deficient conditions (P<0.01), increasing the absorptive area of the roots. Primary root apical cell proliferation was monitored in control and AtAVP1 OX plants germinated under Pi-deficient and Pi-sufficient conditions using a CycB1::CDBGUS reporter associated with meristem activity/indeterminacy (Li et al., 2005). Cell proliferation, a result of meristem activity, in both AtAVP1OX and wild-type plants was curtailed in Pi-deficient conditions, but the switch to determinate growth, indicated by a loss of CycB1::CDBGUS activity, was delayed for 3-4 days in AtAVP1 OX plants.
Materials and Methods
Arabidopsis growing conditions. Arabidopsis was grown as described in Example 6. For hydroponically grown plants, the conditions described by Gibeaut et al. (1997) were followed.
Root acidification. Plants were germinated in half-strength MS medium for 7 days, transferred to low-Pi medium as described above with 1 mM MES, pH 6.8 and 0.04 g/L bromocresol purple, and incubated for 10 days. The pH change was visualized via changes in medium color. Comparisons were made with a colour bar generated by documenting the color change of bromocresol purple in the same medium at specific pH values.
Pi uptake determination. Pi uptake experiments were performed in 125-mL flasks wrapped with aluminium foil. Plants grown hydroponically were used 2 weeks after bolting. After 2 days of incubation in distilled water, the plants were transferred to the flasks filled with 120 mL of medium supplemented with 50 μM Pi. The solution volume was maintained by adding distilled water every 4 h. The Pi concentrations in the medium were determined at 8-h increments for 96 h using the method of Murphy and Riley (1962). This method can determine Pi concentrations as low as 1 μM in seawater, and the salt error is less than 1%.
Pi determination. Plant samples were placed in glass scintillation vials and dried at 70° C. for 72 h. The fresh and dry weights were determined on an analytical balance. The samples were ashed at 500° C. for 6 h. The ash samples were dissolved in 1 N HCl, and the Pi contents were determined using a colorimetric method (Murphy and Riley, 1962).
Results and Discussion
The more robust root systems developed by AtAVP1 OX plants would be expected to increase the acidification of Pi-deficient medium, resulting in more efficient scavenging of Pi. To test this hypothesis, wild-type and AtAVP1 OX plants were transferred from Pi-sufficient to Pi-deficient medium. A visual examination of the plates showed that AtAVP1OX plants had a greater capacity than wild-type controls to acidify the medium, as indicated by the intense yellow color of the pH indicator dye. Rhizosphere acidification was completely inhibited in wild-type and AtAVP1OX plants by 1 mM vanadate, consistent with the inhibition of plasma membrane H + -ATPase activity (Yan et al., 2002). Enhanced Pi uptake, measured as Pi depletion from defined hydroponic medium, was visible in both AtAVP1-1 and AtAVP1-2 over-expression transformants within 8 h of incubation, with AtAVP1-1 exhausting the available Pi almost 30 h earlier than AtAVP1-2. Total depletion of Pi by control plants was not observed at any time point.
AtAVP1OX plants also exhibited enhanced growth and Pi uptake when grown on solid Pi-deficient medium (Table I). AtAVP1OX seedlings germinated and grown in Pi-deficient medium for 20 days exhibited 1.6-fold more root and 1.3-fold more shoot biomass than controls (P<0.01). The Pi content (per plant) was 1.4-fold higher in AtAVP1OX plants than in controls (P<0.01), suggesting that AtAVP1OX plants acquire more Pi and grow accordingly (Gilooly et al., 2005; Hermans et al., 2006). Consistent with the Pi limitation of organismal growth, the Pi content (mmol/g dry weight) of AtAVP1 OX plants grown either at normal or restrictive Pi conditions was no different from controls (Table I).
Materials and Methods
Arabidopsis growing conditions. Arabidopsis was grown as described in Example 6. The composition and pH of the natural low-Pi soil used were analyzed by the Soil Nutrient Analysis Laboratory of the University of Connecticut (pH 6.1; P, 0.5 p.p.m.; K, 123 p.p.m.; Ca, 467 p.p.m.; Mg, 74 p.p.m.; soil texture classification, sandy loam). Pi-free medium with different KH 2 PO 4 concentrations was used to water plants grown in low-Pi soil. Plants were grown in growth chambers with a 16-h light/8-h dark cycle at 21° C. For rock phosphate experiments, plants were grown in sand with a 1:1000 w/w P 2 O 5 /sand ratio as the only source of Pi, and flooded regularly with Pi-free medium.
Leaf area. The rosette leaves were carefully excised with a scalpel blade, and the leaf areas were measured with a Li-Cor 4100 area meter (Lincoln, Nebr., USA).
Results and Discussion
To determine whether the enhanced root systems seen in AVP1 OX plants confer
| TABLE I | |||||
| Effect of Pi availability on growth and Pi content of AtVVP1OX transgenic and Col-0 plants a | |||||
| Genotype & | Root FW | Shoot FW | Total P (content | Total P content | |
| conditions | (mg) | (mg) | Root:shoot | (μg/plant) | (mmol/g DW) |
| 1 mM P | |||||
| Col-0 | 0.79 ± 0.27 | 3.77 ± 0.72 | 0.21 ± 0.043 | 3.75 ± 0.41 | 0.071 ± 0.013 |
| AVP1-1 | 1.25 ± 0.46** | 4.38 ± 0.92* | 0.28 ± 0.066** | 4.60 ± 0.12** | |