WO2011038389A2

WO2011038389A2 - Methods of reducing plant stress

Info

Publication number: WO2011038389A2
Application number: PCT/US2010/050520
Authority: WO
Inventors: Brian B. Goodwin
Original assignee: Floratine Biosciences, Inc.
Priority date: 2009-09-28
Filing date: 2010-09-28
Publication date: 2011-03-31
Also published as: EP2482638A2; US8597395B2; CN102958347B; JP2013505964A; US20140087948A1; US20110078816A1; CL2012000775A1; AU2010297937B2; IN2012DN02849A; WO2011038389A9; EP2482638A4; CA2775468A1; AR081604A1; JP2016154544A; AU2010297937A1; JP5976543B2; CN102958347A

Abstract

A method of regulating plant genes is provided. The method provides improved drought stress or salinity stress for plants. The method comprises treating a part of a plant or the locus thereof with a composition of matter, the composition of matter comprising an agriculturally acceptable mixture of compounds of natural organic material of defined composition.

Description

METHODS OF REDUCING PLANT STRESS

Technical Field

[0001] The present invention relates to composition of matter for improving stress resistance in plants. Specifically, the method comprises contacting a part of a plant or the locus thereof with a composition of matter comprising an agriculturally acceptable complex mixture of dissolved organic material characterized by natural organic matter that is partially humified.

BACKGROUND

[0002] Various mixtures of organic compounds have been proposed in the art as fertilizer additives. Specifically, a humic acid composition, Bio-Liquid Complex™, is stated by Bio Ag Technologies International (1999) www.phelpstek.com/portfolio/humic_acid.pdf to assist in transferring micronutrients, more specifically cationic nutrients, from soil to plant.

[0003] TriFlex™ Bloom Formula nutrient composition of American Agritech is described as containing "phosphoric acid, potassium phosphate, magnesium sulfate, potassium sulfate, potassium silicate[and] sodium silicate." TriFlex™ Grow Formula 2-4- 1 nutrient composition of American Agritech is described as containing "potassium nitrate, magnesium nitrate, ammonium nitrate, potassium phosphate, potassium sulfate, magnesium sulfate, potassium silicate, and sodium silicate." Both compositions are said to be "fortified with selected vitamins, botanical tissue culture ingredients, essential amino acids, seaweed, humic acid, fulvic acid and carbohydrates." See

www.horticulturesource.com/product_info.php/products_id/82. These products are said to be formulated primarily for "soilless hydrogardening" (i.e., hydroponic cultivation) of fruit and flower crops, but are also said to outperform conventional chemical fertilizers in container soil gardens. Their suitability or otherwise for foliar application as opposed to application to the hydroponic or soil growing medium is not mentioned. See

www.americanagritech.com/product/product_detail.asp?ID= I &pro _id_pk= -0.

[0004] The trademark Monarch™, owned by Actagro, LLC is a fertilizer composition containing 2-20-15 primary plant nutrients with 3% non plant food organic compositions derived from natural organic materials.

[0005] Plants in general are susceptible to a variety of environmental stresses, including for example, drought, salinity, low light, water logging, disease, pests, and temperature. Conventional nutritional plant treatments are generally unable or incapable of providing plants with resistance to environmental stresses and are therefore are limited to providing benefit to otherwise healthy or flourishing plants. However, commercial agronomical processes require additional plant treatments to reduce plant stress or enhance the plants ability to resist common environmental stresses and/or to recover from such stresses quickly. Typical examples of common environmental stresses include continuous periods without water (drought), exposure to salt water, flooding, prolonged darkness, and temperature variations/frost. Exposure to such stresses generally can result in poor or no yields, but also can display reduced root growth, and/or reduced leaf growth or count, and/or reduced stalk weight and/strength, and/or reduced fruit size and/or weight and/or nutritional value. While a plant may possess some natural defenses to such stresses, there is a need to provide to plants enhanced abilities to respond and/or recover to such stresses to allow for maximizing agronomical production.

SUMMARY

[0006] Compositions of matter (hereafter also referred to as "CP"; CAS Reg. No.1175006- 56-0) providing plants enhanced stress resistance abilities so as to respond and/or recover to environmental stresses and allow for maximizing agronomical production. The disclosed compositions of matter provide for gene regulation in plants that improve and/or enhance the plants responses to common environmental stresses. This gene regulation includes, among other mechanisms, regulation of transcription factors. Application of CP to a plant prior, during, or shortly thereafter a stress condition improves the plant's ability to resistant and/or recover argronomically from the stress as compared to a similarly situated plant not treated with CP.

[0007] Greenhouse and field experiments have demonstrated that CP can promote plant growth and development so as to increase crop yields. Physiological studies indicate that the composition of matter disclosed herein provides improved nutrient availability and mobility inside the plants. Additionally, CP augments synthesis or availability of plant hormones, and/or CP possesses synergetic actions with some of these plant hormones. At the molecular level, plant growth and development activities are controlled and/or influenced by genes and gene expression. It is likely that CP acts through triggering or altering the expression of critical genes involved in plant growth, development, stress tolerance, and/or disease resistance.

[0008] The potent effects of the above-mentioned compositions of matter on plant gene expression provides for wide application of these products in agriculture, horticulture, and landscaping.

BRIEF DESCRIPTION OF THE FIGURES

[0009] FIG. 1. Photograph representing the effect of a CP composition application on Arabidopsis root formation vs. control;

[00010] FIG. 2. Photograph representing the effect of a CP composition application on Arabidopsis growth vs. control under normal conditions;

[00011] FIG. 3. Photograph representing the effect of a CP composition application after salinity stress on Arabidopsis growth and development vs. control;

[00012] FIG. 4. Photograph representing the effect of a CP composition application before salinity stress on Arabidopsis growth vs. control;

[00013] FIG. 5. Photograph representing the effect of a CP composition application on Arabidopsis drought tolerance vs. control;

[00014] FIG. 6. RNA preparation quality as determined by BioAnalyzer;

[00015] FIG. 7. Genome-wide expression profile of Arabidopsis after CP application vs. control;

[00016] FIG. 8. Gene Expression Profile of Arabidopsis genes with expression levels changed >1.5 fold at p- value < 0.01 after CP application vs. control;

[00017] FIG. 9. Volcano Plot of Arabidopsis genes with expression levels changed >1.5 fold at p-value < 0.01 after CP application vs. control;

[00018] FIG. 10. Heatmap of CP-regulated Arabidopsis genes compared to control;

[00019] FIG. 11. Gene Expression Profile of Arabidopsis genes with expression levels changed >1.5 fold at p-value < 0.01 after CP 1000 application vs. control;

[00020] FIG. 12. Volcano Plot of Arabidopsis genes with expression levels changed >1.5 fold at p-value < 0.01 after CP 1000 application vs. control;

[00021] FIG. 13. Heatmap of CP 1000-regulated Arabidopsis genes compared to control;

[00022] FIG. 14. Graph of the effect of a CP composition application on Arabidopsis drought tolerance vs. control;

[00023] FIG. 15. Graph of the effect of a CP composition application on Arabidopsis salinity tolerance vs. control;

[00024] FIG. 16. Graph and photo of the effect of a CP composition application on Arabidopsis wilting drought tolerance vs. control;

[00025] FIG. 17. Schematic of the Arabidopsis gene analysis after a CP composition treatment vs. control;

[00026] FIG. 18. Schematic of the shared up regulated Arabidopsis gene by a CP composition compositions;

[00027] FIG. 19. Schematic of the shared down regulated Arabidopsis gene by a CP composition compositions.

DETAILED DESCRIPTION

Materials and Methods

[00028] The composition of matter disclosed herein comprises a mixture of organic molecules isolated and extracted from sources rich in natural organic matter into an aqueous solution. The natural organic matter is primarily derived from plant materials that have been modified to varying degrees over time in a soil environment. Some of the plant materials have been recently deposited in the environment. At least a part of the natural organic matter has passed through a partial process of humification to become partially humified natural organic matter. Humification includes microbial, fungal, and/or environmental (heat, pressure, sunlight, lightning, fire, etc.) degradation and/or oxidation of natural organic matter. Most preferably, CP contains natural organic matter that has not substantially undergone humification (partially humified natural organic matter). In one aspect, the natural organic matter is obtained from environments typically containing or providing 5 ppm, 10 ppm, 15 ppm, 20 ppm, 25 ppm, 30 ppm, 35 ppm, 40 ppm, 45 ppm, 50 ppm, 55 ppm, 60 ppm, 65 ppm, 70 ppm, 75 ppm, 80 ppm, 85 ppm, 90 ppm, 95 ppm, 100 ppm, or up to 500 ppm of dissolved organic matter (DOM). In other aspects, the natural organic matter is obtained from environments typically containing or providing about 500 ppm, 1000 ppm, 1500 ppm, 2000 ppm, 2500 ppm, 3000 ppm or more DOM.

[00029] Natural organic matter is extremely complex, with thousands of compounds generally present, depending upon the source and the environmental conditions prevalent about the source. Humic substances such as Fulvic Acid (CAS Reg. No. 479-66-3) and Humic Acid (CAS Reg. No. 1415-93-6) are examples of organic complexes that are derived from natural organic matter, however, CP is chemically and biologically unique from Fulvic and Humic acid, as detailed below.

[00030] CP contains dissolved organic matter, the organic matter being formed during the process of humification as described above, such as microbial, fungicidal, and/or

environmental (heat, pressure, sunlight, lightning, fire, etc.) degradation processes. Other natural or synthetic natural organic matter degradation processes may be involved or may be used. In one aspect, CP contains predominately natural organic matter that has not undergone substantial humification (e.g., partially humified natural organic matter). The amount of humification may be determined and characterized using known methods, for example, by 13C MR.

[00031] In one aspect, CP is obtained by removing a natural organic matter from its source, optionally processing, and/or concentrating to provide a CP composition having a dissolved organic matter (DOM) concentration level of about 10X, 25X, 50X, 100X, 200X, 300X, 400X, 500X, 600X, 700X, 800X, 900X, 1000X, 1500X, 2000X, 2500X, 3000X, 3500X, 4000X, 4500X, or 5000X relative to its original source. In another aspect, CP concentrations of dissolved organic matter (DOM) concentration level can be about 7500X, 10,000X, 15,000X, 20,000X, 25,000X, and up to 50,000X. CP compositions may be adjusted such that the concentration of DOM is between about 10 ppm to about 700,000 ppm. Preferably, CP may be adjusted such that the concentration of DOM is between about 1000 ppm to about 500,000 ppm. CP compositions may be adjusted to a DOM value represented by any ppm value between 1000 ppm and 50,000 ppm, inclusive of any ppm value in 500 ppm increments (e.g., 10,500 ppm, 1 1,000 ppm, 1 1,500 ppm, 12,000 ppm, etc.) in aqueous solution. Other DOM concentrations may be used, for example, an extremely concentrated composition of between about 75,000 ppm and about 750,000 ppm can be prepared. For example, a concentrate of about 30,000X that of the original source can contain about 550,000 ppm of DOM. In certain aspects, CP compositions are approximately between about 91% to about 99% water, the remaining organic material being primarily DOM with minor amounts of alkali-, alkali earth-, and transition metal salts. In yet other aspects, the DOM of the CP composition has been dried or lyophilized in a form suitable for reconstitution with an aqueous solution.

[00032] CP compositions contain a complex mixture of substances, typically a

heterogeneous mixture of compounds for which no single structural formula will suffice. Detailed chemical and biological testing has shown that CP is a unique composition both in its biological effect on plants and its chemical composition compared to Humic and Fulvic acids. Elemental and spectroscopic characterization of CP material differentiates it from most other humic -based organic complexes, such as Humic and Fulvic Acids, as further discussed below. Blending of CP compositions may be performed to provide consistency of material and to compensate for the normal variations of a naturally-derived material.

[00033] CP compositions may be applied to the seed, foliage, or to any other part of the plant or its locus. Application rate of CP can be between about 0.01 gram/hectare to about 10.0 gram/hectare dry weight, between about 0.2 gram/hectare to about 2.0 gram/hectare dry weight, between 0.3 gram/hectare to about 1.5 gram/hectare dry weight, or between about 0.4 gram/hectare to about 1.0 gram/hectare dry weight applied in the soil or as a foliar application to the foliage or the locus of the plant.

Characterization Methods

[00034] The organic compounds making up CP can be characterized in a variety of ways (e.g., by molecular weight, distribution of carbon among different functional groups, relative elemental composition, amino acid content, carbohydrate content, etc.). In one aspect, CP was characterized relative to known standards of humic -based substances.

[00035] For purposes of characterizing carbon distribution among different functional groups, suitable techniques include, without limitation, 13C-NMR, elemental analysis, Fourier transform ion cyclotron resonance mass spectroscopy (FTICR-MS) and Fourier transform infrared spectroscopy (FTIR). The chemical characterization of CP and Humic substance standards were carried out using Electro spray Ionization Fourier Transform Ion Cyclotron Resonance Mass Spectroscopy (ESI-FTICR-MS), Fourier Transform Infrared Spectroscopy (FTIR) and elemental analysis for metals using ICP-AES, conducted by Huffman Laboratories, Inc. and the University of Washington.

[00036] Elemental, molecular weight, and spectroscopic characterization of CP is consistent with an organic complex that consists primarily of lignin and tannin compounds (and mixtures of condensed and un-condensed tannin), condensed aromatics and trace amounts of lipid and inorganics. Thousands of compounds are present, with molecular weights ranging from 225 to 700 daltons, the majority of compounds having between about 10 to about 39 carbon atoms per molecule. CP compositions are generally composed of carbon, oxygen, and hydrogen, with small amounts of nitrogen, and sulfur. CP compositions may also contain potassium and iron at levels above 5%. [00037] The elemental composition of the dissolved solids typically present in CP compositions is given in Table A. If the organic compounds are separated from the i

elements, the elemental breakdown is: C 55%, H 4%, O 38%, N 1.8%, and S 2.2%.

Table A. Average Elemental Composition of dissolved solids, based upon average values from 10 different CP lots.

[00038] Among the classes of organic compounds present in CP, analysis generally reveals that there are lignin and tannin (mixture of condensed and un-condensed), condensed

aromatics, unidentified substances and some lipids present. In one aspect, the CP

composition is characterized in that at least 10% of the total % compounds present in the CP composition is tannins and/or condensed tannins. In another aspect, the CP composition is characterized in that at least 15% of the total % compounds present in the CP composition is tannins and/or condensed tannins. In another aspect, the CP composition is characterized in that at least 20% of the total % compounds present in the CP composition is tannins and/or condensed tannins. Each of these classes of compounds is further characterized by a rather narrow Mw range and number of carbons/molecule. The breakdown of the number and

percentage of each of the various compound classes, their MW's and carbon atoms/molecule

(Carbon Range) for a representative samp] ing of CP is given in Table B 1.

Compound Class # Compounds; % of Total Size Range (daltons) Carbon Range ; Lignin 1139 57 226 - 700 11 to 39

Tanni n 587 30 226 - 700 10 to 31

Condensed Aromatic 220 11 238 - 698 13 to 37

: Lipid 18 1 226 - 480 14 to 30

Carbohydrate 1 0 653 24

\ Other 23 1 241 - 651 12 to 33

Table Bl . Compound Classes in CP along with size and carbon ranges for compounds in

each class. Based upon composite of 3 different production batches. Results for individual batches are very similar.

[00039] A breakdown of the number and percentage of each of the various compound classes, their MW's and carbon atoms/molecule (Carbon Range) for a second representative sampling based upon an average of 3 different production batches for the composition of matter is given in Table B2.

[00040] Table C, summarizes the oxygen-to-carbon (O/C) and hydrogen-to-carbon (H/C) ratios used in defining the classes described above. In one aspect, the CP composition is characterized in that the O/C ratio of the dissolved organic matter is greater than about 0.4 as measured by mass spectroscopy. In one aspect, the CP composition is characterized in that the H/C ratio of the dissolved organic matter is greater than about 0.8 as measured by mass spectroscopy. In another aspect, the CP composition is characterized in that the H/C ratio of the dissolved organic matter is greater than about 0.85 as measured by mass spectroscopy.

Table C. Elemental Ratios and chemical classifications used in characterizing CP samples.

Comparison of CP with Humic Substance Standards

[00041] Comparative elemental and structural characterization of Humic Substances verses CP was performed. Three humic substances standards from the International Humic Substances Society were used: Leonardite Humic Acid (LHA), Pahokee Peat Humic Acid (PPHA), and Suwannee River Fulvic Acid II (SRFA). Each humic substance standards and each CP sample was analyzed by FTIR and ESI-FTICR-MS. A portion of each humic substance standard was dissolved in NH₄OH/water for the ESI-FTICR-MS analysis. Three samples of CP (CP#60, CP#75, and CP#99) were prepared for analysis with cation exchange resin (AG MP-50, Bio-Rad Laboratories, Hercules, CA). Three samples of the composition of matter (CP#1,CP #2, and CP#3) were prepared for analysis with cation exchange resin (AG MP-50, Bio-Rad Laboratories, Hercules, CA). Comparison of the Humic Substance standards and each sample of the composition of matter is presented in Table D.

[00042] Table D indicates that there are major differences between the Humic Substances standards and the CP samples. For example, the O/C ratio is less than 0.4 in all of the Humic Substances but is over 0.5 for the CP samples. The DBE for the CP samples is also significantly lower than for the Humic Acid Standards and the average MW is greater.

[00043] Based on mass spectral analysis, there are a number of compounds present in the CP samples that are substantially absent or greatly reduced in the Humic Substance standards. In particular, at least one component of CP may correspond with one or more tannin compounds. By comparison, in the Humic Substance standards, %tannin compounds are present in a small amount. For example, in the Fulvic Acid standard and in the Humic Acid standards, both standards are at least 3X-4X less than the % tannins found in the CP samples, as shown in Table E.

CP#60 441 35.2

CP#75 357 34.6

CP#99 432 28.3

Table E. Number and % tannins in Humic Substance Standards

verses CP.

[00044] Comparing the Fourier Transform Infrared (FTIR) spectra for the IHSS standards and CP samples, there are similarities, primarily in the region from 1600 to 1800 cm^"1. In both sets of samples we see a very strong peak at around 1700 cm^"1 due to the C=0 stretch from a carboxyl functional group and a peak in the 1590 to 1630 region which is consistent with a C=C bond from alkenes or aromatics. However, significant differences in the region from 700 to 1450 cm^"1 are observed. Peaks at 1160 to 1210 are present in all the spectra and are from the C-0 bond of alcohols, ethers, esters and acids. The biggest difference is the peak at 870 cm^"1 in the CP samples, which is absent in the IHSS standards. This peak may be due to the C-H bond of alkenes and aromatics.

[00045] Based on the above chemical, elemental and structural characterization, CP is chemically and biologically unique from Humic and Fulvic acids or combinations thereof. Further, as a result of the nature and extent of gene regulation and over all effect of CP with respect to improved plant health, drought and salinity stress resistance, CP is unique to that of known humic and/or fulvic acid compositions and treatments, for which such stress resistant activity and gene regulation properties are generally lacking in quality and quantity. Other beneficial plant function attributes of CP may be present or result from the methods of treatment and/or the gene regulation obtained from CP.

[00046] Based on the characterization data, the CP may contain relatively small molecules or supramolecular aggregates with a molecular weight distribution of about 300 to about 18,000 daltons. Included in the organic matter from which the mixture of organic molecules are fractionated are various humic substances, organic acids and microbial exudates. The mixture is shown to have both aliphatic and aromatic characteristics. Illustratively, the carbon distribution shows about 35% in carbonyl and carboxyl groups; about 30% in aromatic groups; about 18% in aliphatic groups, about 7% in acetal groups; and about 12% in other heteroaliphatic groups.

[00047] In some embodiments, the mixture of compounds in the CP comprises organic molecules or supramolecular aggregates with a molecular weight distribution of about 300 to about 30,000 daltons, for example, about 300 to about 25,000 daltons, about 300 to about 20,000 daltons, or about 300 to about 18,000 daltons.

[00048] Characterizing carbon distribution among different functional groups, suitable techniques can be used include without limitation 13C-NMR, elemental analysis, Fourier transform ion cyclotron resonance mass spectroscopy (FTICR-MS) and Fourier transform infrared spectroscopy (FTIR).

[00049] In one aspect, carboxy and carbonyl groups together account for about 25% to about 40%, for example about 30% to about 37%, illustratively about 35%, of carbon atoms in the mixture of organic compounds of the CP.

[00050] In another aspect, aromatic groups account for about 20% to about 45%, for example about 25% to about 40% or about 27% to about 35%, illustratively about 30%, of carbon atoms in the mixture of organic compounds of the CP.

[00051] In another aspect, aliphatic groups account for about 10% to about 30%, for example about 13% to about 26% or about 15% to about 22%, illustratively about 18%, of carbon atoms in the mixture of organic compounds of the CP.

[00052] In another aspect, acetal and other heteroaliphatic groups account for about 10% to about 30%, for example about 13% to about 26% or about 15% to about 22%, illustratively about 19%, of carbon atoms in the mixture of organic compounds of the CP.

[00053] In another aspect, the ratio of aromatic to aliphatic carbon is about 2:3 to about 4: 1 , for example about 1 : 1 to about 3 : 1 or about 3 :2 to about 2: 1 in the CP.

[00054] In a particular illustrative aspect, carbon distribution in the mixture of organic compounds of the CP is as follows: carboxy and carbonyl groups, about 35%; aromatic groups, about 30%; aliphatic groups, about 18%, acetal groups, about 7%; and other heteroaliphatic groups, about 12%.

[00055] Elemental composition of the organic compounds of the CP is independently in one series of embodiments as follows, by weight: C, about 28% to about 55%, illustratively about 38%; H, about 3% to about 5%, illustratively about 4%; 0, about 30% to about 50%, illustratively about 40%; N, about 0.2% to about 3%, illustratively about 1.5%; S, about 0.2% to about 4%, illustratively about 2%. Elemental composition of the organic compounds of the CP is independently in another series of embodiments as follows, by weight: C, about 45% to about 55%, illustratively about 50%; H, about 3% to about 5%, illustratively about 4%; 0, about 40% to about 50%, illustratively about 45%; N, about 0.2% to about 1%, illustratively about 0.5%; S, about 0.2% to about 0.7%, illustratively about 0.4%.

[00056] In a particular illustrative aspect, elemental distribution is, by weight: C, about 38%; H, about 4%; 0, about 40%; N, about 1.5%; and S, about 2%. The balance consists mainly of inorganic ions, principally potassium and iron in the CP. In another particular illustrative aspect, elemental distribution is, by weight: C, about 50%; H, about 4%; 0, about 45%; N, about 0.5%; and S, about 0.4% in the CP.

[00057] Among classes of organic compounds that can be present in the CP are, in various aspects, amino acids, carbohydrates (monosaccharides, disaccharides and polysaccharides), sugar alcohols, carbonyl compounds, polyamines, lipids, and mixtures thereof. These specific compounds typically are present in minor amounts, for example, less than 5% of the total % of compounds. Examples of amino acids that can be present include without limitation arginine, aspartic acid, glutamic acid, glycine, histidine, isoleucine, serine, threonine, tyrosine and valine. Examples of monosaccharide and disaccharide sugars that can be present include without limitation glucose, galactose, mannose, fructose, arabinose, ribose and xylose.

[00058] Based on the above chemical, elemental and structural characterization, the CP is chemically and biologically unique from Humic and Fulvic acids or combinations thereof. Further, as a result of the nature and extent of gene regulation and over all effect of the CP with respect to improved plant health, drought and salinity stress resistance, it is generally believed that the CP is unique to that of known humic and/or fulvic acid compositions and treatments, for which such activity and properties are generally lacking in quality and quantity. Other beneficial plant function attributes of the CP may be present or result from the methods of treatment and/or the gene regulation obtained from the CP.

[00059] A suitable mixture of organic compounds can be found, for example, as one of many components in products marketed as Carbon Boost-S soil solution and KAFE™-F foliar solution of Floratine Biosciences, Inc. (FBS). Information on these products is available at www.fbsciences.com. Thus, exemplary compositions of aspects disclosed and described herein can be prepared by adding to Carbon Boost™-S or KAFE™-F foliar solution as the CP, at least one pesticide as the second component, to a suitable volume of water. In one aspect, the active ingredient is CAS Reg. No. 1 175006-56-0, and corresponds, by way of example, to CP.

[00060] The amount of the CP that should be present in the composition for providing stress resistance and/or gene regulation depends on the particular organic mixture used. The amount should not be so great as to result in a physically unstable composition, for example by exceeding the limit of solubility of the mixture in the composition, or by causing other essential components to fall out of solution. On the other hand, the amount should not be so little as to fail to provide enhanced stress resistance, or gene regulation when applied to a target plant species. For any particular organic mixture, one of skill in the art can, by routine formulation stability and bioefficacy testing, optimize the amount of organic mixture in the composition for any particular use.

[00061] Particularly where a mixture of organic compounds, as found, for example, in the commercially available formulations sold under the tradenames Carbon Boost™-S and KAFE™-F, is used, the amount of the CP needed in a nutrition composition will often be found to be remarkably small. For example, as little as one part by weight (excluding water) of such a mixture can, in some circumstances, assist in foliar delivery of up to about 1000 or more parts by weight of the second component to a site of deposition in a plant. In other circumstances, it may be found beneficial to add a greater amount of the organic mixture, based on routine testing. Typically, a suitable ratio of the CP to the second component is about 1 :2000 to about 1 :5, for example about 1 : 1000 to about 1 : 10 or about 1 :500 to about 1 :20, illustratively about 1 : 100. If using Carbon Boost™-S or KAFE™-F solution as the source of organic compounds, a suitable amount of such solution to be included in a concentrate composition of second component herein is about 1 part by weight Carbon Boost™-S or KAFE™-F solution in about 5 to about 25, for example about 8 to about 18, illustratively about 12, parts by weight of the concentrate composition.

[00062] Optionally, additional components can be present in the composition of matter of the present invention. For example, the composition can further comprise as a second component. The second component can be of at least one agriculturally acceptable source of a plant nutrient other than CP. The second component can also be a pesticide, where the term "pesticide" herein refers to at least one herbicide, insecticide, fungicide, bactericide, antiviral, nematocide, or a combination thereof.

[00063] Methods of use of the composition as described herein for plant and/or seed treating for reducing susceptibility to environmental stress of a plant are further disclosed. The composition can be applied to a single plant (e.g., a houseplant or garden ornamental) or to an assemblage of plants occupying an area. In some embodiments, the composition is applied to an agricultural or horticultural crop, more especially a food crop. A "food crop" herein means a crop grown primarily for human consumption. Methods of the present invention are appropriate both for field use and in protected cultivation, for example, greenhouse use.

[00064] While the present methods can be beneficial for gramineous (belonging to the grass family) crops such as cereal crops, including corn, wheat, barley, oats and rice, they are also highly appropriate for non-gramineous crops, including vegetable crops, fruit crops, broad- leaved field crops such as soybeans, seed crops or a crop of any species grown specially to produce seed. .The terms "fruit" and "vegetable" herein are used in their agricultural or culinary sense, not in a strict botanical sense; for example, tomatoes, cucumbers and zucchini are considered vegetables for present purposes, although botanically speaking it is the fruit of these crops that is consumed.

[00065] Vegetable crops for which the present methods can be found useful include without limitation:

leafy and salad vegetables such as amaranth, beet greens, bitterleaf, bok choy, Brussels sprout, cabbage, catsear, celtuce, choukwee, Ceylon spinach, chicory, Chinese mallow, chrysanthemum leaf, corn salad, cress, dandelion, endive, epazote, fat hen, fiddlehead, fluted pumpkin, golden samphire, Good King Henry, ice plant, jambu, kai- lan, kale, komatsuna, kuka, Lagos bologi, land cress, lettuce, lizard's tail, melokhia, mizuna greens, mustard, Chinese cabbage, New Zealand spinach, orache, pea leaf, polk, radicchio, rocket (arugula), samphire, sea beet, seakale, Sierra Leone bologi, soko, sorrel, spinach, summer purslane, Swiss chard, tatsoi, turnip greens, watercress, water spinach, winter purslane and you choy;

flowering and fruiting vegetables such as acorn squash, Armenian cucumber, avocado, bell pepper, bitter melon, butternut squash, caigua, Cape gooseberry, cayenne pepper, chayote, chili pepper, cucumber, eggplant (aubergine), globe artichoke, luffa, Malabar gourd, parwal, pattypan squash, perennial cucumber, pumpkin, snake gourd, squash (marrow), sweetcorn, sweet pepper, tinda, tomato, tomatillo, winter melon, West Indian gherkin and zucchini (courgette);

podded vegetables (legumes) such as American groundnut, azuki bean, black bean, black-eyed pea, chickpea (garbanzo bean), drumstick, dolichos bean, fava bean (broad bean), French bean, guar, haricot bean, horse gram, Indian pea, kidney bean, lentil, lima bean, moth bean, mung bean, navy bean, okra, pea, peanut (groundnut), pigeon pea, pinto bean, rice bean, runner bean, soybean, tarwi, tepary bean, urad bean, velvet bean, winged bean and yardlong bean;

bulb and stem vegetables such as asparagus, cardoon, celeriac, celery, elephant garlic, fennel, garlic, kohlrabi, kurrat, leek, lotus root, nopal, onion, Prussian asparagus, shallot, Welsh onion and wild leek;

root and tuber vegetables, such as ahipa, arracacha, bamboo shoot, beetroot, black cumin, burdock, broadleaf arrowhead, camas, canna, carrot, cassava, Chinese artichoke, daikon, earthnut pea, elephant-foot yam, ensete, ginger, gobo, Hamburg parsley, horseradish, Jerusalem artichoke, jicama, parsnip, pignut, plectranthus, potato, prairie turnip, radish, rutabaga (swede), salsify, scorzonera, skirret, sweet potato, taro, ti, tigernut, turnip, ulluco, wasabi, water chestnut, yacon and yam; and

herbs, such as angelica, anise, basil, bergamot, caraway, cardamom, chamomile, chives, cilantro, coriander, dill, fennel, ginseng, jasmine, lavender, lemon balm, lemon basil, lemongrass, marjoram, mint, oregano, parsley, poppy, saffron, sage, star anise, tarragon, thyme, turmeric and vanilla.

[00066] Fruit crops for which the present methods can be found useful include without limitation: apple, apricot, banana, blackberry, blackcurrant, blueberry, boysenberry, cantaloupe, cherry, citron, Clementine, cranberry, damson, dragonfruit, fig, grape, grapefruit, greengage, gooseberry, guava, honeydew, jackfruit, key lime, kiwifruit, kumquat, lemon, lime, loganberry, longan, loquat, mandarin, mango, mangosteen, melon, muskmelon, orange, papaya, peach, pear, persimmon, pineapple, plantain, plum, pomelo, prickly pear, quince, raspberry, redcurrant, starfruit, strawberry, tangelo, tangerine, tayberry, ugli fruit and watermelon.

[00067] Seed crops for which the present methods can be found useful include without limitation: specialized crops used to produce seed of any plant species, for which the present methods can be found useful include, in addition to cereals (e.g., barley, corn (maize), millet, oats, rice, rye, sorghum (milo) and wheat), non-gramineous seed crops such as buckwheat, cotton, flaxseed (linseed), mustard, poppy, rapeseed (including canola), safflower, sesame and sunflower.

[00068] Other crops, not fitting any of the above categories, for which the present methods can be found useful include without limitation sugar beet, sugar cane, hops and tobacco.

[00069] Each of the crops listed above has its own particular stress protection needs. Further optimization of compositions described herein for particular crops can readily be undertaken by those of skill in the art, based on the present disclosure, without undue experimentation.

[00070] Methods of using the compositions disclosed and described herein comprise applying a composition as described herein to a seed, to a foliar surface of a plant, or to a locus of the plant or seed.

[00071] The term "agriculturally acceptable" applied to a material or composition herein means not unacceptably damaging or toxic to a plant or its environment, and not unsafe to the user or others that may be exposed to the material when used as described herein.

[00072] A "foliar surface" herein is typically a leaf surface, but other green parts of plants have surfaces that may permit absorption of active ingredient, including petioles, stipules, stems, bracts, flowerbuds, etc., and for present purposes "foliar surfaces" will be understood to include surfaces of such green parts.

[00073] A "locus" as used herein is inclusive of a foliar surface and also includes an area in proximity to a plant or the area in which a plurality of seed is or can be sown.

[00074] "Seed treatment" as used herein refers generally to contacting a seed with a compound or composition of matter containing or comprising at least one active ingredient (a.i. or AI). The compound or composition of matter may be in any form suitable to the seed, for example, liquid, gel, emulsion, suspension, dispersion, spray, or powder. Seed treatment is inclusive of seed coating and seed dressing. In a preferred embodiment, the A.I. is CP.

[00075] "Seed coating" or "seed dressing" as used herein refers generally to a coating or matrix formed on at least part of the seed, the coating or matrix containing or comprising the at least one AI. Optional compounds or agents may be included in the seed coating to facilitate the seed coating process or the disintegration/releasing of the at least one AI from the coating, or to prevent excessive dust-off or to add color to the treated seed.

[00076] The term "seed" as used herein, is not limited to any particular type of seed and can refer to seed from a single plant species, a mixture of seed from multiple plant species, or a seed blend from various strains within a plant species. The disclosed and described compositions can be utilized to treat gymnosperm seed, dicotyledonous angiosperm seed and monocotyledonous angiosperm seed.

[00077] The term "agronomical recovery" as used herein, is related to the relative resumption of biological response of the plant after the stress has been reduced or discontinued. Agronomical recovery is not limited to any particular type of biologically- related plant recovery and can include for example, recovery of some or all of weight, fruit production, yield, survival, color, appearance, fragrance, etc. In one example, agronomical recovery includes one or more of improved plant weight, number of leaves, and stalk weight after discontinuation of drought as compared to a similar plant not treated with the composition of matter disclosed herein.

[00078] Compositions disclosed and described herein can be applied using any

conventional system for applying liquid or solid to a seed or foliar surface or locus. Most commonly, application by spraying will be found most convenient, but other techniques, including application by tumbling, brush or by rope-wick can be used if desired. For spraying, any conventional atomization method can be used to generate spray droplets, including hydraulic nozzles and rotating disk atomizers. Introduction of the composition into an irrigation system can be used.

[00079] For foliage surface or locus applications, the application rate of the composition can be between about 0.01 gram/hectare to about 10.0 gram/hectare dry weight, between about 0.2 gram/hectare to about 2.0 gram/hectare dry weight, between 0.3 gram/hectare to about 1.5 gram/hectare dry weight, or between about 0.4 gram/hectare to about 1.0 gram/hectare dry weight applied in the soil or as a foliar application to the foliage or the locus of the plant.

[00080] Compositions disclosed and described herein can be provided in concentrate form, (e.g., liquid, gel, or reconstitutable powder form), suitable for further dilution and/or mixing in water prior to application to the seed, plant, or locus. Alternatively, they can be provided as a ready-to-use solution for direct application. Because compositions disclosed and described herein can be combined with other fertilizer solutions and/or with pesticide solutions, they can be diluted and/or reconstituted by mixing with such other solutions.

[00081] The above concentrate compositions are suitable for further dilution. For application to plant foliage, a concentrate composition can be diluted up to about 600-fold or more with water, more typically up to about 100-fold or up to about 40-fold. Illustratively, a concentrate product can be applied at about 0.1 to about 30 1/ha, for example about 5 to about 25 1/ha, in a total application volume after dilution of about 60 to about 600 1/ha, for example about 80 to about 400 1/ha or about 100 to about 200 1/ha. [00082] For seed treatment applications, a concentrate composition can be diluted up to about 600-fold or more with water, more typically up to about 100-fold or up to about 40- fold. Illustratively, a concentrate product can be applied at about 0.1 mg/Kg seed to about 100 mg/Kg seed, for example about 0.1 mg/Kg seed, 0.5 mg/Kg seed, 0.75 mg/Kg seed, 1.0 mg/Kg seed, 1.25 mg/Kg seed, 1.5 mg/Kg seed, 1.75 mg/Kg seed, 2.0 mg/Kg seed, 2.5 mg/Kg seed, 3.0 mg/Kg seed, 3.5 mg/Kg seed, 4.0 mg/Kg seed, 4.5 mg/Kg seed, 5.0 mg/Kg seed, 5.5 mg/Kg seed, 6.0 mg/Kg seed, 6.5 mg/Kg seed, 7.0 mg/Kg seed, 7.5 mg/Kg seed, 8.0 mg/Kg seed, 8.5 mg/Kg seed, 9.0 mg/Kg seed, 9.5 mg/Kg seed, and 10.0 mg/Kg seed. A concentrate product can also be applied at about 15 mg/Kg, 20 mg/Kg, 25 mg/Kg, and 30 mg/Kg.

[00083] Application solutions prepared by diluting concentrate compositions as described above represent further aspects of the compositions and methods disclosed and described herein.

Experimental

[00084] CP can affect plant gene expression and those genes that are up-regulated or down- regulated where identified, using the gene microarray technologies and the model plant Arabidopisis. In preliminary experiments on Arabidopsis conducted by Applicant, application of CP demonstrated an increased Arabidopsis leaf number by 24.9%, leaf area by 47.0%, leaf fresh weight by 46.9%, and leaf dry weight by 25% when the treated plants were exposed to salinity stress (NaCl). Similar application of CP delayed the appearance of wilting symptoms on Arabidopsis plants under drought stress. DNA analysis of Arabidopsis thaliana exposed to CP was performed to identify gene expression and regulation with correlation to aspects of various environmental stresses such as drought, oxidative stress, as well as correlation of gene expression and regulation to aspects of ion transport, and other functional mechanisms.

[00085] Plant material and growing conditions. Arabidopsis thaliana , accession Colombia (Col-0), was used. This accession was obtained from Dr. Z. Mou at the University of Florida's Department of Cell Sciences and Microbiology (Gainesville, FL 32611). Seeds were sown in autoclaved Metro-Mix 200 potting mix (SunGro Horticulture), watered with sterile distilled water, and vernalized in a cold room (dark at ~7 C) for 3 days. Seeds were germinated and seedlings were grown in a growth room with room temperature set at 24 C and relative humidity ranging from 45% to 70%. Initially the photoperiod in the growth room was 16 hours light and 8 hours dark, and later it was changed to 10 hours light and 14 hours dark.

[00086] CP vs Control Experiments. For foliar application, CP and comparative example CE, were diluted with deionized water, and sprayed onto Arabidopsis rosette leaves until runoff. To incorporate CP into tissue culture medium, CP stock solution was filter-sterilized under an aseptic hood and added to the medium that was autoc laved and cooled to about 45°C.

[00087] Salinity (salt) stress. This was induced by applying sodium chloride solution (50 mM to 200 mM) to the growing or culture medium.

[00088] Drought stress. Growing medium was allowed to dry out gradually in the growth room without watering.

[00089] Plant growth assay. This was done by counting rosette leaves. At the end of the experiment, leaves were harvested, and their leaf areas were determined using a large flat-bed scanner (Epson Expression 10000XL) and the Winfolia software (Regenet Instrument Inc.). Leaf fresh weights were taken right after harvesting, and dry weights were taken after 24 to 48 hours of drying at 175°C.

Gene Regulation Study

[00090] Microarray analysis indicated that CP compositions are quite potent in regulating the expression of a large and diverse group of Arabidopsis genes. Six hours after foliar application of CP (hereinafter also referred to as "Tl") and a second CP formulation, designated CP 1000 (hereafter also referred to as "T2"), the expression level of 456 genes changed greater than 50% (1.5 fold). Among them, 60 genes increased expression by 1.5 to 3.2 fold, and 396 genes decreased expression level by 1.5 to 38.4 fold. Six hours after foliar application of comparative example CE, the expression level of 423 genes changed by greater than 50% (1.5 fold), among which, 160 genes increased their expression by 1 .5 to 4.0 fold and 263 genes decreased expression by 1.5 to 20.3 fold. The chemical compositions of CP and CP 1000 (Tl and T2) share the characteristics of the partially humified material described herein.

[00091] Some of the genes regulated by CP may be involved in the responses to or metabolism of, plant hormones, such as auxins, gibberellic acid, abscisic acid, etc., and potentially other chemical stimuli. Some other genes are likely involved in ion binding or mobility, plant defense, etc. Most remarkably, many of the genes regulated by CP are transcription factors. [00092] The above results indicate that CP is able to exert significant effects on numerous plant biochemical and physiological processes important for plant growth, development, and stress tolerance. In some sense, CP acts like a nontraditional plant growth regulator.

[00093] Although this study was the first attempt to understand the modulating roles of CP on plant gene expression, the results demonstrate some very intriguing phenomenon regarding the mode of action of CP. Nevertheless, further investigations are ongoing to validate the findings from this study and to better understand the effects of CP on global gene expression and particularly, on key genes involved in critical plant physiological or biochemical processes.

Microarray preparation

[00094] Total RNA was isolated from rosette leaves using the RNease Plant Mini Kit reagent (Qiagen Sciences, MA) and dissolved in RNase-free water (Fisher Scientific).

Microarray preparation and scanning services were provided by the University of Florida's Interdisciplinary Center for Biotechnology Center (UF-ICBR, Gainesville, FL). RNA concentration was initially determined using the Nandrop 8000, and then examined by Agilent 2100 Bioanalyzer. Fluorescently labeled cRNAs were generated from 175 ng of total RNA in each reaction using the Agilent Technologies Quick Amp Labeling Kit/Two Color (Agilent p/n 5190-0444). Cy5-labeled cRNA from a specific treatment was mixed with the same amount of Cy3 -labeled cRNA from the control, or vice versa in dye-swap. Hybridization was performed according to Agilent Technologies's hybridization user's manual and Gene Expression Hybridization Kit (Agilent p/n 5 188-5242). A total of 100 ul of reaction mix was applied to the each Agilent Technologies 44K Arabidopsis 4 microarray (43803 features) and hybridized in a hybridization rotation oven at 65°C for 17 hours. The slides were washed first with Gene Expression Wash Buffer 1 (Agilent p/n 5 188-5325)/0.005% Triton X-102 for 1 minute at room temperature and then with Gene Expression Wash Buffer 2 (Agilent p/n 5188- 5326)/0.005% Triton X-102 for 1 minute at room temperature, and dried by immerging the slides into Agilent Stabilization and Drying Solution (Agilent p/n 5185-5979) for 30 seconds. The arrays were scanned by using a dual-laser DNA microarray scanner (model G2505C, Agilent Technologies). The data were extracted from images and normalized within the arrays using Feature Extraction 10.1.1.1 software (Agilent Technologies). The within array normalization was based on Lowess method. Microarray data analysis

[00095] The GeneSpring GX 10.0.2 package (Agilent Technologies) was used to analyze the microarray data. The two color data (red and green) were imported into GeneSpring as single color data (red or green) using split-channel. During this process, between- array normalization was performed using percentile shift and shift to median of all samples.

[00096] Lists of differentially expressed genes were identified first according to t-test p values (<0.01), then the fold change (> 1.5). Additionally, the R2.3 software and the LIMMA package were used to normalize the microarray data and generate lists of differentially expressed genes.

Results

[00097] 1. Effect of CP on Arabidopsis growth under normal growing conditions : Tests were conducted to determine the effect of CP on normal growing conditions of Arabidopsis plants. These tests indicated that treated Arabidopsis plants appeared to have denser roots on root balls than non-treated plants (FIG. 1), but no significant differences were observed between treated and non-treated plants in leaf number, leaf area, and fresh or dry leaf weight (Table 1).

[00098] The test was repeated under a different photoperiod (10 /14 hours day/night). No significant differences were observed between control CP, (and comparative example CE) treated plants in leaf number (7, 14, and 21 days post treatment), leaf area, and fresh or dry leaf weight (Table 2; FIG. 2; FIG. 14).

Leaves per plant (average over Leaf area Fresh Dry weight

No. plants

8plants) (cm²⁾ weight (g) (g)

Treatment Replicate 7 days 14 days 21 days

Control 1 8 5.9 11.7 14.6 31.52 0.65 0.05

2 8 6.3 11.4 16.1 28.70 0.59 0.05

3 8 5.8 11.8 16.4 29.82 0.63 0.05

4 8 5.8 10.8 15.6 26.16 0.48 0.04

Average 5.9 11.4 15.7 29.05 0.59 0.05

CP 1 8 5.4 11.0 15.3 28.14 0.58 0.05

2 8 5.6 10.8 15.3 25.03 0.48 0.04

3 8 5.8 11.2 15.6 28.35 0.57 0.05

4 8 6.0 11.4 15.8 33.53 0.57 0.05

Average 5.7 11.1 15.5 28.76 0.55 0.05

Table 2. Effect of CI P application on Arabidopsis growth (10/14 hours day/night)

[00099] 2. Effect of CP on salt stress tolerance : Two tests were conducted on Arabidopsis plants to determine the effectiveness of CP on reducing salt stress. In the first one, plants were stressed by irrigating with 100 mM NaCl 4 days before CP application. Each pot (cell) with one plant received 25 mL of 100 mM NaCl on 3 and 5 February 2009. One day later plants were treated with CP or water (control). Seventy-four percent of the treated plants developed multiple shoots (FIG. 3), whereas only 29% of the non-treated plants developed multiple shoots (Table 3).

[000100] In the second test, Arabidopsis plants were treated with CP before they were subjected to salt stress. Different results were obtained. Plants were foliar-sprayed with CP or water on 16 February 2009, and irrigated with 50 mM NaCl 4 days and then 100 mM NaCl 7 days post CP application. In this test, the CP treatment significantly increased leaf number (24.9%), area (47.0%), and fresh weight (46.9%) and dry weight (25.0%) (Table 4; FIG. 4; FIG. 15).

[000101] Additional salt stress experiment were conducted, the purpose of which was to determine the effect of CP in mitigating the impact of induced salt stress on tomato plants (Lycopersicon es.) grown in a greenhouse. The tomatoes were produced from seed and transplanted into 3 inch by 3 inch pots for this experiment. There were five treatments in total with 8 replicates per treatment arranged in a Randomized Complete Block design. All pots received an application of CP as a 25 ml soil drench on the day they were transplanted and a second application 14 days later. The untreated check was treated with only water, and the pots treated with CP had rates that ranged from 0.3 ppm CP to 2.4 ppm CP. Seven days after the second application, half of the pots in each treatment received a 25 ml soil drench of 200 mM NaCl salt solution. Eleven days later, the plants were measured for vigor, plant height, number of leaves, and plant, root, and shoot weights. Data are shown in Tables 4 A and 4B.

2.4 ppm CP 3.1a 2.9a 8.9a 9.1a 5.3a 5.8a

1.2 ppm CP 2.9a 3.0a 9.2a 8.9a 5.6a 6.3a

0.6 ppm CP 3.0a 3.0a 8.6a 9.3a 5.6a 6.6a

0.3 ppm CP 3.1a 3.1a 9.0a 8.8a 6.3a 6.3a

Table 4B. Plant vigor aJ ¾er salt stress. Vigor Ratings: 5= best, 0=dead. Means followed by the same letter do noi t significantly differ (P=.010, Duncan's New MRT).

[000102] This experiment was designed, at least in part, to evaluate the optimum rate of CP for mitigating stress. As is clearly shown above, the salt drench had a negligible effect on plant shoots as shown by the vigor, height, leaf number and shoot weight. However, the salt had a statistically significant negative impact on root weight and overall plant weight for plants in the UTC when compared to the plants in the UTC without salt stress. The addition of high rates of CP (1.2 and 2.4 ppm of CP) caused significant root pruning for both the salt stressed plants and the unstressed plants, but low rates significantly improved root and overall plant size for both the stressed and unstressed plants. For plants treated with the lowest rate of CP, there was no statistical difference in the root weights between the unstressed and stressed plants. The results shown in Tables 4A and 4B were not predicted.

[000103] An additional experiment was performed, the purpose of this experiment was to determine the effect of CP in mitigating the impact of induced salt stress on tomato plants (Lycopersicon es.) grown in a greenhouse. The tomatoes were produced from seed and transplanted into 3 inch by 3 inch pots for this experiment. There were five treatments in total with 8 replicates per treatment arranged in a Randomized Complete Block design. All pots received an application of CP as a 25 ml soil drench on the day they were transplanted and a second application 14 days later. The untreated check was treated with only water, and the pots treated with CP had rates of 0.075 and 0.0375 ppm CP. Seven days after the second application, half of the pots in each treatment received a 25 ml soil drench of 200 mM NaCl salt solution. Thirteen days later, the plants were measured for number of leaves and shoot weights. Data are shown in Tables 4C and 4D.

Table 4C. Plant shoot weight 13 days after salt stress. Means followed by the same letter do not significantly differ (P=.010, Duncan's New MRT).

[000104] This experiment was designed, at least in part, to evaluate two different application rates of CP on plant development and for mitigating stress. As is shown above, plants treated with CP at both rates showed a statistically significant difference in both the shoot weights and the number of leaves, regardless of whether they were exposed to salt induced stress. Further, it is shown that the plants receiving applications of CP and salt were as large or larger than those treated with CP without salt stress, and these plants also had more leaves. Normally, salt applied at these levels would be expected to reduce both size and the number of leaves on a plant. Therefore, the results shown in Tables 4C and 4D were not predicted.

[000105] 3. Effect of CP on drought tolerance: Arabidopsis plants were treated with or without CP on 23 February 2009, and then subjected to the drought condition by discontinuing watering from 9 March 2009 on. These plants were observed from 9 March to 30 March for wilting symptom or plant death. This CP treatment seemed to delay wilting symptoms 1 to 2 days (FIG. 5; FIG. 16). FIGs. 5 and 16 show the effect of CP application on Arabidopsis tolerance to drought. As see in FIG. 5, Left column: CP treated; right column: control. Photo taken 17 days after watering was stopped.

[000106] Additional experiments were conducted, the purpose of which was to determine the effect of CP in mitigating the impact of induced drought stress on tomato plants (Lycopersicon es.) grown in a greenhouse. The tomatoes were produced from seed and transplanted into 3 inch by 3 inch pots for this experiment. There were three treatments in total with 8 replicates per treatment arranged in a Randomized Complete Block design. All pots in Treatment 2 received an application of CP as a 25 ml soil drench on the day they were transplanted and a second application 21 days later. The untreated check and

Treatment 3 were treated with water only. Seven days after the second application, daily watering was discontinued for all plants in Treatments 2 and 3 to simulate extreme drought conditions. At sixteen days after watering was halted, half of the plants in each treatment were harvested to measure root weight, shoot weight, and total weight. Watering was then resumed and the recovery from the drought stress was determined nine days later. The results are shown in Table 4E. As shown, all plants that were not watered for a period of time were eventually impacted whether they were treated with CP or not. The CP appears to have a slight effect in minimizing the impact of no water, but the data may not be statistically significant. However, after watering was resumed, the plants treated with CP had a much improved response/recovery with regard to root and shoot weights as shown Table 4D. This response data was determined to be statistically significant. Thus, the composition of matter disclosed herein provides for an improvement in stress reduction that also includes improved "agronomical recovery" of the plant after the stress is reduced and/or discontinued compared to similar plants not treated with the composition of matter. The autorecovery results shown in Table 4E were not predicted.

[000107] 4. Effect of CP on seed germination in vitro Two tests were conducted to determine the effect of seed germination of Arabidopsis seeds contacted with CP. The first test consisted of the following treatments:

[000108] Y2 MS (Sigma Murashige and Skoog Basal Salt Mixture)

[000109] Y2 MS + CP5000X

[000110] Y2 MS + 125mM NaCl

[000111] Y2 MS + 125mM NaCl + CP5000X [000112] One Petri dish for each treatment, with 200-300 seeds in each plate. The second test consisted of similar treatments:

[000113] Y2 MS

[000114] Y2 MS + CP1000X

[000115] Y2 MS + 125mM NaCl

[000116] Y2 MS + 125mM NaCl + CP1000X

[000117] Four plates for each treatment four plates, and 49 seeds were sown in each plate. No significant differences were observed among the treatments.

[000118] 5. Effect of CP on root growth in vitro: Three tests were conducted to determine the effect of CP on Arabidopsis root growth in vitro. In the first test, seeds were germinated in V2 MS + 125mM NaCl medium, and then 4-day-old seedlings were subjected to the following conditions:

[000119] V2 MS + 125 mM NaCl

[000120] V2 MS + 125 mM NaCl + CP1000X

[000121] V2 MS + 125 mM NaCl + CP5000X

[000122] In the 2^nd test, 4-day-old seedlings germinated in V2 MS medium were transferred to the following Petri dishes containing:

[000123] V2 MS

[000124] V2 MS + CP1000X V2 MS + CP5000X

[000125] Each treatment four plates, 4-6 seedlings in each plate

[000126] In the 3^ri test, seedlings were grown in V2 MS, and then subjected to even

higher concentrations of NaCl:

[000127] V2 MS

[000128] V2 MS + 225mM NaCl

[000129] V2 MS + 225mMNaCl + CP1000X

V2 MS + 225mM NaCl + CP5000X

[000130] Each treatment consisted of four plates, and 4-6 seedlings were placed in each plate. No significant differences were observed in these 3 tests.

[000131] 6. CP-initiated gene expression : High quality RNAs were isolated from

Arabidopsis rosette leaves, as shown in FIG. 6. The expression technique is schematically depicted in FIG. 17. The Agilent Technologies's Arabidopsis Oligo Microarray V4 contains 43603 genes or transcripts that cover the plant's whole genome. Out of the 43,603 genes or transcripts (to be referred as genes for brevity below) that were hybridized, 1,382 genes or 1,115 genes showed significant fold changes at p-value <0.01 for Tl (CP), or comparative example CE, respectively, as summarized in Table 5. FIG. 7 depicts the genome- wide expression profile of Arabidopsis genes (43603 features) in Tl treatment versus control (Y- axis: gene expression level fold change; X-axis: Tl on the left and control on the right).

[000132] Among them, the expression level of 456 and 423 genes was changed by at least 1.5 fold, or 50%, for Tl . Thus, FIG. 8 depicts the expression profile plot of Arabidopsis genes whose expression levels changed > 1 .5 fold at p-value < 0.01 (Y-axis: gene expression level fold change; X-axis: Tl on the left and control on the right). FIG. 9 is a Volcano plot of Arabidopsis genes whose expression levels changed > 1 .5 fold at p- value < 0.01 (Y-axis: -log base 10 of p- value (2 = p-value 0.01); X-axis: gene expression level fold change). FIG. 10 is a Heatmap of CP-regulated genes compared to the control on the right, where each line represents a separate gene. Thicker, darker lines represent up/down regulated genes. FIG. 11 depicts the expression profile plot of Arabidopsis genes whose expression levels changed > 1.5 fold at p-value < 0.01 (Y-axis: gene expression level fold change; X-axis: T2 on the left and control on the right). FIG. 12 is a Volcano plot of Arabidopsis genes whose expression levels changed > 1.5 fold at p- value < 0.01 in T2 versus control (Y-axis: -log base 10 of p-value (2 = p-value 0.01); X- axis: gene expression level fold change). FIG. 13 is a Heatmap of CE-regulated genes compared to the control on the right, where each line represents a separate gene. For CE, the number of up- regulated genes was 60 and 160 for Tl and T2, respectively. Their expression level change ranged from 1.5 (the cut-off) to 4.0 fold, with an average fold change of 1.8 to 1.9.

[000133] A much greater number of genes were down-regulated at 6 hours after CP (Tl) or CP1000 (T2) application as shown in FIGs. 18 and 19. For example, the expression of 394 genes was suppressed by Tl, and their expression level was decreased by as much 38.4 fold. Similarly, for T2, 263 genes were suppressed, and their expression level was decreased by as much as 20.3 fold.

/transcripts of FC FC /transcripts

> 1.5

(no.) (no.)

Tl 1.5 - 1.5 -

1382 (3.17%) 456 (1.05%) 60 1.9 396 2.8 (CP) 3.2 38.4

T2 1.5 - 1.5 -

1115 (2.56% 423 (0.97% 160 1.8 263 2.5 (CE) 4.0 20.3

Table 5. Ei Tect of CP and CE on Arabidopsis Gene Expression. (TS ote: Each array contained 43603 feat ures. FC = fold change. FC 1.5 = 50% change. GeneSpn mg GX 10.0.2 was used, within arraj i normalization done by Lowess method, between array no rmalization done by percentile s hift, and baseline was shifted to median of all samples.)

[000134] Tables 6 and 7 provide details, including gene name, GeneBank accession number, and description (and potential functions), for those genes whose expression level changed > to 1.5 fold and had p <0.01, responsive to Tl and responsive to T2, respectively. Table 6 lists 456 genes found to be responsive to Tl (CP contacted) treatment. Table 7 lists 423 genes responsive to T2 treatment. The following provides a short overview of some of these significantly differentially expressed genes. The large number of genes regulated by contact with CP was not predicted.

[000135] Among the 60 genes up-regulated by Tl are:

5 genes encoding plant regulator production or responses: fold change 1.5 to

1.8 3 for auxin-responsive family proteins;

2 for gibberellin 20 oxidase genes;

3 genes encoding transporters (amino acid, carbohydrate, and purine): fold change 1.5 to

1.8;

8 genes encoding enzymes: fold change 1.5 to 3.2;

3 defense-related genes: fold change 1.6 to 2.6; and

2 genes encoding transcription factor or transcription regulators: fold change 1.8 to 2.2 1 gene encoding ATPase /ion movement: fold change 1.5

[000136] Among the 396 genes down-regulated by Tl are 34 genes encoding transcription factors, transcription regulators, initiators.

[000137] Among the 160 genes up-regulated by T2 are:

10 genes encoding transcription factors: fold change 1.5 to 3.5;

39 genes encoding various kinds of enzymes, such as 12 for various protein kinases and 6 for hydrolases, and others, very diverse.

[000138] Among the 99 genes regulated by both Tl and T2 are: I gene (AT5G2063 receptor): up-regulated by Tl and T2;

I I genes encoding transcription factors, down 1.5 to 6.2 folds, including:

i) Three containing WRKY element

ii) One containing an ethylene-responsive element,

iii) One containing ABA repressor,

iv) One containing salt tolerance zinc finger motif,

v) One containing high light responsive element;

4 putative disease resistance genes, down 1.5 to 2.4;

1 gene encoding putative chitinase protein, down 1.6 to 2.1;

2 genes encoding calcium ion binding proteins, down 4.7 to 5.5;

3 genes encoding zinc ion binding proteins, down 2.2 to 3.5;

1 encoding phosphate induced protein, down 3.2 to 5.0;

1 gene encoding ABC transporter family protein, down 3.2 to 3.5;

1 gene encoding cation/hydrogen exchanger (proton antiporter);

1 glycolipid transporter gene, down 3.3 to 3.7;

1 calmodulin-related protein, down 3.2 to 3.6; 1 protein kinase /sugar binding;

2 protease inhibitor genes, 1.8 to 3.4;

1 pectinesterase family protein, down 2.9 to 8.1;

1 oxidoreductase, down 2.6 to 4.0;

2 transmembrane receptor genes, down 1.9 to 3.4;

1 heat-shock protein gene, down 2.7 to 2.8; and

1 senescence associated protein, down 2.1 to 2.6.

[000139] Table 8 and Table 9 summarize the list of genes responsive to Tl and T2 (CP- induced) verses control, and transcription factor genes up regulated by Tl and genes up regulated by both Tl and T2, respectively. CP has demonstrated potency in regulating the expression of a large and diverse group of plant genes as represented by the Arabidopsis genome study. Some of the genes regulated by CP are involved in responses to or metabolism of plant hormones, such as auxins, gibberellic acid, abscisic acid, etc., and potentially other chemical stimuli. Some of the genes regulated by CP are involved in ion binding or mobility, plant defense, etc. Most remarkably, many of the genes regulated by CP are transcription factors. This indicates CP exerts effects on numerous plant biochemical and physiological processes. These benefits would be applicable to other plants. In some sense, CP acts like a nontraditional plant growth regulator. The aforementioned

experimental further results show that CP can regulated gene expression in plants. This regulation can, for example, improve the growth of plants under stress, such as drought and salinity stress. Moreover, CP can provide improvement of a plant's drought recovery and can delay the appearance of wilting symptoms on plants under drought stress.

Table 6. List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 6. (cont.) List of Genes Responsive to T1 Treatment

Table 7. List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

TablQ 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 7. (cont.) List of Genes Responsive to T2 treatment

Table 8. List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 8. (cont.) List of Genes Responsive to T1 and T2

Table 9. List of 11 Transcription Factor Genes Responsive to T1 and T2

Claims

1. A method of improving stress-response in a plant, the method comprising contacting a part of a seed, a plant, or the locus thereof with a composition of matter, the composition of matter comprising an agriculturally acceptable complex mixture of dissolved organic material characterized by natural organic matter that is partially humified.

2. The method of claim 1, wherein said composition of matter up regulates a receptor of the plant.

3. The method of claim 1, wherein the composition of matter down regulates at least one plant gene selected from WRKY element, an ethylene-responsive element, ABA repressor, salt tolerance zinc finger motif, high light responsive element, a putative disease resistance gene, putative chitinase protein, calcium ion binding proteins, zinc ion binding proteins, phosphate induced protein, ABC transporter family protein, cation/hydrogen exchanger (proton antiporter), glycolipid transporter gene, calmodulin-related protein, protein kinase /sugar binding, protease inhibitor genes, pectinesterase family protein, oxidoreductase, transmembrane receptor gene, heat-shock protein gene, or senescence associated protein.

4. The method of any one of claims 1 or 2, wherein said composition of matter up regulates at least one plant gene selected from plant regulator production or responses, auxin-responsive family proteins, gibberellin 20 oxidase genes, encoding amino acid transporters, carbohydrate transporters, purine transporters, genes encoding enzyme, defense-related genes, genes encoding transcription factor or transcription regulators, or genes encoding ATPase /ion movement.

5. The method of any one of claims 1 or 2, wherein said composition of matter up regulates at least one plant gene selected from genes encoding transcription factors, genes encoding enzymes, protein kinases or hydrolases.

6. The method of claim 1, wherein said composition of matter up regulates at least one plant gene selected from plant regulator production or responses, auxin-responsive family proteins, gibberellin 20 oxidase genes, encoding amino acid transporters, carbohydrate transporters, purine transporters, genes encoding enzyme, defense-related genes, genes encoding transcription factor or transcription regulators, or genes encoding ATPase /ion movement; and down regulates at least one plant gene selected from transcription factors, transcription regulators, growth, defense, metabolism, or ion transport.

7. A method of regulating at least one gene of a plant species, the method comprising contacting a part of a plant or the locus thereof with a composition of matter, the composition of matter comprising an agriculturally acceptable complex mixture of dissolved organic material characterized by natural organic matter that is partially humified; wherein the at least one gene regulates plant function associated with growth, defense, metabolism, or ion transport.

8. The method of claim 7, wherein the at least one gene regulates at least one plant gene selected from genes encoding transcription factors, genes encoding enzymes, protein kinases or hydrolases.

9. The method of any one of claims 1, 2, 6, or 7, wherein said composition of matter is characterized by two or more of:

a. a mixture of condensed hydrocarbons, lignins, and tannins and/or condensed tannins; b. a oxygen-to-carbon ratio for the dissolved organic matter of greater than about 0.5; c. a total number of tannin compounds greater than about 200, the tannin compounds having a hydrogen to carbon ration of about 0.5 to about 1.4, and an aromaticity index of less than about 0.7 as measured by mass spectroscopy; or

d. a mass distribution of about 55-60% lignin compounds, 27-35% tannin

compounds, and about 8-15% condensed hydrocarbon as measured by mass spectroscopy.

10. The method of any one of claims 1 or 7, wherein the composition of matter is

characterized by comprising a mixture of condensed hydrocarbons, lignins, and tannins and/or condensed tannins, characterized in that at least 10% of the total % of compounds of the composition are tannins and/or condensed tannins.

11. The method of any one of claims 1 or 7, wherein the composition of matter is

characterized by comprising a mixture of condensed hydrocarbons, lignins, and tannins and/or condensed tannins, characterized in that at least 20%> of the total % of compounds of the composition are tannins and/or condensed tannins.

12. The method of claim 9, wherein the improvement in stress reduction includes improved agronomical recovery of the plant after said stress is reduced or discontinued as compared to a similar plant species not treated with said composition of matter.

13. The method of claim 12, wherein the stress is drought.