The disclosure provides methods and compositions to improve the nutritional conditions, such as reducing the use of fertilizers applied during the growing season, and tolerance to fungal pathogens in tomato and potato plants.

The present disclosure provides novel fungal strains capable of solubilizing phosphate, as well as compositions and methods of using those strains to increase the amount/concentration of soluble phosphate in a medium that comprises insoluble phosphate.

Provided are methods and compositions for increasing plant resistance to abiotic stress. The composition may comprise a hydrogel and a priming agent. The methods may include contacting the seed with a seed coating composition comprising a hydrogel and a priming agent.

Provided are methods and compositions for increasing plant resistance to abiotic stress. The composition may comprise a hydrogel and a priming agent. The methods may include contacting the seed with a seed coating composition comprising a hydrogel and a priming agent.

The invention provides materials and method for controlling pests, in particular, nematodes. The invention also provides compositions comprising biosurfactants as pesticides.

A process of biodegradation of hydrocarbons using a plant growth promoting rhizobacteria (PGPR) consortium mixed with the oily sludge, The PGPR consortium is created by inoculating a nutrient broth with pure culture of isolated bacterial strains of Bacillus pumilus, Bacillus subtilis, Pseudomonas putida and Exiguobacterium at Optical Density 1 at 660 nm and bacterial density of 10.sup.6 cells/ml, and incubating the inoculated nutrient broth in a shaker incubator for forty-eight to seventy-two hours at 150 rpm.

The invention relates to the field of seed germination and growing of plants. A composition comprising a clay, an inert material, optionally a fibrous material, and a fourth component is provided, characterized in that said fourth component comprises a cation selected from the group consisting of Al, Zr and Ti and an anion selected from the group consisting of oxyhydroxide, oxychloride, nitrate, sulfate, chloride, hydroxide and alkoxide, and wherein the concentration of said fourth component ranges from 0.1 to 70 percent by weight (w %), preferably 0.5-25 w %, more preferably 1-10 w %, of the total weight of the clay, the inert material, and optionally the fibrous material, together.

The invention relates to the field of seed germination and growing of plants. A composition comprising a clay, an inert material, optionally a fibrous material, and a fourth component is provided, characterized in that said fourth component comprises a cation selected from the group consisting of Al, Zr and Ti and an anion selected from the group consisting of oxyhydroxide, oxychloride, nitrate, sulfate, chloride, hydroxide and alkoxide, and wherein the concentration of said fourth component ranges from 0.1 to 70 percent by weight (w %), preferably 0.5-25 w %, more preferably 1-10 w %, of the total weight of the clay, the inert material, and optionally the fibrous material, together.

Embodiments of a technique are provided for removing dust from treated seeds. The method includes applying a treatment to a number of seeds at a seed treatment station and at least partially drying the seeds at the treatment station. The partially dried seeds may then be conveyed through a conveying station from the treatment station to an output area. Air may be directed through an inlet of the conveying station, where the directed air is configured to remove non-seed particles from the seeds. Furthermore, air may be filtered through an outlet of the conveying station to capture the removed non-seed particles using a filtering system. In some cases, an initial temperature of the air may be controlled to optimize the dust removal process, such as by heating and/or chilling the air.

Embodiments of a technique are provided for removing dust from treated seeds. The method includes applying a treatment to a number of seeds at a seed treatment station and at least partially drying the seeds at the treatment station. The partially dried seeds may then be conveyed through a conveying station from the treatment station to an output area. Air may be directed through an inlet of the conveying station, where the directed air is configured to remove non-seed particles from the seeds. Furthermore, air may be filtered through an outlet of the conveying station to capture the removed non-seed particles using a filtering system. In some cases, an initial temperature of the air may be controlled to optimize the dust removal process, such as by heating and/or chilling the air.