The present invention relates to phytase variants. The present invention also relates to polynucleotides encoding the variants; nucleic acid constructs, vectors, and host cells comprising the polynucleotides; and methods of using the variants.

The present invention relates to phytase variants. The present invention also relates to polynucleotides encoding the variants; nucleic acid constructs, vectors, and host cells comprising the polynucleotides; and methods of using the variants.

The present invention relates to a method for identifying a pepsin resistant alpha amylase enzyme for use in a feed supplement comprising: i) providing an alpha amylase enzyme; ii) admixing said alpha amylase with com based feed and buffer solution comprising a pepsin concentration of 9000 U/ml at pH 3, 40° C., 500 rpm for al least 120 minutes and analysing alpha amylase activity on said alpha amylase compared to a control sample; wherein said control sample differs in that no pepsin is present during incubation; and iii) selecting an alpha amylase enzyme which substantially maintains alpha amylase activity under the assay conditions; feed supplements and feed stuffs comprising a pepsin resistant alpha amylase and the use of pepsin resistant alpha amylases in feed.

The present invention relates to a method for identifying a pepsin resistant alpha amylase enzyme for use in a feed supplement comprising: i) providing an alpha amylase enzyme; ii) admixing said alpha amylase with com based feed and buffer solution comprising a pepsin concentration of 9000 U/ml at pH 3, 40° C., 500 rpm for al least 120 minutes and analysing alpha amylase activity on said alpha amylase compared to a control sample; wherein said control sample differs in that no pepsin is present during incubation; and iii) selecting an alpha amylase enzyme which substantially maintains alpha amylase activity under the assay conditions; feed supplements and feed stuffs comprising a pepsin resistant alpha amylase and the use of pepsin resistant alpha amylases in feed.

Methods for enhancing phytase thermal stability by fusing binding elements to target phytases are provided. Engineered phytases that include binding elements fused to target phytases to cause cyclization of the engineered phytases and enhance thermal stability of the target phytases are described. Engineered nucleic acids encoding engineered phytases and hosts engineered to express engineered nucleic acids are also provided. Methods for incorporating engineered phytases in animal feed and animal feed including the same are described.

Methods for enhancing phytase thermal stability by fusing binding elements to target phytases are provided. Engineered phytases that include binding elements fused to target phytases to cause cyclization of the engineered phytases and enhance thermal stability of the target phytases are described. Engineered nucleic acids encoding engineered phytases and hosts engineered to express engineered nucleic acids are also provided. Methods for incorporating engineered phytases in animal feed and animal feed including the same are described.

The present invention provides phytase enzymes exhibiting a surprisingly high thermostability as compared to commercially available phytases. Additionally some of the new phytase variants display up to four fold increased catalytic rate thus greatly increased speed of phytate dephosphorilation.

The present invention provides phytase enzymes exhibiting a surprisingly high thermostability as compared to commercially available phytases. Additionally some of the new phytase variants display up to four fold increased catalytic rate thus greatly increased speed of phytate dephosphorilation.

An oral formulation of bromelain effective to treat and prevent diarrhea caused by pathogenic microbes. This formulation does not kill pathogenic microbes, and thus does not facilitate the proliferation of anti-microbial resistant organisms. The invention entails formulating an aqueous oral suspension of bromelain, Blanose sodium carboxymethyl cellulose, citric acid anhydrous, Epikuron 135F lecithin oil and ethylenedinitrilotetraacetic acid, disodium salt dihydrate (“EDTA”).

The invention relates to a feed additive comprising at least one nutrient, which non-nutrient is incorporated in a matrix, the entirety being encapsulated by a coating comprising at least a plant material whose saponification number is greater than 180.

The invention also deals with a method for preparing a feed additive.

Finally, the invention also relates to the use of the feed additive to improve the zootechnical performance of a ruminant.