The present invention discloses a glycosylated oxalate decarboxylase. The oxalate decarboxylase is derived from edible basidiomycetes, the glycosylated oxalate decarboxylase has an enzyme activity at the pH value of 1.5-7.5, the activity at the pH value of 1.5-2.0 is 10% greater than the optimum activity, and a specific activity is more than 2 U/mg. The present invention also discloses preparation and application of the glycosylated oxalate decarboxylase. The glycosylated oxalate decarboxylase disclosed by the present invention can keep the activity under a low pH value, and can effectively prevent and treat kidney stones.

The present invention comprises methods and compositions for the reduction of oxalate in humans, and methods for the purification and isolation of recombinant oxalate reducing enzyme proteins. The invention provides methods and compositions for the delivery of oxalate-reducing enzymes in particle compositions. The compositions of the present invention are suitable in methods of treatment or prevention of oxalate-related conditions.

Pharmaceutical compositions comprising spray-dried oxalate decarboxylase crystals are disclosed. Methods to treat a disorder associated with elevated oxalate concentration using compositions comprising spray-dried oxalate decarboxylase crystals are also disclosed.

Pharmaceutical compositions comprising spray-dried oxalate decarboxylase crystals are disclosed. Methods to treat a disorder associated with elevated oxalate concentration using compositions comprising spray-dried oxalate decarboxylase crystals are also disclosed.

Oxalate decarboxylase crystals, including stabilized crystals, such as cross-linked crystals of oxalate decarboxylase, are disclosed. Methods to treat a disorder associated with elevated oxalate concentration using oxalate decarboxylase crystals are also disclosed. Additionally disclosed are methods of producing protein crystals.

The present invention provides recombinant bacterial cells comprising at least one heterologous gene encoding at least one oxalate catabolism enzyme. In another aspect, the recombinant bacterial cells further comprise at least one heterologous gene encoding an importer of oxalate. The invention further provides pharmaceutical compositions comprising the recombinant bacteria, and methods for treating disorders in which oxalate is detrimental, such as hyperoxaluria, using the pharmaceutical compositions of the invention.

The present invention comprises methods and compositions for the reduction of oxalate in humans. For example, the invention provides methods and compositions for the delivery of one or more oxalate-reducing enzymes embedded in particle compositions. The compositions of the present invention are suitable in methods of treatment or prevention of oxalate-related conditions including, but not limited to, hyperoxaluria, absorptive hyperoxaluria, enteric hyperoxaluria, primary hyperoxaluria, idiopathic calcium oxalate kidney stone disease (urolithiasis), vulvodynia, oxalosis associated with end-stage renal disease, cardiac conductance disorders, inflammatory bowel disease, Crohn's disease, ulcerative colitis, and patients who have undergone gastrointestinal surgery and bariatric surgery (surgery for obesity), and/or who have undergone antibiotic treatment.

Pharmaceutical compositions comprising spray-dried oxalate decarboxylase crystals are disclosed. Methods to treat a disorder associated with elevated oxalate concentration using compositions comprising spray-dried oxalate decarboxylase crystals are also disclosed.

The present invention comprises methods and compositions for the reduction of oxalate in humans, animals and plants. For example, the invention provides methods and compositions for the delivery of one ore more oxalate-reducing enzymes to the intestinal tracts of persons and animals. The methods and compositions can be used in treating and preventing oxalate-related conditions.

The present disclosure relates to engineered microbial cells that have been engineered to comprise one or more oxalate catabolismgenes that are expressed under the control of non-native, non-inducible promoters. Thus, the genetically engineered microbial cells and pharmaceutical compositions comprising the microbial cells are useful in degrading oxalate inside or outside the engineered microbial cell, resulting in a reduction of the concentration of oxalate outside the cell. The engineered microbial cells of the present disclosure are useful in methods of treating or preventing diseases associated with disorders in which oxalate is detrimental, such as hyperoxalurias. The engineered microbial cells of the present disclosure are also useful in methods of treating calcium oxalate nephrocalcinosis, calcium oxalate nephrolithiasis and calcium oxalate urolithiasis.