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Pathways

PathWhiz ID Pathway Meta Data

PW122490

Pw122490 View Pathway
metabolic

Taurine and Hypotaurine Metabolism

Xenopus laevis

PW088233

Pw088233 View Pathway
metabolic

Taurine and Hypotaurine Metabolism

Bos taurus
There is an organic acid known as Taurine, which is a derivative product of sulfhydryl amino acid (which contains sulfur), as well as cysteine. The synthesis or metabolism in mammalian systems of this acid transpires within the pancreas in such a fashion that it utilizes a pathway known as the cysteine sulfinic acid pathway. To put this process in context, its occurrence is often seen in vivo, in hepatocytes, and is fundamental in the cyclical process of recovering bile acids from the intenstine, turning them back into salts and returning them to the bile. In essence the cysteine pathway induces a sulfhydryl group to be oxidized, creating cysteine sulfinic acid, by utilizing the appropriate enzymes (ie cysteine dioxygenase). This new acid undergoes decarboxylation creating a new compound: hypotaurine. This process goes on as Taurine now is subjected to conjugation vis a vis its amino terminal group. This includes acids such as chenodeoxycholic acid and cholic acid, and in turn the formation of bile salts occurs. Moreover, this entire process can be catalyzed via bile acid and a special amino acid N-acetyltransferase.

PW122491

Pw122491 View Pathway
metabolic

Taurine and Hypotaurine Metabolism

Danio rerio

PW064657

Pw064657 View Pathway
metabolic

Taurine and Hypotaurine Metabolism

Mus musculus
There is an organic acid known as Taurine, which is a derivative product of sulfhydryl amino acid (which contains sulfur), as well as cysteine. The synthesis or metabolism in mammalian systems of this acid transpires within the pancreas in such a fashion that it utilizes a pathway known as the cysteine sulfinic acid pathway. To put this process in context, its occurrence is often seen in vivo, in hepatocytes, and is fundamental in the cyclical process of recovering bile acids from the intenstine, turning them back into salts and returning them to the bile. In essence the cysteine pathway induces a sulfhydryl group to be oxidized, creating cysteine sulfinic acid, by utilizing the appropriate enzymes (ie cysteine dioxygenase). This new acid undergoes decarboxylation creating a new compound: hypotaurine. This process goes on as Taurine now is subjected to conjugation vis a vis its amino terminal group. This includes acids such as chenodeoxycholic acid and cholic acid, and in turn the formation of bile salts occurs. Moreover, this entire process can be catalyzed via bile acid and a special amino acid N-acetyltransferase.

PW088328

Pw088328 View Pathway
metabolic

Taurine and Hypotaurine Metabolism

Rattus norvegicus
There is an organic acid known as Taurine, which is a derivative product of sulfhydryl amino acid (which contains sulfur), as well as cysteine. The synthesis or metabolism in mammalian systems of this acid transpires within the pancreas in such a fashion that it utilizes a pathway known as the cysteine sulfinic acid pathway. To put this process in context, its occurrence is often seen in vivo, in hepatocytes, and is fundamental in the cyclical process of recovering bile acids from the intenstine, turning them back into salts and returning them to the bile. In essence the cysteine pathway induces a sulfhydryl group to be oxidized, creating cysteine sulfinic acid, by utilizing the appropriate enzymes (ie cysteine dioxygenase). This new acid undergoes decarboxylation creating a new compound: hypotaurine. This process goes on as Taurine now is subjected to conjugation vis a vis its amino terminal group. This includes acids such as chenodeoxycholic acid and cholic acid, and in turn the formation of bile salts occurs. Moreover, this entire process can be catalyzed via bile acid and a special amino acid N-acetyltransferase.

PW000038

Pw000038 View Pathway
metabolic

Taurine and Hypotaurine Metabolism

Homo sapiens
There is an organic acid known as Taurine, which is a derivative product of sulfhydryl amino acid (which contains sulfur), as well as cysteine. The synthesis or metabolism in mammalian systems of this acid transpires within the pancreas in such a fashion that it utilizes a pathway known as the cysteine sulfinic acid pathway. To put this process in context, its occurrence is often seen in vivo, in hepatocytes, and is fundamental in the cyclical process of recovering bile acids from the intenstine, turning them back into salts and returning them to the bile. In essence the cysteine pathway induces a sulfhydryl group to be oxidized, creating cysteine sulfinic acid, by utilizing the appropriate enzymes (ie cysteine dioxygenase). This new acid undergoes decarboxylation creating a new compound: hypotaurine. This process goes on as Taurine now is subjected to conjugation vis a vis its amino terminal group. This includes acids such as chenodeoxycholic acid and cholic acid, and in turn the formation of bile salts occurs. Moreover, this entire process can be catalyzed via bile acid and a special amino acid N-acetyltransferase.

PW145503

Pw145503 View Pathway
drug action

Taurine Drug Metabolism Action Pathway

Homo sapiens

PW122576

Pw122576 View Pathway
metabolic

Taurine Metabolism

Pseudomonas aeruginosa
Taurine enters into the cytoplasm through a taurine ATP-binding cassette (ABC) transporters. Once inside, the enzyme taurine dioxygenase encourages the interaction between taurine, oxoglutaric acid and oxygen resulting in the release of succinic acid, sulfite, aminoacetaldehyde, and carbon dioxide.

PW000774

Pw000774 View Pathway
metabolic

Taurine Metabolism

Escherichia coli
Taurine enters into the cytoplasm through a taurine ATP-binding cassette (ABC) transporters. Once inside, the enzyme taurine dioxygenase encourages the interaction between taurine, oxoglutaric acid and oxygen resulting in the release of succinic acid, sulfite, aminoacetaldehyde, and carbon dioxide.

PW001028

Pw001028 View Pathway
metabolic

Taurine Metabolism I

Escherichia coli
Taurine is incorporated into the cytoplasm through a taurine ABC transporter. Once inside the cytoplasm, taurine interacts with an oxoglutaric acid and an oxygen through a taurine dioxygenase resulting in the release of succinic acid, sulfite , aminoacetaldehyde and carbon dioxide.