>Applications
>124|P03038|Tetracycline repressor protein class A from transposon 1721|Escherichia coli|TetR
The Tet system has been used as an ideal transcriptional regulator in eukaryotic cells. Consequently, the past 15 years have seen the broad application of the tetracycline-dependent regulatory systems, mainly in mammalian cell culture, but to an increasing degree in transgenic organism like plants, yeast, protozoan parasites, slime molds, flies, and rodents.
>126|P04483|Tetracycline repressor protein class B from transposon Tn10|Escherichia coli|TetR
The Tet system has been used as an ideal transcriptional regulator in eukaryotic cells. Consequently, the past 15 years have seen the broad application of the tetracycline-dependent regulatory systems, mainly in mammalian cell culture, but to an increasing degree in transgenic organism like plants, yeast, protozoan parasites, slime molds, flies, and rodents.
>127|P03039|Tetracycline repressor protein class C|Escherichia coli|TetR
The Tet system has been used as an ideal transcriptional regulator in eukaryotic cells. Consequently, the past 15 years have seen the broad application of the tetracycline-dependent regulatory systems, mainly in mammalian cell culture, but to an increasing degree in transgenic organism like plants, yeast, protozoan parasites, slime molds, flies, and rodents.
>128|P09164|Tetracycline repressor protein class D|Escherichia coli|TetR
The Tet system has been used as an ideal transcriptional regulator in eukaryotic cells. Consequently, the past 15 years have seen the broad application of the tetracycline-dependent regulatory systems, mainly in mammalian cell culture, but to an increasing degree in transgenic organism like plants, yeast, protozoan parasites, slime molds, flies, and rodents.
>278|P72185|Repressor protein|Propionibacterium freudenreichii|TetR
Propionibacterium freudenreichii is a gram-positive bacterium that has been used in several dairy and fermentation systems, including the production of propionic acid and vitaminin B12.
>416|Q60011|Virginiae butanolide receptor|Streptomyces virginiae|TetR
The VB autoinducer-BarA system regultes the coordinate production of two structurally different compounds, virginiamycin M1 (VM1) and virginiamycin S (VS), a pair of antibiotics that show strong synergistyc bactericidal activity.
>866|Q9F0Y2|Pip|Streptomyces coelicolor|TetR
The Pip/ptr promoter system served as the basis for the develoment of systems allowing repression ot induction of cloned genes in mammalian and plant cells in response of streptogramin antibiotics such as pristinamycin I.
>892|Q9F9Z7|PhaD (Fragment)|Pseudomonas resinovorans|TetR
Polyhydroxyalkanoates are storage polymers accumulated by a wide variety of bacteria under conditions of nutrient limitation and carbon excess. PHAs are under investigation because of their potential as biodegradable polymers produced from renewable resources.
>965|Q9RA03|Hypothetical repressor protein KstR|Rhodococcus erythropolis|TetR
Several Rhodococcus species degrade natural phytosterols. Microbial phytosterol degradation proceeds via the formation of steroids as pathway intermediated. These steroid pathway intermediates may be used as presursors for the production of bioactive steroids.
>5116|15600252|probable transcriptional regulator|Pseudomonas aeruginosa PAO1|TetR
Polyhydroxyalkanoates are storage polymers accumulated by a wide variety of bacteria under conditions of nutrient limitation and carbon excess. PHAs are under investigation because of their potential as biodegradable polymers produced from renewable resources.
>6026|26991683|transcriptional regulator, TetR family|Pseudomonas putida KT2440|TetR
Polyhydroxyalkanoates are storage polymers accumulated by a wide variety of bacteria under conditions of nutrient limitation and carbon excess. PHAs are under investigation because of their potential as biodegradable polymers produced from renewable resources.
>7937|28872258|transcriptional regulator PhaD|Pseudomonas syringae pv. tomato str. DC3000|TetR
Polyhydroxyalkanoates are storage polymers accumulated by a wide variety of bacteria under conditions of nutrient limitation and carbon excess. PHAs are under investigation because of their potential as biodegradable polymers produced from renewable resources.
>9416|O24741|FarA|Streptomyces sp. FRI-5|TetR
FarA from Streptomyces sp. strain FRI-5 controls the production of the nucleoside antibiotics showdomycin and minimycin.