Literature summary extracted from

Khammar, N.; Martin, G.; Ferro, K.; Job, D.; Aragno, M.; Verrecchia, E.
Use of the frc gene as a molecular marker to characterize oxalate-oxidizing bacterial abundance and diversity structure in soil (2008), J. Microbiol. Methods, 76, 120-127.

Application

EC Number	Application	Comment	Organism
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Escherichia coli
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Starkeya novella
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Azospirillum brasilense
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Streptomyces violaceoruber
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Xanthomonas sp.
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Xanthobacter flavus
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Cupriavidus oxalaticus
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Methylorubrum extorquens
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Methylobacterium organophilum
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Variovorax paradoxus
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Azospirillum lipoferum
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Oxalobacter formigenes
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Cupriavidus necator
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Rhodopseudomonas palustris
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Shigella flexneri
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Streptomyces avermitilis
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Streptomyces coelicolor
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Xanthobacter autotrophicus
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Ancylobacter polymorphus
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Ancylobacter oerskovii
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Bradyrhizobium japonicum
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Methylorubrum thiocyanatum
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Pandoraea sp.
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Oxalicibacterium flavum
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Bradyrhizobium sp.
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Arquibacter sp.
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Herminiimonas saxobsidens
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Azorhizobium sp.
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Paraburkholderia xenovorans
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Herminiimonas arsenicoxydans
2.8.3.16	environmental protection	bacterial oxalate-degrading function, microbiological processes are considered as the main oxalate sinks in natural environments, in soil oxalate from fungi, plant root exudates and decaying plant tissues display powerful metal chelating properties. Oxalate takes part in plant nutrition status by increasing the availability of phosphate and other poorly soluble micro-nutriments, through its ability to complex and remove excess metal cations. It also plays an important role in the detoxification of heavy metals in the vicinity of plant roots.	Janthinobacterium sp. Marseille
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Escherichia coli
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Starkeya novella
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Azospirillum brasilense
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Streptomyces violaceoruber
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Xanthomonas sp.
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Xanthobacter flavus
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Cupriavidus oxalaticus
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Methylorubrum extorquens
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Methylobacterium organophilum
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Variovorax paradoxus
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Azospirillum lipoferum
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Oxalobacter formigenes
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Cupriavidus necator
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Rhodopseudomonas palustris
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Shigella flexneri
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Streptomyces avermitilis
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Streptomyces coelicolor
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Xanthobacter autotrophicus
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Ancylobacter polymorphus
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Ancylobacter oerskovii
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Bradyrhizobium japonicum
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Methylorubrum thiocyanatum
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Pandoraea sp.
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Oxalicibacterium flavum
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Bradyrhizobium sp.
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Arquibacter sp.
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Herminiimonas saxobsidens
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Azorhizobium sp.
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Paraburkholderia xenovorans
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Herminiimonas arsenicoxydans
2.8.3.16	medicine	bacterial oxalate-degrading function, in humans an accumulation of oxalic acid can result in a number of pathologic conditions, including hyperoxaluria, urolithiasis, renal failure, cardiomyopathy and cardiac conductance disorders	Janthinobacterium sp. Marseille
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Escherichia coli
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Starkeya novella
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Azospirillum brasilense
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Streptomyces violaceoruber
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Xanthomonas sp.
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Xanthobacter flavus
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Cupriavidus oxalaticus
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Methylorubrum extorquens
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Methylobacterium organophilum
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Variovorax paradoxus
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Azospirillum lipoferum
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Oxalobacter formigenes
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Cupriavidus necator
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Rhodopseudomonas palustris
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Shigella flexneri
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Streptomyces avermitilis
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Streptomyces coelicolor
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Xanthobacter autotrophicus
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Ancylobacter polymorphus
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Ancylobacter oerskovii
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Bradyrhizobium japonicum
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Methylorubrum thiocyanatum
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Pandoraea sp.
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Oxalicibacterium flavum
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Bradyrhizobium sp.
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Arquibacter sp.
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Herminiimonas saxobsidens
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Azorhizobium sp.
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Paraburkholderia xenovorans
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Herminiimonas arsenicoxydans
2.8.3.16	molecular biology	use of the frc gene as template for PCR to detect oxalotrophic bacteria	Janthinobacterium sp. Marseille

Cloned(Commentary)

EC Number	Cloned (Comment)	Organism
2.8.3.16	expression in Escherichia coli XL1	Escherichia coli
2.8.3.16	expression in Escherichia coli XL1	Starkeya novella
2.8.3.16	expression in Escherichia coli XL1	Azospirillum brasilense
2.8.3.16	expression in Escherichia coli XL1	Streptomyces violaceoruber
2.8.3.16	expression in Escherichia coli XL1	Xanthomonas sp.
2.8.3.16	expression in Escherichia coli XL1	Xanthobacter flavus
2.8.3.16	expression in Escherichia coli XL1	Cupriavidus oxalaticus
2.8.3.16	expression in Escherichia coli XL1	Methylorubrum extorquens
2.8.3.16	expression in Escherichia coli XL1	Methylobacterium organophilum
2.8.3.16	expression in Escherichia coli XL1	Variovorax paradoxus
2.8.3.16	expression in Escherichia coli XL1	Azospirillum lipoferum
2.8.3.16	expression in Escherichia coli XL1	Oxalobacter formigenes
2.8.3.16	expression in Escherichia coli XL1	Cupriavidus necator
2.8.3.16	expression in Escherichia coli XL1	Rhodopseudomonas palustris
2.8.3.16	expression in Escherichia coli XL1	Shigella flexneri
2.8.3.16	expression in Escherichia coli XL1	Streptomyces avermitilis
2.8.3.16	expression in Escherichia coli XL1	Streptomyces coelicolor
2.8.3.16	expression in Escherichia coli XL1	Xanthobacter autotrophicus
2.8.3.16	expression in Escherichia coli XL1	Ancylobacter polymorphus
2.8.3.16	expression in Escherichia coli XL1	Ancylobacter oerskovii
2.8.3.16	expression in Escherichia coli XL1	Bradyrhizobium japonicum
2.8.3.16	expression in Escherichia coli XL1	Methylorubrum thiocyanatum
2.8.3.16	expression in Escherichia coli XL1	Pandoraea sp.
2.8.3.16	expression in Escherichia coli XL1	Oxalicibacterium flavum
2.8.3.16	expression in Escherichia coli XL1	Bradyrhizobium sp.
2.8.3.16	expression in Escherichia coli XL1	Arquibacter sp.
2.8.3.16	expression in Escherichia coli XL1	Herminiimonas saxobsidens
2.8.3.16	expression in Escherichia coli XL1	Azorhizobium sp.
2.8.3.16	expression in Escherichia coli XL1	Paraburkholderia xenovorans
2.8.3.16	expression in Escherichia coli XL1	Herminiimonas arsenicoxydans
2.8.3.16	expression in Escherichia coli XL1	Janthinobacterium sp. Marseille

Natural Substrates/ Products (Substrates)

EC Number	Natural Substrates	Organism	Comment (Nat. Sub.)	Natural Products	Comment (Nat. Pro.)	Rev.
2.8.3.16	formyl-CoA + oxalate	Escherichia coli	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Starkeya novella	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Azospirillum brasilense	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Streptomyces violaceoruber	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Xanthomonas sp.	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Xanthobacter flavus	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Cupriavidus oxalaticus	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Methylorubrum extorquens	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Methylobacterium organophilum	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Variovorax paradoxus	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Azospirillum lipoferum	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Oxalobacter formigenes	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Cupriavidus necator	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Rhodopseudomonas palustris	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Shigella flexneri	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Streptomyces avermitilis	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Streptomyces coelicolor	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Xanthobacter autotrophicus	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Ancylobacter polymorphus	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Ancylobacter oerskovii	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Bradyrhizobium japonicum	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Methylorubrum thiocyanatum	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Pandoraea sp.	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Oxalicibacterium flavum	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Bradyrhizobium sp.	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Arquibacter sp.	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Herminiimonas saxobsidens	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Azorhizobium sp.	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Paraburkholderia xenovorans	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Herminiimonas arsenicoxydans	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Janthinobacterium sp. Marseille	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	Cupriavidus necator JMP 134-1	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	formate + oxalyl-CoA	-	?

Organism

EC Number	Organism	UniProt	Comment	Textmining
2.8.3.16	Ancylobacter oerskovii	-	-	-
2.8.3.16	Ancylobacter polymorphus	B3VMH8	fragment	-
2.8.3.16	Arquibacter sp.	-	-	-
2.8.3.16	Azorhizobium sp.	-	-	-
2.8.3.16	Azospirillum brasilense	-	-	-
2.8.3.16	Azospirillum lipoferum	-	-	-
2.8.3.16	Bradyrhizobium japonicum	Q89QH2	USDA 110, gene frc, no detection of the frc-gene in Klebsiella oxytoca, Bacillus subtilis, Micrococcus luteus, Microvirgula aerodenitrificans, Paracoccus denitrificans, Rhodococcus opacus, Xanthobacter agilis and Pseudomonas aeruginosa	-
2.8.3.16	Bradyrhizobium sp.	A5EGD7	BTAi1, frc gene	-
2.8.3.16	Cupriavidus necator	Q0K0H8	H16 gene	-
2.8.3.16	Cupriavidus necator	Q46S66	JMP134, Reut_B4669 gene	-
2.8.3.16	Cupriavidus necator	Q46S72	JMP 134	-
2.8.3.16	Cupriavidus necator JMP 134-1	Q46S72	JMP 134	-
2.8.3.16	Cupriavidus oxalaticus	-	-	-
2.8.3.16	Escherichia coli	-	B, frc gene, but no Ca-oxalat utilization	-
2.8.3.16	Escherichia coli	P69902	K12, frc gene	-
2.8.3.16	Herminiimonas arsenicoxydans	A4G241	frcA gene	-
2.8.3.16	Herminiimonas arsenicoxydans	A4G242	frcB gene	-
2.8.3.16	Herminiimonas saxobsidens	-	-	-
2.8.3.16	Janthinobacterium sp. Marseille	A6T0J2	caiB3 gene	-
2.8.3.16	Methylobacterium organophilum	-	-	-
2.8.3.16	Methylorubrum extorquens	-	-	-
2.8.3.16	Methylorubrum thiocyanatum	-	-	-
2.8.3.16	Oxalicibacterium flavum	-	-	-
2.8.3.16	Oxalobacter formigenes	O06644	frc gene	-
2.8.3.16	Pandoraea sp.	-	-	-
2.8.3.16	Paraburkholderia xenovorans	Q13RQ4	LB400, frc gene	-
2.8.3.16	Rhodopseudomonas palustris	Q6N8F8	CGA009, frc gene	-
2.8.3.16	Shigella flexneri	P69903	2a strain 301, frc gene	-
2.8.3.16	Starkeya novella	-	-	-
2.8.3.16	Streptomyces avermitilis	Q82M40	MA-4680, frc gene	-
2.8.3.16	Streptomyces coelicolor	O87838	A3, frc gene	-
2.8.3.16	Streptomyces violaceoruber	-	-	-
2.8.3.16	Variovorax paradoxus	-	-	-
2.8.3.16	Xanthobacter autotrophicus	A7ICK2	Py2, Xaut_0487 gene	-
2.8.3.16	Xanthobacter flavus	-	-	-
2.8.3.16	Xanthomonas sp.	-	frc gene, but no Ca-oxalate utilization	-

Source Tissue

EC Number	Source Tissue	Comment	Organism	Textmining
2.8.3.16	enrichment culture	oxalate enrichment culture	Escherichia coli	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Starkeya novella	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Azospirillum brasilense	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Streptomyces violaceoruber	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Xanthomonas sp.	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Xanthobacter flavus	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Cupriavidus oxalaticus	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Methylorubrum extorquens	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Methylobacterium organophilum	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Variovorax paradoxus	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Azospirillum lipoferum	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Oxalobacter formigenes	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Cupriavidus necator	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Rhodopseudomonas palustris	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Shigella flexneri	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Streptomyces avermitilis	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Streptomyces coelicolor	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Xanthobacter autotrophicus	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Ancylobacter polymorphus	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Ancylobacter oerskovii	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Bradyrhizobium japonicum	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Methylorubrum thiocyanatum	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Pandoraea sp.	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Oxalicibacterium flavum	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Bradyrhizobium sp.	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Arquibacter sp.	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Herminiimonas saxobsidens	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Azorhizobium sp.	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Paraburkholderia xenovorans	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Herminiimonas arsenicoxydans	-
2.8.3.16	enrichment culture	oxalate enrichment culture	Janthinobacterium sp. Marseille	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Escherichia coli	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Starkeya novella	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Azospirillum brasilense	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Streptomyces violaceoruber	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Xanthomonas sp.	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Xanthobacter flavus	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Cupriavidus oxalaticus	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Methylorubrum extorquens	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Methylobacterium organophilum	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Variovorax paradoxus	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Azospirillum lipoferum	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Oxalobacter formigenes	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Cupriavidus necator	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Rhodopseudomonas palustris	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Shigella flexneri	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Streptomyces avermitilis	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Streptomyces coelicolor	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Xanthobacter autotrophicus	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Ancylobacter polymorphus	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Ancylobacter oerskovii	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Bradyrhizobium japonicum	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Methylorubrum thiocyanatum	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Pandoraea sp.	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Oxalicibacterium flavum	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Bradyrhizobium sp.	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Arquibacter sp.	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Herminiimonas saxobsidens	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Azorhizobium sp.	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Paraburkholderia xenovorans	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Herminiimonas arsenicoxydans	-
2.8.3.16	soil	soil samples are collected below the Ca-oxalate producing trees Milicia excelsa and Afzelia africana and in a similar soil distant from trees	Janthinobacterium sp. Marseille	-

Substrates and Products (Substrate)

EC Number	Substrates	Comment Substrates	Organism	Products	Comment (Products)	Rev.
2.8.3.16	formyl-CoA + oxalate	-	Escherichia coli	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Starkeya novella	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Azospirillum brasilense	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Streptomyces violaceoruber	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Xanthomonas sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Xanthobacter flavus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Cupriavidus oxalaticus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Methylorubrum extorquens	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Methylobacterium organophilum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Variovorax paradoxus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Azospirillum lipoferum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Oxalobacter formigenes	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Cupriavidus necator	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Rhodopseudomonas palustris	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Shigella flexneri	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Streptomyces avermitilis	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Streptomyces coelicolor	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Xanthobacter autotrophicus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Ancylobacter polymorphus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Ancylobacter oerskovii	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Bradyrhizobium japonicum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Methylorubrum thiocyanatum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Pandoraea sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Oxalicibacterium flavum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Bradyrhizobium sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Arquibacter sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Herminiimonas saxobsidens	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Azorhizobium sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Paraburkholderia xenovorans	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Herminiimonas arsenicoxydans	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Janthinobacterium sp. Marseille	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Escherichia coli	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Starkeya novella	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Azospirillum brasilense	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Streptomyces violaceoruber	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Xanthomonas sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Xanthobacter flavus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Cupriavidus oxalaticus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Methylorubrum extorquens	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Methylobacterium organophilum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Variovorax paradoxus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Azospirillum lipoferum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Oxalobacter formigenes	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Cupriavidus necator	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Rhodopseudomonas palustris	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Shigella flexneri	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Streptomyces avermitilis	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Streptomyces coelicolor	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Xanthobacter autotrophicus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Ancylobacter polymorphus	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Ancylobacter oerskovii	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Bradyrhizobium japonicum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Methylorubrum thiocyanatum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Pandoraea sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Oxalicibacterium flavum	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Bradyrhizobium sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Arquibacter sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Herminiimonas saxobsidens	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Azorhizobium sp.	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Paraburkholderia xenovorans	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Herminiimonas arsenicoxydans	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Janthinobacterium sp. Marseille	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	-	Cupriavidus necator JMP 134-1	formate + oxalyl-CoA	-	?
2.8.3.16	formyl-CoA + oxalate	oxalate is a highly oxidized compound that may be used as C- and energy sources by oxalotrophic bacteria	Cupriavidus necator JMP 134-1	formate + oxalyl-CoA	-	?

Synonyms

EC Number	Synonyms	Comment	Organism
2.8.3.16	formyl-CoA-transferase	-	Escherichia coli
2.8.3.16	formyl-CoA-transferase	-	Starkeya novella
2.8.3.16	formyl-CoA-transferase	-	Azospirillum brasilense
2.8.3.16	formyl-CoA-transferase	-	Streptomyces violaceoruber
2.8.3.16	formyl-CoA-transferase	-	Xanthomonas sp.
2.8.3.16	formyl-CoA-transferase	-	Xanthobacter flavus
2.8.3.16	formyl-CoA-transferase	-	Cupriavidus oxalaticus
2.8.3.16	formyl-CoA-transferase	-	Methylorubrum extorquens
2.8.3.16	formyl-CoA-transferase	-	Methylobacterium organophilum
2.8.3.16	formyl-CoA-transferase	-	Variovorax paradoxus
2.8.3.16	formyl-CoA-transferase	-	Azospirillum lipoferum
2.8.3.16	formyl-CoA-transferase	-	Oxalobacter formigenes
2.8.3.16	formyl-CoA-transferase	-	Cupriavidus necator
2.8.3.16	formyl-CoA-transferase	-	Rhodopseudomonas palustris
2.8.3.16	formyl-CoA-transferase	-	Shigella flexneri
2.8.3.16	formyl-CoA-transferase	-	Streptomyces avermitilis
2.8.3.16	formyl-CoA-transferase	-	Streptomyces coelicolor
2.8.3.16	formyl-CoA-transferase	-	Xanthobacter autotrophicus
2.8.3.16	formyl-CoA-transferase	-	Ancylobacter polymorphus
2.8.3.16	formyl-CoA-transferase	-	Ancylobacter oerskovii
2.8.3.16	formyl-CoA-transferase	-	Bradyrhizobium japonicum
2.8.3.16	formyl-CoA-transferase	-	Methylorubrum thiocyanatum
2.8.3.16	formyl-CoA-transferase	-	Pandoraea sp.
2.8.3.16	formyl-CoA-transferase	-	Oxalicibacterium flavum
2.8.3.16	formyl-CoA-transferase	-	Bradyrhizobium sp.
2.8.3.16	formyl-CoA-transferase	-	Arquibacter sp.
2.8.3.16	formyl-CoA-transferase	-	Herminiimonas saxobsidens
2.8.3.16	formyl-CoA-transferase	-	Azorhizobium sp.
2.8.3.16	formyl-CoA-transferase	-	Paraburkholderia xenovorans
2.8.3.16	formyl-CoA-transferase	-	Herminiimonas arsenicoxydans
2.8.3.16	formyl-CoA-transferase	-	Janthinobacterium sp. Marseille