Literature summary extracted from

Buttlaire, D.H.
Purification and properties of formyltetrahydrofolate synthetase (1980), Methods Enzymol., 66, 585-599.

Crystallization (Commentary)

EC Number	Crystallization (Comment)	Organism
6.3.4.3	-	Clostridium cylindrosporum

General Stability

EC Number	General Stability	Organism
6.3.4.3	purified enzyme as crystalline suspension, 15% loss of activity after 1 month	Clostridium cylindrosporum
6.3.4.3	tetramer is stabilized by 0.1 M sulfate in absence of an active monovalent cation	Clostridium cylindrosporum
6.3.4.3	unstable in absence of monovalent cations	Clostridium cylindrosporum
6.3.4.3	unstable in presence of urea and guanidinium chloride	Clostridium cylindrosporum

Inhibitors

EC Number	Inhibitors	Comment	Organism
6.3.4.3	5,5'-dithiobis(2-nitrobenzoate)	-	Clostridium cylindrosporum
6.3.4.3	Adenylyl imidodiphosphate	competitive to ATP	Clostridium cylindrosporum
6.3.4.3	ADP	competitive to ATP	Clostridium cylindrosporum
6.3.4.3	alpha,beta-methyleneadenosine 5'-triphosphate	competitive to ATP	Clostridium cylindrosporum
6.3.4.3	beta,gamma-methyleneadenosine 5'-triphosphate	competitive to ATP	Clostridium cylindrosporum
6.3.4.3	Formyltetrahydrofolate	-	Clostridium cylindrosporum
6.3.4.3	Mersalyl	-	Clostridium cylindrosporum
6.3.4.3	NEM	-	Clostridium cylindrosporum
6.3.4.3	p-hydroxymercuribenzoate	-	Moorella thermoacetica
6.3.4.3	phosphate	-	Clostridium cylindrosporum

KM Value [mM]

EC Number	KM Value [mM]	KM Value Maximum [mM]	Substrate	Comment	Organism
6.3.4.3	additional information	-	additional information	-	Oryctolagus cuniculus
6.3.4.3	additional information	-	additional information	-	Moorella thermoacetica
6.3.4.3	additional information	-	additional information	monovalent cations decrease the Km for formate	Clostridium cylindrosporum
6.3.4.3	0.025	-	5,6,7,8-tetrahydropteroyltriglutamate	-	Pisum sativum
6.3.4.3	0.025	-	5,6,7,8-tetrahydropteroyltriglutamate	-	Clostridium cylindrosporum
6.3.4.3	0.12	-	ATP	-	Saccharomyces cerevisiae
6.3.4.3	0.12	-	ATP	N10-formyltetrahydropteroyl-Glu3	Clostridium cylindrosporum
6.3.4.3	0.13	-	ADP	formyltetrahydrofolate synthesis	Clostridium cylindrosporum
6.3.4.3	0.14	-	ATP	-	Pisum sativum
6.3.4.3	0.14	-	ATP	-	Clostridium cylindrosporum
6.3.4.3	0.22	-	ATP	-	Clostridium cylindrosporum
6.3.4.3	5	-	phosphate	-	Clostridium cylindrosporum
6.3.4.3	6.7	-	formate	wild-type enzyme	Clostridium cylindrosporum
6.3.4.3	10	-	N10-formyltetrahydrofolate	-	Clostridium cylindrosporum

Metals/Ions

EC Number	Metals/Ions	Comment	Organism
6.3.4.3	Ca2+	the requirement for a divalent cation is most effectively satisfied by Mg2+. Mn2+ and Ca2+ can substitute for Mg2+	Spinacia oleracea
6.3.4.3	Ca2+	the requirement for a divalent cation is most effectively satisfied by Mg2+. Mn2+ and Ca2+ can substitute for Mg2+	Clostridium cylindrosporum
6.3.4.3	Cs+	-	Spinacia oleracea
6.3.4.3	Cs+	specific monovalent cations required for maximal activity, order of effectiveness: NH4+, Tl+, Rb+ ~ K+, Cs+, Na+ ~ Li+	Clostridium cylindrosporum
6.3.4.3	divalent metal ion	the requirement for a divalent cation is most effectively satisfied by Mg2+. Mn2+ and Ca2+ can substitute for Mg2+	Spinacia oleracea
6.3.4.3	divalent metal ion	the requirement for a divalent cation is most effectively satisfied by Mg2+. Mn2+ and Ca2+ can substitute for Mg2+	Clostridium cylindrosporum
6.3.4.3	K+	-	Saccharomyces cerevisiae
6.3.4.3	K+	-	Oryctolagus cuniculus
6.3.4.3	K+	-	Spinacia oleracea
6.3.4.3	K+	-	Moorella thermoacetica
6.3.4.3	K+	specific monovalent cations required for maximal activity, order of effectiveness: NH4+, Tl+, Rb+ ~ K+, Cs+, Na+ ~ Li+	Clostridium cylindrosporum
6.3.4.3	Li+	specific monovalent cations required for maximal activity, order of effectiveness: NH4+, Tl+, Rb+ ~ K+, Cs+, Na+ ~ Li+	Clostridium cylindrosporum
6.3.4.3	Mg2+	-	Saccharomyces cerevisiae
6.3.4.3	Mg2+	-	Pisum sativum
6.3.4.3	Mg2+	the requirement for a divalent cation is most effectively satisfied by Mg2+. Mn2+ and Ca2+ can substitute for Mg2+	Spinacia oleracea
6.3.4.3	Mg2+	the requirement for a divalent cation is most effectively satisfied by Mg2+. Mn2+ and Ca2+ can substitute for Mg2+	Clostridium cylindrosporum
6.3.4.3	Mn2+	the requirement for a divalent cation is most effectively satisfied by Mg2+. Mn2+ and Ca2+ can substitute for Mg2+	Spinacia oleracea
6.3.4.3	Mn2+	the requirement for a divalent cation is most effectively satisfied by Mg2+. Mn2+ and Ca2+ can substitute for Mg2+	Clostridium cylindrosporum
6.3.4.3	monovalent cations	-	Spinacia oleracea
6.3.4.3	monovalent cations	specific monovalent cations required for maximal activity, order of effectiveness: NH4+, Tl+, Rb+ ~ K+, Cs+, Na+ ~ Li+	Clostridium cylindrosporum
6.3.4.3	Na+	-	Spinacia oleracea
6.3.4.3	Na+	specific monovalent cations required for maximal activity, order of effectiveness: NH4+, Tl+, Rb+ ~ K+, Cs+, Na+ ~ Li+	Clostridium cylindrosporum
6.3.4.3	NH4+	-	Oryctolagus cuniculus
6.3.4.3	NH4+	-	Spinacia oleracea
6.3.4.3	NH4+	-	Pisum sativum
6.3.4.3	NH4+	-	Moorella thermoacetica
6.3.4.3	NH4+	specific monovalent cations required for maximal activity, order of effectiveness: NH4+, Tl+, Rb+ ~ K+, Cs+, Na+ ~ Li+	Clostridium cylindrosporum
6.3.4.3	Rb+	-	Spinacia oleracea
6.3.4.3	Rb+	specific monovalent cations required for maximal activity, order of effectiveness: NH4+, Tl+, Rb+ ~ K+, Cs+, Na+ ~ Li+	Clostridium cylindrosporum
6.3.4.3	Tl+	specific monovalent cations required for maximal activity, order of effectiveness: NH4+, Tl+, Rb+ ~ K+, Cs+, Na+ ~ Li+	Clostridium cylindrosporum

Molecular Weight [Da]

EC Number	Molecular Weight [Da]	Molecular Weight Maximum [Da]	Comment	Organism
6.3.4.3	240000	-	gel filtration, sedimentation analysis	Clostridium cylindrosporum

Natural Substrates/ Products (Substrates)

EC Number	Natural Substrates	Organism	Comment (Nat. Sub.)	Natural Products	Comment (Nat. Pro.)	Rev.
6.3.4.3	ATP + formate + tetrahydrofolate	Gallus gallus	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Escherichia coli	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Homo sapiens	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Saccharomyces cerevisiae	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Oryctolagus cuniculus	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Neurospora crassa	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Ovis aries	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Spinacia oleracea	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Pisum sativum	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Priestia megaterium	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Pigeon	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Proteus vulgaris	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Clostridium cylindrosporum	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Clostridium acidi-urici	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Moorella thermoacetica	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Micrococcus aerogenes	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	Veillonella parvula	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	?	-	?

Organism

EC Number	Organism	UniProt	Comment	Textmining
6.3.4.3	Clostridium acidi-urici	-	-	-
6.3.4.3	Clostridium cylindrosporum	-	-	-
6.3.4.3	Escherichia coli	-	-	-
6.3.4.3	Gallus gallus	-	-	-
6.3.4.3	Homo sapiens	-	trifunctional enzyme with 10-formyltetrahydrofolate synthetase, EC 6.3.4.3, 5,10-methenyltetrahydrofolate cyclohydrolase, EC 3.5.4.9, and 5,10-methylenetetrahydrofolate dehydrogenase activity, EC 1.5.1.5	-
6.3.4.3	Micrococcus aerogenes	-	-	-
6.3.4.3	Moorella thermoacetica	-	-	-
6.3.4.3	Neurospora crassa	-	-	-
6.3.4.3	Oryctolagus cuniculus	-	-	-
6.3.4.3	Ovis aries	-	trifunctional enzyme with 10-formyltetrahydrofolate synthetase, EC 6.3.4.3, 5,10-methenyltetrahydrofolate cyclohydrolase, EC 3.5.4.9, and 5,10-methylenetetrahydrofolate dehydrogenase activity, EC 1.5.1.5	-
6.3.4.3	Pigeon	-	-	-
6.3.4.3	Pisum sativum	-	-	-
6.3.4.3	Priestia megaterium	-	-	-
6.3.4.3	Proteus vulgaris	-	-	-
6.3.4.3	Saccharomyces cerevisiae	-	trifunctional enzyme with 10-formyltetrahydrofolate synthetase, EC 6.3.4.3, 5,10-methenyltetrahydrofolate cyclohydrolase, EC 3.5.4.9, and 5,10-methylenetetrahydrofolate dehydrogenase activity, EC 1.5.1.5	-
6.3.4.3	Spinacia oleracea	-	spinach	-
6.3.4.3	Veillonella parvula	-	-	-

Purification (Commentary)

EC Number	Purification (Comment)	Organism
6.3.4.3	-	Clostridium cylindrosporum

Reaction

EC Number	Reaction	Comment	Organism	Reaction ID
6.3.4.3	ATP + formate + tetrahydrofolate = ADP + phosphate + 10-formyltetrahydrofolate	substrate binds to the enzyme in a random fashion, products are not released until all substrates are bound	Clostridium cylindrosporum	a

Source Tissue

EC Number	Source Tissue	Comment	Organism	Textmining
6.3.4.3	leaf	-	Spinacia oleracea	-
6.3.4.3	leaf	-	Pisum sativum	-
6.3.4.3	leukocyte	-	Homo sapiens	-
6.3.4.3	liver	-	Gallus gallus	-
6.3.4.3	liver	-	Oryctolagus cuniculus	-
6.3.4.3	liver	-	Ovis aries	-
6.3.4.3	liver	-	Pigeon	-

Specific Activity [micromol/min/mg]

EC Number	Specific Activity Minimum [µmol/min/mg]	Specific Activity Maximum [µmol/min/mg]	Comment	Organism
6.3.4.3	additional information	-	-	Oryctolagus cuniculus
6.3.4.3	additional information	-	-	Pisum sativum
6.3.4.3	additional information	-	-	Clostridium cylindrosporum

Substrates and Products (Substrate)

EC Number	Substrates	Comment Substrates	Organism	Products	Comment (Products)	Rev.
6.3.4.3	ATP + formate + 5,6,7,8-tetrahydropteroyltriglutamate	-	Pisum sativum	ADP + phosphate + 10-formyltetrahydrofolyltriglutamate	-	?
6.3.4.3	ATP + formate + 5,6,7,8-tetrahydropteroyltriglutamate	-	Clostridium cylindrosporum	ADP + phosphate + 10-formyltetrahydrofolyltriglutamate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Gallus gallus	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Escherichia coli	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Homo sapiens	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Saccharomyces cerevisiae	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Oryctolagus cuniculus	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Neurospora crassa	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Ovis aries	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Spinacia oleracea	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Pisum sativum	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Priestia megaterium	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Pigeon	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Proteus vulgaris	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Clostridium acidi-urici	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Micrococcus aerogenes	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	-	Veillonella parvula	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	r	Clostridium cylindrosporum	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	r	Moorella thermoacetica	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	ATP in form of MgATP2-	Saccharomyces cerevisiae	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	ATP in form of MgATP2-	Pisum sativum	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	ATP in form of MgATP2-	Clostridium cylindrosporum	ADP + phosphate + 10-formyltetrahydrofolate	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Gallus gallus	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Escherichia coli	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Homo sapiens	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Saccharomyces cerevisiae	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Oryctolagus cuniculus	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Neurospora crassa	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Ovis aries	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Spinacia oleracea	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Pisum sativum	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Priestia megaterium	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Pigeon	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Proteus vulgaris	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Clostridium cylindrosporum	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Clostridium acidi-urici	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Moorella thermoacetica	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Micrococcus aerogenes	?	-	?
6.3.4.3	ATP + formate + tetrahydrofolate	two different physiological roles: 1. Functions anabolically in most organisms to activate formate via the forward reaction, and brings it into the one-carbon metabolic pool as N10-formyltetrahydrofolate, 2. In purine-fermenting bacteria the enzyme probably functions catabolically in the terminal step of the purine degradative pathway. This reaction may be responsible for ATP production in these organisms	Veillonella parvula	?	-	?
6.3.4.3	ATP + formate + tetrahydropteroyl-(Glu)n	-	Oryctolagus cuniculus	ADP + phosphate + 10-formyltetrahydropteroyl-(Glu)n	-	?
6.3.4.3	ATP + formate + tetrahydropteroyl-(Glu)n	-	Pisum sativum	ADP + phosphate + 10-formyltetrahydropteroyl-(Glu)n	-	?
6.3.4.3	ATP + formate + tetrahydropteroyl-(Glu)n	r, n: 3	Clostridium cylindrosporum	ADP + phosphate + 10-formyltetrahydropteroyl-(Glu)n	-	?
6.3.4.3	Carbamoyl phosphate + ADP	-	Clostridium cylindrosporum	? + ATP	-	?
6.3.4.3	dATP + formate + tetrahydrofolate	37% of the activity relative to ATP	Clostridium cylindrosporum	dADP + phosphate + 10-formyltetrahydrofolate	-	?

Temperature Optimum [°C]

EC Number	Temperature Optimum [°C]	Temperature Optimum Maximum [°C]	Comment	Organism
6.3.4.3	42	-	-	Clostridium cylindrosporum

pH Optimum

EC Number	pH Optimum Minimum	pH Optimum Maximum	Comment	Organism
6.3.4.3	7	9	-	Clostridium cylindrosporum

pH Stability

EC Number	pH Stability	pH Stability Maximum	Comment	Organism
6.3.4.3	6.5	9	unstable below pH 6.5 and above pH 9.0	Clostridium cylindrosporum