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Beta-ketoacyl-ACP synthase

January 18, 2024

In molecular biology, Beta-ketoacyl-ACP synthase EC 2.3.1.41, is an enzyme involved in fatty acid synthesis. It typically uses malonyl-CoA as a carbon source to elongate ACP-bound acyl species, resulting in the formation of ACP-bound β-ketoacyl species such as acetoacetyl-ACP.[1]

3-oxoacyl-ACP synthase, mitochondrial
Identifiers
SymbolOXSM
NCBI gene54995
HGNC26063
OMIM610324
RefSeqNM_017897
UniProtQ9NWU1
Other data
EC number2.3.1.41
LocusChr. 3 p24.2
Search for
StructuresSwiss-model
DomainsInterPro
Beta-ketoacyl synthase, N-terminal domain
the crystal structure of beta-ketoacyl-[acyl carrier protein] synthase ii from streptococcus pneumoniae, triclinic form
Identifiers
Symbolketoacyl-synt
PfamPF00109
Pfam clanCL0046
InterProIPR014030
PROSITEPDOC00529
SCOP21kas / SCOPe / SUPFAM
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
Beta-ketoacyl synthase, C-terminal domain
arabidopsis thaliana mitochondrial beta-ketoacyl acp synthase hexanoic acid complex
Identifiers
SymbolKetoacyl-synt_C
PfamPF02801
Pfam clanCL0046
InterProIPR014031
PROSITEPDOC00529
SCOP21kas / SCOPe / SUPFAM
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

Beta-ketoacyl-ACP synthase is a highly conserved enzyme that is found in almost all life on earth as a domain in fatty acid synthase (FAS). FAS exists in two types, aptly named type I and II. In animals, fungi, and lower eukaryotes, Beta-ketoacyl-ACP synthases make up one of the catalytic domains of larger multifunctional proteins (Type I), whereas in most prokaryotes as well as in plastids and mitochondria, Beta-ketoacyl-ACP synthases are separate protein chains that usually form dimers (Type II).[1][2] Beta-ketoacyl-ACP synthase III, perhaps the most well known of this family of enzymes, catalyzes a Claisen condensation between acetyl CoA and malonyl ACP. The image below reveals how CoA fits in the active site as a substrate of synthase III.

Proposed active site of beta-ketoacyl-ACP synthase III

Beta-ketoacyl-ACP synthases I and II only catalyze acyl-ACP reactions with malonyl ACP. Synthases I and II are capable of producing long-chain acyl-ACPs. Both are efficient up to acyl-ACPs with a 14 carbon chain, at which point synthase II is the more efficient choice for further carbon additions. Type I FAS catalyzes all the reactions necessary to create palmitic acid, which is a necessary function in animals for metabolic processes, one of which includes the formation of sphingosines.[1]

Beta-ketoacyl-ACP synthase is found as a component of a number of enzymatic systems, including fatty acid synthetase (FAS); the multi-functional 6-methysalicylic acid synthase (MSAS) from Penicillium patulum,[3] which is involved in the biosynthesis of a polyketide antibiotic; polyketide antibiotic synthase enzyme systems; Emericella nidulans multifunctional protein Wa, which is involved in the biosynthesis of conidial green pigment; Rhizobium nodulation protein nodE, which probably acts as a beta-ketoacyl synthase in the synthesis of the nodulation Nod factor fatty acyl chain; and yeast mitochondrial protein CEM1.

Structure edit

 
Crystal structure of Beta-ketoacyl-ACP synthase III from E.coli

Beta-ketoacyl synthase contains two protein domains. The active site is located between the N- and C-terminal domains. The N-terminal domain contains most of the structures involved in dimer formation and also the active site cysteine. Residues from both domains contribute to substrate binding and catalysis[4]

In animals and in prokaryotes, beta-ketoacyl-ACP synthase is a domain on type I FAS, which is a large enzyme complex that has multiple domains to catalyze multiple different reactions. Analogously, beta-ketoacyl-ACP synthase in plants is found in type II FAS; note that synthases in plants have been documented to have a range of substrate specificities.[1] The presence of similar ketoacyl synthases present in all living organisms point to a common ancestor.[5] Further examination of beta-ketoacyl-ACP synthases I and II of E. coli revealed that both are homodimeric, but synthase II is slightly larger. However, even though they are both involved in fatty acid metabolism, they also have highly divergent primary structure.[6] In synthase II, each subunit consists of a five-stranded beta pleated sheet surrounded by multiple alpha helices, shown in the image on the left. The active sites are relatively close, only about 25 angstroms apart, and consist of a mostly hydrophobic pocket.[4] Certain experiments have also suggested the presence of "fatty acid transport tunnels" within the beta-ketoacyl-ACP synthase domain that lead to one of many "fatty acid cavities", which essentially acts as the active site.[7]

Mechanism edit

Beta-ketoacyl-synthase’s mechanism is a topic of debate among chemists. Many agree that Cys171 of the active site attacks acetyl ACP's carbonyl, and, like most enzymes, stabilizes the intermediate with other residues in the active site. ACP is subsequently eliminated, and it deprotonates His311 in the process. A thioester is then regenerated with the cysteine in the active site. Decarboxylation of a malonyl CoA that is also in the active site initially creates an enolate, which is stabilized by His311 and His345. The enolate tautomerizes to a carbanion that attacks the thioester of the acetyl-enzyme complex.[8] Some sources speculate that an activated water molecule also resides in the active site as a means of hydrating the released CO2 or of attacking C3 of malonyl CoA. Another proposed mechanism considers the creation of a tetrahedral transition state.[1] The driving force of the reaction comes from the decarboxylation of malonyl ACP; the energy captured in that bond technically comes from ATP, which is what is initially used to carboxylate acetyl CoA to malonyl CoA.[9]

 
Beta ketoacyl synthase mechanism

Biological function edit

The main function of beta-ketoacyl-ACP synthase is to produce fatty acids of various lengths for use by the organism. These uses include energy storage and creation of cell membranes. Fatty acids can also be used to synthesize prostaglandins, phospholipids, and vitamins, among many other things. Further, palmitic acid, which is created by the beta-ketoacyl-synthases on type I FAS, is used in a number of biological capacities. It is a precursor of both stearic and palmitoleic acids. Palmitoleic can subsequently be used to create a number of other fatty acids.[10] Palmitic acid is also used to synthesize sphingosines, which play a role in cell membranes.[1]

Clinical significance edit

The different types of beta-ketoacyl-ACP synthases in type II FAS are called FabB, FabF, and FabH synthases. FabH catalyzes the quintessential ketoacyl synthase reaction with malonyl ACP and acetyl CoA. FabB and FabF catalyze other related reactions. Given that their function is necessary for proper biological function surrounding lipoprotein, phospholipid, and lipopolysaccharide synthesis, they have become a target in antibacterial drug development. In order to adapt to their environment, bacteria alter the phospholipid composition of their membranes. Inhibiting this pathway may thus be a leverage point in disrupting bacterial proliferation.[11] By studying Yersinia pestis, which causes bubonic, pneumonic, and septicaemic plagues, researchers have shown that FabB, FabF, and FabH can theoretically all be inhibited by the same drug due to similarities in their binding sites. However, such a drug has not yet been developed.[12] Cerulenin, a molecule that appears to inhibit by mimicking the "condensation transition state" can only inhibit B or F, but not H. Another molecule, thiolactomycin, which mimics malonyl ACP in the active site, can only inhibit FabB.[13] Lastly, platensimycin also has possible antibiotic use due to its inhibition of FabF.[14]

These types of drugs are highly relevant. For example, Y. pestis was the main agent in the Justinian Plague, Black Death, and the modern plague. Even within the last five years, China, Peru, and Madagascar all experienced an outbreak of infection by Y. pestis. If it is not treated within 24 hours, it normally results in death. Furthermore, there is worry that it can now be used as a possible biological warfare weapon.[12]

Unfortunately, many drugs that target prokaryotic beta-ketoacyl-synthases carry many side effects. Given the similarities between prokaryotic ketoacyl synthases and mitochondrial ones, these types of drugs tend to unintentionally also act upon mitochondrial synthases, leading to many biological consequences for humans.[2]

Industrial applications edit

Recent efforts in bioengineering include engineering of FAS proteins, which includes beta-ketoacyl-ACP synthase domains, in order to favor the synthesis of branched carbon chains as a renewable energy source. Branched carbon chains contain more energy and can be used in colder temperatures because of their lower freezing point. Using E. coli as the organism of choice, engineers have replaced the endogenous FabH domain on FAS, which favors unbranched chains, with FabH versions that favor branching due to their high substrate specificity for branched acyl-ACPs.[15]

See also edit

References edit

  1. ^ a b c d e f Witkowski, Andrzej; Joshi, Anil K.; Smith, Stuart (2002). "Mechanism of the β-Ketoacyl Synthase Reaction Catalyzed by the Animal Fatty Acid Synthase †". Biochemistry. 41 (35): 10877–10887. doi:10.1021/bi0259047. PMID 12196027.
  2. ^ a b Christensen, Caspar Elo; Kragelund, Birthe B.; von Wettstein-Knowles, Penny; Henriksen, Anette (2007-02-01). "Structure of the human β-ketoacyl [ACP] synthase from the mitochondrial type II fatty acid synthase". Protein Science. 16 (2): 261–272. doi:10.1110/ps.062473707. ISSN 0961-8368. PMC 2203288. PMID 17242430.
  3. ^ Beck J, Ripka S, Siegner A, Schiltz E, Schweizer E (Sep 1990). "The multifunctional 6-methylsalicylic acid synthase gene of Penicillium patulum. Its gene structure relative to that of other polyketide synthases". European Journal of Biochemistry. 192 (2): 487–98. doi:10.1111/j.1432-1033.1990.tb19252.x. PMID 2209605.
  4. ^ a b Huang W, Jia J, Edwards P, Dehesh K, Schneider G, Lindqvist Y (Mar 1998). "Crystal structure of beta-ketoacyl-acyl carrier protein synthase II from E.coli reveals the molecular architecture of condensing enzymes". The EMBO Journal. 17 (5): 1183–91. doi:10.1093/emboj/17.5.1183. PMC 1170466. PMID 9482715.
  5. ^ Beld, Joris; Blatti, Jillian L.; Behnke, Craig; Mendez, Michael; Burkart, Michael D. (2014-08-01). "Evolution of acyl-ACP-thioesterases and β-ketoacyl-ACP-synthases revealed by protein-protein interactions". Journal of Applied Phycology. 26 (4): 1619–1629. doi:10.1007/s10811-013-0203-4. ISSN 0921-8971. PMC 4125210. PMID 25110394.
  6. ^ Garwin, J. L.; Klages, A. L.; Cronan, J. E. (1980-12-25). "Structural, enzymatic, and genetic studies of beta-ketoacyl-acyl carrier protein synthases I and II of Escherichia coli". Journal of Biological Chemistry. 255 (24): 11949–11956. doi:10.1016/S0021-9258(19)70226-9. ISSN 0021-9258. PMID 7002930.
  7. ^ Cui, Wei; Liang, Yan; Tian, Weixi; Ji, Mingjuan; Ma, Xiaofeng (2016-03-01). "Regulating effect of β-ketoacyl synthase domain of fatty acid synthase on fatty acyl chain length in de novo fatty acid synthesis". Biochimica et Biophysica Acta (BBA) - Molecular and Cell Biology of Lipids. 1861 (3): 149–155. doi:10.1016/j.bbalip.2015.12.002. PMID 26680361.
  8. ^ Lee, Wook; Engels, Bernd (2014). "The Protonation State of Catalytic Residues in the Resting State of KasA Revisited: Detailed Mechanism for the Activation of KasA by Its Own Substrate". Biochemistry. 53 (5): 919–931. doi:10.1021/bi401308j. PMID 24479625.
  9. ^ Tymoczko, John; Berg; Stryer (2013). Biochemistry A Short Course. United States of America: W.H. Freeman and Company. ISBN 978-1-4292-8360-1.
  10. ^ "Palmitic acid, a saturated fatty acid, in Cell Culture". Sigma-Aldrich. Retrieved 2016-02-29.
  11. ^ Zhang, Yong-Mei; Rock, Charles O. (2008-03-01). "Membrane lipid homeostasis in bacteria". Nature Reviews Microbiology. 6 (3): 222–233. doi:10.1038/nrmicro1839. ISSN 1740-1526. PMID 18264115. S2CID 7888484.
  12. ^ a b Nanson, Jeffrey D.; Himiari, Zainab; Swarbrick, Crystall M. D.; Forwood, Jade K. (2015-10-15). "Structural Characterisation of the Beta-Ketoacyl-Acyl Carrier Protein Synthases, FabF and FabH, of Yersinia pestis". Scientific Reports. 5: 14797. Bibcode:2015NatSR...514797N. doi:10.1038/srep14797. PMC 4606726. PMID 26469877.
  13. ^ Price, Allen C.; Choi, Keum-Hwa; Heath, Richard J.; Li, Zhenmei; White, Stephen W.; Rock, Charles O. (2001-03-02). "Inhibition of β-Ketoacyl-Acyl Carrier Protein Synthases by Thiolactomycin and Cerulenin STRUCTURE AND MECHANISM". Journal of Biological Chemistry. 276 (9): 6551–6559. doi:10.1074/jbc.M007101200. ISSN 0021-9258. PMID 11050088.
  14. ^ Wright, H Tonie; Reynolds, Kevin A (2007-10-01). "Antibacterial targets in fatty acid biosynthesis". Current Opinion in Microbiology. Antimicrobials/Genomics. 10 (5): 447–453. doi:10.1016/j.mib.2007.07.001. PMC 2271077. PMID 17707686.
  15. ^ Jiang, Wen; Jiang, Yanfang; Bentley, Gayle J.; Liu, Di; Xiao, Yi; Zhang, Fuzhong (2015-08-01). "Enhanced production of branched-chain fatty acids by replacing β-ketoacyl-(acyl-carrier-protein) synthase III (FabH)". Biotechnology and Bioengineering. 112 (8): 1613–1622. doi:10.1002/bit.25583. ISSN 1097-0290. PMID 25788017. S2CID 35469786.

External links edit

Further reading edit

  • Jiang W, Jiang Y, Bentley GJ, Liu D, Xiao Y, Zhang F (Aug 2015). "Enhanced production of branched-chain fatty acids by replacing β-ketoacyl-(acyl-carrier-protein) synthase III (FabH)". Biotechnology and Bioengineering. 112 (8): 1613–22. doi:10.1002/bit.25583. PMID 25788017. S2CID 35469786.
  • Witkowski A, Joshi AK, Smith S (Sep 2002). "Mechanism of the beta-ketoacyl synthase reaction catalyzed by the animal fatty acid synthase". Biochemistry. 41 (35): 10877–87. doi:10.1021/bi0259047. PMID 12196027.
  • Christensen CE, Kragelund BB, von Wettstein-Knowles P, Henriksen A (Feb 2007). "Structure of the human beta-ketoacyl [ACP] synthase from the mitochondrial type II fatty acid synthase". Protein Science. 16 (2): 261–72. doi:10.1110/ps.062473707. PMC 2203288. PMID 17242430.
  • Lee W, Engels B (Feb 2014). "The protonation state of catalytic residues in the resting state of KasA revisited: detailed mechanism for the activation of KasA by its own substrate". Biochemistry. 53 (5): 919–31. doi:10.1021/bi401308j. PMID 24479625.
This article incorporates text from the public domain Pfam and InterPro: IPR014030
This article incorporates text from the public domain Pfam and InterPro: IPR014031

January 18, 2024
beta, ketoacyl, synthase, molecular, biology, enzyme, involved, fatty, acid, synthesis, typically, uses, malonyl, carbon, source, elongate, bound, acyl, species, resulting, formation, bound, ketoacyl, species, such, acetoacetyl, oxoacyl, synthase, mitochondria. In molecular biology Beta ketoacyl ACP synthase EC 2 3 1 41 is an enzyme involved in fatty acid synthesis It typically uses malonyl CoA as a carbon source to elongate ACP bound acyl species resulting in the formation of ACP bound b ketoacyl species such as acetoacetyl ACP 1 3 oxoacyl ACP synthase mitochondrialIdentifiersSymbolOXSMNCBI gene54995HGNC26063OMIM610324RefSeqNM 017897UniProtQ9NWU1Other dataEC number2 3 1 41LocusChr 3 p24 2Search forStructuresSwiss modelDomainsInterProBeta ketoacyl synthase N terminal domainthe crystal structure of beta ketoacyl acyl carrier protein synthase ii from streptococcus pneumoniae triclinic formIdentifiersSymbolketoacyl syntPfamPF00109Pfam clanCL0046InterProIPR014030PROSITEPDOC00529SCOP21kas SCOPe SUPFAMAvailable protein structures Pfam structures ECOD PDBRCSB PDB PDBe PDBjPDBsumstructure summaryBeta ketoacyl synthase C terminal domainarabidopsis thaliana mitochondrial beta ketoacyl acp synthase hexanoic acid complexIdentifiersSymbolKetoacyl synt CPfamPF02801Pfam clanCL0046InterProIPR014031PROSITEPDOC00529SCOP21kas SCOPe SUPFAMAvailable protein structures Pfam structures ECOD PDBRCSB PDB PDBe PDBjPDBsumstructure summary Beta ketoacyl ACP synthase is a highly conserved enzyme that is found in almost all life on earth as a domain in fatty acid synthase FAS FAS exists in two types aptly named type I and II In animals fungi and lower eukaryotes Beta ketoacyl ACP synthases make up one of the catalytic domains of larger multifunctional proteins Type I whereas in most prokaryotes as well as in plastids and mitochondria Beta ketoacyl ACP synthases are separate protein chains that usually form dimers Type II 1 2 Beta ketoacyl ACP synthase III perhaps the most well known of this family of enzymes catalyzes a Claisen condensation between acetyl CoA and malonyl ACP The image below reveals how CoA fits in the active site as a substrate of synthase III Proposed active site of beta ketoacyl ACP synthase IIIBeta ketoacyl ACP synthases I and II only catalyze acyl ACP reactions with malonyl ACP Synthases I and II are capable of producing long chain acyl ACPs Both are efficient up to acyl ACPs with a 14 carbon chain at which point synthase II is the more efficient choice for further carbon additions Type I FAS catalyzes all the reactions necessary to create palmitic acid which is a necessary function in animals for metabolic processes one of which includes the formation of sphingosines 1 Beta ketoacyl ACP synthase is found as a component of a number of enzymatic systems including fatty acid synthetase FAS the multi functional 6 methysalicylic acid synthase MSAS from Penicillium patulum 3 which is involved in the biosynthesis of a polyketide antibiotic polyketide antibiotic synthase enzyme systems Emericella nidulans multifunctional protein Wa which is involved in the biosynthesis of conidial green pigment Rhizobium nodulation protein nodE which probably acts as a beta ketoacyl synthase in the synthesis of the nodulation Nod factor fatty acyl chain and yeast mitochondrial protein CEM1 Contents 1 Structure 2 Mechanism 3 Biological function 4 Clinical significance 5 Industrial applications 6 See also 7 References 8 External links 9 Further readingStructure edit nbsp Crystal structure of Beta ketoacyl ACP synthase III from E coliBeta ketoacyl synthase contains two protein domains The active site is located between the N and C terminal domains The N terminal domain contains most of the structures involved in dimer formation and also the active site cysteine Residues from both domains contribute to substrate binding and catalysis 4 In animals and in prokaryotes beta ketoacyl ACP synthase is a domain on type I FAS which is a large enzyme complex that has multiple domains to catalyze multiple different reactions Analogously beta ketoacyl ACP synthase in plants is found in type II FAS note that synthases in plants have been documented to have a range of substrate specificities 1 The presence of similar ketoacyl synthases present in all living organisms point to a common ancestor 5 Further examination of beta ketoacyl ACP synthases I and II of E coli revealed that both are homodimeric but synthase II is slightly larger However even though they are both involved in fatty acid metabolism they also have highly divergent primary structure 6 In synthase II each subunit consists of a five stranded beta pleated sheet surrounded by multiple alpha helices shown in the image on the left The active sites are relatively close only about 25 angstroms apart and consist of a mostly hydrophobic pocket 4 Certain experiments have also suggested the presence of fatty acid transport tunnels within the beta ketoacyl ACP synthase domain that lead to one of many fatty acid cavities which essentially acts as the active site 7 Mechanism editBeta ketoacyl synthase s mechanism is a topic of debate among chemists Many agree that Cys171 of the active site attacks acetyl ACP s carbonyl and like most enzymes stabilizes the intermediate with other residues in the active site ACP is subsequently eliminated and it deprotonates His311 in the process A thioester is then regenerated with the cysteine in the active site Decarboxylation of a malonyl CoA that is also in the active site initially creates an enolate which is stabilized by His311 and His345 The enolate tautomerizes to a carbanion that attacks the thioester of the acetyl enzyme complex 8 Some sources speculate that an activated water molecule also resides in the active site as a means of hydrating the released CO2 or of attacking C3 of malonyl CoA Another proposed mechanism considers the creation of a tetrahedral transition state 1 The driving force of the reaction comes from the decarboxylation of malonyl ACP the energy captured in that bond technically comes from ATP which is what is initially used to carboxylate acetyl CoA to malonyl CoA 9 nbsp Beta ketoacyl synthase mechanismBiological function editThe main function of beta ketoacyl ACP synthase is to produce fatty acids of various lengths for use by the organism These uses include energy storage and creation of cell membranes Fatty acids can also be used to synthesize prostaglandins phospholipids and vitamins among many other things Further palmitic acid which is created by the beta ketoacyl synthases on type I FAS is used in a number of biological capacities It is a precursor of both stearic and palmitoleic acids Palmitoleic can subsequently be used to create a number of other fatty acids 10 Palmitic acid is also used to synthesize sphingosines which play a role in cell membranes 1 Clinical significance editThe different types of beta ketoacyl ACP synthases in type II FAS are called FabB FabF and FabH synthases FabH catalyzes the quintessential ketoacyl synthase reaction with malonyl ACP and acetyl CoA FabB and FabF catalyze other related reactions Given that their function is necessary for proper biological function surrounding lipoprotein phospholipid and lipopolysaccharide synthesis they have become a target in antibacterial drug development In order to adapt to their environment bacteria alter the phospholipid composition of their membranes Inhibiting this pathway may thus be a leverage point in disrupting bacterial proliferation 11 By studying Yersinia pestis which causes bubonic pneumonic and septicaemic plagues researchers have shown that FabB FabF and FabH can theoretically all be inhibited by the same drug due to similarities in their binding sites However such a drug has not yet been developed 12 Cerulenin a molecule that appears to inhibit by mimicking the condensation transition state can only inhibit B or F but not H Another molecule thiolactomycin which mimics malonyl ACP in the active site can only inhibit FabB 13 Lastly platensimycin also has possible antibiotic use due to its inhibition of FabF 14 These types of drugs are highly relevant For example Y pestis was the main agent in the Justinian Plague Black Death and the modern plague Even within the last five years China Peru and Madagascar all experienced an outbreak of infection by Y pestis If it is not treated within 24 hours it normally results in death Furthermore there is worry that it can now be used as a possible biological warfare weapon 12 Unfortunately many drugs that target prokaryotic beta ketoacyl synthases carry many side effects Given the similarities between prokaryotic ketoacyl synthases and mitochondrial ones these types of drugs tend to unintentionally also act upon mitochondrial synthases leading to many biological consequences for humans 2 Industrial applications editRecent efforts in bioengineering include engineering of FAS proteins which includes beta ketoacyl ACP synthase domains in order to favor the synthesis of branched carbon chains as a renewable energy source Branched carbon chains contain more energy and can be used in colder temperatures because of their lower freezing point Using E coli as the organism of choice engineers have replaced the endogenous FabH domain on FAS which favors unbranched chains with FabH versions that favor branching due to their high substrate specificity for branched acyl ACPs 15 See also editBeta ketoacyl ACP synthase I Beta ketoacyl ACP synthase II Beta ketoacyl ACP synthase III 3 oxoacyl acyl carrier protein reductaseReferences edit a b c d e f Witkowski Andrzej Joshi Anil K Smith Stuart 2002 Mechanism of the b Ketoacyl Synthase Reaction Catalyzed by the Animal Fatty Acid Synthase Biochemistry 41 35 10877 10887 doi 10 1021 bi0259047 PMID 12196027 a b Christensen Caspar Elo Kragelund Birthe B von Wettstein Knowles Penny Henriksen Anette 2007 02 01 Structure of the human b ketoacyl ACP synthase from the mitochondrial type II fatty acid synthase Protein Science 16 2 261 272 doi 10 1110 ps 062473707 ISSN 0961 8368 PMC 2203288 PMID 17242430 Beck J Ripka S Siegner A Schiltz E Schweizer E Sep 1990 The multifunctional 6 methylsalicylic acid synthase gene of Penicillium patulum Its gene structure relative to that of other polyketide synthases European Journal of Biochemistry 192 2 487 98 doi 10 1111 j 1432 1033 1990 tb19252 x PMID 2209605 a b Huang W Jia J Edwards P Dehesh K Schneider G Lindqvist Y Mar 1998 Crystal structure of beta ketoacyl acyl carrier protein synthase II from E coli reveals the molecular architecture of condensing enzymes The EMBO Journal 17 5 1183 91 doi 10 1093 emboj 17 5 1183 PMC 1170466 PMID 9482715 Beld Joris Blatti Jillian L Behnke Craig Mendez Michael Burkart Michael D 2014 08 01 Evolution of acyl ACP thioesterases and b ketoacyl ACP synthases revealed by protein protein interactions Journal of Applied Phycology 26 4 1619 1629 doi 10 1007 s10811 013 0203 4 ISSN 0921 8971 PMC 4125210 PMID 25110394 Garwin J L Klages A L Cronan J E 1980 12 25 Structural enzymatic and genetic studies of beta ketoacyl acyl carrier protein synthases I and II of Escherichia coli Journal of Biological Chemistry 255 24 11949 11956 doi 10 1016 S0021 9258 19 70226 9 ISSN 0021 9258 PMID 7002930 Cui Wei Liang Yan Tian Weixi Ji Mingjuan Ma Xiaofeng 2016 03 01 Regulating effect of b ketoacyl synthase domain of fatty acid synthase on fatty acyl chain length in de novo fatty acid synthesis Biochimica et Biophysica Acta BBA Molecular and Cell Biology of Lipids 1861 3 149 155 doi 10 1016 j bbalip 2015 12 002 PMID 26680361 Lee Wook Engels Bernd 2014 The Protonation State of Catalytic Residues in the Resting State of KasA Revisited Detailed Mechanism for the Activation of KasA by Its Own Substrate Biochemistry 53 5 919 931 doi 10 1021 bi401308j PMID 24479625 Tymoczko John Berg Stryer 2013 Biochemistry A Short Course United States of America W H Freeman and Company ISBN 978 1 4292 8360 1 Palmitic acid a saturated fatty acid in Cell Culture Sigma Aldrich Retrieved 2016 02 29 Zhang Yong Mei Rock Charles O 2008 03 01 Membrane lipid homeostasis in bacteria Nature Reviews Microbiology 6 3 222 233 doi 10 1038 nrmicro1839 ISSN 1740 1526 PMID 18264115 S2CID 7888484 a b Nanson Jeffrey D Himiari Zainab Swarbrick Crystall M D Forwood Jade K 2015 10 15 Structural Characterisation of the Beta Ketoacyl Acyl Carrier Protein Synthases FabF and FabH of Yersinia pestis Scientific Reports 5 14797 Bibcode 2015NatSR 514797N doi 10 1038 srep14797 PMC 4606726 PMID 26469877 Price Allen C Choi Keum Hwa Heath Richard J Li Zhenmei White Stephen W Rock Charles O 2001 03 02 Inhibition of b Ketoacyl Acyl Carrier Protein Synthases by Thiolactomycin and Cerulenin STRUCTURE AND MECHANISM Journal of Biological Chemistry 276 9 6551 6559 doi 10 1074 jbc M007101200 ISSN 0021 9258 PMID 11050088 Wright H Tonie Reynolds Kevin A 2007 10 01 Antibacterial targets in fatty acid biosynthesis Current Opinion in Microbiology Antimicrobials Genomics 10 5 447 453 doi 10 1016 j mib 2007 07 001 PMC 2271077 PMID 17707686 Jiang Wen Jiang Yanfang Bentley Gayle J Liu Di Xiao Yi Zhang Fuzhong 2015 08 01 Enhanced production of branched chain fatty acids by replacing b ketoacyl acyl carrier protein synthase III FabH Biotechnology and Bioengineering 112 8 1613 1622 doi 10 1002 bit 25583 ISSN 1097 0290 PMID 25788017 S2CID 35469786 External links editbeta Ketoacyl ACP Synthase at the U S National Library of Medicine Medical Subject Headings MeSH Further reading editJiang W Jiang Y Bentley GJ Liu D Xiao Y Zhang F Aug 2015 Enhanced production of branched chain fatty acids by replacing b ketoacyl acyl carrier protein synthase III FabH Biotechnology and Bioengineering 112 8 1613 22 doi 10 1002 bit 25583 PMID 25788017 S2CID 35469786 Witkowski A Joshi AK Smith S Sep 2002 Mechanism of the beta ketoacyl synthase reaction catalyzed by the animal fatty acid synthase Biochemistry 41 35 10877 87 doi 10 1021 bi0259047 PMID 12196027 Christensen CE Kragelund BB von Wettstein Knowles P Henriksen A Feb 2007 Structure of the human beta ketoacyl ACP synthase from the mitochondrial type II fatty acid synthase Protein Science 16 2 261 72 doi 10 1110 ps 062473707 PMC 2203288 PMID 17242430 Lee W Engels B Feb 2014 The protonation state of catalytic residues in the resting state of KasA revisited detailed mechanism for the activation of KasA by its own substrate Biochemistry 53 5 919 31 doi 10 1021 bi401308j PMID 24479625 This article incorporates text from the public domain Pfam and InterPro IPR014030 This article incorporates text from the public domain Pfam and InterPro IPR014031 Retrieved from https en wikipedia org w index php title Beta ketoacyl ACP synthase amp oldid 1147240667, wikipedia, wiki, book, books, library,

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