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Pantothenate kinase

January 01, 1970

Pantothenate kinase (EC 2.7.1.33, PanK; CoaA) is the first enzyme in the Coenzyme A (CoA) biosynthetic pathway. It phosphorylates pantothenate (vitamin B5) to form 4'-phosphopantothenate at the expense of a molecule of adenosine triphosphate (ATP). It is the rate-limiting step in the biosynthesis of CoA.[1][2]

Pantothenate kinase
Identifiers
EC no.2.7.1.33
CAS no.9026-48-6
Databases
IntEnzIntEnz view
BRENDABRENDA entry
ExPASyNiceZyme view
KEGGKEGG entry
MetaCycmetabolic pathway
PRIAMprofile
PDB structuresRCSB PDB PDBe PDBsum
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PMCarticles
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NCBIproteins
[2]

CoA is a necessary cofactor in all living organisms. It acts as the major acyl group carrier in many important cellular processes, such as the citric acid cycle (tricarboxylic acid cycle) and fatty acid metabolism. Consequently, pantothenate kinase is a key regulatory enzyme in the CoA biosynthetic pathway.[3]

Types edit

Three distinct types of PanK has been identified - PanK-I (found in bacteria), PanK-II (mainly found in eukaryotes, but also in the Staphylococci) and PanK-III, also known as CoaX (found in bacteria). Eukaryotic PanK-II enzymes often occur as different isoforms, such as PanK1, PanK2, PanK3 and PanK4. In humans, multiple PanK isoforms are expressed by four genes. PANK1 gene encodes the PanK1α and PanK1β forms, and PANK2 and PANK3 encode PanK2 and PanK3, respectively.[4] The four major isoforms found in mammals have different subcellular localizations. PanK1α is nuclear, while PanK1β and PanK3 are cytosolic. In mice, PanK2 is also cytosolic, while in humans, this enzyme is mitochondrial and nuclear.[5] The tissue distribution of these isoforms also varies. In mouse models, PanK1 is the predominant species in the heart, liver and brown adipose tissue, along with the kidneys. PanK2 and PanK3 are more prominent in the brain and skeletal muscle, and PanK3 is particularly high in the intestines and white adipose tissue.[6]

Structure edit

PanK-II edit

 
Fig. 1 Dimer structure of PanK-II

PanK-II contains two protein domains, as illustrated in Figure 1. The A domain and A' domain each has a glycine-rich loop (sequence GXXXXGKS; P loop) that is characteristic of nucleotide-binding sites; this is where ATP is assumed to bind.[7] located between residues 95 and 102 on the A domain

The two ATP binding sites display cooperative behavior. The dimerization interface consists of two long helices, one from each monomer, that interact with each other. The C-terminal ends of the helices are held together by van der Waals interactions between valine and methionine residues of each monomer. The middle of the helices is attached by hydrogen bonds between asparagine residues. At the N-terminal end, each helix widens and forms a four-helix bundle with two shorter helices. This bundle consists of a hydrophobic core formed by non-polar residues that utilize van der Waals forces to further stabilize the dimer.[4]

In the active site, pantothenate is oriented by hydrogen bonds between pantothenate and the side chains of aspartate, tyrosine, histidine, tyrosine, and asparagine residues.[8] Asparagine, histidine, and arginine residues are involved in catalysis.

Human PanK-II isoforms PanK1α, PanK1β, PanK2, and PanK3 have a common, highly homologous catalytic core of approximately 355 residues.[4] PanK1α and PanK1β are both encoded by the PANK1 gene and have the same catalytic domain of 363 amino acids, encoded by exons 2 through 7. The PanK1α transcript starts with exon 1α that encodes a 184-residue regulatory domain at the N-terminus. This region allows for feedback inhibition by free CoA and acyl-CoA and regulation by acetyl-CoA and malonyl-CoA. On the other hand, the PanK1β transcript starts with exon 1β, which produces a 10-residue N-terminus that does not include a feedback regulatory domain.[9]

PanK-III edit

 
Fig. 2 Dimer structure of PanK-III

PanK-III also contains two protein domains, and the key catalytic residues of PanK-II are conserved. The monomer units of PanK-II and PanK-III are virtually identical, but they have distinctly different dimer assemblies. A study between the structures of Staphylococcus aureus type II and the Pseudomonas aeruginosa type III demonstrate that the PanK-II monomer has a loop region that is absent from the PanK-III monomer, and the PanK-III monomer has a loop region that is absent from the PanK-II monomer.[10] This minor variation has a crucial difference on the dimerization interface in which the helices of the PanK-II dimer coil around one another and the helices of the PanK-III dimer interact at a 70° angle (Figure 2).[11]

As a result of this difference in dimerization interface between PanK-II and PanK-III, the conformations of the substrate binding sites for ATP and pantothenate are also distinct.[12][13]

Catalytic Mechanism edit

 
Fig. 3 Proposed catalytic mechanism for PanK-II

PanK-II edit

A proposed mechanism of the phosphoryl transfer reaction of PanK-II is a concerted mechanism with a dissociative transition state.

First, the ATP binds at the binding groove created by residues of the P loop and nearby residues. Here, the conserved lysine (Lys-101) is the key residue required for ATP binding.[14][15] Additionally, the side chains of residues Lys-101, Ser-102, Glu-199, and Arg-243 orient the nucleotide in the binding groove. The pantothenate is bound and oriented by forming hydrogen bond interactions with residues Asp-127, Tyr-240, Asn-282, Tyr-175, and His-177.[8] When both ATP and pantothenate are bound, Asp-127 deprotonates the C1 hydroxyl group of pantothenate. The oxygen from the pantothenate then attacks the γ-phosphate of the bound ATP. Here, charge stabilization of β- and γ-phosphate groups is achieved by Arg-243, Lys-101, and a coordinated Mg2+ ion.[16] In this concerted mechanism, the planar phosphorane of the γ-phosphate is transferred in-line to the attacking oxygen of pantothenate.[8] Finally, 4'-phosphopantothenate dissociates from PanK, followed by ADP.

Regulation of pantothenate kinase edit

PanK-II edit

The regulation of pantothenate kinase is essential to controlling the intracellular CoA concentration.[17] Pantothenate kinase is regulated via feedback inhibition by CoA and its thioesters (i.e., acetyl-CoA, malonyl-CoA).[18] Inhibition of the human isoforms of PanK by acetyl-CoA varies dramatically. PanK1β is inhibited the least strongly, with an IC50 value of around 5 μM, while PanK2 is the most strongly inhibited, with an IC50 of around 0.1 μM.[6]

CoA inhibits PanK activity by competitively binding to the ATP binding site and preventing ATP binding to Lys-101.[14][15] Although CoA binds at the same site as ATP, they bind in distinct orientations, and their adenine moieties interact with the enzyme with nonoverlapping sets of residues. His-177, Phe-247, and Arg-106 are necessary for CoA recognition but not for ATP, and while Asn-43 and His-307 interact with the adenine base of ATP, His-177 and Phe-247 interact with the adenine base of CoA.[16] Both molecules use Lys-101 to neutralize the charge on their respective phosphodiesters.

Nonesterified CoA has more potent inhibition than its thioesters. This phenomenon is best explained by the tight fit of the thiol group with the surrounding aromatic residues, Phe-244, Phe-259, Tyr-262, and Phe-252. Free CoA has an optimal fit, but when an acyl group is attached to CoA, the steric hindrance makes it difficult for the thioester to interact with Phe-252. Thus, the inhibition by thioesters is less effective than that by nonesterified CoA.[16]

Deletion of PanK1 disrupts metabolic pathways, including fatty acid oxidation and gluconeogenesis. PanK1-/- mouse models in a fasted state show impaired gluconeogenesis, indicating that this pathway is disrupted. In addition, CoA levels decrease significantly between PanK1-/- and wild-type mice. This reduction in CoA also appears to correlate with a disruption in fatty acid oxidation. Higher levels of long-chain acyl-carnitines were observed in PanK1-/- mice, indicating a lower capability for fatty acid oxidation in these mice.[19]

 
PanK2 Regulation

Because PanK2 is so strongly inhibited by acetyl-CoA, an abundant metabolite in the mitochondria, this enzyme likely would not be active under physiological conditions without activators.[6] Palmitoyl-carnitine and other long-chain acyl-carnitines can reverse acetyl-CoA inhibition and can activate PanK2 without acetyl-CoA present. Palmitoyl-carnitine is competitive with acetyl-CoA.[20] The activation of PanK2 by palmitoyl-carnitine and other long-chain acyl-carnitines sheds light on the regulatory pathways of this enzyme: Under normal conditions, PanK2 is likely inhibited by high levels of acetyl-CoA. Without CoA production, fatty acid oxidation decreases, leading to an increase in long-chain acyl-carnitines.[19] These acyl-carnitines can then reduce inhibition by acetyl-CoA, activating PanK2 and increasing CoA biosynthesis. PanK3 is also activated by palmitoyl-carnitine and other long-chain acyl-carnitines, including oleoyl-carnitine.[21]

PanK-III edit

The regulation outlined above corresponds to PanK-II. PanK-III is resistant to feedback inhibition.[10][12][13]

Genes edit

In humans:

The PANK2 gene encodes for PanK2, which regulates the formation of CoA in mitochondria, the cell’s energy-producing centers.[22] PANK2 mutation is the cause of Pantothenate kinase-associated neurodegeneration (PKAN), formerly called Hallervorden-Spatz syndrome. This rare disease presents with profound dystonia, spasticity and is often fatal.

There are many mutations in PanK2 that lead to PKAN. In a survey of several common mutations, it was found that several of these mutations did not cause a major loss in the catalytic activity of PanK2, indicating that loss of catalytic function of this enzyme is not fully responsible for this disease.[23]

References edit

  1. ^ Robishaw JD, Berkich D, Neely JR (September 1982). "Rate-limiting step and control of coenzyme A synthesis in cardiac muscle". The Journal of Biological Chemistry. 257 (18): 10967–72. doi:10.1016/S0021-9258(18)33918-8. PMID 7107640.
  2. ^ a b Yang K, Eyobo Y, Brand LA, Martynowski D, Tomchick D, Strauss E, Zhang H (August 2006). "Crystal structure of a type III pantothenate kinase: insight into the mechanism of an essential coenzyme A biosynthetic enzyme universally distributed in bacteria". Journal of Bacteriology. 188 (15): 5532–40. doi:10.1128/JB.00469-06. PMC 1540032. PMID 16855243.
  3. ^ Leonardi R, Zhang YM, Rock CO, Jackowski S (2005-03-01). "Coenzyme A: back in action". Progress in Lipid Research. 44 (2–3): 125–53. doi:10.1016/j.plipres.2005.04.001. PMID 15893380.
  4. ^ a b c Hong BS, Senisterra G, Rabeh WM, Vedadi M, Leonardi R, Zhang YM, Rock CO, Jackowski S, Park HW (September 2007). "Crystal structures of human pantothenate kinases. Insights into allosteric regulation and mutations linked to a neurodegeneration disorder". The Journal of Biological Chemistry. 282 (38): 27984–93. doi:10.1074/jbc.M701915200. PMID 17631502.
  5. ^ Alfonso-Pecchio, Adolfo; Garcia, Matthew; Leonardi, Roberta; Jackowski, Suzanne (2012). "Compartmentalization of mammalian pantothenate kinases". PLOS ONE. 7 (11): e49509. doi:10.1371/journal.pone.0049509. ISSN 1932-6203. PMC 3496714. PMID 23152917.
  6. ^ a b c Dansie, Lorraine E.; Reeves, Stacy; Miller, Karen; Zano, Stephen P.; Frank, Matthew; Pate, Caroline; Wang, Jina; Jackowski, Suzanne (August 2014). "Physiological roles of the pantothenate kinases". Biochemical Society Transactions. 42 (4): 1033–1036. doi:10.1042/BST20140096. ISSN 1470-8752. PMC 4948118. PMID 25109998.
  7. ^ Saraste M, Sibbald PR, Wittinghofer A (November 1990). "The P-loop--a common motif in ATP- and GTP-binding proteins". Trends in Biochemical Sciences. 15 (11): 430–4. doi:10.1016/0968-0004(90)90281-F. PMID 2126155.
  8. ^ a b c Ivey RA, Zhang YM, Virga KG, Hevener K, Lee RE, Rock CO, Jackowski S, Park HW (August 2004). "The structure of the pantothenate kinase.ADP.pantothenate ternary complex reveals the relationship between the binding sites for substrate, allosteric regulator, and antimetabolites". The Journal of Biological Chemistry. 279 (34): 35622–9. doi:10.1074/jbc.M403152200. PMID 15136582.
  9. ^ Rock CO, Karim MA, Zhang YM, Jackowski S (2002). "The murine pantothenate kinase (Pank1) gene encodes two differentially regulated pantothenate kinase isozymes". Gene. 291 (1–2): 35–43. doi:10.1016/S0378-1119(02)00564-4. PMID 12095677.
  10. ^ a b Yang K, Strauss E, Huerta C, Zhang H (February 2008). "Structural basis for substrate binding and the catalytic mechanism of type III pantothenate kinase". Biochemistry. 47 (5): 1369–80. doi:10.1021/bi7018578. PMID 18186650.
  11. ^ Hong BS, Yun MK, Zhang YM, Chohnan S, Rock CO, White SW, Jackowski S, Park HW, Leonardi R (August 2006). "Prokaryotic type II and type III pantothenate kinases: The same monomer fold creates dimers with distinct catalytic properties". Structure. 14 (8): 1251–61. doi:10.1016/j.str.2006.06.008. PMID 16905099.
  12. ^ a b Brand LA, Strauss E (May 2005). "Characterization of a new pantothenate kinase isoform from Helicobacter pylori". The Journal of Biological Chemistry. 280 (21): 20185–8. doi:10.1074/jbc.C500044200. PMID 15795230.
  13. ^ a b Choudhry AE, Mandichak TL, Broskey JP, Egolf RW, Kinsland C, Begley TP, Seefeld MA, Ku TW, Brown JR, Zalacain M, Ratnam K (June 2003). "Inhibitors of pantothenate kinase: novel antibiotics for staphylococcal infections". Antimicrobial Agents and Chemotherapy. 47 (6): 2051–5. doi:10.1128/AAC.47.6.2051-2055.2003. PMC 155856. PMID 12760898.
  14. ^ a b Song WJ, Jackowski S (October 1994). "Kinetics and regulation of pantothenate kinase from Escherichia coli". The Journal of Biological Chemistry. 269 (43): 27051–8. doi:10.1016/S0021-9258(18)47124-4. PMID 7929447.
  15. ^ a b Song WJ, Jackowski S (October 1992). "Cloning, sequencing, and expression of the pantothenate kinase (coaA) gene of Escherichia coli". Journal of Bacteriology. 174 (20): 6411–7. doi:10.1128/jb.174.20.6411-6417.1992. PMC 207592. PMID 1328157.
  16. ^ a b c Yun M, Park CG, Kim JY, Rock CO, Jackowski S, Park HW (September 2000). "Structural basis for the feedback regulation of Escherichia coli pantothenate kinase by coenzyme A". The Journal of Biological Chemistry. 275 (36): 28093–9. doi:10.1074/jbc.M003190200. PMID 10862768.
  17. ^ Jackowski S, Rock CO (December 1981). "Regulation of coenzyme A biosynthesis". Journal of Bacteriology. 148 (3): 926–32. doi:10.1128/jb.148.3.926-932.1981. PMC 216294. PMID 6796563.
  18. ^ Rock CO, Park HW, Jackowski S (June 2003). "Role of feedback regulation of pantothenate kinase (CoaA) in control of coenzyme A levels in Escherichia coli". Journal of Bacteriology. 185 (11): 3410–5. doi:10.1128/JB.185.11.3410-3415.2003. PMC 155388. PMID 12754240.
  19. ^ a b Leonardi, Roberta; Rehg, Jerold E.; Rock, Charles O.; Jackowski, Suzanne (2010-06-14). "Pantothenate kinase 1 is required to support the metabolic transition from the fed to the fasted state". PLOS ONE. 5 (6): e11107. Bibcode:2010PLoSO...511107L. doi:10.1371/journal.pone.0011107. ISSN 1932-6203. PMC 2885419. PMID 20559429.
  20. ^ Leonardi, Roberta; Rock, Charles O.; Jackowski, Suzanne; Zhang, Yong-Mei (2007-01-30). "Activation of human mitochondrial pantothenate kinase 2 by palmitoylcarnitine". Proceedings of the National Academy of Sciences. 104 (5): 1494–1499. doi:10.1073/pnas.0607621104. ISSN 0027-8424. PMC 1785270. PMID 17242360.
  21. ^ Leonardi, Roberta; Zhang, Yong-Mei; Yun, Mi-Kyung; Zhou, Ruobing; Zeng, Fu-Yue; Lin, Wenwei; Cui, Jimmy; Chen, Taosheng; Rock, Charles O.; White, Stephen W.; Jackowski, Suzanne (2010-08-27). "Modulation of Pantothenate Kinase 3 Activity by Small Molecules that Interact with the Substrate/Allosteric Regulatory Domain". Chemistry & Biology. 17 (8): 892–902. doi:10.1016/j.chembiol.2010.06.006. ISSN 1074-5521. PMC 2929395. PMID 20797618.
  22. ^ "PANK2 gene". Genetics Home Reference. 2016-02-22. Retrieved 2016-02-29.
  23. ^ Zhang, Yong-Mei; Rock, Charles O.; Jackowski, Suzanne (2006-01-06). "Biochemical properties of human pantothenate kinase 2 isoforms and mutations linked to pantothenate kinase-associated neurodegeneration". The Journal of Biological Chemistry. 281 (1): 107–114. doi:10.1074/jbc.M508825200. ISSN 0021-9258. PMID 16272150.

External links edit

January 01, 1970
pantothenate, kinase, pank, coaa, first, enzyme, coenzyme, biosynthetic, pathway, phosphorylates, pantothenate, vitamin, form, phosphopantothenate, expense, molecule, adenosine, triphosphate, rate, limiting, step, biosynthesis, identifiersec, 33cas, 9026, 6dat. Pantothenate kinase EC 2 7 1 33 PanK CoaA is the first enzyme in the Coenzyme A CoA biosynthetic pathway It phosphorylates pantothenate vitamin B5 to form 4 phosphopantothenate at the expense of a molecule of adenosine triphosphate ATP It is the rate limiting step in the biosynthesis of CoA 1 2 Pantothenate kinaseIdentifiersEC no 2 7 1 33CAS no 9026 48 6DatabasesIntEnzIntEnz viewBRENDABRENDA entryExPASyNiceZyme viewKEGGKEGG entryMetaCycmetabolic pathwayPRIAMprofilePDB structuresRCSB PDB PDBe PDBsumSearchPMCarticlesPubMedarticlesNCBIproteins 2 CoA is a necessary cofactor in all living organisms It acts as the major acyl group carrier in many important cellular processes such as the citric acid cycle tricarboxylic acid cycle and fatty acid metabolism Consequently pantothenate kinase is a key regulatory enzyme in the CoA biosynthetic pathway 3 Contents 1 Types 2 Structure 2 1 PanK II 2 2 PanK III 3 Catalytic Mechanism 3 1 PanK II 4 Regulation of pantothenate kinase 4 1 PanK II 4 2 PanK III 5 Genes 6 References 7 External linksTypes editThree distinct types of PanK has been identified PanK I found in bacteria PanK II mainly found in eukaryotes but also in the Staphylococci and PanK III also known as CoaX found in bacteria Eukaryotic PanK II enzymes often occur as different isoforms such as PanK1 PanK2 PanK3 and PanK4 In humans multiple PanK isoforms are expressed by four genes PANK1 gene encodes the PanK1a and PanK1b forms and PANK2 and PANK3 encode PanK2 and PanK3 respectively 4 The four major isoforms found in mammals have different subcellular localizations PanK1a is nuclear while PanK1b and PanK3 are cytosolic In mice PanK2 is also cytosolic while in humans this enzyme is mitochondrial and nuclear 5 The tissue distribution of these isoforms also varies In mouse models PanK1 is the predominant species in the heart liver and brown adipose tissue along with the kidneys PanK2 and PanK3 are more prominent in the brain and skeletal muscle and PanK3 is particularly high in the intestines and white adipose tissue 6 Structure editPanK II edit nbsp Fig 1 Dimer structure of PanK II PanK II contains two protein domains as illustrated in Figure 1 The A domain and A domain each has a glycine rich loop sequence GXXXXGKS P loop that is characteristic of nucleotide binding sites this is where ATP is assumed to bind 7 located between residues 95 and 102 on the A domainThe two ATP binding sites display cooperative behavior The dimerization interface consists of two long helices one from each monomer that interact with each other The C terminal ends of the helices are held together by van der Waals interactions between valine and methionine residues of each monomer The middle of the helices is attached by hydrogen bonds between asparagine residues At the N terminal end each helix widens and forms a four helix bundle with two shorter helices This bundle consists of a hydrophobic core formed by non polar residues that utilize van der Waals forces to further stabilize the dimer 4 In the active site pantothenate is oriented by hydrogen bonds between pantothenate and the side chains of aspartate tyrosine histidine tyrosine and asparagine residues 8 Asparagine histidine and arginine residues are involved in catalysis Human PanK II isoforms PanK1a PanK1b PanK2 and PanK3 have a common highly homologous catalytic core of approximately 355 residues 4 PanK1a and PanK1b are both encoded by the PANK1 gene and have the same catalytic domain of 363 amino acids encoded by exons 2 through 7 The PanK1a transcript starts with exon 1a that encodes a 184 residue regulatory domain at the N terminus This region allows for feedback inhibition by free CoA and acyl CoA and regulation by acetyl CoA and malonyl CoA On the other hand the PanK1b transcript starts with exon 1b which produces a 10 residue N terminus that does not include a feedback regulatory domain 9 PanK III edit nbsp Fig 2 Dimer structure of PanK III PanK III also contains two protein domains and the key catalytic residues of PanK II are conserved The monomer units of PanK II and PanK III are virtually identical but they have distinctly different dimer assemblies A study between the structures of Staphylococcus aureus type II and the Pseudomonas aeruginosa type III demonstrate that the PanK II monomer has a loop region that is absent from the PanK III monomer and the PanK III monomer has a loop region that is absent from the PanK II monomer 10 This minor variation has a crucial difference on the dimerization interface in which the helices of the PanK II dimer coil around one another and the helices of the PanK III dimer interact at a 70 angle Figure 2 11 As a result of this difference in dimerization interface between PanK II and PanK III the conformations of the substrate binding sites for ATP and pantothenate are also distinct 12 13 Catalytic Mechanism edit nbsp Fig 3 Proposed catalytic mechanism for PanK II PanK II edit A proposed mechanism of the phosphoryl transfer reaction of PanK II is a concerted mechanism with a dissociative transition state First the ATP binds at the binding groove created by residues of the P loop and nearby residues Here the conserved lysine Lys 101 is the key residue required for ATP binding 14 15 Additionally the side chains of residues Lys 101 Ser 102 Glu 199 and Arg 243 orient the nucleotide in the binding groove The pantothenate is bound and oriented by forming hydrogen bond interactions with residues Asp 127 Tyr 240 Asn 282 Tyr 175 and His 177 8 When both ATP and pantothenate are bound Asp 127 deprotonates the C1 hydroxyl group of pantothenate The oxygen from the pantothenate then attacks the g phosphate of the bound ATP Here charge stabilization of b and g phosphate groups is achieved by Arg 243 Lys 101 and a coordinated Mg2 ion 16 In this concerted mechanism the planar phosphorane of the g phosphate is transferred in line to the attacking oxygen of pantothenate 8 Finally 4 phosphopantothenate dissociates from PanK followed by ADP Regulation of pantothenate kinase editPanK II edit The regulation of pantothenate kinase is essential to controlling the intracellular CoA concentration 17 Pantothenate kinase is regulated via feedback inhibition by CoA and its thioesters i e acetyl CoA malonyl CoA 18 Inhibition of the human isoforms of PanK by acetyl CoA varies dramatically PanK1b is inhibited the least strongly with an IC50 value of around 5 mM while PanK2 is the most strongly inhibited with an IC50 of around 0 1 mM 6 CoA inhibits PanK activity by competitively binding to the ATP binding site and preventing ATP binding to Lys 101 14 15 Although CoA binds at the same site as ATP they bind in distinct orientations and their adenine moieties interact with the enzyme with nonoverlapping sets of residues His 177 Phe 247 and Arg 106 are necessary for CoA recognition but not for ATP and while Asn 43 and His 307 interact with the adenine base of ATP His 177 and Phe 247 interact with the adenine base of CoA 16 Both molecules use Lys 101 to neutralize the charge on their respective phosphodiesters Nonesterified CoA has more potent inhibition than its thioesters This phenomenon is best explained by the tight fit of the thiol group with the surrounding aromatic residues Phe 244 Phe 259 Tyr 262 and Phe 252 Free CoA has an optimal fit but when an acyl group is attached to CoA the steric hindrance makes it difficult for the thioester to interact with Phe 252 Thus the inhibition by thioesters is less effective than that by nonesterified CoA 16 Deletion of PanK1 disrupts metabolic pathways including fatty acid oxidation and gluconeogenesis PanK1 mouse models in a fasted state show impaired gluconeogenesis indicating that this pathway is disrupted In addition CoA levels decrease significantly between PanK1 and wild type mice This reduction in CoA also appears to correlate with a disruption in fatty acid oxidation Higher levels of long chain acyl carnitines were observed in PanK1 mice indicating a lower capability for fatty acid oxidation in these mice 19 nbsp PanK2 Regulation Because PanK2 is so strongly inhibited by acetyl CoA an abundant metabolite in the mitochondria this enzyme likely would not be active under physiological conditions without activators 6 Palmitoyl carnitine and other long chain acyl carnitines can reverse acetyl CoA inhibition and can activate PanK2 without acetyl CoA present Palmitoyl carnitine is competitive with acetyl CoA 20 The activation of PanK2 by palmitoyl carnitine and other long chain acyl carnitines sheds light on the regulatory pathways of this enzyme Under normal conditions PanK2 is likely inhibited by high levels of acetyl CoA Without CoA production fatty acid oxidation decreases leading to an increase in long chain acyl carnitines 19 These acyl carnitines can then reduce inhibition by acetyl CoA activating PanK2 and increasing CoA biosynthesis PanK3 is also activated by palmitoyl carnitine and other long chain acyl carnitines including oleoyl carnitine 21 PanK III edit The regulation outlined above corresponds to PanK II PanK III is resistant to feedback inhibition 10 12 13 Genes editIn humans PANK1 PANK2 PANK3 PANK4 The PANK2 gene encodes for PanK2 which regulates the formation of CoA in mitochondria the cell s energy producing centers 22 PANK2 mutation is the cause of Pantothenate kinase associated neurodegeneration PKAN formerly called Hallervorden Spatz syndrome This rare disease presents with profound dystonia spasticity and is often fatal There are many mutations in PanK2 that lead to PKAN In a survey of several common mutations it was found that several of these mutations did not cause a major loss in the catalytic activity of PanK2 indicating that loss of catalytic function of this enzyme is not fully responsible for this disease 23 References edit Robishaw JD Berkich D Neely JR September 1982 Rate limiting step and control of coenzyme A synthesis in cardiac muscle The Journal of Biological Chemistry 257 18 10967 72 doi 10 1016 S0021 9258 18 33918 8 PMID 7107640 a b Yang K Eyobo Y Brand LA Martynowski D Tomchick D Strauss E Zhang H August 2006 Crystal structure of a type III pantothenate kinase insight into the mechanism of an essential coenzyme A biosynthetic enzyme universally distributed in bacteria Journal of Bacteriology 188 15 5532 40 doi 10 1128 JB 00469 06 PMC 1540032 PMID 16855243 Leonardi R Zhang YM Rock CO Jackowski S 2005 03 01 Coenzyme A back in action Progress in Lipid Research 44 2 3 125 53 doi 10 1016 j plipres 2005 04 001 PMID 15893380 a b c Hong BS Senisterra G Rabeh WM Vedadi M Leonardi R Zhang YM Rock CO Jackowski S Park HW September 2007 Crystal structures of human pantothenate kinases Insights into allosteric regulation and mutations linked to a neurodegeneration disorder The Journal of Biological Chemistry 282 38 27984 93 doi 10 1074 jbc M701915200 PMID 17631502 Alfonso Pecchio Adolfo Garcia Matthew Leonardi Roberta Jackowski Suzanne 2012 Compartmentalization of mammalian pantothenate kinases PLOS ONE 7 11 e49509 doi 10 1371 journal pone 0049509 ISSN 1932 6203 PMC 3496714 PMID 23152917 a b c Dansie Lorraine E Reeves Stacy Miller Karen Zano Stephen P Frank Matthew Pate Caroline Wang Jina Jackowski Suzanne August 2014 Physiological roles of the pantothenate kinases Biochemical Society Transactions 42 4 1033 1036 doi 10 1042 BST20140096 ISSN 1470 8752 PMC 4948118 PMID 25109998 Saraste M Sibbald PR Wittinghofer A November 1990 The P loop a common motif in ATP and GTP binding proteins Trends in Biochemical Sciences 15 11 430 4 doi 10 1016 0968 0004 90 90281 F PMID 2126155 a b c Ivey RA Zhang YM Virga KG Hevener K Lee RE Rock CO Jackowski S Park HW August 2004 The structure of the pantothenate kinase ADP pantothenate ternary complex reveals the relationship between the binding sites for substrate allosteric regulator and antimetabolites The Journal of Biological Chemistry 279 34 35622 9 doi 10 1074 jbc M403152200 PMID 15136582 Rock CO Karim MA Zhang YM Jackowski S 2002 The murine pantothenate kinase Pank1 gene encodes two differentially regulated pantothenate kinase isozymes Gene 291 1 2 35 43 doi 10 1016 S0378 1119 02 00564 4 PMID 12095677 a b Yang K Strauss E Huerta C Zhang H February 2008 Structural basis for substrate binding and the catalytic mechanism of type III pantothenate kinase Biochemistry 47 5 1369 80 doi 10 1021 bi7018578 PMID 18186650 Hong BS Yun MK Zhang YM Chohnan S Rock CO White SW Jackowski S Park HW Leonardi R August 2006 Prokaryotic type II and type III pantothenate kinases The same monomer fold creates dimers with distinct catalytic properties Structure 14 8 1251 61 doi 10 1016 j str 2006 06 008 PMID 16905099 a b Brand LA Strauss E May 2005 Characterization of a new pantothenate kinase isoform from Helicobacter pylori The Journal of Biological Chemistry 280 21 20185 8 doi 10 1074 jbc C500044200 PMID 15795230 a b Choudhry AE Mandichak TL Broskey JP Egolf RW Kinsland C Begley TP Seefeld MA Ku TW Brown JR Zalacain M Ratnam K June 2003 Inhibitors of pantothenate kinase novel antibiotics for staphylococcal infections Antimicrobial Agents and Chemotherapy 47 6 2051 5 doi 10 1128 AAC 47 6 2051 2055 2003 PMC 155856 PMID 12760898 a b Song WJ Jackowski S October 1994 Kinetics and regulation of pantothenate kinase from Escherichia coli The Journal of Biological Chemistry 269 43 27051 8 doi 10 1016 S0021 9258 18 47124 4 PMID 7929447 a b Song WJ Jackowski S October 1992 Cloning sequencing and expression of the pantothenate kinase coaA gene of Escherichia coli Journal of Bacteriology 174 20 6411 7 doi 10 1128 jb 174 20 6411 6417 1992 PMC 207592 PMID 1328157 a b c Yun M Park CG Kim JY Rock CO Jackowski S Park HW September 2000 Structural basis for the feedback regulation of Escherichia coli pantothenate kinase by coenzyme A The Journal of Biological Chemistry 275 36 28093 9 doi 10 1074 jbc M003190200 PMID 10862768 Jackowski S Rock CO December 1981 Regulation of coenzyme A biosynthesis Journal of Bacteriology 148 3 926 32 doi 10 1128 jb 148 3 926 932 1981 PMC 216294 PMID 6796563 Rock CO Park HW Jackowski S June 2003 Role of feedback regulation of pantothenate kinase CoaA in control of coenzyme A levels in Escherichia coli Journal of Bacteriology 185 11 3410 5 doi 10 1128 JB 185 11 3410 3415 2003 PMC 155388 PMID 12754240 a b Leonardi Roberta Rehg Jerold E Rock Charles O Jackowski Suzanne 2010 06 14 Pantothenate kinase 1 is required to support the metabolic transition from the fed to the fasted state PLOS ONE 5 6 e11107 Bibcode 2010PLoSO 511107L doi 10 1371 journal pone 0011107 ISSN 1932 6203 PMC 2885419 PMID 20559429 Leonardi Roberta Rock Charles O Jackowski Suzanne Zhang Yong Mei 2007 01 30 Activation of human mitochondrial pantothenate kinase 2 by palmitoylcarnitine Proceedings of the National Academy of Sciences 104 5 1494 1499 doi 10 1073 pnas 0607621104 ISSN 0027 8424 PMC 1785270 PMID 17242360 Leonardi Roberta Zhang Yong Mei Yun Mi Kyung Zhou Ruobing Zeng Fu Yue Lin Wenwei Cui Jimmy Chen Taosheng Rock Charles O White Stephen W Jackowski Suzanne 2010 08 27 Modulation of Pantothenate Kinase 3 Activity by Small Molecules that Interact with the Substrate Allosteric Regulatory Domain Chemistry amp Biology 17 8 892 902 doi 10 1016 j chembiol 2010 06 006 ISSN 1074 5521 PMC 2929395 PMID 20797618 PANK2 gene Genetics Home Reference 2016 02 22 Retrieved 2016 02 29 Zhang Yong Mei Rock Charles O Jackowski Suzanne 2006 01 06 Biochemical properties of human pantothenate kinase 2 isoforms and mutations linked to pantothenate kinase associated neurodegeneration The Journal of Biological Chemistry 281 1 107 114 doi 10 1074 jbc M508825200 ISSN 0021 9258 PMID 16272150 External links editPantothenate kinase at the U S National Library of Medicine Medical Subject Headings MeSH EC 2 7 1 33 Portal nbsp Biology Retrieved from https en wikipedia org w index php title Pantothenate kinase amp oldid 1172356249, wikipedia, wiki, book, books, library,

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