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<StructureSection load='3GRO' size='350' frame='true' align='right' caption='Human Palmitoyl-protein thioesterase 1 (PPT-1) homodimer (PDB: [[3gro]])' scene='43/436866/Overall-3-rainbow/1' > | |||
=Introduction= | |||
'''<scene name='43/436866/Overall-3-rainbow/1'>Palmitoyl-protein thioesterase 1 (PPT-1)</scene>''' is a small glycoprotein [[hydrolase]] found in the lysosome that breaks the thioester bond between cysteine [[amino acids]] and <scene name='43/436866/Palmitic_acid_self/2'>palmitic acid</scene><ref name="newest">PMID:24083319</ref>. PPT-1 is a homodimer that is composed primarily of alpha helices and beta sheets with a <scene name='58/580839/Narrow_binding_groove/1'>hydrophobic groove</scene> that allows the [http://en.wikipedia.org/wiki/Palmitic_acid palmitic acid] to bind, exposing the thioester bond to the catalytic triad. PPT-1 was first found as an enzyme that removed palmitate from [[GTPase HRas]] and now has many additional cellular substrates <ref name="mutations">PMID:10781062</ref>. When PPT-1 is not functioning properly, lipid modified proteins can build up in the cells, causing lysosomal storage diseases and aiding in tumor formation <ref name="INCL">PMID:19302939</ref>. | |||
[[Image:Protopedia_surface_w_acid.png |300px|left|thumb|Figure 1: Surface view of PPT-1 (green) showing the hydrophobic groove and palmitate (blue with red oxygen)]] | |||
==Catalytic Triad== | |||
The binding surface of PPT-1 creates an external hydrophobic groove that binds the palmitate acid in-between carbon 4 and 5 (Figure 1). The acid binds in a [https://en.wikipedia.org/wiki/Gauche_effect gauche conformation] creating a <scene name='58/580839/Kink_in_acid/1'>kink </scene> | |||
in the acid chain. This bending suggests that PPT-1 was originally designed to react with an unsaturated fatty acid with cis-double bonds. The catalytic <scene name='43/436866/Triad_w_zoom_no_backbones/1'>triad</scene> is composed of Serine-115, Aspartate-233, and Histidine-289 <ref name="mutations" />. Ser-115 is deprotonated by His-289 and attacks the carbonyl carbon of the thioester bond connecting palmitic acid to the protein substrate. The negative charge is pushed onto the oxygen and is stabilized in an oxyanion hole by a water molecule. The tetrahedral intermediate collapses and kicks the palmatic acid off of the cysteine residue<ref name="mutations" />. | |||
[[Image:Rxn ppt1.jpg|400px|right|thumb|Figure 2: The basic enzymatic reaction catalyzed by PPT-1. Ser-115, depronated by His-289, attacks the carbonyl carbon of the thioester bond ]] | |||
=Inhibitors of PPT-1= | |||
'''<scene name='43/436866/Overall-3-rainbow/1'>PPT-1</scene>''' is a lysosomal enzyme, which has a serine [[lipase]] consensus sequence; a key characteristic of lysosomal enzymes. Despite having a serine lipase consensus sequence, PPT-1, is not deactivated by phenylmethylsulfonyl fluoride [https://en.wikipedia.org/wiki/PMSF (PMSF)], a common serine-modifying reagent. <scene name='58/580839/Hdsf_by_itself/1'>Hexadecylsulfonylfluoride</scene> (HDSF) is a serine-modifying reagent that is able to <scene name='58/580839/Basic-hdsf-nosurface/4'> bind and inhibit PPT-1</scene>. Unlike other inhibitors, <scene name='58/580839/Basic-hdsf-surfacelook/2'>HDSF is able to fit in the narrow, hydrophobic groove of PPT-1</scene> leading away from the active site of PPT-1. PMSF is unable to fit into this small narrow groove due to steric constraints that relate to the unique structure of the substrate-binding site of PPT-1. The sulphur of HDSF will <scene name='58/580839/Hdsf_bound_to_ser-115-best/1'>bind to SER-115 in the active site of PPT-1</scene> via a sulphonylation reaction and thus will inhibit the actions of PPT-1<ref name="INCL">PMID:10801859</ref>. | |||
=Disorder Associated With PPT-1= | |||
Mutations in Palmitoyl Protein Thioesterase 1 (PPT-1) can cause three types of disorders: [http://en.wikipedia.org/wiki/Infantile_neuronal_ceroid_lipofuscinosis Infantile Neuronal Ceroid Lipofuscinosis (INCL)], [http://www.mun.ca/biology/dmarshall/One%20Pager.htm Late Infantile Neuronal Ceroid Lipofuscinosis (LINCL)], and [http://ghr.nlm.nih.gov/condition/juvenile-batten-disease Juvenile Neuronal Cerioid Lipofuscinosis (JNCL)]. The severity of most of the mutations are dependent upon their location inside the protein with respect to the catalytic triad. “Mutations that affect catalysis or substrate binding or disrupt proper folding of the core result in inactive enzymes and lead to a severe clinical phenotype” <ref name="mutations" />. Other mutations that cause less severe disorders can sometimes retain some residual thioesterase activity. These less severe mutations are believed to have small, local changes in areas of the protein that are far away from the catalytic <scene name='43/436866/Triad_w_zoom_no_backbones/1'>triad</scene> and palmitate binding site. A more detailed explanation of how some of the different disorders arise through mutations is explained below<ref name="mutations" />. | |||
==Infantile Neuronal Ceroid Lipofuscinosis== | |||
[[Image:All_mutations.jpg|200px|right|thumb|Figure 3: Mutations to PPT-1 associated with INCL. Twelve common mutations of INCL are shown in the white on the blue PPT-1 protein.]] | |||
[https://en.wikipedia.org/wiki/Infantile_neuronal_ceroid_lipofuscinosis Infantile Neuronal Ceroid Lipofuscinosis (INCL)] is a recessively inherited disease that is associated with a decrease in PPT-1 activity due to mutations in PPT-1. Onset of symptoms which include retinal blindness, ataxia, seizures, and cortical atrophy of the brain, begin 1-2 years after birth. Death typically occurs between the ages of 8-11. Several mutations in the ''1p32'' chromosome have been identified to cause INCL <ref name="mutations" />. | |||
===Mutations leading to Infantile Neuronal Ceroid Lipofuscinosis=== | |||
Various mutations have been found in INCL patients<ref name="Ryan-1">PMID:10191107</ref>. Most of these mutations are caused by nonsense or missense mutations within close proximity to the catalytic <scene name='43/436866/Triad_w_zoom_no_backbones/1'>triad</scene>. These mutations lead to an inactive PPT-1 enzyme as they are predicted to create unfavorable steric, polar, and electrostatic interactions that could disturb the nucleophilic elbow <ref name="mutations" />. The nucleophilic elbow is responsible for proper location and orientation of the Ser-115. The catalytic activity of PPT-1 is greatly reduced if the positioning of Ser-115 is altered, as Ser-115 must be properly orientated to be activated by His-289 to be positioned to attack the substrate. An example of a INCL mutation such as <scene name='58/580837/Methionine/9'>Val181Met</scene> and <scene name='58/580837/Lysine_mutation/4'>Glu184Lys</scene> gives a good depiction of how the increase in size in the mutated amino acids and positive charge on the inserted lysine residue would create steric and polar clashes with the adjacent helices of the binding pocket compared to the <scene name='58/580837/Val181glu184/3'>normal Val-181 and Glu-184</scene>. <scene name='58/580837/Arginine_fine/5'>Normal Arg-122</scene> which is below <ref name="Ryan-1">PMID:10191107</ref>. | |||
(*All mutation scenes are the proposed best rotamers of the mutation. These mutations were created through the use of the mutagenesis wizard in the PyMOL program) | |||
Known INCL Mutations | |||
1. Arg122Trp 2. Phe225Ser | |||
3. Gly118Asp 4. Gly42Gln | |||
5. Tyr109Asp 6. His39Asp | |||
7. Glu184Lys 8. Val181Met | |||
====Arg122Trp==== | |||
The most common mutation in INCL that occurs in PPT-1 is a single missense mutation of Arg122Trp. <scene name='58/580837/Arginine_fine/7'>Arg-122</scene> is located immediately after the nucleophilic elbow of PPT-1. The sidechain of Arg-122 has a main function to control the spacing between the αC and α6 helices in this region. This is done by Arg-122 having <scene name='58/580837/Arginine_fine/3'>three hydrogen bonds</scene> with three adjacent amino acids: Ile-205, Asn-206, and Gln-205. <scene name='58/580837/Trp122_mutation/24'>Mutation of Arg-122 to Trp</scene> means not only a loss of those three hydrogen bonds but also a steric and polarity mismatch with the surrounding residues <ref name="mutations" />. These <scene name='58/580837/Trp122_mutation/25'>steric clashes</scene> will cause a misfolding of the enzyme’s core and cause it to be trapped in the endoplasmic reticulum, which results in no detectable PPT-1 activity. | |||
==Late-Infantile and Juvenile Neuronal Ceroid Lipofuscinosis== | |||
Juvenile NCL (JNCL) and Late-Infantile NCL (LINCL) are less severe forms of INCL in which onset of symptoms occur much later in life; between the ages of 30-40. A possible explanation for the later onset of symptoms could be that the mutations associated with JNCL and LINCL occur away from the active site of PPT-1. Since the mutation does not affect the active site this results in a higher activity of the PPT-1 enzyme. A common mutation associated with JNCL and LINCL involves the mutation of Thr-75, an amino acid located on the alpha-1 helix of PPT-1 (Figure 4). The Thr-75 amino acid is located 20.6Å away from the active site of PPT-1 which indicates that Thr-75 plays no role in the catalytic activity of the catalytic triad | |||
<ref name="mutations" />. | |||
[[Image:Thr-_mut.png|200px|left|thumb|Figure 4: Common Mutation associated with JNCL and LINCL involves mutations far away from the active Ser-115. ]] | |||
In both JNCL and LINCL, the activity of PPT-1 is at only 2% of the normal activity rate of PPT-1. This suggests that a small increase in activity of PPT-1 may aid in delaying the symptoms associated with INCL, LINCL, and JNCL. One way to potentially increase the activity of mutant PPT-1 variants is to use [https://en.wikipedia.org/wiki/Protein_chaperones protein chaperones] that help refold PPT-1 in the [http://en.wikipedia.org/wiki/Endoplasmic_reticulum endoplasmic reticulum]. Although this is not a cure for INCL, increasing the activity of PPT-1 by only two-fold can also increase the life expectancy for individuals with INCL <ref name="Kelly-1">PMID:20346914</ref>. | |||
Despite the life-threatening disorders associated with decreased PPT-1 activity, inhibition of PPT-1 has also been shown to be a potential cancer target. Proteins involved in signaling and growth are post-translationally modified with palmitic acid. PPT-1 is involved with removing palmitate from lipid-modified proteins and this [http://en.wikipedia.org/wiki/Palmitoylation palmitoylation] is necessary for membrane association. When PPT-1 is over expressed, cells become protected from cell death, which leads to tumor formation. PPT-1 inhibition in cultured tumor cells led to selective tumor cell death <ref name="Kelly-1" />. | |||
===Mutations leading to Late-Infantile Neuronal Ceroid Lipofuscinosis=== | |||
LINCl is caused by a mutation in the CLN2 gene which “codes for a lysosomal pepstatin-insensitive acid protease that is deficient in LINCL patients”<ref name="Ryan-2">PMID:9989590</ref>. Mutations that tend to lead to LINCL still disrupt the active site and binding pocket geometry, but not to the degree that is seen in INCL. One LINCL mutation is <scene name='58/580837/Multiple_mutations_mutating/5'>Gln177Glu</scene>. <scene name='58/580837/Multiple_mutations/5'>Gln-177</scene> acts as a hydrogen bond donor to Ala-171 and Ala-183 and as a hydrogen bond acceptor from Ile-200. The mutation of Gln-177 likely causes a conformation change of the helices in the area. Ala-171 and Ala-183 make hydrophobic contact with the palmitate, and so the altered conformation associated with those two amino acids would decrease binding affinity of the palmitate, decreasing, but not killing the catalytic activity of PPT-1. | |||
===Mutations leading to Juvenile Neuronal Ceroid Lipofuscinosis=== | |||
JNCL is caused by a mutation in the CLN3 gene which codes for a lysosomal membrane protein of unknown function <ref name="Ryan-3">PMID:9151311</ref>. Unlike the mutations that cause INCL and LINCL, mutations that lead to JNCL are located away from the active site and are seen to cause less damage to the overall structure of PPT-1. Some of the mutations in JNCL have been noted as retaining a low level of PPT-1 activity as the catalytic site is left fairly unperturbed. Mutations associated with JNCl are found in two locations, Thr75Pro with Asp79Gly and <scene name='58/580837/Juvenile_mutation/4'>Tyr247His with Gly250Val</scene>. These mutations occur in conjugate with its other pair and are predicted to disturb the geometry of helix α1, increasing the flexibility of the region, and alter the antiparallel βsheet motif in sheets βa and βb compared to the <scene name='58/580837/Tyrosine_normal/2'>normal Tyr-247 and Gly-250</scene>. | |||
</StructureSection> | |||
==References== | |||
<references/> | |||
==External Resources== | |||
[https://en.wikipedia.org/wiki/Gauche_effect Gauche Effect] Wikipedia page | |||
[http://en.wikipedia.org/wiki/Palmitic_acid Palmitic acid] Wikipedia page | |||
[https://en.wikipedia.org/wiki/Infantile_neuronal_ceroid_lipofuscinosis Infantile Neuronal Ceroid Lipofuscinosis] Wikipedia page | |||
[https://en.wikipedia.org/wiki/PMSF PMSF] Wikipedia page | |||
[https://en.wikipedia.org/wiki/Protein_chaperones Protein Chaperones] Wikipedia page | |||
[http://en.wikipedia.org/wiki/Endoplasmic_reticulum Endoplasmic reticulum] Wikipedia page | |||
[http://en.wikipedia.org/wiki/Palmitoylation Palmitoylation] Wikipedia page | |||
Page on [http://www.mun.ca/biology/dmarshall/One%20Pager.htm Late Infantile neuronal Ceroid Lipofuscinosis] | |||
Page on [http://ghr.nlm.nih.gov/condition/juvenile-batten-disease Juvenile neuronal Ceroid Lipofuscinosis] | |||