Sandbox Reserved 1458

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This Sandbox is Reserved from October 22, 2018 through April 30, 2019 for use in the course Biochemistry taught by Bonnie Hall at the Grand View University, Des Moines, IA USA. This reservation includes Sandbox Reserved 1456 through Sandbox Reserved 1470.

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Structure of PLpro

1 Function
2 Disease
3 Relevance
4 Structural highlights
5 Kinetic Data

Function

The protein is from is Coronaviruses. IBV PLpro performs deubiquitination with catalytic efficiencies that are different from other PLpros. Papain-like protease (PLpro) of coronaviruses (CoVs) carries out proteolytic maturation of non-structural proteins that play a role in replication of the virus and performs deubiquitination of host cell factors to scuttle antiviral responses. This action blocks the activation of host antiviral signaling pathway. The enzyme is PLpro and the substrate is ubiquitin.

Disease

A disease associated with the PLpro protein is avian infectious bronchitis in poultry. The protein helps out with scuttling antiviral responses and when this protein is working it stops the host(chicken) from being able to keep the virus from replicating. Ubiquitination marks protein for degradation via the proteasome and in this case would mark the virus but since the virus can disrupt the markers by removing them this anitviral response is not effective anymore. Other diseases associated with PLpro include respiratory tract infections and uro-gential tract infections.

Relevance

The avian infectious bronchitis virus, IBV, causes bronchitis in chickens and results in huge economic losses every year in the poultry business, and it encodes a PLpro. Understanding how this protein works in the body can help us figure out how to fight this virus and stop the huge loss of chickens each year. The results from this can help provide a way to create antivirals for not only this virus but others as well. Since ubiquitination is not limited to immune responses, PLpros are probably capable of modulating other aspects of the host cell regulated by ubiquitination meaning their impact on the cells goes beyond just this and should be explored further. Ubiquitination affects proteins in differernt ways and some of these ways include, marking them for degradation via the proteasome, altering their cellular location, affecting their activity, and promoting or preventing protein interactions. In this case ubiquitin is marking the proteins for degredation where they will be destroyed later, since now we know the virus has a way to take those markers off more research can be done to figure out how this happening and how to stop it.

Structural highlights

Here is a of PLpro, it's main secondary features are mainly beta sheets and with alpha helixes and a little less random coils. In this the most important tertiary structures of PLpro are highlighted. They include the thumb, palm, finger and ubl domain. These specific domains have an impact on catalytic efficiency, when changed like in MERS or SARs the protein's efficiency changes. This is a view of PLpro where it shows how much space the atoms take up in the protein. This model is useful because it allows us to see shape and relative dimension of the molecule as well as the shape of the surface. Here is a of PLpro, the importance of hydrophobic and hydrophilic regions are that they determine how the proteins fold and that is the case in PLpro as well. PLpro has a mix of hydrophobic and hydrophilic regions. Here is a view of the . The ball seen is Zinc and the rest is the protein. The important chemical features of the ligand is that they form H bonds with each other and have metal interactions with Zinc. The amino acids that interact with the ligand are Cystine, Threonine and Arginine. Cystine interacts with Zn through metal interactions as well as forms H bonds with other Cystines and Threonine. This is the and it helps the protein achieve its function by helping the protein reveal key differences in substrate binding sites of PLpros. Specifically the P3 and P4 sub sites and the residues that interact with the-barrel of ubiquitin are different. This suggest a difference in catalytic activity. It helps the protein function more efficiently by revealing and opening up different binding sites. The catalytic triad include D275, H264, C101. The is pictured here and has the key amino acids highlighted. Those key amino acids are W156, D223, N155 and IIe. W156 is involved in shaping the S2 subsite for a glycine, D223 and N155 help form the pocket and shape active site. IIe replaces T302 which obstructs the placement of the side chain of lysine residue causing BL1 to be moved creating a larger pocket.

Additional structural features include the region around , the the region between the of the PLpro that binds the beta barrel of ubiquitin or the viral peptide substrate, and the region behind that holds the part of the peptide downstream of the cleavage site. In the BL2 image, the black region is the protein and the teal is specifically the BL2 domain. The finger and palm domain are shown in blue and yellow. In the last image of the region right behind BL2 there is the darker green region. These regions are important because they govern the substrate selection.

Kinetic Data

This article compares the kinetic parameters of PLpros from different COVs. Sars COV followed by IBV had higher catalytic efficiencies than MERS COV. This information helps tell us what the proteins can cleave at a given catalytic efficiency. This allows them to see the relationship between the two and see at what catalytic efficiency can the protein still operate and function properly.

References

^[1] ^[2] ^[3]

↑ Kong L, Shaw N, Yan L, Lou Z, Rao Z. Structural View and Substrate Specificity of Papain-like Protease from Avian Infectious Bronchitis Virus. J Biol Chem. 2015 Mar 13;290(11):7160-8. doi: 10.1074/jbc.M114.628636. Epub 2015 , Jan 21. PMID:25609249 doi:http://dx.doi.org/10.1074/jbc.M114.628636
↑ Lei J, Hilgenfeld R. Structural and mutational analysis of the interaction between the Middle-East respiratory syndrome coronavirus (MERS-CoV) papain-like protease and human ubiquitin. Virol Sin. 2016 May 30. PMID:27245450 doi:http://dx.doi.org/10.1007/s12250-016-3742-4
↑ Yu L, Zhang X, Wu T, Wang Y, Meng J, Liu Q, Niu X, Wu Y. The papain-like protease of avian infectious bronchitis virus has deubiquitinating activity. Arch Virol. 2017 Jul;162(7):1943-1950. doi: 10.1007/s00705-017-3328-y. Epub 2017 , Mar 18. PMID:28316013 doi:http://dx.doi.org/10.1007/s00705-017-3328-y

Retrieved from "http://52.214.119.220/wiki/index.php/Sandbox_Reserved_1458"

@@ Line 16: / Line 16: @@
 == Structural highlights ==
 Here is a <scene name='79/799586/4x2z1/2'>cartoon view</scene> of PLpro, it's main secondary features are mainly beta sheets and with alpha helixes and a little less random coils.
-In this <scene name='79/799586/4x2zb/1'>cartoon view</scene> the most important tertiary and quaternary structures of PLpro are highlighted. They include the P4 residues which is the resides that the most impact on catalytic efficiency.
+In this <scene name='79/799586/4x2zb/1'>cartoon view</scene> the most important tertiary structures of PLpro are highlighted. They include the thumb, palm, finger and ubl domain. These specific domains have an impact on catalytic efficiency, when changed like in MERS or SARs the protein's efficiency changes.
-This is a <scene name='79/799586/4x2zhydrophobicity/3'> space fill view</scene> view of PLpro where it shows how much space the atoms take up in the protein. This model is useful because it allows us to see shape and relative dimension of the molecule as well as the shape of the surface.
+This is a <scene name='79/799586/4z2zspacefill/1'>spacefill</scene> view of PLpro where it shows how much space the atoms take up in the protein. This model is useful because it allows us to see shape and relative dimension of the molecule as well as the shape of the surface.
 Here is a <scene name='79/799586/4x2zhydrophobicity/3'> hydrophobic view</scene> of PLpro, the importance of hydrophobic and hydrophilic regions are that they determine how the proteins fold and that is the case in PLpro as well. PLpro has a mix of hydrophobic and hydrophilic regions.
-Here is a view of the <scene name='79/799586/4x2zligand/3'>ligand</scene>. The important chemical features of the ligand is that they form H bonds with each other and have metal interactions with Zinc. The amino acids that interact with the ligand are Cystine, Threonine and Arginine. Cystine interacts with Zn through metal interactions as well as forms H bonds with other Cystines and Threonine.
+Here is a view of the <scene name='79/799586/4x2zligand/3'>ligand</scene>. The ball seen is Zinc and the rest is the protein. The important chemical features of the ligand is that they form H bonds with each other and have metal interactions with Zinc. The amino acids that interact with the ligand are Cystine, Threonine and Arginine. Cystine interacts with Zn through metal interactions as well as forms H bonds with other Cystines and Threonine.
 This is the <scene name='79/799586/4x2zcat/3'>catalytic triad</scene> and it helps the protein achieve its function by helping the protein reveal key differences in substrate binding sites of PLpros. Specifically the P3 and P4 sub sites and the residues that interact with the-barrel of ubiquitin are different. This suggest a difference in catalytic activity. It helps the protein function more efficiently by revealing and opening up different binding sites. The catalytic triad include D275, H264, C101.
 The <scene name='79/799586/Activesite/1'>active site</scene> is pictured here and has the key amino acids highlighted. Those key amino acids are W156, D223, N155 and IIe. W156 is involved in shaping the S2 subsite for a glycine, D223 and N155 help form the pocket and shape active site. IIe replaces T302 which obstructs the placement of the side chain of lysine residue causing BL1 to be moved creating a larger pocket.
-Additional structural features include the region around <scene name='79/799586/Bl2/1'>BL2</scene>, the the region between the <scene name='79/799586/Bl2b/2'>finger and palm region</scene> of the PLpro that binds the beta barrel of ubiquitin or the viral peptide substrate, and the region behind <scene name='79/799586/Bl2b/1'>BL2</scene> that holds the part of the peptide downstream of the cleavage site. These regions are important because they govern the substrate selection.
+Additional structural features include the region around <scene name='79/799586/Bl2/1'>BL2</scene>, the the region between the <scene name='79/799586/Bl2b/2'>finger and palm region</scene> of the PLpro that binds the beta barrel of ubiquitin or the viral peptide substrate, and the region behind <scene name='79/799586/Bl2b/1'>BL2</scene> that holds the part of the peptide downstream of the cleavage site.  In the BL2 image, the black region is the protein and the teal is specifically the BL2 domain. The finger and palm domain are shown in blue and yellow. In the last image of the region right behind BL2 there is the darker green region. These regions are important because they govern the substrate selection.
 == Kinetic Data ==
@@ Line 30: / Line 30: @@
 == References ==
 <ref>PMID 25609249</ref>
+<ref>PMID 27245450</ref>
+<ref>PMID 28316013</ref>
 <references/>

Sandbox Reserved 1458

From Proteopedia

Current revision

Structure of PLpro

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Function

Disease

Relevance

Structural highlights

Kinetic Data

References

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