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SARS-CoV-2 Spike Protein (7JZL):SARS-CoV-2 Spike Protein (7JZL): A trimer responsible for interacting with host ACE2 receptors to deliver the virus into host cells. Receptor binding domains (RBDs) are highlighted at the top of each monomer.

Drag the structure with the mouse to rotate

1 Introduction
2 Vaccines
3 Protein Inhibitor Development
- 3.1 The Process of Discovery
- 3.2 Stability
4 Binding Site and Interactions
5 Conclusion

Introduction

Figure 1: The process of the SARS-CoV-2 virus entering human cells. This image was created using BioRender.

SARS-CoV-2 better known as Covid-19 sent the world into a global pandemic due to its rapid transmission and infection. In order to create a vaccine, it was essential to understand how SARS-CoV-2 infected us.

The enzyme angiotensin converting enzyme 2 is attached to our cell membranes and then can be bound to a receptor binding domain ^[1]. The virus, SARS-CoV-2, enters our bodies containing a protruding from the viral membrane. The RBD on the end of the spike protein giving SARS-CoV-2 the ability to enter our host cells ^[2]. Once the spike protein has access to our host cells, it is able to further infect our cells and spread the virus throughout our bodies, causing us to get sick. Figure 1 demonstrates the path SARS-CoV-2 takes to get into our cells. In order to create an effective vaccine, the pathway between the spike protein and the RBD needed to be interrupted ^[3].

Vaccines

A vaccine activates the body’s immune system by containing weakened parts of viruses. This activation stimulates the production of antibodies. then compete with the ACE2 protein for the binding of viral spike proteins. In the case of SARS-CoV-2 spike proteins, once they enter the body they to the Fab fragment of the antibody, a 90% neutralizing response for targeting the RBD is created. In this scene only the Fab fragment is being shown due to the fact that the Fab fragment is the part of the antibody that interacts with the RBD. With this being said, this method of treatment is difficult for long term use due to the evolution of the viral cells ^[4].

Protein Inhibitor Development

Protein inhibitors were thought of as a new idea for creating vaccines due to their smaller size and better stability compared to antibody vaccines^[5]. These protein inhibitors, also referred to as mini-binders, interact with the receptor binding domain of the spike protein,

The Process of Discovery

Figure 2: The use of the Rosetta Blueprint protein design to create the AHB2 inhibitor (7JZL & 7UHB).

The first mini-binder to be created to combat COVID-19 is called AHB2. In order to ensure that the mini-binder would bind to the same RBD that the ACE2 was bound to, AHB2 was designed by looking at the specific sequence of ACE2 to find the alpha-helix that makes interactions with the spike receptor binding domain. This design process is referred to as the Rosetta Blueprint protein design. Figure 2 shows the RBD trimer with one part of ACE2 being used for the reference alpha helix to create AHB2 ^[5].

Figure 3:The use of the De Novo protein design to create the LCB1 and LCB3 inhibitors (7JZL).

As the AHB2 inhibitors were tested and found to be effective, it was then time to manipulate the mini-binders to create a more effective vaccine. A rotamer interaction field docking with in silico mini-proteins were used by using a scaffold library to generate binders to more distinct regions of the RBD surface Cite error: Invalid <ref> tag; refs with no content must have a name. This method is known as the de novo protein design and it is how the LCB1 and LCB3 mini-binders were created. Figure 3 shows the difference LCBs pulled from the scaffold library to create the different LCB inhibitors.

Stability

One of the most important findings with these De Novo proteins is their high stability, allowing for less delicate forms of administration. Additionally, it was found that the Rosetta built minibinder had a lower thermal stability than the completely De Novo proteins. Looking at the , there are only 4 key internal residues significantly contributing to stability, and they are not oriented directly towards the center of the protein for optimal interaction. Comparatively, the and had 5 key internal residues more centrally directed contributing to stability.

Binding Site and Interactions

In order to best target the RBD of the spike protein, the minibinders reveal a wide range of interactions to compete with .

The first design method, Rosetta, created AHB2 based on the single interacting helix of ACE2. With , we see two alpha helices mimicking ACE2. Hydrogen bonding interactions between N36, D11, K43, E41, and E30 of the minibinder interact with residues K417, R403, Y449, Q493, and N487, respectively, in the spike protein.

De novo designed proteins, as discussed previously, focused on computational design to determine residues best able to interact with the spike protein. We will focus on LCB1 and LCB3. reveals hydrogen bonding between D30 of the minibinder and both K417 and R403 of the spike protein, in addition to D17 and R14 of the minibinder interacting with Q493 of the spike protein. Similarly, reveals hydrogen bonding between D11 of the minibinder to K417 and R403 of the spike protein.

Within all four binding sites, we see two conserved residues throughout: K417 and Q493. This finding reveals the importance of these residues in both binding and stability.

Furthermore, an interesting difference between the two design methods is the location of hydrogen bonding interactions. In AHB2, similar to ACE2, we see interactions spanning the entirety of the helices in contact with the spike protein. De novo design, on the other hand, reveals the main hydrogen bonding interactions occurring within the center residues of the helices.

Figure 4 shows the sequence comparison between the interacting helix of ACE2 and the helices of the three minibinders.

Figure 4: The sequence differences between ACE2, AHB2, LCB1 and LCB3.

Conclusion

References

↑ Borkotoky S, Dey D, Hazarika Z. Interactions of angiotensin-converting enzyme-2 (ACE2) and SARS-CoV-2 spike receptor-binding domain (RBD): a structural perspective. Mol Biol Rep. 2023 Mar;50(3):2713-2721. PMID:36562937 doi:10.1007/s11033-022-08193-4
↑ Jackson CB, Farzan M, Chen B, Choe H. Mechanisms of SARS-CoV-2 entry into cells. Nat Rev Mol Cell Biol. 2022 Jan;23(1):3-20. PMID:34611326 doi:10.1038/s41580-021-00418-x
↑ Zhu Y, Li M, Liu N, Wu T, Han X, Zhao G, He Y. Development of highly effective LCB1-based lipopeptides targeting the spike receptor-binding motif of SARS-CoV-2. Antiviral Res. 2023 Mar;211:105541. PMID:36682464 doi:10.1016/j.antiviral.2023.105541
↑ Zhang H, Lv P, Jiang J, Liu Y, Yan R, Shu S, Hu B, Xiao H, Cai K, Yuan S, Li Y. Advances in developing ACE2 derivatives against SARS-CoV-2. Lancet Microbe. 2023 May;4(5):e369-e378. PMID:36934742 doi:10.1016/S2666-5247(23)00011-3
↑ ^5.0 ^5.1 Cao L, Goreshnik I, Coventry B, Case JB, Miller L, Kozodoy L, Chen RE, Carter L, Walls AC, Park YJ, Strauch EM, Stewart L, Diamond MS, Veesler D, Baker D. De novo design of picomolar SARS-CoV-2 miniprotein inhibitors. Science. 2020 Oct 23;370(6515):426-431. PMID:32907861 doi:10.1126/science.abd9909

PDB Files

[1]https://www.rcsb.org/structure/7UHB

[2]RCSB PDB - 8YZC: Structure of BA.2.86 spike protein in complex with ACE2.

[3]RCSB PDB - 7JZL: SARS-CoV-2 spike in complex with LCB1 (2RBDs open)

[4]RCSB PDB - 6LZG: Structure of novel coronavirus spike receptor-binding domain complexed with its receptor ACE2

[5]RCSB PDB - 7CDI: Crystal structure of SARS-CoV-2 antibody P2C-1F11 with RBD

Student Contributors

Giavanna Yowell
Shea Bailey
Matthew Pereira

Proteopedia Page Contributors and Editors (what is this?)

Shea Bailey

Retrieved from "http://52.214.119.220/wiki/index.php/User:Shea_Bailey/Sandbox_1"

@@ Line 1: / Line 1: @@
-<scene name='10/1075219/Ace2/1'>Text To Be Displayed</scene><scene name='10/1075219/Lcb1/1'>Text To Be Displayed</scene><scene name='10/1075219/Lcb3/1'>Text To Be Displayed</scene>==SARS-CoV-2 Miniprotein Inhibitors, LCB1==
+<StructureSection load='7jzl' size='350' frame='true' side='right' caption='SARS-CoV-2 Spike Protein (7JZL):SARS-CoV-2 Spike Protein (7JZL): A trimer responsible for interacting with host ACE2 receptors to deliver the virus into host cells. Receptor binding domains (RBDs) are highlighted at the top of each monomer.' scene='10/1078124/Spike_protein/1'>
-<StructureSection load='7jzu' size='350' frame = 'true' side='right' caption='LCB1 7ZJU' scene=''>
 ==Introduction==
+[[Image:Illustration.png|400 px|right|thumb|Figure 1: The process of the SARS-CoV-2 virus entering human cells. This image was created using BioRender.]]
-[http://https://en.wikipedia.org/wiki/COVID-19 COVID-19] was crazy! It achieves it's goal by the spike protein, on the surface of COVID-19, interacting with ACE2, angiotensin-converting enzyme, to allow entrance of the virus into the host cell.
+SARS-CoV-2 better known as Covid-19 sent the world into a global pandemic due to its rapid [https://www.who.int/europe/emergencies/situations/covid-19 transmission and  infection]. In order to create a vaccine, it was essential to understand how SARS-CoV-2 infected us.
-==Function==
+The enzyme angiotensin converting enzyme 2 <scene name='10/1077473/Ace2_monomer/1'>(ACE2)</scene> is attached to our cell membranes and then can be bound to a receptor binding domain <scene name='10/1077473/Ace2andrbd2/1'>(RBD)</scene> <ref name="Borkotoky">PMID:36562937</ref>. The virus, SARS-CoV-2, enters our bodies containing a <scene name='10/1077473/Rbd_only/2'>spike protein</scene> protruding from the viral membrane. The RBD on the end of the spike protein <scene name='10/1076049/Ace2andrbd/1'>binds to ACE2</scene> giving SARS-CoV-2 the ability to enter our host cells <ref name="Jackson">PMID:34611326</ref>. Once the spike protein has access to our host cells, it is able to further infect our cells and spread the virus throughout our bodies, causing us to get sick. Figure 1 demonstrates the path SARS-CoV-2 takes to get into our cells. In order to create an effective vaccine, the pathway between the spike protein and the RBD needed to be interrupted <ref name=”Zhu”>PMID:36682464</ref>.
-==Mechanism==
-===Active Site===
+==Vaccines==
+A [https://en.wikipedia.org/wiki/Vaccine vaccine] activates the body’s immune system by containing weakened parts of viruses. This activation stimulates the production of antibodies. <scene name='10/1077473/Antibody_overview/4'>Antibodies</scene> then compete with the ACE2 protein for the binding of viral spike proteins. In the case of SARS-CoV-2 spike proteins, once they enter the body they <scene name='10/1077473/Antibody/7'>bind</scene>
+to the Fab fragment of the antibody, a 90% neutralizing response for targeting the RBD is created. In this scene only the Fab fragment is being shown due to the fact that the Fab fragment is the part of the antibody that interacts with the RBD. With this being said, this method of treatment is difficult for long term use due to the evolution of the viral cells <ref name=”Zhang”>PMID:36934742</ref>.
+==Protein Inhibitor Development==
+Protein inhibitors were thought of as a new idea for creating vaccines due to their smaller size and better stability compared to antibody vaccines<ref name="Cao">DOI:10.1126/science.abd9909</ref>. These protein inhibitors, also referred to as mini-binders, interact with the receptor binding domain of the spike protein, <scene name='10/1075220/Spikeblockedbyminibinder/2'>preventing association of the viral cell with ACE2.</scene>
+===The Process of Discovery===
+[[Image:AHB2_Method.png|400 px|right|thumb|Figure 2: The use of the Rosetta Blueprint protein design to create the AHB2 inhibitor (7JZL & 7UHB).]]
+The first mini-binder to be created to combat COVID-19 is called AHB2. In order to ensure that the mini-binder would bind to the same RBD that the ACE2 was bound to, AHB2 was designed by looking at the specific sequence of ACE2 to find the alpha-helix that makes interactions with the spike receptor binding domain. This design process is referred to as the Rosetta Blueprint protein design. Figure 2 shows the RBD trimer with one part of ACE2 being used for the reference alpha helix to create AHB2 <ref name="Cao">PMID:32907861</ref>.
+[[Image:LCB_Method.png|400 px|right|thumb|Figure 3:The use of the De Novo protein design to create the LCB1 and LCB3 inhibitors (7JZL).]]
+As the AHB2 inhibitors were tested and found to be effective, it was then time to manipulate the mini-binders to create a more effective vaccine. A rotamer interaction field docking with in silico mini-proteins were used by using a scaffold library to generate binders to more distinct regions of the RBD surface <ref name=”Cao”/>. This method is known as the de novo protein design and it is how the LCB1 and LCB3 mini-binders were created. Figure 3 shows the difference LCBs pulled from the scaffold library to create the different LCB inhibitors.
+===Stability===
+One of the most important findings with these De Novo proteins is their high stability, allowing for less delicate forms of administration. Additionally, it was found that the Rosetta built minibinder had a lower thermal stability than the completely De Novo proteins. Looking at the <scene name='10/1078124/Ahb2_internal_stability/1'>nonpolar core of AHB2</scene>, there are only 4 key internal residues significantly contributing to stability, and they are not oriented directly towards the center of the protein for optimal interaction. Comparatively, the <scene name='10/1078124/Lcb1_internal_stability/1'>nonpolar core of LCB1</scene> and <scene name='10/1078124/Lcb3_internal_stability/1'>LCB3</scene> had 5 key internal residues more centrally directed contributing to stability.
+==Binding Site and Interactions==
 In order to best target the RBD of the spike protein, the minibinders reveal a wide range of interactions to compete with <scene name='10/1075219/Ace2/1'>ACE2 binding</scene>.
-The first design method, Rosetta, created AHB2 based on the single interacting helix of ACE2. With <scene name='10/1075219/Ahb2/2'>AHB2 binding</scene>, we see two alpha helices mimicking ACE2. Hydrogen bonding interactions between N36, D11, K43, E41, and E30 of the minibinder interact with residues K417, R403, Y449, Q493, and N487, respectively, in the spike protein.
+The first design method, Rosetta, created AHB2 based on the single interacting helix of ACE2. With <scene name='10/1075219/Ahb2/3'>AHB2 binding</scene>, we see two alpha helices mimicking ACE2. Hydrogen bonding interactions between N36, D11, K43, E41, and E30 of the minibinder interact with residues K417, R403, Y449, Q493, and N487, respectively, in the spike protein.
 De novo designed proteins, as discussed previously, focused on computational design to determine residues best able to interact with the spike protein. We will focus on LCB1 and LCB3. <scene name='10/1075219/Lcb1/4'>LCB1 binding</scene> reveals hydrogen bonding between D30 of the minibinder and both K417 and R403 of the spike protein, in addition to D17 and R14 of the minibinder interacting with Q493 of the spike protein. Similarly, <scene name='10/1075219/Lcb3/5'>LCB3 binding</scene> reveals hydrogen bonding between D11 of the minibinder to K417 and R403 of the spike protein.
-Within all four binding sites, we see two conserved residues throughout: K417 and Q493.
+Within all four binding sites, we see two conserved residues throughout: K417 and Q493. This finding reveals the importance of these residues in both binding and stability.
-[[Image:LCB1 new side 1.png|400 px|right|thumb|Figure 1. The coolest image of this protein's binding site EVAH!!!]]
+Furthermore, an interesting difference between the two design methods is the location of hydrogen bonding interactions. In AHB2, similar to ACE2, we see interactions spanning the entirety of the helices in contact with the spike protein. De novo design, on the other hand, reveals the main hydrogen bonding interactions occurring within the center residues of the helices.
-== References ==
+Figure 4 shows the sequence comparison between the interacting helix of ACE2 and the helices of the three minibinders. [[Image:Comparison.jpeg|400 px|left|thumb|Figure 4: The sequence differences between ACE2, AHB2, LCB1 and LCB3.]]
-<ref name="Ransey">PMID:28504306</ref>
-<ref name="Lao">PMID:32907861</ref>
+==Conclusion==
-<ref name="Wrapp">PMID:32075877</ref>
+</StructureSection>
+==References==
 <references/>
-==Student Contributors==
+===PDB Files===
+[1]https://www.rcsb.org/structure/7UHB
+[2]RCSB PDB - 8YZC: Structure of BA.2.86 spike protein in complex with ACE2.
+[3]RCSB PDB - 7JZL: SARS-CoV-2 spike in complex with LCB1 (2RBDs open)
+[4]RCSB PDB - 6LZG: Structure of novel coronavirus spike receptor-binding domain complexed with its receptor ACE2
+[5]RCSB PDB - 7CDI: Crystal structure of SARS-CoV-2 antibody P2C-1F11 with RBD
+==Student Contributors==
+*Giavanna Yowell
 *Shea Bailey
+*Matthew Pereira