Determination of molecular structures of HIV envelope glycoproteins using cryo-electron tomography and automated sub-tomogram averaging

Joel R. Meyerson; Tommi A. White; Donald Bliss; Amy Moran; Alberto Bartesaghi; Mario J. Borgnia; M. Jason V. de la Cruz; David Schauder; Lisa M. Hartnell; Rachna Nandwani; Moez Dawood; Brianna Kim; Jun Hong Kim; John Sununu; Lisa Yang; Siddhant Bhatia; Carolyn Subramaniam; Darrell E. Hurt; Laurent Gaudreault; Sriram Subramaniam

doi:10.3791/2770

Determination of molecular structures of HIV envelope glycoproteins using cryo-electron tomography and automated sub-tomogram averaging

Joel R. Meyerson, Tommi A. White, Donald Bliss, Amy Moran, Alberto Bartesaghi, Mario J. Borgnia, M. Jason V. de la Cruz, David Schauder, Lisa M. Hartnell, Rachna Nandwani, Moez Dawood, Brianna Kim, Jun Hong Kim, John Sununu, Lisa Yang, Siddhant Bhatia, Carolyn Subramaniam, Darrell E. Hurt, Laurent Gaudreault, Sriram Subramaniam

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

Since its discovery nearly 30 years ago, more than 60 million people have been infected with the human immunodeficiency virus (HIV) (www.usaid.gov). The virus infects and destroys CD4+ T-cells thereby crippling the immune system, and causing an acquired immunodeficiency syndrome (AIDS) 2. Infection begins when the HIV Envelope glycoprotein spike makes contact with the CD4 receptor on the surface of the CD4+ T-cell. This interaction induces a conformational change in the spike, which promotes interaction with a second cell surface co-receptor 5,9. The significance of these protein interactions in the HIV infection pathway makes them of profound importance in fundamental HIV research, and in the pursuit of an HIV vaccine. The need to better understand the molecular-scale interactions of HIV cell contact and neutralization motivated the development of a technique to determine the structures of the HIV spike interacting with cell surface receptor proteins and molecules that block infection. Using cryo-electron tomography and 3D image processing, we recently demonstrated the ability to determine such structures on the surface of native virus, at̃20 Å resolution 9,14. This approach is not limited to resolving HIV Envelope structures, and can be extended to other viral membrane proteins and proteins reconstituted on a liposome. In this protocol, we describe how to obtain structures of HIV envelope glycoproteins starting from purified HIV virions and proceeding stepwise through preparing vitrified samples, collecting, cryo-electron microscopy data, reconstituting and processing 3D data volumes, averaging and classifying 3D protein subvolumes, and interpreting results to produce a protein model. The computational aspects of our approach were adapted into modules that can be accessed and executed remotely using the Biowulf GNU/Linux parallel processing cluster at the NIH (http://biowulf.nih.gov). This remote access, combined with low-cost computer hardware and high-speed network access, has made possible the involvement of researchers and students working from school or home.

Original language	English (US)
Article number	e2770
Journal	Journal of Visualized Experiments
Issue number	58
DOIs	https://doi.org/10.3791/2770
State	Published - 2011
Externally published	Yes

Keywords

Cryo-electron tomography
Envelope glycoprotein
High school science
Hiv
Immunology
Issue 58
Membrane protein
National cancer institute
National institutes of health
National library of medicine
Scientific outreach
Scientific visualization
Structural biology
Transmission electron microscopy
Vaccine design

ASJC Scopus subject areas

General Neuroscience
General Chemical Engineering
General Biochemistry, Genetics and Molecular Biology
General Immunology and Microbiology

Access to Document

10.3791/2770

Cite this

Meyerson, J. R., White, T. A., Bliss, D., Moran, A., Bartesaghi, A., Borgnia, M. J., de la Cruz, M. J. V., Schauder, D., Hartnell, L. M., Nandwani, R., Dawood, M., Kim, B., Kim, J. H., Sununu, J., Yang, L., Bhatia, S., Subramaniam, C., Hurt, D. E., Gaudreault, L., & Subramaniam, S. (2011). Determination of molecular structures of HIV envelope glycoproteins using cryo-electron tomography and automated sub-tomogram averaging. Journal of Visualized Experiments, (58), Article e2770. https://doi.org/10.3791/2770

Meyerson, JR, White, TA, Bliss, D, Moran, A, Bartesaghi, A, Borgnia, MJ, de la Cruz, MJV, Schauder, D, Hartnell, LM, Nandwani, R, Dawood, M, Kim, B, Kim, JH, Sununu, J, Yang, L, Bhatia, S, Subramaniam, C, Hurt, DE, Gaudreault, L & Subramaniam, S 2011, 'Determination of molecular structures of HIV envelope glycoproteins using cryo-electron tomography and automated sub-tomogram averaging', Journal of Visualized Experiments, no. 58, e2770. https://doi.org/10.3791/2770

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title = "Determination of molecular structures of HIV envelope glycoproteins using cryo-electron tomography and automated sub-tomogram averaging",

abstract = "Since its discovery nearly 30 years ago, more than 60 million people have been infected with the human immunodeficiency virus (HIV) (www.usaid.gov). The virus infects and destroys CD4+ T-cells thereby crippling the immune system, and causing an acquired immunodeficiency syndrome (AIDS) 2. Infection begins when the HIV Envelope glycoprotein spike makes contact with the CD4 receptor on the surface of the CD4+ T-cell. This interaction induces a conformational change in the spike, which promotes interaction with a second cell surface co-receptor 5,9. The significance of these protein interactions in the HIV infection pathway makes them of profound importance in fundamental HIV research, and in the pursuit of an HIV vaccine. The need to better understand the molecular-scale interactions of HIV cell contact and neutralization motivated the development of a technique to determine the structures of the HIV spike interacting with cell surface receptor proteins and molecules that block infection. Using cryo-electron tomography and 3D image processing, we recently demonstrated the ability to determine such structures on the surface of native virus, a{\~t}20 {\AA} resolution 9,14. This approach is not limited to resolving HIV Envelope structures, and can be extended to other viral membrane proteins and proteins reconstituted on a liposome. In this protocol, we describe how to obtain structures of HIV envelope glycoproteins starting from purified HIV virions and proceeding stepwise through preparing vitrified samples, collecting, cryo-electron microscopy data, reconstituting and processing 3D data volumes, averaging and classifying 3D protein subvolumes, and interpreting results to produce a protein model. The computational aspects of our approach were adapted into modules that can be accessed and executed remotely using the Biowulf GNU/Linux parallel processing cluster at the NIH (http://biowulf.nih.gov). This remote access, combined with low-cost computer hardware and high-speed network access, has made possible the involvement of researchers and students working from school or home.",

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AU - Meyerson, Joel R.

AU - White, Tommi A.

AU - Bliss, Donald

AU - Moran, Amy

AU - Bartesaghi, Alberto

AU - Borgnia, Mario J.

AU - de la Cruz, M. Jason V.

AU - Schauder, David

AU - Hartnell, Lisa M.

AU - Nandwani, Rachna

AU - Dawood, Moez

AU - Kim, Brianna

AU - Kim, Jun Hong

AU - Sununu, John

AU - Yang, Lisa

AU - Bhatia, Siddhant

AU - Subramaniam, Carolyn

AU - Hurt, Darrell E.

AU - Gaudreault, Laurent

AU - Subramaniam, Sriram

PY - 2011

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N2 - Since its discovery nearly 30 years ago, more than 60 million people have been infected with the human immunodeficiency virus (HIV) (www.usaid.gov). The virus infects and destroys CD4+ T-cells thereby crippling the immune system, and causing an acquired immunodeficiency syndrome (AIDS) 2. Infection begins when the HIV Envelope glycoprotein spike makes contact with the CD4 receptor on the surface of the CD4+ T-cell. This interaction induces a conformational change in the spike, which promotes interaction with a second cell surface co-receptor 5,9. The significance of these protein interactions in the HIV infection pathway makes them of profound importance in fundamental HIV research, and in the pursuit of an HIV vaccine. The need to better understand the molecular-scale interactions of HIV cell contact and neutralization motivated the development of a technique to determine the structures of the HIV spike interacting with cell surface receptor proteins and molecules that block infection. Using cryo-electron tomography and 3D image processing, we recently demonstrated the ability to determine such structures on the surface of native virus, at̃20 Å resolution 9,14. This approach is not limited to resolving HIV Envelope structures, and can be extended to other viral membrane proteins and proteins reconstituted on a liposome. In this protocol, we describe how to obtain structures of HIV envelope glycoproteins starting from purified HIV virions and proceeding stepwise through preparing vitrified samples, collecting, cryo-electron microscopy data, reconstituting and processing 3D data volumes, averaging and classifying 3D protein subvolumes, and interpreting results to produce a protein model. The computational aspects of our approach were adapted into modules that can be accessed and executed remotely using the Biowulf GNU/Linux parallel processing cluster at the NIH (http://biowulf.nih.gov). This remote access, combined with low-cost computer hardware and high-speed network access, has made possible the involvement of researchers and students working from school or home.

AB - Since its discovery nearly 30 years ago, more than 60 million people have been infected with the human immunodeficiency virus (HIV) (www.usaid.gov). The virus infects and destroys CD4+ T-cells thereby crippling the immune system, and causing an acquired immunodeficiency syndrome (AIDS) 2. Infection begins when the HIV Envelope glycoprotein spike makes contact with the CD4 receptor on the surface of the CD4+ T-cell. This interaction induces a conformational change in the spike, which promotes interaction with a second cell surface co-receptor 5,9. The significance of these protein interactions in the HIV infection pathway makes them of profound importance in fundamental HIV research, and in the pursuit of an HIV vaccine. The need to better understand the molecular-scale interactions of HIV cell contact and neutralization motivated the development of a technique to determine the structures of the HIV spike interacting with cell surface receptor proteins and molecules that block infection. Using cryo-electron tomography and 3D image processing, we recently demonstrated the ability to determine such structures on the surface of native virus, at̃20 Å resolution 9,14. This approach is not limited to resolving HIV Envelope structures, and can be extended to other viral membrane proteins and proteins reconstituted on a liposome. In this protocol, we describe how to obtain structures of HIV envelope glycoproteins starting from purified HIV virions and proceeding stepwise through preparing vitrified samples, collecting, cryo-electron microscopy data, reconstituting and processing 3D data volumes, averaging and classifying 3D protein subvolumes, and interpreting results to produce a protein model. The computational aspects of our approach were adapted into modules that can be accessed and executed remotely using the Biowulf GNU/Linux parallel processing cluster at the NIH (http://biowulf.nih.gov). This remote access, combined with low-cost computer hardware and high-speed network access, has made possible the involvement of researchers and students working from school or home.

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KW - Transmission electron microscopy

KW - Vaccine design

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Determination of molecular structures of HIV envelope glycoproteins using cryo-electron tomography and automated sub-tomogram averaging

Abstract

Keywords

ASJC Scopus subject areas

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