Scientists reveal first structure of a class of proteins that help guide blood cell movement

Oct 07, 2010
This is a structure of a pair of linked CXCR4 molecules (blue and gold) bound by loop-shaped peptide inhibitors (red and magenta). Credit: Raymond Stevens, the Scripps Research Institute, La Jolla, Calif.

Researchers have determined the structure of a protein that helps guide blood-forming stem cells, or hematopoetic stem cells. The protein is also one of the main receptors used by the human immunodeficiency virus (HIV) to get inside blood cells.

The findings are described in the October 7, 2010 issue of the journal Science.

The structure offers a detailed view of how the cell surface receptor, called CXCR4, interacts with molecules outside the cell. The results have implications for developing new drugs for hematopoetic stem cell transplantation, a therapeutic path to treat cancer and immune disorders, as well as for treating .

"The structures open up entire new areas for understanding fundamental principles in chemokine GPCR signaling," said Scripps Research Professor Raymond C. Stevens, who is senior author of the collaborative study.

Sniffing Out Signals

CXCR4 belongs to a large family of more than 700 proteins known as G protein-coupled receptors (GPCRs). These proteins sit in the cell membrane and sense various molecules outside the cell, including odors, hormones, neurotransmitters, and light. After binding these molecules, GPCRs trigger the appropriate response inside the cell.

This video is not supported by your browser at this time.
This model shows how HIV, in gray, might latch on to immune cell receptor molecules, allowing the virus to enter and infect the cell. The viral protein, gp120, shown in light blue, binds to receptors CD4 and CXCR4, shown in tan and dark blue. Models like this one allow scientists to test their ideas about how HIV gains access to cells -- and help pinpoint important targets for developing drugs to impede HIV. Credit: Animation courtesy of Gye Won Han of the Scripps Research Institute. Video produced by the National Institute of General Medical Sciences, part of the National Institutes of Health.

"My lab is really interested in how this one protein family recognizes millions of different types of ligands with incredible specificity," said Stevens, "and how when one ligand binds a receptor it may have one intracellular effect such as activation and a closely related ligand can have an opposite effect such as antagonism."

To understand how these receptors function, the Stevens group has already determined the structures of two other GPCRs: the adrenergic receptor, involved in the fight-or-flight response, and the A2A adenosine receptor, sometimes also referred to as the "caffeine" receptor. The newly solved protein CXCR4 belongs to a different group of GPCRs, one that binds to called chemokines, which primarily function to steer the movement of blood and immune cells to their appropriate locations in the body.

Comparing Wine Glasses

To get the first-ever glimpse of a chemokine receptor bound to a ligand, Stevens and colleagues turned to GPCR biochemistry, receptor stabilization and X-ray crystallography.

"One challenging aspect of this research is the biochemistry—learning what the receptor likes and dislikes," said Stevens. "Each receptor and receptor-ligand complex has a distinctly different biophysical personality."

The crystal structure of CXCR4, just like that of other known GPCRs, resembles a wine glass stuck inside the cell membrane, with the glass opening (where the ligands bind) facing the outside of the cell and the stem portion the inside. But there are important differences.

"The adrenergic receptor looks like a pinot noir glass that curves inward towards the top to hold in the wine vapors; the A2A receptor looks like a champagne flute," explained Stevens. "The CXCR4 structure looks like chardonnay glass with a wider opening and shorter depth."

The wider mouth allows CXCR4 to bind to its chemokine ligand, CXCL-12, which is a protein and thus a larger molecule than the ligands that bind the adrenergic and A2Areceptors. CXCL-12 is the signal in the blood that guides hematopoetic to the bone marrow, a process known as homing.

Finding Therapies

One of the biggest surprises of the CXCR4 structure was that this receptor, unlike the adrenergic and A2A receptors, likes to form pairs or dimers.

"The dimerization observation was very intriguing," said Stevens. "We solved five different crystal structures in multiple crystal forms, and each one had the same dimer interface. It has long been debated how GPCRs might dimerize, if they did at all. This is the first solid observation about a consistent structural GPCR dimer."

Preventing dimerization might provide a new way to block CXCR4 function. Drugs that block CXCR4 appear to be capable of releasing hematopoietic stem cells from the bone marrow into the bloodstream—a step that is critical for . Only one such drug, called Mozobil, is currently on the market. In addition, drugs that block CXCR4 are useful in treating HIV infection.

Having determined the structure of CXCR4, Stevens and colleagues were able to determine which portions of the protein are critical to chemokine recognition. This knowledge can now be used to understand basic principles of chemokine recognition and signaling, as well as to design new therapeutic candidates or improve the affinity and efficacy of existing drugs.

Like all membrane proteins, GPCRs are notoriously difficult to crystallize, but CXCR4 was a particularly difficult structure to crack, according to Stevens.

"Each GPCR structure is a tour de force and this one took a team of several people three years to complete," he said. " I wish I could identify one step that was the most challenging, but I would say every step was hard."

Explore further: A real-time tracking system developed to monitor dangerous bacteria inside the body

More information: "Structure of the CXCR4 chemokine receptor with small molecule and cyclic peptide antagonists," Science, October 7, 2010.

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