One more gene between us and bird flu

We’re always in favor of stopping a massive viral pandemic, or at least knowing more about what might make one Read more

Antibody diversity mutations come from a vast genetic library

The antibody-honing process of somatic hypermutation is not Read more

Emory Microbiome Research Center inaugural symposium

Interest in bacteria and other creatures living on and inside us keeps climbing. On August 15 and 16, scientists from a wide array of disciplines will gather for the Emory Microbiome Research Center inaugural Read more

VDJ recombination

Antibody diversity mutations come from a vast genetic library

Vaccine scientists want to nudge the immune system into producing antibodies that will protect us from infection. In doing so, they are playing with fire – in a limited way. With every healthy antibody response, a process of internal evolution takes place among B cells, the immune cells that produce antibodies. It’s called “somatic hypermutation.”

In the lymph nodes, individual B cells undergo an accelerated rate of mutation. It’s as if those B cells’ DNA were being cooked with radiation or mutagenic chemicals – but only in a few genes. Then the lymph nodes select the B cells with high-affinity antibodies.

Gordon Dale, a just-defended graduate student from Joshy Jacob’s lab in Emory Vaccine Center, has a new paper in Journal of Immunology that sheds light on how somatic hypermutation takes place in both mice and humans.

In particular, Dale and Jacob found that the mutations that occur in human and mouse antibody genes are not random. They appear to borrow information from gene segments that are leftovers from the process of assembling antibody DNA in B cells.

In a mix and match process called VDJ recombination, B cells use one of many V, D, and J segments to form their antibody genes. What Dale and Jacob were looking at occurs after the VDJ step, when B cells get stimulated as part of an immune response.

They analyzed the patterns of mutations in human and mouse antibody genes, and found that mutations tend to come together, in a way that suggests that they are being copied from leftover V segments. They call this pattern “tem Read more

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How antiviral antibodies become part of immune memory

Weapons production first, research later. During wartime, governments follow these priorities, and so does the immune system.

When fighting a bacterial or viral infection, an otherwise healthy person will make lots of antibodies, blood-borne proteins that grab onto the invaders. The immune system also channels some of its resources into research: storing some antibody-making cells as insurance for a future encounter, and tinkering with the antibodies to improve them.

In humans, scientists know a lot about the cells involved in immediate antibody production, called plasmablasts, but less about the separate group of cells responsible for the “storage/research for the future” functions, called memory B cells. Understanding how to elicit memory B cells, along with plasmablasts, is critical for designing effective vaccines.

EbolaBcells

Activated B cells (blue) and plasmablasts (red) in patients hospitalized for Ebola virus infection, with a healthy donor for comparison. From Ellebedy et al Nature Immunology (2016).

Researchers at Emory Vaccine Center and Stanford’s Department of Pathology have been examining the precursors of memory B cells, called activated B cells, after influenza vaccination and infection and during Ebola virus infection. The Ebola-infected patients were the four who were treated at Emory University Hospital’s Serious Communicable Disease Unit in 2014.

The findings were published Monday, August 15 in Nature Immunology.

“Ebola virus infection represents a situation when the patients’ bodies were encountering something they’ve never seen before,” says lead author Ali Ellebedy, PhD, senior research scientist at Emory Vaccine Center. “In contrast, during both influenza vaccination and infection, the immune system generally is relying on recall.”

Unlike plasmablasts, activated B cells do not secrete antibodies spontaneously, but can do so if stimulated. Each B cell carries different rearrangements in its DNA, corresponding to the specificity and type of antibody it produces. The rearrangements allowed Ellebedy and his colleagues to track the activated B cells, like DNA bar codes, as an immune response progresses. Read more

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Alternative antibody architecture

This complex diagram, showing the gene segments that encode lamprey variable lymphocyte receptors, comes from a recent PNAS paper published by Emory’s Max Cooper and his colleagues along with collaborators from Germany led by Thomas Boehm. Lampreys have molecules that resemble our antibodies in function, but they look very different at the protein level. The study of lamprey immunity provides hints to how the vertebrate immune system has evolved.
PNAS-2014-Das-1415580111_Page_4

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