Follicular helper T cells (Tfh cells,
shown in blue) play a crucial role in the maturation of antibody-producing B
cells (shown in green). Activated B cells give rise germinal centers (shown in
red), where mature B cells proliferate and produce highly specific antibodies
against pathogens. Top left: normal germinal center in a mouse tonsil. All
others: Germinal centers fail to form when the interaction between ICOS and
TBK1 is interrupted. Credit: Dr. Kok-Fai Kong at La Jolla Institute for Allergy
and Immunology and Nature Immunology
Follicular
helper T cells (Tfh cells), a rare type of T cells, are indispensable for the
maturation of antibody-producing B cells. They promote the proliferation of B
cells that produce highly selective antibodies against invading pathogens while
weeding out those that generate potentially harmful ones. In their latest
study, researchers at La Jolla Institute for Allergy and Immunology identified
a key signal that drives the commitment of immature Tfh cells into fully functional
Tfh cells and thus driving the step-by-step process that results in a precisely
tailored and effective immune response.
Specifically,
the study published in the May issue of Nature Immunology and led by La
Jolla Institute Professor Shane Crotty, Ph.D., and Instructor Kok-Fai Kong,
Ph.D., reported that an enzyme called TANK-binding kinase 1 (TBK1) controls the
maturation of antibodies by associating with a key signaling molecule known as
Inducible T cell Co-Stimulator or ICOS.
While
ICOS was known to be clearly essential for most Tfh cell functions, the
underlying mechanism had remained unclear. Understanding the molecular details
of how ICOS exercises its critical influence may allow scientists to manipulate
antibody specificity to design better vaccines and create novel treatments for
autoimmune disorders. Autoimmunity lies at the root of over 80 disease
including type 1 diabetes, multiple sclerosis, rheumatoid arthritis and lupus.
"Tfh
cells have recently been recognized as important players in the immune system,
and we now know they are essential for almost all antibody responses,"
said Crotty. "Tfh cells control the whole process of generating high
affinity antibodies, and ICOS is a receptor molecule strongly required for Tfh
cells to work. Understand ICOS better, and you can make more Tfh when needed,
and block it when not needed."
In
fact, TBK1 may also be a contributor to debilitating diseases such as ALS (Lou
Gehrig's disease) and childhood herpes simplex virus encephalitis, if its
connection with ICOS somehow triggers B cell activation and specific antibody production against the body's own cells
in ALS or an excessive response to the invading viruses in childhood
encephalitis. Knowing how ICOS is regulated will help scientists understand how
these diseases erupt, as much as it could help further vaccine development.
ICOS
gets antibody production started by promoting the maturation of Tfh cells,
which migrate into compartments or follicles of immune organs such as spleens
and lymph nodes, which themselves are full of B cells. The body has billions of
B cells, each one and its daughter
cells recognize something different, so very few of which can
recognize the structure of any given germ. Once in contact with Tfh, some B
cells become activated, migrate to an area of the follicle called the germinal
center and start dividing rapidly under influence from Tfh. While most B cells
have a low affinity for pathogens, which might effectively fend off a
relatively mild virus, Tfh (with the stimulation of ICOS) allows the select few
that produce highly specific and more strongly reactive antibodies to
proliferate and out-compete their less specific brethren. The survivors undergo
successive rounds of mutation resulting in better and better antibodies during
the course of an immune response.
"We
were looking to find out a specific signaling pathway that impacted ICOS,"
said Kong. "There is a family of such checkpoint molecules like ICOS, but
ICOS has a capability that is not shared with other checkpoint molecules. Its
ability to drive antibody differentiation is found only in ICOS, and not in
other family members. The connection between ICOS and TBK1 provides important
clues to this mystery."
Kong
and Crotty's team discovered that ICOS recruits the signaling TBK1 enzyme,
which activates certain genes in Tfh cells,
thus beginning the whole process of high-affinity antibody production. The team
led by Dr. Kong identified a region of the ICOS molecule that recruits TBK1,
and moreover, disrupting this area prohibits the association between ICOS and
TBK1 and severely impairs Tfh and ultimately antibody production. Therefore,
this could provide an important target for disease interventions or vaccine
designs.
The
researchers are now looking at how ICOS signals can be altered to diminish
autoimmune disorders and augmented for more effective vaccine development, and
are beginning research on how ICOS signaling may benefit Chimeric Antigen
Receptor-T cell (CAR-T) therapies, which involves engineering of patient's own immune
cells to recognize and attack their cancers.
http://medicalxpress.com/news/2016-05-scientists-molecular-mechanism-specific-antibody.html
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