A single enzyme plays a critical role in helping the body effectively
fight viral infection
The body’s initial response to
invading bacteria or viruses is mediated by the innate immune system, wherein
cells secrete signaling factors called cytokines that promote inflammation and
stimulate a generalized counterattack against targets perceived as ‘foreign’.
The protein Toll-like receptor 3 (TLR3), for instance, helps initiate the
innate immune response against viruses.
Kong-Peng Lam at the A*STAR
Bioprocessing Technology Institute and co-workers have now gained insights into
how TLR3 helps ‘rally the troops’1. They showed that TLR3 recognizes viral
genetic material, and subsequently undergoes activation via the enzymatic
addition of phosphate chemical groups to specific amino acids — a process known
as phosphorylation.
The researchers identified Bruton’s
tyrosine kinase (BTK) as a TLR3-activating enzyme in this pathway. They found
BTK to be a promising candidate based on its prominent role in immune function:
mutations in this gene result in X-linked agammaglobulinemia (XLA), a disease
characterized by failures in B cell production and function. “These patients
are also very susceptible to recurrent bacterial and viral infections,” says
Lam, “which suggested that BTK might be involved in innate immunity.”
To test their hypothesis, the
researchers injected mice with polyribocytidylic acid, a molecule that
resembles viral RNA and triggers an antiviral immune response. In normal mice,
this treatment can trigger a strong inflammatory overreaction that leads to
fatal septic shock. However, both BTK-deficient and TLR3-deficient mice proved
resistant to septic shock, suggesting these two molecules work together in a
common pathway. TLR3 activation also generates signals that stimulate
production of the immunostimulatory molecule interferon β, but the absence of
BTK effectively crippled this response in mice. Accordingly, BTK-deficient mice
proved far less capable of clearing dengue virus from their system than
wild-type animals.
Biochemical experiments clearly
demonstrated that BTK was required for the phosphorylation of TLR3. Following
activation, TLR3 binds to TRIF, an ‘adapter’ protein that allows it to interact
with various other signaling factors. However, without BTK, TLR3 fails to
undergo phosphorylation. As a result, TRIF cannot bind to downstream signaling
molecules, thus stopping the signaling cascade in its tracks (see image).
Lam now hopes to determine
whether BTK represents a general component of innate immunity outside of the
TLR3 pathway. In the meantime, he suggests that BTK-targeting drugs could prove
a useful tool for immunomodulation. “Conceptually, BTK inhibitors could be used
to dampen exaggerated immune responses when the host ‘cytokine storm’ is a
curse rather than a blessing, such as in the case of SARS coronavirus
infection,” says Lam.
The A*STAR-affiliated researchers
contributing to this research are from the Bioprocessing Technology Institute
References
- Lee, K. G. et al. Bruton’s tyrosine
kinase phosphorylates Toll-like receptor 3 to initiate antiviral response.Proceedings
of the National Academy of Sciences USA 109, 5791–5796
(2012). | article
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