Evaluation of the role of innate lymphoid cells following viral vector vaccination
Abstract
Over the past decade, studies in our laboratory have established
that i) compared to systemic route of delivery, mucosal delivery
of recombinant fowlpox virus (rFPV) prime can induce excellent
high avidity mucosal/systemic HIV-specific CD8+ T cell immunity,
ii) this was associated with IL-4/IL-13 cytokine milieu and iii)
transient inhibition of IL-13 at the vaccination site can recruit
unique lung dendritic cell (DC) subsets, responsible for the
induction of high quality CD8+ T cell immunity. Therefore, to
understand which cells at the vaccination site was the
predominant source of IL-13 was assessed by evaluating the
different cells at the vaccination site, specifically innate
lymphoid cells (ILC) following rFPV vaccination with and without
transient inhibition of IL-13. These studies for the first time
revealed that ILC2 were the main source of IL-13 at the
vaccination site (24 h post vaccination) responsible for inducing
high quality T and B cells immune responses reported previously.
Intranasal vaccination induced ST2/IL-33R+ ILC2 in lung, whilst
intramuscular vaccination exclusively induced IL-25R+ ILC2 in
muscle. Moreover, adjuvants that transiently inhibited IL-13 at
the vaccination site significantly influenced the IFN-γ
expression by ILC1/ILC3 indicating that ILC2-derived IL-13 at the
vaccination site also modulated ILC1/ILC3 function/activity.
As intranasal and intramuscular vaccinations induced different
ILC2 subsets, two rFPV vaccines co-expressing adjuvants that
transiently sequestered IL-25 and IL-33 at the vaccination site
(rFPV-IL-12BP and rFPV-IL-33BP) were used to further evaluate ILC
development following vaccination. Unlike IL-13 inhibitor
vaccination conditions, intranasal delivery of IL-25BP adjuvanted
vaccine induced not only ST2/IL-33R+ ILC2 but also IL-25R+ and
TSLPR+ ILC2 subsets that were able to express IL-13. Moreover
TSLPR+ ILC2 subset was also able to express IL-4. Interestingly,
intranasal delivery of IL-25BP also induced significantly
elevated number of NKp46+/- ILC1/ILC3 expressing IL-17A compared
to IFN-γ, unlike the unadjuvanted or IL-13 inhibitor conditions.
Taken together, these inhibitor studies indicated that IL-25 play
a fundamental role in early ILC development than IL-33,
suggesting that there is a hierarchical regulation of ILC
development, where IL-25 is most likely the master regulator of
ILC.
Data also revealed that ILC and their cytokine expression
profiles were vastly different during permanent verses transient
blockage of IL-13, and STAT6 at the vaccination site. STAT6-/-
mice given the FPV-HIV vaccine showed elevated ST2/IL-33R+
ILC2-driven IL-13 expression whilst reduced IFN-γ expression by
both NKp46+/- ILC1/ILC3, unlike transient blockage of STAT6 which
showed the opposing effect. When IL-13-/- mice were vaccinated
with FPV-HIV significantly elevated lung lineage- ST2/IL-33R+
ILC2s were detected compared to BALB/c mice given the
FPV-HIV-IL-13Rα2 adjuvanted vaccine (transient inhibition of
IL-13), and their NKp46+/- ILC1/ILC3-driven IFN-γ expression was
significantly lower compared to transient inhibition of STAT6. In
previous studies when IL-13 was inhibited, no or low antibody
differentiation has been reported, unlike STAT6 inhibition. Thus,
current data further corroborated that ST2/IL-33R+ ILC2-derived
IL-13 play a crucial role in modulating downstream B cell immune
outcomes. Specifically, co-regulation of ST2/IL-33R+ ILC2-derived
IL-13 and NKp46+/- ILC1/ILC3-derived IFN-γ may play an important
role in modulating antibody differentiation process in a STAT6
independent manner via the IL-13Rα2 pathway.
When trying to understand the molecular mechanism involved in
this process, data revealed that the expression of IL-13Rα2,
type I and II IL-4Rs on ST2/IL-33R+ ILC2 and NKp46- ILC1/ILC3
were co-regulated 24 h post intranasal rFPV vaccination.
Inhibition of STAT6 signalling significantly impacted the
IL-13Rα2 expression on both ST2/IL-33R+ ILC2 and NKp46-
ILC1/ILC3, unlike IL-13 inhibition, suggesting that under STAT6
inhibition conditions, IL-13 could signal via IL-13Rα2 pathway.
As elevated number of ST2/IL-33R+ ILC2 expressing IL-13Rα2 were
detected in BALB/c mice given the FPV-HIV-IL-4R antagonist
vaccine, this also indicated an autocrine regulation of IL-13 at
the ILC2 via IL-13Rα2. The Il-4/IL-13 receptor expression
profile on NKp46+ ILC1/ILC3 and NKp46- ILC1/ILC3 were vastly
different, suggesting that these cells may play different roles
in downstream immune outcomes.
Collectively, findings in this thesis demonstrated that i) ILC
activity is significantly modulated by route of vaccine delivery
and vaccine adjuvants early as 24 h post vaccination, ii) When
designing vaccines against chronic pathogens, understanding the
fundamental roles of ILC at the vaccination site may help design
better vaccines in the future, iii) IL-25 regulated initial
development/differentiation of all ILCs and IL-33 most likely
only play a role in ILC2 homing to the lung mucosae, iv) Post
viral vector vaccination ILC-derived IL-13 and IFN-γ balance was
crucial for shaping the downstream immune outcomes, v) The IL-13
regulation at the ILC level occurred via an STAT6 independent
pathway, most likely IL-13Rα2 (due to low IL-13 conditions). In
conclusion, this work has provided unique insights into ILC
function and activity during viral vector vaccination, that could
be used to tailor vaccine vectors to induce effective immune
outcomes against target pathogens (for example TB verses an HIV
vaccine).
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