The global burden of neonatal and infant mortality due to infection is staggering, particularly in resource-poor settings. Early childhood vaccination is one of the major interventions that can reduce this burden, but there are specific limitations to inducing effective immunity in early life, including impaired neonatal leukocyte production of Th1-polarizing cytokines to many stimuli. Characterizing the ontogeny of Toll-like receptor (TLR)-mediated innate immune responses in infants may shed light on susceptibility to infection in this vulnerable age group, and provide insights into TLR agonists as candidate adjuvants for improved neonatal vaccines. As little is known about the leukocyte responses of infants in resource-poor settings, we characterized production of Th1-, Th2-, and anti-inflammatory-cytokines in response to agonists of TLRs 1-9 in whole blood from 120 Gambian infants ranging from newborns (cord blood) to 12 months of age. Most of the TLR agonists induced TNFα, IL-1β, IL-6, and IL-10 in cord blood. The greatest TNFα responses were observed for TLR4, -5, and -8 agonists, the highest being the thiazoloquinoline CLO75 (TLR7/8) that also uniquely induced cord blood IFNγ production. For most agonists, TLR-mediated TNFα and IFNγ responses increased from birth to 1 month of age. TLR8 agonists also induced the greatest production of the Th1-polarizing cytokines TNFα and IFNγ throughout the first year of life, although the relative responses to the single TLR8 agonist and the combined TLR7/8 agonist changed with age. In contrast, IL-1β, IL-6, and IL-10 responses to most agonists were robust at birth and remained stable through 12 months of age. These observations provide fresh insights into the ontogeny of innate immunity in African children, and may inform development of age-specific adjuvanted vaccine formulations important for global health.
The global burden of neonatal and infant mortality due to infection is staggering, particularly in resource-poor settings. Early childhood vaccination is one of the major interventions that can reduce this burden, but there are specific limitations to inducing effective immunity in early life, including impaired neonatal leukocyte production of Th1-polarizing cytokines to many stimuli. Characterizing the ontogeny of Toll-like receptor (TLR)-mediated innate immune responses in infants may shed light on susceptibility to infection in this vulnerable age group, and provide insights into TLR agonists as candidate adjuvants for improved neonatal vaccines. As little is known about the leukocyte responses of infants in resource-poor settings, we characterized production of Th1-, Th2-, and anti-inflammatory-cytokines in response to agonists of TLRs 1-9 in whole blood from 120 Gambian infants ranging from newborns (cord blood) to 12 months of age. Most of the TLR agonists induced TNFα, IL-1β, IL-6, and IL-10 in cord blood. The greatest TNFα responses were observed for TLR4, -5, and -8 agonists, the highest being the thiazoloquinolineCLO75 (TLR7/8) that also uniquely induced cord blood IFNγ production. For most agonists, TLR-mediated TNFα and IFNγ responses increased from birth to 1 month of age. TLR8 agonists also induced the greatest production of the Th1-polarizing cytokines TNFα and IFNγ throughout the first year of life, although the relative responses to the single TLR8 agonist and the combined TLR7/8 agonist changed with age. In contrast, IL-1β, IL-6, and IL-10 responses to most agonists were robust at birth and remained stable through 12 months of age. These observations provide fresh insights into the ontogeny of innate immunity in African children, and may inform development of age-specific adjuvanted vaccine formulations important for global health.
The greatest burden of morbidity and mortality from infectious diseases occurs in
children under 5 years of age, with the highest rates occurring in resource-poor
countries. This urgent global issue is the target of United Nations Millennium Goal
4 to reduce under-five child mortality by two-thirds by 2015 [1]. One of the most effective
measures to prevent infection is vaccination early in life, in particular at birth
as it is the most reliable point of healthcare contact [2], [3]. However, young
children often do not respond to vaccines as efficiently as adults as a result of
distinct features of their immune systems [4]–[8].Among the distinct features of neonatal immune system is a diminished ability of
monocytes and antigen-presenting cells (APCs) to generate Th1-polarizing signals in
response to most stimuli, including reduced production of TNFα and interferon
gamma (IFNγ) important for host defence against intracellular pathogens and for
generation of adaptive immune responses [9]–[11]. However, the impairment is
stimulus-specific and some stimuli are able to effectively activate neonatal APCs
[7], [10], [12]. In this
context, characterizing the ontogeny of human immune responses including the
contribution of innate immunity, provides insight into susceptibility of newborns
and infants to infection, assesses immune polarization that may affect risks of
allergy and atopy [13], and may inform development of age-specific adjuvanted
vaccines [7].Modifying the innate response may increase the strength of adaptive responses
required for inducing efficient immunological memory in infants. Until recently, the
only approved adjuvant component in vaccines was alum. However, the discovery that
microbial products activate host cells via pattern recognition receptors such as
Toll-like receptors (TLRs) and enhance adaptive immune responses by triggering
cytokine production and dendritic cell maturation, has led to TLR agonists being
developed as vaccine adjuvants [14]–[18]. The TLR4 agonist
monophosphoryllipid A (MPL) has been combined with alum (AS04) in hepatitis B and
humanpapilloma vaccines[19]–[21]. Agonists of several other TLRs, including TLR3, 7, 8 and
9, are in clinical development as vaccine adjuvants targeting mycobacterial,
parasitic and diseases [22]
[7], [23]–[27]. Of note,
several existing vaccines trigger TLRs: Bacillus Calmette Guerin
(BCG), the most widely used vaccine against TB with an established safety and
efficacy profile activates TLR2, -4 and -8 [28]–[30] and the meningococcal outer
membrane protein complex used to adjuvant the Haemophilus conjugate vaccine, was
subsequently shown to be a TLR2 agonist [31]. These examples suggest that in
certain contexts TLR agonists can be safe and effective as vaccine adjuvants and
highlight the importance of characterizing ontogeny of TLR-mediated responses in
target populations, including newborns and infants.Age-dependent changes in TLR function have been demonstrated in humans by natural
deficiencies in TLR signaling molecules including a deficiency in IRAK-4 (a kinase
involved in the TLR signaling cascade) [32], [33] and MyD88 (a TLR adaptor molecule)
[11] that can
result in life-threatening infections in infancy and childhood. Of note, infections
decrease in IRAK-4-deficient children >8 years of age, suggesting a greater
dependency early in life on TLR signaling for protection against infection. Although
newborns demonstrate similar basal expression of monocyte TLRs at birth [34], neonatal blood
mononuclear cell responses to TLR agonists are distinct from those of adults, with
impairment of Th1 cytokine responses (e.g., TNFα, IFNγ) but similar or
greater production of cytokines with Th2 (IL-6, IL-1β), Th17 (IL-23) and
anti-inflammatory (IL-10) activity [4], [34]–[42]. By contrast, cord blood
responses to TLR8 agonists, including imidazoquinoline compounds and single stranded
RNAs (ssRNAs), induced robust adult-like TNFα responses raising the possibility
that TLR8 agonists may serve as effective vaccine adjuvants for newborns and young
infants [34], [43].Because infant peripheral blood is more difficult to obtain than cord blood,
relatively less is known about TLR function during infancy. The few infant studies
available have been conducted in resource-rich settings and indicate that there is a
marked increase in TLR-mediated Th1 cytokine production within the first 6 months of
life [13],
[37], [44], [45]. To our
knowledge, there are no published studies of TLR function in newborns and infants
from resource-poor countries and none from the African continent. Such data may be
of considerable importance as these populations are at high risk of infection, and
may demonstrate distinct innate response profiles compared to other populations with
lesser burdens of disease. For example, infants from resource-poor countries often
respond quite differently to immune stimuli including to BCG vaccination [46], [47]. In
addition to providing insight into age-dependent development of TLR-mediated innate
immunity, characterizing the ontogeny of TLR responses in an African country may
also inform development of adjuvanted vaccines for high-risk newborns and infants.
We therefore characterised the production of Th1, Th2, and anti-inflammatory
cytokines in response to agonists of TLRs 1 – 9 in whole blood cultures
derived from Gambian infants during the first year of life. We found that cord blood
Th1-polarising cytokine responses were generally impaired, that TLR8 agonists gave
the strongest Th1-cytokine responses at birth and that by 1 month of age the
pro-inflammatory responses to most TLR agonists were increased, with predominance of
responses to TLR4, -5 and -8 agonists that changed across the first 12 months of
life.
Materials and Methods
Study Design
This cross-sectional study was approved by the Joint Gambia Government/Medical
Research Council Ethics Committee and the London School of Hygiene and Tropical
Medicine Ethics Committee. Between June and November 2009, 120 Gambian infants,
up to 12 months of age, were recruited at the Sukuta Health Centre (a peri-urban
(area surrounding an urban town with characteristics of a rural setting)
population 30 minutes from the coast of The Gambia). Infants were recruited into
8 age groups: birth and 1-, 2-, 3-, 4-, 6-, 9- or 12- months of age (or +2
weeks of age stated; n = 15 per group). For every study
subject, written informed consent of a parent/guardian was obtained. Children
were excluded if they had any signs of intercurrent infection. Neonates were
also excluded if they had a low birth weight (< 2.5 kg) or were a twin. Each
child within an age group had received comparable vaccines according to the
Gambian Extended Programme of Immunisation (EPI) schedule, and had not received
any vaccine within the previous 7 days. Infants were also excluded if their
weight was outside the target range for age stated on the Infant Welfare Card.
Ten millilitres of umbilical cord blood (collected before delivery of the
placenta) and 3 mL of infant venous blood was collected into tubes containing
heparin (sodium salt from porcine intestinal mucosa, Sigma-Aldrich, Poole, UK)
at 7.5 U/mL blood and transferred to the laboratories within 6 hrs of
collection. Blood was acquired prior to administration of any EPI vaccine that
may have been indicated on the day of recruitment.
Cell culture conditions
From each blood sample, 100 µl of undiluted whole blood (per condition) was
cultured overnight (18–24 hours) without stimulation (negative control),
with phorbol 12-myristate 13-acetate (PMA; 0.1 µg/mL, Sigma)/ionomycin
(calcium salt, from Streptomyces conglobatus, 1 µg/mL,
Sigma) (positive control) and with each of the 9 TLR agonists (Table S1).
TLR agonists were purchased from InvivoGen (San Diego, CA, US) and included:
Pam3CSK4 (synthetic tripalmitoylated lipopeptide that mimics bacterial
lipoproteins; TLR1/2, 1 µg/mL), Poly (I:C) (a synthetic analog of
double-stranded RNA (dsRNA) associated with viral infection; TLR3, 100
µg/mL), LPS (Escherichia. coli K12Lipopolysaccharide;
TLR4, 1 µg/mL), flagellin (from Salmonella typhimurium;
TLR5, 10 µg/mL), FSL-1 (synthetic lipoprotein of Mycoplasma
salivarium; TLR2/6, 10 µg/mL), ssRNA40 (20-mer phosphothioate
protected single-stranded RNA oligonucleotide; TLR8, 10 µg/mL), CL075
(thiazoloquinolone derivative; TLR8, 10 µg/mL), Gardiquimod™ (an
imidazoquinoline amine analogue to guanosine; TLR7, 10 µg/mL), ODN M362
(synthetic type C unmethylated-CpG dinucleotide-containing oligonucleotide;
TLR9, 1 µM) (Table S1). TLR concentrations were selected
based on those that induced maximal cytokine responses from previous studies
[34], [43] and from
preliminary studies in 9 months old Gambian infants (unpublished data). After
overnight culture, 100 µL of ice-cold serum-free RPMI media was added to
the wells and centrifuged at 1,500 rpm for 10 mins. 120 µL of supernatant
was collected and stored at −20°C for subsequent analysis. For RNA
studies, 300 µL of whole blood were cultured in each of four conditions
(unstimulated, ssRNA, Gardiquimod™ or CLO75) for 4 hours then added to 860
µL PaxGene lysing reagent (PreAnalytiX, Becton Dickinson, France) prior to
storage at −70°C ahead of RNA extraction.
Cytokine measurement
Supernatants were thawed and centrifuged at 1500 rpm for 5 mins to pellet any
precipitation in the sample. Concentrations of TNFα, IL-1β, IL-6,
IFNγ and IL-10 (Th1 cytokine kit, Bio-Rad, Hercules, California, US) were
measured for all samples. The bead array assays were conducted according to the
manufacturer's instructions (Bioplex Reagent kit, Bio-Rad) using 50
µL of serial (1∶4) dilutions of the standard in RPMI medium
containing 10% human serum and 50 µl of samples. Standard curve
outliers were eliminated by identifying samples where the coefficient of
variance (CV) was greater than 10% and observed/expected x 100
(obs/exp*100) was outside the range of 100±20. Cytokine
concentrations below the level of detection (out of range (OOR) <) were
assigned a value of half the lowest value recorded in that assay. Similarly, all
samples with values above the level of detection (OOR>) were assigned a value
of twice the largest value recorded in that assay.
RNA extraction
Samples were thawed and left at room temperature (15 – 25°C) >4
hours for complete lysis prior to centrifugation for 10 mins at 5000 rpm. RNA
was extracted according to manufacturer's instructions with modification
for the small blood volumes (PaxGene Blood RNA kit, QIAGEN, Germany). Briefly,
the pellet was resuspended in 500 µL of RNase-free water and centrifuged
again at 5,000 rpm for 10 mins. The pellet was then resuspended in 360 µL
of BR1 buffer (PaxGene Blood RNA kit). The samples were further processed
according to the manufacturer's instructions and eluted in a final volume
of 80 µL of Tris/EDTA (TE)-based elution buffer (BR5). RNA was then
purified further using the RNeasy Mini Elute Clean Up kit (QIAGEN, Germany) and
resuspended in 12 µL of BR5. The RNA yield was measured on the Nanodrop
(Thermo Scientific, Wilmington, Delaware, US) and purity was based on absorption
values at 280 nm (protein) and 230 nm (detection of contaminating
organics/proteins) using the following criteria: 260 nm/280 nm >1.8 and 260
nm/230 nm >1.8.
SA Bioscience Microarrays
0.1 µg total RNA was reverse transcribed to cDNA using RT2 First
Strand Kit (C-03) (SA Biosciences, Frederick, MD, US) according to the
manufacturer's instructions and diluted with RNase-free water into a final
volume of 111 µL. A customized 6-gene real time PCR array (SABiosciences,
Frederick, MD) was employed, containing primers specific for TNF, IL-6, IL-10,
IL12A, IL12B and IFNG and using the RT-SYBR Green/ROX qPCR Master Mix according
to the manufacturer's instructions (SABiosciences, Frederick, MD) using
approximately 1 ng of original RNA per gene. mRNA expression was calculated as a
copy number (Ct) value and normalized using multiple housekeeping genes (B2M,
RPL13A, GAPDH, ΔCt). Fold change (ΔΔCt) in
gene expression was used to display the data and calculated between the
unstimulated control cells in comparison to TLR agonist-stimulated cells
applying the following equation: if X >1, X, -1/X, if X
= ΔCt therefore all values <0
represented down-regulated genes and all values >0 represented up-regulated
genes. ΔCt values were used for all statistical analysis.
Statistical analysis
Net cytokine responses were calculated by subtracting the cytokine concentrations
in the medium control wells from those in supernatants derived form samples
stimulated with TLR agonists. For each TLR agonist/cytokine combination the
resulting datasets of net responses (all ages combined) were dichotomised into
≥ median value, or < median value. Due to a number of responses above the
level of detection, comparisons of responses at difference ages were made by
comparing the proportions of values above and below the median using
Fisher's exact test. Tests for a trend with age were carried out using
logistic regression with above or below the median as the response variable and
age as the independent variable. Comparisons between the response to medium and
the gross responses to each of the TLR agonists in cord blood were made using
Sign tests which are robust to the influence of out of range values, in
accordance with the paired nature of the data. Analyses that compared two time
points or two ages were done using a non-parametric Mann U Whitney test and
correlations were calculated on log-transformed data using a Pearson
correlation. Data were analysed using Stata version 11.0 (StataCorp, Texas, US)
and GraphPad Prism version 5.01 (GraphPad Software Inc., US). Real time PCR
analysis used software from SA Biosciences as stated above. Box and whisker
plots demonstrate inter-quartile ranges indicated by boxes, median values by
horizontal bars, and 10 and 90 percentiles indicated by whiskers. P-values
<0.05 were taken to indicate statistical significance.
Results
Reactivity to TLR4, 5 and 8 agonists predominate at birth
The positive control PMA/ionomycin induced cytokine responses that were largely
independent of age (TNFα p = 0.603, IL-6
p = 0.758, IL-1β p = 0.257,
IFNγ p = 0.167). The lone exception was IL-10, whose
production diminished with increasing age (p = 0.005; data
not shown).Compared to the unstimulated control, there was a significant induction of
TNFα, IL-6, IL-1β and IL-10 production in cord blood to all the TLR
agonists studied with the exception of FSL-1 (TLR2/6) that did not induce a
significant TNFα response (Table 1).
Table 1
TLR agonists induce cytokine production in cord blood of Gambian
newborns.
Unstim. Control
Pam. (TLR1/2)
PolyI:C (TLR3)
LPS (TLR4)
Flag. (TLR5)
FSL-1 (TLR2/6)
Guard. (TLR7)
ssRNA (TLR8)
CL075 (TLR7/8)
ODN (TLR9)
TNFα
1.309
3.98*
6.34*
1,117.17***
133.52***
4.29
12.13*
5,003.68***
5,180.04***
10.74**
IL-6
245.9
7,161.75***
1,831.22**
22,529.47***
25,209.28***
8,811.02***
5,390.73***
14,412.48**
21,262.00***
3,802.29**
IL-1β
3.11
36.42**
15.31**
1,293.61***
1,522.90***
30.17**
59.92**
3,069.16***
2,557.96***
36.92**
IL-10
10.36
151.20***
35.05**
966.90***
1,145.50***
145.06***
156.36***
745.06***
1,647.61***
33.06**
IFNγ
3.335
3.34
2.83
6.37
6.38
3.24
3.34
23.36
59.17**
3.34
100 µl cord whole blood was cultured overnight with each of the
TLR agonists and cytokine production (pg/mL) in supernatants was
measured as described in the Materials
and Methods. Concentrations are absolute values in pg/mL.
Comparisons between unstimulated and stimulated values,
n = 12–15;
*p = 0.05 – 0.019,
**p = 0.01 – 0.001,
***p<0.001.
100 µl cord whole blood was cultured overnight with each of the
TLR agonists and cytokine production (pg/mL) in supernatants was
measured as described in the Materials
and Methods. Concentrations are absolute values in pg/mL.
Comparisons between unstimulated and stimulated values,
n = 12–15;
*p = 0.05 – 0.019,
**p = 0.01 – 0.001,
***p<0.001.Of note, the efficacy with which TLR agonists induced these cytokines, differed
both between agonists and with age. Agonists of TLR4, -5, and, in particular
TLR8 (including the combined TLR7/8 agonist) induced the highest levels of most
cytokines, with agonists of TLR1/2, -3, -2/6, -7 and -9 eliciting a reduced
cytokine response (Table 1
and Figure 1A). The combined
TLR7/8 agonist (the thiazoloquinolone CL075) induced the highest levels of
TNFα compared to agonists of TLR4 (p = 0.0202) and TLR5
(<0.0001). Moreover CL075 (TLR 7/8) was the only TLR agonist that induced
IFNγ in cord blood compared to the unstimulated control
(p = 0.002, Table 1 and Figure
1B). In agreement with previous studies [43], the TLR8 agonists (ssRNA and
CLO75) induced significantly more cytokine production in cord blood cultures
compared to the TLR7 agonist (Gardiquimod™) (Figure 2).
Figure 1
TLR-mediated cytokine production in cord blood.
100 µl of whole cord blood was cultured overnight with each of the
TLR agonists and supernatants recovered for measurement of (A) TNFα
and (B) IFNγ as described in Materials
and Methods (pg/mL) and presented as box and whisker plots
illustrating 10 and 90 percentile error bars,
n = 12–15. Comparisons
between cytokine levels in the stimulated samples and the unstimulated
samples were analysed using a paired Sign test at 5% significance
(* represent significant differences).
Figure 2
TLR7 and 8 agonist-induced cytokine induction in cord blood.
100 µl of whole cord blood was cultured overnight with each of the
TLR agonists and supernatants recovered for measurement of IFNγ,
TNFα, IL-10, IL-1β and IL-6 as described in Materials and Methods (pg/mL),
n = 12–15. Unstimulated
values are subtracted from stimulated values and presented as box and
whisker plots, n = 12–15.
TLR-mediated cytokine production in cord blood.
100 µl of whole cord blood was cultured overnight with each of the
TLR agonists and supernatants recovered for measurement of (A) TNFα
and (B) IFNγ as described in Materials
and Methods (pg/mL) and presented as box and whisker plots
illustrating 10 and 90 percentile error bars,
n = 12–15. Comparisons
between cytokine levels in the stimulated samples and the unstimulated
samples were analysed using a paired Sign test at 5% significance
(* represent significant differences).
TLR7 and 8 agonist-induced cytokine induction in cord blood.
100 µl of whole cord blood was cultured overnight with each of the
TLR agonists and supernatants recovered for measurement of IFNγ,
TNFα, IL-10, IL-1β and IL-6 as described in Materials and Methods (pg/mL),
n = 12–15. Unstimulated
values are subtracted from stimulated values and presented as box and
whisker plots, n = 12–15.
TLR-mediated IL-6 and IL-1β production is high from birth, while TNFα
and IFNγ production peak at 1 month
Each cytokine studied demonstrated a distinct age-dependent profile in response
to each TLR agonist during the first year of life. An assessment of effect with
age for each cytokine response to each agonist revealed that TNFα responses
to FSL-1 (TLR2/6; p<0.001), LPS (TLR4; p = 0.009),
Flagellin (TLR5; p = 0.001), Gardiquimod™ (TLR7; p
<0.001), ssRNA (TLR8; p<0.001), and CL075 (TLR7/8; p <0.001) all
demonstrated age-dependent effects (Table S2A). Graphic representation of these
data suggested this effect was due to a predominant increase in TNFα
production between cord blood and 1 month of age in response to most agonists
(Figure 3). This
impression was confirmed by repeating the analysis between ages 1 to 12 months
(excluding the cord blood) (Table S2B) and comparing the individual
responses between birth and 1 month of age (Figure 4). After the initial increase in
TNFα responses by 1 month, TNFα responses to most agonists were stable
from 1 month to 12 months of age (Table S2B and Figure 3).
Figure 3
Net TLR-mediated TNFα responses differ between agonists and
across the first year of life.
100 µl of whole blood was cultured overnight with each of the TLR
agonists at birth, 1, 2, 3, 4, 6, 9 and 12 months of age (x axis) and
TNFα cytokine production (y axis) was measured as described in the
Materials and Methods (pg/mL).
Unstimulated values are subtracted from stimulated values and presented
as box and whisker plots, n = 12-15.
Figure 4
TLR agonists induce greater cytokine production in Gambian newborns
at 1 month compared to at birth.
100 µl whole blood was cultured overnight with each of the TLR
agonists and cytokine production (pg/mL) in supernatants was measured as
described in the Materials and
Methods. Comparisons between cytokine levels at birth and 1
month of age were calculated using a non-parametric Mann Whitney test.
*(light grey square) p = 0.05 – 0.019,
**(medium grey square) p = 0.01 –
0.001, ***(dark grey square) p<0.001. Pam3.
= Pam3CysSerLys4, Gard.
= Gardiquimod.
Net TLR-mediated TNFα responses differ between agonists and
across the first year of life.
100 µl of whole blood was cultured overnight with each of the TLR
agonists at birth, 1, 2, 3, 4, 6, 9 and 12 months of age (x axis) and
TNFα cytokine production (y axis) was measured as described in the
Materials and Methods (pg/mL).
Unstimulated values are subtracted from stimulated values and presented
as box and whisker plots, n = 12-15.
TLR agonists induce greater cytokine production in Gambian newborns
at 1 month compared to at birth.
100 µl whole blood was cultured overnight with each of the TLR
agonists and cytokine production (pg/mL) in supernatants was measured as
described in the Materials and
Methods. Comparisons between cytokine levels at birth and 1
month of age were calculated using a non-parametric Mann Whitney test.
*(light grey square) p = 0.05 – 0.019,
**(medium grey square) p = 0.01 –
0.001, ***(dark grey square) p<0.001. Pam3.
= Pam3CysSerLys4, Gard.
= Gardiquimod.Responses to the TLR8 agonist (ssRNA) and the combined TLR7/8 agonist (CLO75)
were notable exceptions to this pattern. The initial increase in reactivity to
CLO75 from birth to 1 month of age (p = 0.005), was then
followed by a decline from 1 to 12 months of age (trend analysis p<0.001,
from a median at 1 month of 13,852 pg/mL, to a median at 12 months of 2,771
pg/mL), though nevertheless remained higher than those for TLR2, -3, -2/6 and -9
(Table
S2 and Figure 3).
In contrast, TNFα responses to ssRNA (TLR8) did not reveal a significant
trend from 1 to 12 months of age (Figure 3). The relatively low TNFα response to Pam3CSK4
(TLR1/2), Poly (I:C) (TLR3) and ODN M362 (TLR9) at birth failed to increase in
any age group to 12 months, in fact the TLR9-mediated TNFα response
significantly decreased from the 1 month to 12 month age groups (trend analysis
p = 0.008, Table S2 and Figure 3).While TLR-mediated IFNγ production at birth was very limited (Figure 1 and Table 1), most TLR agonists
elicited greater IFNγ production by 1 month of age: Pam3CSK4 (TLR1/2;
p = 0.003 (Figure 5A), Poly I:C (TLR3; p<0.001), LPS (TLR4; p<0.001),
Flagellin (TLR5; p<0.001), FSL-1 (TLR6/2; p = 0.002),
Gardiquimod™ (TLR7; p<0.001; Figure 5B), ssRNA (TLR8;
p = 0.017; Figure 5C), CL075 (TLR7/8; p<0.001; Figure 5D), ODN M362 (TLR9;
p = 0.066; Figure 4 and Table S2). TLR-mediated IFNγ production
then remained stable from 1 to 12 months of age, with the exception of responses
to the TLR1/2 agonist that decreased with age (trend analysis;
p = 0.003, Figure 5A).
Figure 5
Net TLR-mediated IFNγ responses differ between agonists and
across the first year of life.
100 µl of whole blood was cultured overnight with (A) Pam3CSK4
(TLR1/2 agonist), (B) Gardiquimod™ (TLR7 agonist), (C) ssRNA (TLR8
agonist) and (D) CL075 (TLR7/8 agonist) at birth (cord), 1, 2, 3, 4, 6,
9 and 12 months of age (x axis) and IFNγ cytokine production (y
axis) was measured in supernatants (pg/mL) as described in Materials and Methods. Unstimulated
values are subtracted from stimulated values and data were presented as
box and whisker, n = 12–15.
Net TLR-mediated IFNγ responses differ between agonists and
across the first year of life.
100 µl of whole blood was cultured overnight with (A) Pam3CSK4
(TLR1/2 agonist), (B) Gardiquimod™ (TLR7 agonist), (C) ssRNA (TLR8
agonist) and (D) CL075 (TLR7/8 agonist) at birth (cord), 1, 2, 3, 4, 6,
9 and 12 months of age (x axis) and IFNγ cytokine production (y
axis) was measured in supernatants (pg/mL) as described in Materials and Methods. Unstimulated
values are subtracted from stimulated values and data were presented as
box and whisker, n = 12–15.All the TLR agonists studied induced high levels of IL-6 at birth (Table 1) and generally
TLR-mediated IL-6 production remained high for the first year of life (Table S2).
Similarly, IL-1β and IL-10 production was high at birth in response to TLR4,
-5, and -8 agonists and remained high for the first year of life with the
exception of the combined TLR7/8 agonist (CL075) that induced less IL-1β
with age (Table
S2). In accordance with prior reports of an early life bias towards a
high ratio of IL-6/TNFα production [40], [41], in our cohort, ratios of
TLR-mediated IL-6/TLR-mediated TNFα were initially high at birth (cord) and
then decreased with age, reflecting a relatively constant and robust IL-6
production and an increase in TLR-mediated TNFα by 1 month of age (data not
shown).
TLR8 agonists elicit distinct early age-dependent Th1 responses
In accordance with a prior cord blood study [43], TLR8 agonists induced
greater Th1-polarising cytokine responses in early life compared to agonists of
other TLRs. CLO75 (TLR7/8) and ssRNA (TLR8) differed with respect to the
dynamics across age of cytokine responses. By one month of age, CL075 induced
higher concentrations of TNFα than ssRNA (p = 0.006),
but by 2 months of age the two agonists induced similar concentrations
(p = 0.735) which remained constant up to 12 months (Figure 6A). IFNγ responses
to these two agonists were similar from birth up to 6 months of age, from which
point ssRNA induced greater levels of IFNγ than CL075 through 12 months of
age (p = 0.001) (Figure 6B). In contrast, CL075-induced IL-10
production exceeded that induced by ssRNA at all ages (p<0.05, data not
shown).
Figure 6
TLR8 agonists induce distinct patterns of TNFα and IFNγ
production across the first year of life.
100 µl of whole blood was cultured overnight with ssRNA (TLR8
agonist) and CL075 (TLR7/8) at birth, 1, 2 and 12 months of age. (A)
TNFα and (B) IFNγ cytokine (pg/mL) was measured in supernatants
as described in the Materials and
Methods. Unstimulated values are subtracted from stimulated
values and data are presented as box and whisker plots,
n = 12–15.
TLR8 agonists induce distinct patterns of TNFα and IFNγ
production across the first year of life.
100 µl of whole blood was cultured overnight with ssRNA (TLR8
agonist) and CL075 (TLR7/8) at birth, 1, 2 and 12 months of age. (A)
TNFα and (B) IFNγ cytokine (pg/mL) was measured in supernatants
as described in the Materials and
Methods. Unstimulated values are subtracted from stimulated
values and data are presented as box and whisker plots,
n = 12–15.
TLR8-mediated IFNγ protein production correlates with gene
transcription
As the ability to induce IFNγ is of particular importance to host defence and
generation of adaptive immunity, we further characterised TLR-mediated IFNγ
induction in blood samples from 5 individuals for which longitudinal samples
were available from birth, 1 and 12 months of age. In addition, we also measured
IL-12A and IL-12B that encode components
of IL-12p70, a cytokine that is important to IFNγ production [48], [49] and to
Th1 adaptive immune responses but can be challenging to detect at the protein
level. Total RNA was purified from blood samples that were stimulated for 4
hours with Gardiquimod™ (TLR7), ssRNA (TLR8) and CL075 (TLR7/8) and mRNA
levels measured by real time PCR. Cytokine mRNAs were significantly up-regulated
at each time point for each TLR agonist-stimulated condition compared to the
unstimulated control (data not shown).In accordance with the protein data, cytokine mRNA expression patterns appeared
similar with lower responses to Gardiquimod™ (TLR7) compared to ssRNA
(TLR8) and CL075 (TLR7/8) for most cytokines at each age (Figure 7) except IL-12A
expression that appeared to be expressed at similar levels in response to each
of the agonists at a given age (Figure 7). In addition, the pattern of protein concentrations of
IL-10 demonstrated similar expression patterns to IL-10 mRNA
with greater responses to CL075 than to ssRNA for all ages (Figure 7).
Figure 7
TLR7- and TLR8-mediated cytokine mRNA expression varies between
agonists and across the first year of life.
300 µl of whole blood was cultured for 4 hours with
Gardiquimod™ (TLR7), ssRNA (TLR8 agonist) and CL075 (TLR7/8) at
(A) birth, (B) 1 month and (C) 12 months of age. RNA was purified and
cytokine mRNA was quantified by real time PCR as described in Materials and Methods. Ct values were
normalised against the housekeeping genes and compared to the
unstimulated control (ΔCt) and fold differences of ΔCt values
between unstimulated and stimulated cultures were calculated
(ΔΔCt). Fold changes are presented as box and whisker plots,
n = 5.
TLR7- and TLR8-mediated cytokine mRNA expression varies between
agonists and across the first year of life.
300 µl of whole blood was cultured for 4 hours with
Gardiquimod™ (TLR7), ssRNA (TLR8 agonist) and CL075 (TLR7/8) at
(A) birth, (B) 1 month and (C) 12 months of age. RNA was purified and
cytokine mRNA was quantified by real time PCR as described in Materials and Methods. Ct values were
normalised against the housekeeping genes and compared to the
unstimulated control (ΔCt) and fold differences of ΔCt values
between unstimulated and stimulated cultures were calculated
(ΔΔCt). Fold changes are presented as box and whisker plots,
n = 5.Correlations between mRNA expression levels and protein levels for the same
cytokines were analysed as pooled ages. In accord with greater IFNγ response
to TLR8 versus TLR7 agonists, significant correlations were noted between TLR
agonist-induced mRNA expression of IFNG and IFNγ protein
levels induced by ssRNA (p = 0.005; Figure 8B) and CL075
(p = 0.027; Figure 8C), but not Gardiquimod™
(p = 0.075; Figure 8A). Of note, TLR-mediated increases in
IL12A and IL12B mRNA also correlated with
TLR-mediated IFNγ protein production, including ssRNA-induced
IL-12A and IL-12B expression
(p = 0.017, p = 0.001 respectively) as
well as CL075- and Gardiquimod™-induced IL-12B expression
(p = 0.027 and p = 0.035,
respectively). For the other cytokines studied, the ssRNA- and CL075-induced
cytokine mRNA levels at 4 hours of stimulation did not correlate with the
corresponding cytokine protein levels at 24 hours.
Figure 8
Correlations between ssRNA-induced cytokine mRNA and protein
expression.
300 µl of whole blood was cultured for 4 hours with (A)
Gardiquimod™ (TLR7), (B) ssRNA (TLR8) and (C) CL075 (TLR7/8). RNA
was purified and cytokine mRNA was quantified by real time PCR as
described in Materials and Methods.
Comparisons between IFNγ protein and IFNG mRNA
levels were calculated where stimulated values (Ct and cytokine
concentrations) were divided by unstimulated values. The values were log
transformed and compared using Pearson correlation test, linear
regression line presented in graph, n = 5. At
birth (black circles), 1 month (open circles), or 12 months (crosses) of
age.
Correlations between ssRNA-induced cytokine mRNA and protein
expression.
300 µl of whole blood was cultured for 4 hours with (A)
Gardiquimod™ (TLR7), (B) ssRNA (TLR8) and (C) CL075 (TLR7/8). RNA
was purified and cytokine mRNA was quantified by real time PCR as
described in Materials and Methods.
Comparisons between IFNγ protein and IFNG mRNA
levels were calculated where stimulated values (Ct and cytokine
concentrations) were divided by unstimulated values. The values were log
transformed and compared using Pearson correlation test, linear
regression line presented in graph, n = 5. At
birth (black circles), 1 month (open circles), or 12 months (crosses) of
age.Levels of TLR-mediated IL-12A and IL-12B mRNA
expression were age-dependent for all three TLR agonists whereas
IFNG showed similar levels between birth, 1 and 12 months
of age (Figure 9 and Figure 7). In response to
CL075 (TLR7/8 agonist), expression of IL-12A increased from
birth to 1 month of age (p = 0.008) but subsequently
decreased by 12 months of age (p = 0.008). These mRNA
patterns corresponded to a similar pattern of IFNγ protein production by the
same agonist (comparing for the same subjects): birth vs. 1 month of age
(p = 0.002), and 1 month vs. 12 months of age
(p = 0.018). Gardiquimod™ also demonstrated
age-dependent expression of mRNAs encoding IL-10, IL-6 and
TNF mainly due to low expression levels at birth that
increased with age: birth to 1 month of age: IL-10
(p = 0.008), and birth to 12 months of age: IL-10
p = 0.3095, IL-6 p = 0.032, TNF
p = 0.008 (Figure 9 and Figure
7).
Figure 9
Age-dependent effects of cytokine transcription in response to TLR
agonists.
300 µl whole blood was cultured for 4 hours with Gardiquimod™
(TLR7 agonist), ssRNA (TLR8 agonist) and CL075 (TLR7/8 agonist) at birth
(cord), 1 and 12 months of age and IL-12A, IL-12B, IFNG,IL-6,
IL-10 and TNF cytokine mRNA gene
transcription was measured. Ct values were normalised against the
housekeeping genes and compared to the unstimulated control (ΔCt).
Comparisons of responses from birth, 1 and 12 months of age were made
using the Kruskall Wallis test. Grey squares represent significant
effects with age, p>0.05. Gard.
= Gardiquimod.
Age-dependent effects of cytokine transcription in response to TLR
agonists.
300 µl whole blood was cultured for 4 hours with Gardiquimod™
(TLR7 agonist), ssRNA (TLR8 agonist) and CL075 (TLR7/8 agonist) at birth
(cord), 1 and 12 months of age and IL-12A, IL-12B, IFNG,IL-6,
IL-10 and TNF cytokine mRNA gene
transcription was measured. Ct values were normalised against the
housekeeping genes and compared to the unstimulated control (ΔCt).
Comparisons of responses from birth, 1 and 12 months of age were made
using the Kruskall Wallis test. Grey squares represent significant
effects with age, p>0.05. Gard.
= Gardiquimod.
Discussion
Our study evaluated the ontogeny of TLR-mediated in vitro whole
blood cytokine responses during the first year of life in infants from The Gambia
employing agonists of TLRs 1-9 and blood samples from 8 different age groups. We
found that cytokine responses of Gambian infants varied between TLR agonists, with
the greatest responses to TLR8 agonists (ssRNA and CL075), substantial responses to
TLR4 and TLR5 agonists, and relatively weak responses to TLR1, 2, 3, 7 and 9
agonists at all ages. Thus the ontogeny of responses is TLR-specific with distinct
differences across age groups in the first 12 months of life. Most of the previous
studies exploring TLR-mediated responses of newborns have focused solely on
comparisons between cord blood and adults [4], [34], [40]. The few studies that have
also examined infant responses are limited to resource-rich setting and did not
include the wide range of agonists tested in our study [37], [39], [44], [45].We found that CL075 (TLR7/8) was the only TLR agonist to induce IFNγ at birth but
that in general, cord blood pro-inflammatory/Th1-polarizing cytokine responses
(i.e., TNFα and IFNγ) were lower than at later age groups, in accordance
with prior studies [4], [34], [39]. In contrast, TLR-mediated neonatal IL-6, IL-1β and
IL-10 production was higher or similar at birth compared to later age groups,
suggesting that neonatal TLR-mediated responses are biased towards acute phase
(IL-1β and IL-6) and anti-inflammatory (IL-10) cytokines. We have previously
shown in 5-day cultures that IL-10 and IL-6 responses to mycobacterial antigens were
present at birth [50]. It has been speculated that the bias towards high IL-10
production may reflect the need to dampen potentially over-exuberant responses to
the numerous new antigens to which an infant is exposed in early life [51]. Greater
IL-6 to TNFα ratios have been found in cord blood compared to adults, both in
response to in vitro stimulation [41] and with respect to basal serum
levels during the first week of life [40]. Our findings indicate a
similar polarisation in our cohort with greater IL-6 to TNFα ratios at birth
compared to 12 months of age. Relatively high IL-6 production in newborns likely
contributes to initiation of an acute phase response at birth that may serve to
clear perinatally-acquired microbes [52]. In addition, IL-6 enhances both differentiation of Th17
cells and production of IL-17, and thereby may enhance neutrophil- and antimicrobial
peptide-based host defence at neonatal mucosal and epithelial barriers [52–[. That this neonatal
bias towards TLR-mediated IL-6 and IL-10 responses is evident in
vivo was recently demonstrated in a field trial of alum-adjuvanted
pneumococcal conjugate vaccine [3].For most TLR agonists the major effect of age occurred within the first month of life
during which time TLR-mediated TNFα and IFNγ cytokine production increased,
suggesting early maturation in the ability to mount these responses. Whether this
maturation in cytokine production reflects changes in the adenosine system that
serves to limit production of TNFα in human newborn cord blood [41], will be the
subject of future studies. The only other study that reported responses in 1 month
old infants was conducted by Belderbos et al in Holland, which also
showed increased pro-inflammatory responses (e.g., IL-12p70 and IFNα) from birth
to 1 month of age in response to TLR3, -4, -7 and -9 agonists but similar levels of
IL-10 production in response to TLR3, -4 and -9 [39]. That study found that
loxoribine (TLR7)-induced IL-10 responses increased by 1 month of age, in accord
with our observation of a borderline increase at 1 month of age
(p = 0.05) using the TLR7 agonist Guardiquimod™. A
Belgian study by Ngyuen et al also found that LPS-induced cord
blood production of IL-10 and IL-6 was greater than in later age groups (6-9 months
and 12 months of age). Taken together, our current study and those by Belderbos
et al
[39], and
Vosters et al
[44] indicate
that for most TLR agonists, IL-10 production is largely similar from birth through
to 18 months of age.A comparison of the few studies of infant TLR function [37], [39], [44], [45] and our current study
indicates that Gambian infants have broadly similar TLR-mediated responses to those
found in a Western European environment. However, Ngyuen et al
studying a Belgian cohort found a slower postnatal increase in TNFα production
in response to LPS from birth compared to our study, such that adult levels were not
reached until 6 months of age [37], whereas our Gambian cohort demonstrated LPS-induced
TNFα responses that peaked at 1 month of and then remained stable to 12 months
of age. Earlier maturation of LPS-induced TNFα responses in Gambian infants than
in the European infants [37], [39], [45] may reflect more rapid polarisation to Th1 responses in a
resource-poor setting, in accord with the hygiene hypothesis [13], [57], [58], and may also suggest that TLR4
agonists, currently used in several vaccine formulations (e.g., MPL[59]), may be
useful vaccine adjuvants in early infancy.Although TLR8 agonist-induced cord blood TNFα responses have been shown to be
greater than TNFα responses to agonists of TLRs 1–7 [43], little is known
regarding cytokine responses to TLR8 agonists such as ssRNA (TLR8 only) and CL075
(TLR7/8 agonist) during the first year of life. Our study confirmed the greater
responsiveness to TLR8 agonists in cord blood and extended the finding by
demonstrating that TLR8 agonists were the predominant inducers of pro-inflammatory
cytokines up to 12 months of age in Gambian infants. We also found that the combined
TLR7/8 agonist (CL075) induced more TNFα than the TLR7 selective agonist
Gardiquimod™ or the TLR8 selective agonist ssRNA up to 1 month of age. By 12
months of age however, there was a trend towards reduced TNFα production in
response to the combined agonist compared to the single TLR8 agonist. Likewise,
IFNγ production was similar between the two agonists up to 6 months of age after
which CL075-induced IFNγ diminished relative to ssRNA-induced IFNγ and
remained lower up to 12 months of age. It should be noted however, that in addition
to differences between TLR7 and TLR8 selectivity, differences in biochemical
structures between ssRNA and the low-molecular weight thiazoloquinolone, CL075 may
affect TLR-independent variables (e.g., solubility, protein binding and cell
penetration) that may also contribute to distinct bioactivities. The correlations
between IFNG mRNA and IFNγ protein in response to ssRNA and
CL075 indicate that the ontogeny of TLR-mediated IFNγ production is manifest at
the transcriptional level. Given the importance of IL-12 to IFNγ production
[49], [60], [61] and the
observed correlations of TLR-mediated IFNγ protein with IL12B
message, TLR8-mediated IFNγ responses may also involve activation of
IL-12B (that encodes for IL-12p40)[49]. However, expression of
IL-12A (that encodes for IL-12p35) was very low at all three
ages tested, in agreement with Western European studies that demonstrate deficiency
in TLR-mediated IL-12p35 production by neonatal DCs, contributing to impaired
neonatal IFNγ responses [62]. Analysis of TLR-mediated production of additional
cytokines that may influence adaptive immune responses, including IL-4 (Th2) and
IL-17 (Th17), is of importance and should be included in future studies.Overall, characterizing the ontogeny of innate immune responses may eventually inform
selection of adjuvant vaccine formulations that are tailored for certain age groups.
Indeed, recent studies highlight that appropriate immunologic signatures can predict
vaccine efficacy [17], [63]. To the extent that TNFα and IFNγ may be markers
of strong Th1-polarising responses required for induction of cell-mediated immunity,
and that the whole blood in vitro responses measured in our study
may reflect those that would pertain in vivo, our data suggest that
vaccine adjuvants based on TLR4, -5 or -8 agonists, may be particularly effective in
protecting newborns and infants against pathogens requiring cell-mediated
immunity.Summary of the TLR agonists used in the study.(DOC)Click here for additional data file.Analysis for age-dependent evolution of cytokine responses to TLR
agonists. 100 µl of whole blood was cultured overnight with
Pam3CSK4 (TLR1/2), Poly (I:C) (TLR3), LPS (TLR4), Flagellin (TLR), FSL-1
(TLR6/2), Gardiquimod™ (TLR7), ssRNA (TLR8) and CL075 (TLR7/8) or ODN
M362 (TLR9) at birth (cord), 1, 2, 3, 4, 6, 9 and 12 months of age.
IFNγ, TNFα,IL-1β,IL-10and IL-6 cytokine concentrations (pg/mL)
were measured in supernatants as described in Materials and Methods. Comparisons of responses were made (A)
from birth to 12 months of age and (B) from 1 to 12 months of age by
comparing the proportions of values above and below the median using
Fisher's exact test. All grey squares represent significant effects
with age (p<0.05) while dark grey squares indicate the effects with age
corresponding to a significant decline in cytokine production from 1 to 12
months of age using trend analysis.(DOC)Click here for additional data file.
Authors: Capucine Picard; Horst von Bernuth; Pegah Ghandil; Maya Chrabieh; Ofer Levy; Peter D Arkwright; Douglas McDonald; Raif S Geha; Hidetoshi Takada; Jens C Krause; C Buddy Creech; Cheng-Lung Ku; Stephan Ehl; László Maródi; Saleh Al-Muhsen; Sami Al-Hajjar; Abdulaziz Al-Ghonaium; Noorbibi K Day-Good; Steven M Holland; John I Gallin; Helen Chapel; David P Speert; Carlos Rodriguez-Gallego; Elena Colino; Ben-Zion Garty; Chaim Roifman; Toshiro Hara; Hideto Yoshikawa; Shigeaki Nonoyama; Joseph Domachowske; Andrew C Issekutz; Mimi Tang; Joanne Smart; Simona Eva Zitnik; Cyrille Hoarau; Dinakantha S Kumararatne; Adrian J Thrasher; E Graham Davies; Claire Bethune; Nicolas Sirvent; Dominique de Ricaud; Yildiz Camcioglu; Júlia Vasconcelos; Margarida Guedes; Artur Bonito Vitor; Carlos Rodrigo; Francisco Almazán; Maria Méndez; Juan Ignacio Aróstegui; Laia Alsina; Claudia Fortuny; Janine Reichenbach; James W Verbsky; Xavier Bossuyt; Rainer Doffinger; Laurent Abel; Anne Puel; Jean-Laurent Casanova Journal: Medicine (Baltimore) Date: 2010-11 Impact factor: 1.889
Authors: Ofer Levy; Kol A Zarember; Rene M Roy; Colette Cywes; Paul J Godowski; Michael R Wessels Journal: J Immunol Date: 2004-10-01 Impact factor: 5.422
Authors: Sen Rong Yan; Gefei Qing; David M Byers; Andrew W Stadnyk; Walla Al-Hertani; Robert Bortolussi Journal: Infect Immun Date: 2004-03 Impact factor: 3.441
Authors: Sunil K Jain; Eric W Baggerman; Krishnan Mohankumar; Kopperuncholan Namachivayam; Ramasamy Jagadeeswaran; Victor E Reyes; Akhil Maheshwari Journal: Am J Physiol Gastrointest Liver Physiol Date: 2014-01-09 Impact factor: 4.052
Authors: Antonio Gonzalez; Jose C Clemente; Ashley Shade; Jessica L Metcalf; Sejin Song; Bharath Prithiviraj; Brent E Palmer; Rob Knight Journal: EMBO Rep Date: 2011-07-01 Impact factor: 8.807
Authors: Simon D van Haren; David J Dowling; Willemina Foppen; Dennis Christensen; Peter Andersen; Steven G Reed; Robert M Hershberg; Lindsey R Baden; Ofer Levy Journal: J Immunol Date: 2016-10-28 Impact factor: 5.422
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