Bio Vaccine
Immune response to mRNA COVID vaccines delayed in pregnant women
Researchers in the United States
have conducted comprehensive profiling of humoral immune responses in pregnant,
lactating, and non-pregnant women following coronavirus disease 2019 (COVID-19)
messenger RNA (mRNA) vaccination to probe differences in vaccine-induced
immunity.
The team from Harvard University,
Massachusetts Institute of Technology, Massachusetts General Hospital, and the
University of Pennsylvania, in their recent research published in the journal
Science Translational Medicine, have reported distinct response profiles across
each of these immunological states, suggesting that vaccines may drive
different antibody functional profiles, programmed evolutionarily to maximize
protection for the mother-baby dyad in that unique immune state.
Immunological adaptations occur
throughout pregnancy and lactation
Pregnant women undergo substantial
immunological changes to render immunological tolerance to the fetus and allow
fetal growth without rejection. Other adaptations also occur, allowing the
maternal immune system to continue to protect the mother-infant dyad against
infections during pregnancy and after delivery through lactation.
Physiological and hormonal changes,
along with this delicate balance of tolerance and immunity, contribute to
increased susceptibility to some infections in pregnancy, including more severe
COVID-19.
Antibodies, in addition to their
role in neutralization, contribute to protection against COVID-19 through their
ability to recruit the innate immune response with their Fc-domain, which is
associated with protection from infection following vaccination, play a
critical role in antibody transfer across the placenta, and may also influence
transfer into breastmilk.
While reports have shown the
immunogenic potential of vaccines in pregnant and lactating women, none have
characterized the Fc-profile of vaccine-induced antibodies in pregnant and
lactating women.
Therefore, it is critical to
understand how pregnancy and lactation affect immune responses, including Fc
immune profile, to vaccination, impacting antibody transit across the placenta
or into breastmilk to guide the vaccine recommendations for this vulnerable
population.
Cohort study on pregnant,
lactating, and non-pregnant controls vaccinated with mRNA vaccines
The team evaluated the SARS-CoV-2
humoral immune responses in a cohort of 84 pregnant, 31 lactating and 16
non-pregnant age-matched controls vaccinated with either BNT162b2 or mRNA-1273
vaccine.
Serological and functional assays
were performed on samples collected after the first dose (post-prime, at the
time of the second dose), after the second dose (post-boost, 2-5.5 weeks
following the second dose), and at delivery (for pregnant participants).
Pregnant, lactating, and
non-pregnant women show differential immune profiles post-vaccination
In post-prime serum samples, the
team observed lower antibody and FcR-binding capacity among pregnant and
lactating women compared to non-pregnant controls. Non-pregnant women had
higher IgG subclass responses, higher antibody functions, and higher
FcR-binding compared to pregnant and lactating women.
Post-boost samples presented lesser
differences between pregnant or lactating and non-pregnant women. However,
persisting differences were nearly exclusively linked to enhanced FcR-binding
in non-pregnant women.
“Fc receptor
(FcR)-binding and antibody effector functions were induced with delayed
kinetics in both pregnant and lactating women compared to non-pregnant women
after the first vaccine dose, which normalized after the second dose”, observed
the team.
Noticeably, lactating women boosted
their antibody response more effectively than pregnant women, marked by higher
IgG titers and higher natural killer (NK) cell activity, in post-boost
samples, suggesting lactating women make
qualitatively different responses to the second dose of vaccine compared to pregnant
individuals.
Both pregnant and lactating women
raised FcR-binding serum antibodies after the second dose. Nevertheless, all
FcR-binding antibodies in pregnant women and FcγR2b-binding antibodies in
lactating women remained lower as compared to the non-pregnant women. The team
suggests that these higher FcR-binding profiles in lactating and non-pregnant
women could be linked to enhanced coordination in the humoral immune responses
compared to pregnant women.
All three populations induced
similar antibody-dependent cellular phagocytosis (ADCP) and did not increase
ADCP function post-boost vaccination. In contrast, antibody-dependent
neutrophil phagocytosis (ADNP) activity was increased in pregnant and lactating
women after boosting.
Overall, these data point to
restriction in the ability of pregnant women to generate functional, but not
total, antibodies with boosting compared to lactating women. Further, these
data suggest that pregnant and lactating women show potential early alterations
in vaccine-induced immune responses that improve after a booster vaccine.
Humoral profiles vary between
maternal serum and umbilical cord blood
Maternal blood had a higher titer
of antibodies compared to cord blood. Variable patterns of transfer of IgG
titer, FcR-binding and antibody function were observed from the mother to the
cord. Despite the recency of vaccination, equivalent, IgG1 spike
protein-specific titers were transferred across the placenta to the infant.
Stable phagocytic antibodies but
decreased NK-cell activating antibodies were transferred to infants. However,
despite the lower titers of antibodies in the cord, the placenta was able to
select for FcγR3a-binding, functionally enhanced vaccine-induced antibodies.
Boosting enhances transfer of
FcR-binding IgG antibodies in breastmilk
Lactating mother serum had a
preferential boosting of FcR-binding IgG responses after a booster vaccine
dose. The team observed the transfer of a similar profile to the breastmilk,
with high IgG antibodies and high FcR-binding capabilities post-boost.
“Vaccination
appears to augment highly functional IgG transit to the milk that is likely key
to antiviral immunity across viral pathogens,” the team highlights.
NK-cell activating antibodies had a
low transfer ratio at the post-boost timepoint, suggesting a sieve at the
mammary gland, preventing the transfer of highly inflammatory antibodies
through breastmilk.
mRNA-1273 and BNT162b2 vaccination
induce differential antibody responses in pregnant and lactating women.
mRNA-1273 vaccinated women
exhibited more focused coordination in the humoral immune response, centered
around a high IgG1/IgG3 response with robust FcR-binding and functional
coordination. Conversely, women receiving BNT162b2 generated a broader
coordinated immune response, including IgG2 and IgM responses and the exclusion
of monocyte phagocytosis (ADCP), suggesting a more diffuse overall humoral
immune coordination profile.
These serum differences translated
to differences in antibodies transferred in breastmilk. In addition, the team
observed differences in the overall antibody profile across women receiving
mRNA-1273 and BNT162b2.
Thus, as per the team’s
speculation, the extra week prior to mRNA-1273 boosting may provide the time
needed for the humoral immune response to mature, resulting in more functional
antibody profiles.
These findings collectively point
to an extended window of vulnerability in pregnancy and lactation following
vaccination, requiring timely boosting to achieve fully-functional antibodies
that can protect pregnant individual and their infant.
출처: News Medical