According to the study, babies do
not have immature immune cells, but extra immune-suppressive cells, called
CD71+ cells. These special cells eventually develop into red blood cells. CD71+
cells contain the enzyme arginase-2, which helps to repress immune cells.
Enzymes are biological proteins within cells that lower the activation energy
needed for certain reactions to occur. If arginase-2 is inhibited by other
molecules, which means it can no longer function due to a change in structure,
its ability to reduce the effectiveness of immune cells is prevented. This also
occurs in the presence of the molecule L-arginase. To test this, the
researchers used newborn mice and blood cells from umbilical cord blood. In
both test subjects, CD71+ cells were found in increased concentrations. They
concluded that the presence of these cells allows infants to adapt to the increased
stimuli and microbial presence after birth. For example, beneficial bacteria
have to colonize in the intestines to aid with digestion, and many other types
of bacteria will be present on the skin. If the immune system is not
suppressed, the infant experiences increased inflammation in the intestines,
and necessary bacteria would not be able to colonize. As the infant grows, the
presence of CD71+ declines and the immune system becomes more effective. The
researchers concluded that it is most important for the infant’s body to adapt
to its environment and to allow bacteria to colonize before it can prevent
infection.
These new findings are intriguing,
and can possibly explain trends in infant mortality. In history class, we
learned about infant mortality rates throughout time. In the 19th
century, as Americans moved into cities, the likelihood of survival for infants
and children greatly decreased. In these urbanized areas, disease was
prevalent, due to primitive waste disposal systems and open sewage areas. Maybe
the inability of the infant immune system to prevent infection at a young age
was a weakness rather than an adaptation in that historical environment. I
believe research should be conducted to explain and prevent trends like this.
In the future, these findings could
be used to lower infant mortality, especially in countries where disease
control is poor. The researchers intend to explore the possibility of
strengthening the infant immune system while still allowing the CD71+ cells to
assist in the colonization of bacteria in the intestines. The CD71+ cells could
be manipulated or drugs could be used to increase immunity to harmful bacteria.
This would change the future of medicine and could improve the outlook for
infants who are exposed to disease. I hope to become a pediatrician in the
future, so this is especially interesting to me. If doctors could protect
newborns from harmful diseases, their job would consist of more active measures
of prevention. Instead of telling families to limit their infants’ exposure to
people who might carry diseases, doctors could prescribe medicines to protect their
bodies. This would allow infants to be around family members and in places such
as daycares. Further research could have an interesting impact on medicine and children’s
health.
Though this study is compelling, I
question the scientific and ethical issues accompanying the research. The
impact of the CD71+ cells was only observed in mice and in umbilical cord
blood, not in human infants. Of course, for safety reasons, human newborns
cannot be tested, but it might be difficult to compare humans and mice. Humans
have a more complex immune system compared to mice, and are exposed to a wide
range of disease-carrying microbes. Even with complex trials, it will be
difficult to tell how potential medicines or prevention techniques will affect
humans. Additionally, the ethical concern over testing on live animals is
raised. Before reading this article, I strongly believed that researchers
should not use animals – even mice – as test subjects. After reading the study,
I have a greater understanding of why it is important to test on the mice. Before
administering drugs or new techniques to human babies, it is crucial to know
that the method is safe and effective. As long as the testing methods are
humane and necessary, I now feel more comfortable supporting testing on animals
to ensure the safety of human infants.
At a time when so much important
medical research is being conducted, it is exciting to learn that scientists
might be able to combat infectious disease in newborns. The possibilities for this
research seem promising, and could impact both patients and professionals in
the medical field. It is amazing to think that the most basic unit of life, the
cell, can be manipulated to save lives.
Works
Cited
Elahi,
Shokrollah. "Immunosuppressive CD71+ erythroid cells compromise neonatal
host defence against infection." Nature. N.p., n.d. Web. 22 Nov.
2013.
<http://www.nature.com/nature/journal/vaop/ncurrent/full/nature12675.html>.
"Immune-suppressing
cells explain newborn infection vulnerability." Medical News Today.
MediLexicon International, n.d. Web. 20 Nov. 2013.
<http://www.medicalnewstoday.com/articles/268394.php>.
