Different delivery methods of newborn babies has a big effect on the types of microbial communities they harbor as they emerge into the world, says a new study. These are findings with potential implications for the heath of infants as they grow and develop.
The study, led by the University of Puerto Rico and involving the University of Colorado at Boulder and two Venezuelan institutes, showed that babies delivered vaginally had bacterial communities resembling their mother's vaginal bacteria, while Caesarian section newborns had common skin bacterial communities. Researchers believe many of the different microbial communities residing on humans -- each of which is personally unique -- may help protect individuals from various diseases.
The new findings establish an important baseline for tracking the succession of bacterial communities on babies and their associated effects on human health, said co-lead study author Maria Dominguez-Bello of the University of Puerto Rico.
Dominguez-Bello said the bacterial communities of C-section babies were dominated by species from the Staphylococcus genus, most of which are harmless but a few of which can cause severe infections. "These differences we are seeing in this study might be related with increased health risks in C-section babies, although more research is needed," she said.
Previous studies indicate babies born via C-section can be more susceptible to certain pathogens, allergies and asthma than newborns born vaginally. The PNAS study results may help explain the higher incidence of Methicillin-resistant Staphylococcus aureus, or MRSA, in C-section babies, a hard-to-treat bacterial infection that has been increasing in hospitals and clinics in recent years, according to the researchers.
In a 2004 study undertaken in Chicago and Los Angeles County hospitals, between 64 percent and 82 percent of reported cases of MRSA skin infections in newborns occurred in C-section infants. While the World Health Organization has recommended the percentage of births via C-section not exceed 15 percent in any country because of potential medical complications, the rate is much higher in a number of countries, including China at nearly 50 percent and the United States at about 30 percent.
Human microbial communities play an important role in digestion and immune health and are believed to collectively endow us with the essential traits we rely on for such functions, according to the research team. One possibility is that the direct transmission of a mother's vaginal bacteria onto newborns may act as a defense against diseases by limiting the colonization of more harmful pathogens, they said.
In a related 2009 study led by Knight, researchers developed the first atlas of microbial diversity across the human body in adults, charting wide variations in microbe populations from the forehead and feet to noses and navels of individuals -- differences that were not yet apparent in the PNAS newborn study. One goal of the human bacterial studies is to find out what is normal for healthy people, which should provide a baseline for studies looking at human disease states, said Knight.
"The prospects of learning how differences in individual human microbial communities can be used as a diagnostic tool in biomedicine is frankly quite exciting," said Knight of CU-Boulder's chemistry and biochemistry department. "With these new data on babies, we now have a second point in time for comparison."
"In a sense, the skin of newborn infants is like freshly tilled soil that is awaiting seeds for planting -- in this case bacterial communities," said Fierer of CU-Boulder's ecology and evolutionary biology department. "The microbial communities that cluster on newborns essentially act as their first inoculation."
Fierer, also a fellow at CU's Cooperative Institute for Research in Environmental Sciences, said that during vaginal births "it appears that the newborns pick up the bacteria from the mothers on the way out. But in C-sections, the bacterial communities of infants could come from the first person to handle the baby, perhaps the father."
The new study has allowed the researchers "to capture the first moments in time" of infant bacterial communities, said Costello, a former CU-Boulder postdoctoral researcher. "The challenge now is to fill in the rest of the story by tracking microbial communities in infants to toddlers to children and adults over weeks, months and years to see how they evolve and change," she said.
The PNAS study included nine women from 21 to 33 years old and 10 newborns and was undertaken at the Puerto Ayacucho Hospital in Amazonas State, Venezuela. The babies were sampled within 24 hours of birth by swabbing their mouths and skin and by taking samples from their upper throats and gastrointestinal tracts, said Costello. The research team then used a powerful gene sequencing technique to simultaneously analyze all of the bacteria.
The effort involved isolating and amplifying tiny bits of microbial DNA, then building complementary DNA strands with a high-powered sequencing machine that allowed the team to pool hundreds of samples together in single sequencing runs to identify different families and genera of bacteria, said Knight.
"While the cost of gene sequencing is dropping rapidly, new techniques are allowing us to speed up the process at the same time," said Knight. "We can now foresee a time when such genetic sequencing could be used in relatively small biomedical laboratories in developing countries."
The new PNAS study was supported by the Venezuelan Institute for Scientific Research,