TY - JOUR
T1 - Limitations to estimating bacterial cross-species transmission using genetic and genomic markers
T2 - Inferences from simulation modeling
AU - Benavides, Julio A.
AU - Cross, Paul C.
AU - Luikart, Gordon
AU - Creel, Scott
PY - 2014/8
Y1 - 2014/8
N2 - Cross-species transmission (CST) of bacterial pathogens has major implications for human health, livestock, and wildlife management because it determines whether control actions in one species may have subsequent effects on other potential host species. The study of bacterial transmission has benefitted from methods measuring two types of genetic variation: variable number of tandem repeats (VNTRs) and single nucleotide polymorphisms (SNPs). However, it is unclear whether these data can distinguish between different epidemiological scenarios. We used a simulation model with two host species and known transmission rates (within and between species) to evaluate the utility of these markers for inferring CST. We found that CST estimates are biased for a wide range of parameters when based on VNTRs and a most parsimonious reconstructed phylogeny. However, estimations of CST rates lower than 5% can be achieved with relatively low bias using as low as 250 SNPs. CST estimates are sensitive to several parameters, including the number of mutations accumulated since introduction, stochasticity, the genetic difference of strains introduced, and the sampling effort. Our results suggest that, even with whole-genome sequences, unbiased estimates of CST will be difficult when sampling is limited, mutation rates are low, or for pathogens that were recently introduced.
AB - Cross-species transmission (CST) of bacterial pathogens has major implications for human health, livestock, and wildlife management because it determines whether control actions in one species may have subsequent effects on other potential host species. The study of bacterial transmission has benefitted from methods measuring two types of genetic variation: variable number of tandem repeats (VNTRs) and single nucleotide polymorphisms (SNPs). However, it is unclear whether these data can distinguish between different epidemiological scenarios. We used a simulation model with two host species and known transmission rates (within and between species) to evaluate the utility of these markers for inferring CST. We found that CST estimates are biased for a wide range of parameters when based on VNTRs and a most parsimonious reconstructed phylogeny. However, estimations of CST rates lower than 5% can be achieved with relatively low bias using as low as 250 SNPs. CST estimates are sensitive to several parameters, including the number of mutations accumulated since introduction, stochasticity, the genetic difference of strains introduced, and the sampling effort. Our results suggest that, even with whole-genome sequences, unbiased estimates of CST will be difficult when sampling is limited, mutation rates are low, or for pathogens that were recently introduced.
KW - Bacterial pathogens
KW - Cross-species transmission
KW - Infectious disease
KW - Molecular epidemiology
KW - Most parsimonious phylogenetic reconstruction
KW - Simulation modeling
UR - http://www.scopus.com/inward/record.url?scp=84906675866&partnerID=8YFLogxK
U2 - 10.1111/eva.12173
DO - 10.1111/eva.12173
M3 - Article
AN - SCOPUS:84906675866
SN - 1752-4563
VL - 7
SP - 774
EP - 787
JO - Evolutionary Applications
JF - Evolutionary Applications
IS - 7
ER -