Cross-species transmission (CST), also called interspecies transmission, host jump, or spillover, is the ability for a foreign virus,
once introduced into an individual of a new host species, to infect
that individual and spread throughout a new host population.
Steps involved in the transfer of viruses to new hosts include contact
between the virus and the host, infection of an initial individual
leading to amplification and an outbreak, and the generation within the
original or new host of viral variants that have the ability to spread
efficiently between individuals in populations of the new host Often seen in emerging viruses where one species transfers to another, which in turn transfers to humans. Examples include HIV-AIDS, SARS, ebola, swine flu, rabies, and avian influenza. Bacterial pathogens can also be associated with CST.
The exact mechanism that facilitates transfer is unknown, however, it is believed that viruses with a rapid mutation rate are able to overcome host-specific immunological defenses. This can occur between species that have high contact rates. It can also occur between species with low contact rates but usually through an intermediary species. Bats, for example, are mammals and can directly transfer rabies to humans through bite and also through aerosolization of bat saliva and urine which are then absorbed by human mucous membranes in the nose, mouth and eyes. Note: the document used as a reference does not use the words urine or saliva so this citation is questionable. A host shifting event is defined as a strain that was previously zoonotic and now circulates exclusively among humans.
Similarity between species, for example, transfer between mammals, is believed to be facilitated by similar immunological defenses. Other factors include geographic area, intraspecies behaviours, and phylogenetic relatedness. Virus emergence relies on two factors: initial infection and sustained transmission.
The exact mechanism that facilitates transfer is unknown, however, it is believed that viruses with a rapid mutation rate are able to overcome host-specific immunological defenses. This can occur between species that have high contact rates. It can also occur between species with low contact rates but usually through an intermediary species. Bats, for example, are mammals and can directly transfer rabies to humans through bite and also through aerosolization of bat saliva and urine which are then absorbed by human mucous membranes in the nose, mouth and eyes. Note: the document used as a reference does not use the words urine or saliva so this citation is questionable. A host shifting event is defined as a strain that was previously zoonotic and now circulates exclusively among humans.
Similarity between species, for example, transfer between mammals, is believed to be facilitated by similar immunological defenses. Other factors include geographic area, intraspecies behaviours, and phylogenetic relatedness. Virus emergence relies on two factors: initial infection and sustained transmission.
Prevalence
Cross-species transmission is the most significant cause of disease emergence in humans and other species. Wildlife zoonotic diseases of microbial origin are also the most common group of human emerging diseases, and CST between wildlife and livestock has appreciable economic impacts in agriculture by reducing livestock productivity and imposing export restrictions. This makes CST of major concern for public health, agriculture, and wildlife management.
A large proportion of viral pathogens that have emerged recently
in humans are considered to have originated from various animal species.
This is shown by several recent epidemics such as, avian flu, Ebola, monkey pox, and Hanta viruses.
There is evidence to suggest that some diseases can potentially be
re-introduced to human populations through animal hosts after they have
been eradicated in humans. There is a risk of this phenomenon occurring with morbilliviruses as they can readily cross species barriers. CST can also have a significant effect on produce industries. Genotype VI-Avian paramyxovirus serotype 1 (GVI-PMV1) is a virus that arose through cross-species transmission events from Galliformes (i.e. chicken) to Columbiformes, and has become prevalent in the poultry industry. CST of rabies
virus variants between many different species populations is a major
wildlife management concern. Introduction of these variants into
non-reservoir animals increases the risk of human exposures and
threatens current advances toward rabies control.
Many pathogens are thought to have host specialization, which explains the maintenance of distinct strains in host species.
Pathogens would have to overcome their host specificity to cross to a
new host species. Some studies have argued that host specializations
may be exaggerated, and pathogens are more likely to exhibit CST than
previously thought. Original hosts usually have low death rates when infected with a pathogen, with fatality rates tending to be much higher in new hosts.
Cross-Species Transmission between Humans and Nonhuman Primates
Due to the close relation of humans and nonhuman primates
(NHP), disease transmission between NHP and humans is relatively common
and can become a major public health concern. Diseases, such as HIV and human adenoviruses have been associated with NHP interactions.
In places where contact between humans and NHPs is frequent, precautions are often taken to prevent disease transmission. Simian foamy viruses (SFV) is an enzootic retrovirus that has high rates of cross-species transmission and has been known to affect humans bitten by infected NHPs. It has caused health concerns in places like Indonesia where visitors at monkey temples can contract SFV from temple macaques (Macaca fascicularis). TMAdV (titi monkey adenovirus) is a highly divergent, sharing <57 a="" href="https://en.wikipedia.org/wiki/Pairwise_comparison" title="Pairwise comparison">pairwise57>
nucleotide identity with other adenoviruses, NHP virus that had a high
fatality rate (83%) in monkeys and is capable of spreading through human
hosts.
Predicting and Preventing Transmission between Species
Prediction
and monitoring are important for the study of CSTs and their effects.
However, factors that determine the origin and fate of cross-species
transmission events remain unclear for the majority of human pathogens. This has resulted in the use of different statistical models for the analyzation of CST. Some of these include risk-analysis models, single rate dated tip (SRDT) models, and phylogenetic diffusion models. The study of the genomes of pathogens involved in CST events is very useful in determining their origin and fate. This is because a pathogens genetic diversity and mutation
rate are key factors in determining if it is able to transmit across
multiple hosts. This makes it important for the genomes of transmission
species to be partially or completely sequenced.
A change in genomic structure could cause a pathogen that has narrow
host range to become capable of exploiting a wider host range. Genetic distance between different species, geographical range, and other interaction barriers will also influence cross-species transmission.
One approach to risk assessment analysis of CST is to develop
risk-analysis models that break the ‘‘process’’ of disease transmission
into component parts. Processes and interactions that could lead to
cross-species disease transmission are explicitly described as a
hypothetical infection chain. Data from laboratory and field experiments
is used to estimate the probability of each component, expected natural
variation, and margins of error.
Different types of CST research would require different analysis
pathways to meet their needs. A study on identification of viruses in
bats that could spread to other mammals used the workflow: sequencing
of genomic samples → “cleaning” of raw reads → elimination of host reads
and eukaryotic contaminants → de novo assembly of the remaining reads →
annotation of viral contigs → molecular detection of specific viruses →
phylogenetic analysis → interpretation of data.
Detecting CST and estimating its rate based on prevalence data is challenging. Due to these difficulties computational methods are used to analyse CST events and the pathogens associated with them. The explosive development of molecular techniques has opened new possibilities for using phylogenetic analysis of pathogen genetics to infer epidemiological parameters.
This provides some insight into the origins of these events and how
they could be addressed. Methods of CST prevention are currently using
both biological and computational data. An example of this is using both
cellular assays and phylogenetic
comparisons to support a role for TRIM5α, the product of the TRIM5
gene, in suppressing interspecies transmission and emergence of
retroviruses in nature.
Cross-Species Transmission Analyzation
Phylogeny
The comparison of genomic data is very important for the study of cross-species transmission. Phylogenetic analysis
is used to compare genetic variation in both pathogens associated with
CST and the host species that they infect. Taken together, it is
possible to infer what allowed a pathogen to crossover to a new host
(i.e. mutation in a pathogen, change in host susceptibility) and how
this can be prevented in the future. If the mechanisms a pathogens uses
to initially enter a new species are well characterized and understood a
certain level of risk control and prevention can be obtained. In
contact, a poor understanding of pathogens, and their associated
diseases, makes it harder for preventive measures to be taken.
Alternative hosts can also potentially have a critical role in the evolution and diffusion of a pathogen. When a pathogen crosses species it often acquires new characteristics that allow it to breach host barriers. Different pathogen variants can have very different effects on host species.
Thus it can be beneficial to CST analysis to compare the same pathogens
occurring in different host species. Phylogenetic analysis can be used
to track a pathogens history through different species populations. Even
if a pathogen is new and highly divergent, phylogenetic comparison can
be very insightful. A useful strategy for investigating the history of epidemics caused by pathogen transmission combines molecular clock analysis, to estimate the timescale of the epidemic, and coalescent theory, to infer the demographic history of the pathogen.
When constructing phylogenies, computer databases and tools are often used. Programs, such as BLAST, are used to annotate pathogen sequences, while databases like GenBank
provide information about functions based on the pathogens genomic
structure. Trees are constructed using computational methods such as MPR
or Bayesian Inference, and models are created depending on the needs of
the study. Single rate dated tip (SRDT) models, for example, allows for estimates of timescale under a phylogenetic tree. Models for CST prediction will vary depending on what parameters need to be accounted for when constructing the model.
Most Parsimonious Reconstruction (MPR)
Parsimony
is the principle in which one chooses the simplest scientific
explanation that fits the evidence. In terms of building phylogenetic
trees, the best hypothesis
is the one that requires the fewest evolutionary changes. Using
parsimony to reconstruct ancestral character states on a phylogenetic
tree is a method for testing ecological and evolutionary hypotheses.
This method can be used in CST studies to estimate the number of
character changes that exist between pathogens in relation to their
host.
This makes MPR useful for tracking a CST pathogen to its origins. MPR
can also be used to the compare traits of host species populations.
Traits and behaviours within a population could make them more
susceptible to CST. For example, species which migrate regionally are important for spreading viruses through population networks.
Despite the success of parsimony reconstructions, research
suggests they are often sensitive and can sometimes be prone to bias in
complex models.
This can cause problems for CST models that have to consider many
variables. Alternatives methods, such as maximum likelihood, have been
developed as an alternative to parsimony reconstruction.
Using Genetic Markers
Two methods of measuring genetic variation, variable number tandem repeats (VNTRs) and single nucleotide polymorphisms (SNPs), have been very beneficial to the study of bacterial transmission. VNTRs, due to the low cost and high mutation rates, make them particularly useful to detect genetic differences in recent outbreaks,
and while SNPs have a lower mutation rate per locus than VNTRs, they
deliver more stable and reliable genetic relationships between isolates.
Both methods are used to construct phylogenies for genetic analysis,
however, SNPs are more suitable for studies on phylogenies contraction.
However, it can be difficult for these methods accurately simulate CSTs everts. Estimates of CST based on phylogenys
made using VNTR marker can be biased towards detecting CST events
across a wide range of the parameters. SNPs tend to be less biased and
variable in estimates of CST when estimations of CST rates are low and
low number of SNPs is used. In general, CST rate estimates using these
methods are most reliable in systems with more mutations, more markers,
and high genetic differences between introduced strains.
CST is very complex and models need to account for a lot of parameters
to accurately represent the phenomena. Models that oversimplify reality
can result in biased data. Multiple parameters such as number of
mutations accumulated since introduction, stochasticity,
the genetic difference of strains introduced, and the sampling effort
can make unbiased estimates of CST difficult even with whole-genome
sequences, especially if sampling is limited, mutation rates are low, or
if pathogens were recently introduced.
More information on the factors that influence CST rates is needed for
the contraction of more appropriate models to study these events.
The process of using genetic markers to estimate CST rates should
take into account several important factors to reduce bias. One, is
that the phylogenetic tree constructed in the analysis needs to capture
the underlying epidemiological process generating the tree.
The models need to account for how the genetic variability of a
pathogen influences a disease in a species, not just general differences
in genomic structure. Two, the strength of the analysis will depend on
the amount of mutation accumulated since the pathogen was introduced in
the system.
This is due to many models using amount of mutations as an indicator of
CST frequency. Therefore, efforts are focused on estimating either time
since introduction or the substitution rate of the marker (from
laboratory experiments or genomic comparative analysis). This is
important not only when using the MPR method but also for Likelihood approaches that require an estimation of the mutation rate.
Three, CST will also affect disease prevalence in the potential host,
so combining both epidemiological time series data with genetic data may
be an excellent approach to CST study
Bayesian Analysis
Bayesian
frameworks are a form of maximum likelihood-based analyses and can be
very effective in cross-species transmission studies. Bayesian inference
of character evolution methods can account for phylogenetic tree
uncertainty and more complex scenarios, with models such as the
character diffusion model currently being developed for the study of CST
in RNA viruses.
A Bayesian statistical approach presents advantages over other analyses
for tracking CST origins. Computational techniques allow integration
over an unknown phylogeny, which cannot be directly observed, and
unknown migration process, which is usually poorly understood.
The Bayesian frameworks are also wellsuited to bring together
different kinds of information. The BEAST software, which has a strong
focus on calibrated phylogenies and genealogies, illustrates this by
offering a large number of complementary evolutionary models including
substitution models, demographic and relaxed clock models that can be
combined into a full probabilistic model. By adding spatial
reconstruction, these models create the probability of biogeographical history reconstruction from genetic data. This could be useful for determining origins of cross-species transmissions.
The high effectiveness of Bayesian statistical methods has made them instrumental in evolutionary studies.
Bayesian ancestral host reconstruction under discrete diffusion models
can be used to infer the origin and effects of pathogens associated with
CST. One study on Human adenoviruses using Bayesian supported a gorilla and chimpanzee origin for the viral species, aiding prevention efforts.
Despite presumably rare direct contact between sympatric populations of
the two species, CST events can occur between them. The study also
determined that two independent HAdV-B transmission events to humans
occurred and that the HAdV-Bs circulating in humans are of zoonotic
origin and have probably affected global health for most of our species
lifetime.
Phylogenetic diffusion models are frequently used for
phylogeographic analyses, with the inference of host jumping becoming of
increasing interest.
The Bayesian inference approach enables model averaging over a number
of potential diffusion predictors and estimates the support and
contribution of each predictor while marginalizing over phylogenetic
history.
For studying viral CST, the flexibility of the Bayesian statistical
framework allows for the reconstruction of virus transmission between
different host species while simultaneously testing and quantifying the
contribution of multiple ecological and evolutionary influences of both
CST spillover and host shifting. One study on rabies in bats showed geographical range overlap is a modest predictor for CST, but not for host shifts.[3] This highlights how Bayesian inferences in models can be used for CST analysis.