1 Lyme group spirochete and is not considered
zoonotic.
2 s is currently unknown but is presumed to be
zoonotic.
3 hese results strongly suggest ongoing direct
zoonotic acquisition of STLV-1 in humans through severe
4 hosphorylated genome, is a highly pathogenic
zoonotic agent with significant public health implicatio
5 act as an avian pathogen and possibly also a
zoonotic agent.
6 e they pose a threat to human health as both
zoonotic agents and potential pandemic candidates.
7 Leptospirosis is
zoonotic and emerging infectious disease of global impor
8 for investigation and aid in the control of
zoonotic and emerging infectious diseases.
9 and Hendra virus (HeV) are recently emergent
zoonotic and highly lethal pathogens with pandemic poten
10 l variants may pose the greatest threats for
zoonotic and pandemic emergence.IMPORTANCE Avian influen
11 of pigs in which novel strains of IAVs with
zoonotic and pandemic potential can emerge.
12 The former two species are
zoonotic and the latter is thought to infect only humans
13 Rift Valley fever (RVF) is a
zoonotic and vector-borne disease, mainly present in Afr
14 as intermediate hosts in which viruses with
zoonotic and/or pandemic potential could originate, part
15 iven species and the proportion likely to be
zoonotic are predictable.
16 pigs and supporting further investigation of
zoonotic Ascaris transmission in the United States.
17 However, little is known about how
zoonotic bacteria maintain the ability to colonize multi
18 a and influenza, (iii) enteric disease, (iv)
zoonotic bacterial disease, and (v) fungal disease.
19 the same facility, is cross-contamination of
zoonotic bacterial pathogens especially Salmonella.
20 emergence of host generalist lineages of the
zoonotic bacterium Campylobacter.
21 detected in humans, but they are potentially
zoonotic because they infect other mammalian hosts.
22 the only animal prion disease reputed to be
zoonotic,
causing variant Creutzfeldt-Jakob disease (vCJ
23 this end, we selected a strain from the main
zoonotic clonal-complex, obtained a mutant in the ferric
24 notic S. suis clone that diverged from a non-
zoonotic clone by means of gene loss, a capsule switch,
25 In 2012, a
zoonotic coronavirus was identified as the causative age
26 Two
zoonotic coronaviruses (CoVs)-SARS-CoV and MERS-CoV-have
27 iloviruses, henipaviruses, lyssaviruses, and
zoonotic coronaviruses.
28 dly SARS-CoV and MERS-CoV) and their related
zoonotic CoVs, our structure of HCoV-NL63 M(pro) provide
29 ogenic Leptospira bacteria are maintained in
zoonotic cycles involving a diverse array of mammals, wi
30 ely contributes to the paucity of detectable
zoonotic cynomolgi malaria.
31 llular Gram-negative bacteria that cause the
zoonotic disease brucellosis, one of the most common glo
32 Background Babesiosis, a tickborne
zoonotic disease caused by intraerythrocytic protozoa of
33 Bovine tuberculosis (TB) is a
zoonotic disease caused by Mycobacterium bovis.
34 oci for Rhodesian sleeping sickness, a fatal
zoonotic disease caused by trypanosomes transmitted by t
35 hich regions are at greatest risk for future
zoonotic disease emergence are two goals which both requ
36 experiments to test underlying mechanisms of
zoonotic disease emergence.
37 Rift Valley fever (RVF) is a mosquito-borne
zoonotic disease endemic to Africa and characterized by
38 The increasing frequency of
zoonotic disease events underscores a need to develop fo
39 erium and tier 1 biothreat, causes the fatal
zoonotic disease glanders.
40 worldwide and is increasingly implicated in
zoonotic disease in East and South-East Asia.
41 us (Macacine herpesvirus 1) can cause deadly
zoonotic disease in humans.
42 Animal viruses frequently cause
zoonotic disease in humans.
43 ial pathogen and an etiological agent of the
zoonotic disease known as brucellosis.
44 genetic information is available, and their
zoonotic disease potential remains unknown.
45 ular Gram-negative bacterium that causes the
zoonotic disease Q fever.
46 h also comprise a disproportionate number of
zoonotic disease reservoirs.
47 Swine influenza is a highly contagious
zoonotic disease that threatens animal and public health
48 urnetii is the causative agent of Q fever, a
zoonotic disease that threatens both human and animal he
49 s through axons.IMPORTANCE Rabies is a fatal
zoonotic disease with a nearly 100% case fatality rate.
50 ospirosis is a life-threatening and emerging
zoonotic disease with a worldwide annual occurrence of m
51 Zoonotic diseases are a major cause of morbidity, and pr
52 As the frequency and prevalence of
zoonotic diseases increase worldwide, investigating how
53 For many
zoonotic diseases it is difficult to attribute human cas
54 thesis remains controversial, especially for
zoonotic diseases of humans.
55 To mitigate the effects of
zoonotic diseases on human and animal populations, it is
56 ility to generate testable predictions about
zoonotic diseases originating from wild mammals.
57 s are increasingly being seen as a source of
zoonotic diseases, including malaria and rickettsiosis.
58 g new approaches for treating and preventing
zoonotic diseases.
59 y of stemming and alleviating the impacts of
zoonotic diseases.
60 obal hotspot map of spatial variation in our
zoonotic EID risk index, and partial dependence plots il
61 ccounting for reporting effort, we show that
zoonotic EID risk is elevated in forested tropical regio
62 China during 2010 to 2013, which led to the
zoonotic emergence of H7N9 viruses.
63 epidemic highlights a recurring trend in the
zoonotic emergence of virulent pathogens likely to come
64 is assessed, for example, in the context of
zoonotic emergence, antigenic escape, and drug resistanc
65 m preexisting immunity and the potential for
zoonotic emergence.
66 Nipah virus (NiV) is a
zoonotic emerging paramyxovirus that can cause fatal res
67 These
zoonotic events are enabled by the specific interaction
68 No
zoonotic exposures were identified.
69 ST283 is a
zoonotic GBS clone associated with farmed freshwater fis
70 iated with clonal complex 1, the predominant
zoonotic genotype.
71 Reconstruction of the phylogenies of
zoonotic genotypes demonstrates significant interminglin
72 sma and those of the relatively understudied
zoonotic genus Babesia In humans, babesiosis, particular
73 in Streptococcus suis, an important emerging
zoonotic Gram-positive bacterium, while only RelA is fun
74 This study investigated the N9 NA from a
zoonotic H7N9 virus strain in order to determine its pos
75 urified protein and virus that the NA of the
zoonotic H7N9 viruses has a binding capacity via both th
76 Zoonotic helminth exposure in Norway was less frequent i
77 However,
zoonotic helminths, such as Toxocara species (spp.), hav
78 virus, human metapneumovirus, and the deadly
zoonotic henipaviruses Hendra and Nipah virus (NiV).
79 th spiked human samples as well as human and
zoonotic host backgrounds.
80 nderstanding of the current distributions of
zoonotic hosts and pathogens.
81 asting these patterns against global maps of
zoonotic hosts from all 27 orders of terrestrial mammals
82 s at risk of infection due to spillover from
zoonotic hosts or vectors, identifying where index cases
83 have been identified in this region, but the
zoonotic impact in Asia remains unknown.
84 In conclusion, this study reveals
zoonotic implications for HuNoV, and to elucidate the si
85 vine tuberculosis (bTB), a disease of global
zoonotic importance.
86 lyzed the impact of these deletions on virus
zoonotic infection characteristics and fitness.
87 e test our "drifted" viruses to assess their
zoonotic infection characteristics and transmissibility
88 Hepatitis E virus (HEV) is considered a
zoonotic infection in developed nations.
89 To minimize associated risks of
zoonotic infection or transmission of unknown pathogens
90 bles straightforward attribution of cases of
zoonotic infection to putative sources of infection.
91 likely to be important in protection against
zoonotic infection with FeLV.IMPORTANCE Domestic exposur
92 respectively, is recognized as an important
zoonotic infection worldwide.
93 deforestation may be particularly exposed to
zoonotic infections because of the higher likelihood for
94 insights into how to prevent and fight human
zoonotic infections caused by bat-borne viruses.
95 The increasing number of
zoonotic infections caused by influenza A virus (IAV) su
96 g many wild and domestic animals and causing
zoonotic infections in humans.
97 (H7N9) viruses have caused a large number of
zoonotic infections since their emergence in 2013.
98 e research because of bioterrorism concerns,
zoonotic infections, and the side effects of existing sm
99 posure is a major risk factor for human H7N9
zoonotic infections, for which the mode of transmission
100 Yersinia species cause
zoonotic infections, including enterocolitis and plague.
101 Both SARS-CoV and MERS-CoV are
zoonotic infections, with bats as the primary source.
102 enhanced neuropathogenicity associated with
zoonotic infections.
103 nto the neuropathogenicity of B virus during
zoonotic infections.
104 in Europe, raising concerns about potential
zoonotic infections.
105 tor for the spread of livestock diseases and
zoonotic infections.
106 on.IMPORTANCE Human monkeypox is an emerging
zoonotic infectious disease caused by Monkeypox virus (M
107 enza subtype H5N1 (HPAI H5N1) is a worldwide
zoonotic infectious disease, threatening humans, poultry
108 Human monkeypox is considered an emerging
zoonotic infectious disease.
109 lley fever (RVF), an emerging mosquito-borne
zoonotic infectious viral disease caused by the RVF viru
110 nfluenza virus, in 1958, 16 different novel,
zoonotic influenza A virus subtype groups in 29 countrie
111 Two
zoonotic influenza A viruses (IAV) of global concern, H5
112 The pandemic threat posed by emerging
zoonotic influenza A viruses necessitates development of
113 uring the assessment of the pandemic risk of
zoonotic influenza A viruses.
114 Human infections with
zoonotic influenza virus subtypes continue to be a great
115 ially prominent in pandemic viruses and some
zoonotic influenza viruses causing human infections.
116 id ongoing risk assessment analyses as these
zoonotic influenza viruses continue to circulate and ada
117 need for continuous surveillance of emerging
zoonotic influenza viruses inclusive of mammalian specie
118 Cross-species transmission of
zoonotic influenza viruses increases public health conce
119 Influenza pandemics occur unpredictably when
zoonotic influenza viruses with novel antigenicity acqui
120 Zoonotic influenza viruses, such as A(H5N1) and A(H7N9)
121 aid in the continuous surveillance of these
zoonotic influenza viruses.
122 Babesia microti, a
zoonotic intraerythrocytic parasite, is the primary etio
123 ember 2013 in Guinea, probably from a single
zoonotic introduction.
124 Zoonotic isolates have smaller genomes than non-zoonotic
125 notic isolates have smaller genomes than non-
zoonotic isolates, but contain more virulence factors.
126 In Malaysia, where both species are common,
zoonotic knowlesi malaria has recently become dominant,
127 an and environmental factors associated with
zoonotic knowlesi malaria risk.
128 As the primary reservoir host of the
zoonotic Lassa virus, a landscape genetics approach may
129 ic pathways, such as pectinolysis within the
zoonotic marine pathogen V. vulnificus.
130 The transmission routes and risk factors for
zoonotic Middle East respiratory syndrome coronavirus (M
131 Japanese encephalitis is an acute
zoonotic,
mosquito-borne disease caused by Japanese ence
132 Building on a previously published
zoonotic niche map, this study incorporates new human an
133 MERS-CoV has a
zoonotic origin and poses a major threat to public healt
134 A
zoonotic origin of infection was suggested, as both indi
135 p among porcine and human strains suggesting
zoonotic origin of Taiwanese human G9 strains detected i
136 To determine factors involved in the
zoonotic origin of the 1957 pandemic, we performed analy
137 merging infectious diseases in humans are of
zoonotic origin.
138 nd include the pathogenic human pathogens of
zoonotic origin: severe acute respiratory syndrome CoV (
139 However, the
zoonotic origins of the 2009 A/H1N1 influenza pandemic v
140 e the potential to cause a future HIV-1-like
zoonotic outbreak.
141 easonal epidemics, infrequent pandemics, and
zoonotic outbreaks.
142 Hendra virus (HeV) is a
zoonotic paramyxovirus that causes deadly illness in hor
143 Nipah virus (NiV) is a
zoonotic paramyxovirus that causes high mortality rates
144 irus (NiV) is a highly pathogenic and deadly
zoonotic paramyxovirus.
145 , human respiratory syncytial virus, and the
zoonotic paramyxoviruses Nipah virus and Hendra virus.
146 .IMPORTANCE Hendra virus and Nipah virus are
zoonotic paramyxoviruses that cause lethal infections in
147 Toxocara canis is a
zoonotic parasite of major socioeconomic importance worl
148 The
zoonotic parasite Plasmodium knowlesi has become the mos
149 the main risk factors for the spread of the
zoonotic parasite Taenia solium.
150 Using the
zoonotic parasite Toxoplasma gondii in California, USA a
151 Plasmodium knowlesi is a
zoonotic parasite transmitted from macaques causing mala
152 of sheltered and stray dogs as reservoirs of
zoonotic parasites in different parts of the world, espe
153 significant evidence for dilution effects of
zoonotic parasites of humans.
154 Sheltered and stray dogs, exposed to
zoonotic parasites, including protozoa, helminths, and a
155 inue to represent an important reservoir for
zoonotic parasites.
156 on, and intracellular survival of the global
zoonotic pathogen Brucella abortus.
157 alley fever virus (RVFV) is a mosquito-borne
zoonotic pathogen causing disease outbreaks in Africa an
158 Brucella melitensis is a well-adapted
zoonotic pathogen considered a scourge of mankind since
159 e learning to data describing the traits and
zoonotic pathogen diversity of the most speciose group o
160 time-kill experiments were conducted with a
zoonotic pathogen Pasteurella multocida and the fluoroqu
161 AS for investigating transmission in natural
zoonotic pathogen populations and provides evidence that
162 UK Equine Hospital, identifying an emerging
zoonotic pathogen so far only sporadically recorded in t
163 Streptococcus suis is a neglected
zoonotic pathogen that has to adapt to the nutritional r
164 As a
zoonotic pathogen that primarily affects livestock, RVFV
165 a causative agent of Lyme borreliosis, is a
zoonotic pathogen that survives in nutrient-limited envi
166 Campylobacter jejuni is an important
zoonotic pathogen transmitted to humans mainly via the f
167 Campylobacter jejuni is a
zoonotic pathogen, and a hypervirulent clone, named clon
168 Campylobacter jejuni is a major
zoonotic pathogen, and its resistance to antibiotics is
169 ng the host range and tissue tropism of this
zoonotic pathogen.
170 d a potential target for the control of this
zoonotic pathogen.
171 Human health risks from exposure to
zoonotic pathogens aerosolized during manure irrigation
172 high probabilities of harboring undiscovered
zoonotic pathogens based on trait profiles that may serv
173 timate human health risks due to aerosolized
zoonotic pathogens downwind of spray-irrigated dairy man
174 rations of manure-borne fecal indicators and
zoonotic pathogens during 21 full-scale dairy manure irr
175 ociated with inhalation exposure to airborne
zoonotic pathogens emitted following application of dair
176 The emerging
zoonotic pathogens Hendra virus (HeV) and Nipah virus (N
177 trast, populations of the reservoir hosts of
zoonotic pathogens often appear to tolerate these infect
178 pylobacter jejuni and Campylobacter coli are
zoonotic pathogens once considered asaccharolytic, but a
179 pulations can help to predict the risks that
zoonotic pathogens pose to humans.
180 a, and influenza, and the emergence of novel
zoonotic pathogens represent major clinical management c
181 ck-borne viruses include medically important
zoonotic pathogens that can cause life-threatening disea
182 uses (CoVs), several of which are related to
zoonotic pathogens that cause severe disease in humans.
183 Hantaviruses are
zoonotic pathogens that cause severe hemorrhagic fever a
184 oviruses, Ebola virus and Marburg virus, are
zoonotic pathogens that cause severe hemorrhagic fever i
185 Marburg (MARV) and Ebola (EBOV) viruses are
zoonotic pathogens that cause severe hemorrhagic fever i
186 Influenza A viruses (IAV) are
zoonotic pathogens that pose a major threat to human and
187 However, microbial strain typing allows
zoonotic pathogens to be categorised, and the relative f
188 phylococcus intermedius group (SIG) includes
zoonotic pathogens traditionally associated with dog bit
189 Zoonotic pathogens were more climate sensitive than huma
190 e, may serve as overlooked vectors/hosts for
zoonotic pathogens, and the amphibian IFN system provide
191 Rickettsiales are important
zoonotic pathogens, causing severe disease in humans glo
192 clinical symptoms in bats but are dangerous
zoonotic pathogens, like Ebola or rabies virus.
193 antimicrobial roles in infections caused by
zoonotic pathogens, such as influenza viruses and Lister
194 ase the risk of exposure to vector-borne and
zoonotic pathogens.
195 nus Toxocara are socioeconomically important
zoonotic pathogens.
196 he simian arteriviruses may be "preemergent"
zoonotic pathogens.
197 Human coronaviruses are important
zoonotic pathogens.
198 fluenza virus (SwIV) is one of the important
zoonotic pathogens.
199 could be used as an early detection tool of
zoonotic pathogens.
200 sk 'Are bats special reservoirs for emerging
zoonotic pathogens?' We collate evidence from the past d
201 ndrome coronavirus (MERS-CoV) highlights the
zoonotic potential of Betacoronaviruses.
202 The
zoonotic potential of CWD is unknown, as well as the mec
203 CoV) into human populations demonstrates the
zoonotic potential of emerging coronaviruses, and there
204 We discuss the
zoonotic potential of host species from the top six most
205 n studies are necessary to better assess the
zoonotic potential of other prion diseases with high pre
206 Our results indicate that
zoonotic potential of S. suis results from gene loss, re
207 nsmissions to humanized mice showed that the
zoonotic potential of scrapie might be similar to c-BSE.
208 This study assessed the prevalence and
zoonotic potential of Shiga toxin-producing Escherichia
209 serotype and genotype, which can explain the
zoonotic potential of SS2.
210 nfect canine and human cells might reflect a
zoonotic potential of these recently identified bat viru
211 its pathogenesis, epidemiology and possible
zoonotic potential of this emerging virus.
212 te sequences can be applied to predict their
zoonotic potential, identifying cattle strains more like
213 r viral traits are significant predictors of
zoonotic potential, providing a novel framework to asses
214 dentify genomic differences that can explain
zoonotic potential, we compared whole genomes of 98 S. s
215 e targeted at herds carrying strains of high
zoonotic potential.
216 olution and the emergence of novel CoVs with
zoonotic potential.
217 usceptible to poxvirus infections, including
zoonotic poxvirus transmission.
218 ions, suggesting the presence of a potential
zoonotic reservoir for this assemblage.
219 ther prime example of virus emergence from a
zoonotic reservoir.
220 Key predictors of
zoonotic reservoirs include biogeographical properties,
221 tic abortion of ewes and poses a significant
zoonotic risk for pregnant women.
222 ost up-to-date estimate of the extent of EVD
zoonotic risk in Africa.
223 ion of assemblage E in humans suggests a new
zoonotic route of Giardia transmission.
224 We identified a
zoonotic S. suis clone that diverged from a non-zoonotic
225 ciated with food-borne transmission in Asia,
zoonotic S. suis infections are mainly occupational haza
226 t respiratory disease, and is related to the
zoonotic SARS and MERS betacoronaviruses, which have hig
227 avirus (CoV) is an emerging CoV with a known
zoonotic source in dromedary camels.
228 viruses, providing an intriguing clue to the
zoonotic source of hepatitis C virus.
229 investigation was performed to identify the
zoonotic source.
230 t coronaviruses are currently spreading from
zoonotic sources and can be highly pathogenic, causing s
231 e coronavirus (MERS-CoV) infects humans from
zoonotic sources and causes severe pulmonary disease.
232 syndrome coronavirus (SARS-CoV) emerged from
zoonotic sources in 2002 and caused over 8,000 infection
233 thogenic respiratory virus that emerged from
zoonotic sources in 2012.
234 thogenic respiratory virus that emerged from
zoonotic sources in 2012.
235 ic threats are caused by viruses from either
zoonotic sources or vector-borne sources.
236 Outbreaks from
zoonotic sources represent a threat to both human diseas
237 n future experimental investigations of this
zoonotic species.
238 the epidemiologic circumstances involved in
zoonotic spillover, amplification, and spread of disease
239 nd human IAVs, facilitating the emergence of
zoonotic strains.
240 evolution of influenza A viruses, including
zoonotic strains.
241 hreat of emergence for currently circulating
zoonotic strains.
242 ZoonoticS.
suisinfections are emerging in humans causing
243 Streptococcus suis is a
zoonotic swine pathogen and a major public health concer
244 es, significant respiratory pathogens, and a
zoonotic threat.
245 ts, illustrates the potential for widespread
zoonotic transmission and adds to the known aetiologies
246 therefore, to be a requirement for efficient
zoonotic transmission and human disease potential.
247 rigin of the virus is thought to have been a
zoonotic transmission from a bat to a two-year-old boy i
248 makes it impossible to determine the role of
zoonotic transmission in epidemiology.
249 Adaptation is critical for pathogens after
zoonotic transmission into a new host species or to achi
250 ns and wildlife are genetically similar, and
zoonotic transmission might play a potential role in hum
251 protein represents a potent barrier against
zoonotic transmission of avian influenza viruses.
252 vides a basis for age-restricted tropism and
zoonotic transmission of G10P[11] rotaviruses.
253 This might contribute to
zoonotic transmission of H7N9 and to the severe to fatal
254 e have been increasing reports of food-borne
zoonotic transmission of hepatitis E virus (HEV) genotyp
255 Zoonotic transmission of influenza A viruses can give ri
256 that GPC cleavage represents no barrier for
zoonotic transmission of these pathogens.
257 Rapid change and
zoonotic transmission to humans have enhanced the virule
258 rocally harbor alphaherpesviruses poised for
zoonotic transmission to humans.
259 cificity and there is no evidence supporting
zoonotic transmission, so an animal reservoir is conside
260 To mimic
zoonotic transmission, two ferrets were exposed to a pla
261 ely few data are available for evaluation of
zoonotic transmission.
262 poxvirus infections can be acquired through
zoonotic transmission.
263 N9 subtypes which have been associated with
zoonotic transmission.
264 haracterized by sporadic outbreaks caused by
zoonotic transmission.
265 The burden of
zoonotic tuberculosis in people needs important reassess
266 These challenges faced by people with
zoonotic tuberculosis might not be proportional to the s
267 ystematic review and meta-analysis of global
zoonotic tuberculosis showed that the same challenges an
268 derestimated in human beings as the cause of
zoonotic tuberculosis.
269 lso observed in isolates from an outbreak of
zoonotic vaccinia virus that occurred in Brazil.
270 human cell lines to FeLV-B, the most likely
zoonotic variant.
271 ven epidemiological classes (human-specific,
zoonotic,
vector-borne, non-vector-borne, bacterial, vir
272 ses high fatality rates when it spreads from
zoonotic vectors into the human population.
273 CCHFV is an emerging
zoonotic virus that causes often-fatal hemorrhagic fever
274 iratory syndrome coronavirus is considered a
zoonotic virus that has crossed the species barrier to h
275 ty.IMPORTANCE MERS-CoV is a recently emerged
zoonotic virus that is still circulating in the human po
276 esented an example of invasion dynamics of a
zoonotic virus where stochastic fadeout have played a ma
277 Diseases caused by
zoonotic viruses (viruses transmittable between humans a
278 NHPs) are a historically important source of
zoonotic viruses and are a gold-standard model for resea
279 rol study for investigating the evolution of
zoonotic viruses compared to single-host viruses, using
280 key component in phylogeographic analysis of
zoonotic viruses involves identifying the specific locat
281 lling for research effort, the proportion of
zoonotic viruses per species is predicted by phylogeneti
282 Since
zoonotic viruses rely on viral proteins to recognize, or
283 harbour a significantly higher proportion of
zoonotic viruses than all other mammalian orders.
284 Henipaviruses are
zoonotic viruses that can cause severe and acute respira
285 Mammalian arenaviruses are
zoonotic viruses that cause asymptomatic, persistent inf
286 Hantaviruses are
zoonotic viruses that show various degrees of vasculopat
287 smission mechanisms involved in spillover of
zoonotic viruses to date, and discover that viruses with
288 fluenza in pigs and reduce the potential for
zoonotic viruses to emerge.
289 Bats host a large number of
zoonotic viruses, including several viruses that are hig
290 Bats serve as a reservoir for various, often
zoonotic viruses, including significant human pathogens
291 ats are natural reservoir hosts for numerous
zoonotic viruses, little is known about the long-term dy
292 history and the evolution dynamics of these
zoonotic viruses, originating from and hosted by wild an
293 to inhibit in vitro replication of human and
zoonotic viruses, representing 16 HA subtypes.
294 Zoonotic viruses, such as HIV, Ebola virus, coronaviruse
295 implications for surveillance on potentially
zoonotic viruses.
296 ive species barrier that must be overcome by
zoonotic viruses.
297 ence and pathogenic potential of circulating
zoonotic viruses.
298 icle, we introduce and review three emerging
zoonotic viruses.
299 Bats are asymptomatic reservoirs for many
zoonotic viruses.
300 ty of human emerging infectious diseases are
zoonotic,
with viruses that originate in wild mammals of