Literature DB >> 33966919

New Approaches to Anticipate the Risk of Reverse Zoonosis.

Peng Jia1, Shaoqing Dai2, Tong Wu3, Shujuan Yang4.   

Abstract

The coronavirus disease 2019 (COVID-19) pandemic can cause reverse zoonoses (i.e., human-animal transmission of COVID-19). It is vital to utilize up-to-date methods to improve the control, management, and prevention of reverse zoonoses. Awareness of reverse zoonoses should be raised at both individual and regional/national levels for better protection of both humans and animals.
Copyright © 2021 Elsevier Ltd. All rights reserved.

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Mesh:

Year:  2021        PMID: 33966919      PMCID: PMC8100872          DOI: 10.1016/j.tree.2021.03.012

Source DB:  PubMed          Journal:  Trends Ecol Evol        ISSN: 0169-5347            Impact factor:   20.589


Human Activities Exacerbate the Risks from Zoonotic Diseases

The COVID-19 has been the most widespread zoonotic pandemic to affect humanity in over a century, reflecting the problem of human activities exacerbating the risks of pathogen spillover, such as hunting, butchering, farming, deforestation, reforestation, irrigation, and traveling. Moreover, it has caused ecological feedbacks at local scales (e.g., bi-directional transmission of COVID-19 between animals and humans, which could augment the COVID-19 risk in both animals and humans). Understanding these feedbacks is crucial to mitigating zoonotic disease risks, which requires transdisciplinary collaborative research on pandemic risks among multiple fields, including epidemiology, virology, public health, geography, and ecology [1,2].

Reverse Zoonosis of COVID-19

Infection of animals with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) from humans has highlighted the importance of understanding ‘reverse zoonosis’ (zooanthroponosis). Compared with three of the four possible routes of transmission for zoonotic diseases (i.e., animal–human, animal–animal, human–human), which have been well studied and confirmed [3], human–animal transmission lacks sufficient research due to the rare occurrence prior to COVID-19 [4]. Once such reverse zoonosis occurs it may cause the further evolution of viruses and affect the effectiveness of potential COVID-19 vaccines [5]. Given the growing populations of livestock and other domesticated animals, increasing proximity between animals and humans in multiple settings (e.g., wet markets, home, and animal production facilities), and the relatively fewer resources assigned for animal testing during human outbreaks with zoonotic potential (particularly asymptomatic infections), new animals diseases may spread undetected. Proactive consideration of such reverse zoonosis enables the creation of management strategies. Therefore, reverse zoonoses require more rigorous and widespread macroecological and microbial studies. As of 11 March 2021, the 1 year anniversary of the official declaration of COVID-19 pandemic by the World Health Organization (WHO), a total of 167 natural infections (i.e., SARS-CoV-2 positive) in 11 species of animals (excluding mink), both domesticated and captive, have been reported in 25 countries during the COVID-19 pandemic (Figure 1 ), with the origin of the infection probably being human COVID-19 cases in different settings (Table 1 ). Two peaks of reporting of pet infection were between July and August 2020 and between December 2020 and February 2021. Cat infection emerged 1 month later than dog infection, but has had a faster and stable increase and a larger total number of infections reported (86 versus 56). SARS-CoV-2 was mostly detected in their oral, throat, nasal, and rectal swabs. About 38% (64/167) of the infected animals showed digestive and respiratory symptoms and flu signs, with the remainder not showing any signs of illness. However, their contaminated fecal matter and urine could still transmit the virus to exposed humans if they are unaware of that risk [6]. Also, lions, pumas, and tigers at zoos, all belonging to the same family as cats (Felidae), were infected by asymptomatic and symptomatic patients in two countries (USA and South Africa), with SARS-CoV-2 detected in their fecal samples. About 73% of the infected zoo animals were reported in January and February 2021. In addition to pet and zoo animals, 138 infected mink farms were reported in 11 countries, with about 90% in Europe and 10% in North America (most in The Netherlands, 36%, followed by Denmark, 21%, and Greece, 20%). The mink in 15 out of 138 farms showed signs of illness, including respiratory symptoms and death, with SARS-CoV-2 detected in lung and throat/rectal swabs.
Figure 1

Coronavirus Disease 2019 (COVID-19) Natural Infections of Pet, Zoo, and Livestock Animals as of 11 March 2021 Mapped onto Number of Confirmed Cases in the Human Population.

Data for human confirmed cases from https://covid19.who.int/ and data for animal cases from https://www.oie.int/en/scientific-expertise/specific-information-and-recommendations/questions-and-answers-on-2019novel-coronavirus/events-in-animals/, https://www.avma.org/resources-tools/animal-health-and-welfare/covid-19/depth-summary-reports-naturally-acquired-sars-cov-2, and https://www.aphis.usda.gov/aphis/ourfocus/animalhealth/SA_One_Health/sars-cov-2-animals-us.

Table 1

COVID-19 Natural Infections of Pet, Zoo, and Livestock Animals and Experimental Infections as of 11 March 2021a

AnimalReporting dateRegionSourcebMethod (Samples) of initial diagnosiscLocation of infectiondSymptoms
Cat (Felis catus)2020/03/27BelgiumCPCR (feces, vomit)HomeDiarrhea, nausea, and respiratory symptoms
2020/04/03Hong Kong, ChinaCPCR (oral cavity, nasal, rectal)HomeNA
2020/04/22New York, USACPCRHomeOcular discharge and sneezing
2020/04/22New York, USACPCRHomeOcular discharge and sneezing
2020/05/01Paris, FranceCPCR (rectal)HomeNA
2020/05/08Catalonia, SpainCPCR (nasal cavity, gastrointestinal tract)HomeNA
2020/05/12Bordeaux, FranceCPCR (nasopharyngeal)HomeCough and respiratory symptoms
2020/05/13Upper Palatinate, Bavaria, GermanyCPCR (throat swab)HomeDied
2020/05/15The NetherlandsNAPCR, AbMink farmNA (Seropositive but PCR negative)
2020/05/15The NetherlandsNAPCR, AbMink farmNA (Seropositive but PCR negative)
2020/05/15The NetherlandsNAPCR, AbMink farmNA (Seropositive but PCR negative)
2020/05/21La Rioja, SpainCPCR (oropharyngeal swab)HomeNA
2020/05/26Moscow, RussiaNAPCR (throat, nasal swab)NANA
2020/06/01Minnesota, USACPCRHomeDepression, fever, and harsh lung sounds
2020/06/10Illinois, USACPCRHomeDepression, fever, and harsh lung sounds
2020/07/09California, USAEPCRHomeHeart murmur, hypothermia, respiratory symptoms, and tachypnea
2020/07/22Utah, USAEAbNANA
2020/07/22Utah, USAEAbNANA
2020/07/22Utah, USAEAbNANA
2020/07/22Utah, USAEAbNANA
2020/07/23Texas, USACPCRHomeNA
2020/07/24Hong Kong, ChinaCPCR (oral swab)HomeNA
2020/07/27South England, UKCPCR, Ab (oral swab)HomeRespiratory symptoms of feline herpes virus
2020/07/30Texas, USACPCRHomeNA
2020/08/10Hong Kong, ChinaCPCR (swab)HomeNA
2020/08/10Hong Kong, ChinaCPCR (swab)HomeNA
2020/08/10Hong Kong, ChinaCPCR (swab)HomeNA
2020/08/12New York, USAEAbShelterNA
2020/08/12New York, USAEAbShelterNA
2020/08/13Texas, USAEPCRHomeNA
2020/08/19Hong Kong, ChinaCPCR, Ab (swab)HomeNA
2020/08/25Arizona, USACAbShelterNA
2020/08/27California, USACPCRHomeVery mild respiratory symptoms
2020/08/27Georgia, USACPCR (Mycoplasma felis)HomeHyperthyroidism and respiratory symptoms
2020/08/27Louisiana, USACPCRHomeMild respiratory symptoms
2020/08/27Maryland, USACPCR (oropharyngeal swab)HomeMild respiratory symptoms
2020/09/02Texas, USACPCRNANA
2020/09/02Texas, USACPCRNANA
2020/09/02Texas, USACPCRNANA
2020/09/18SpainCPCR, Ab (nasal swabs, nasal turbinate, mesenteric lymph node)HomeSevere dyspnea
2020/09/24Kentucky, USACPCR, AbHomeCongestion, cough, increased respiratory rate, sneezing, and vomiting
2020/09/24New York, USACAbHomeNA
2020/10/02Texas, USACPCR, AbHomeNA
2020/10/09Alabama, USACPCR, AbHomeUpper respiratory symptoms, foaming from the nose, and neurologic symptoms, head pressing and staggering, in one case died
2020/10/22Santiago, ChileCPCR, Ab (nasal secretions, feces)HomeNA
2020/10/28Cuiaba, BrazilCPCRHomeNA
2020/10/31Pennsylvania, USACPCR, AbHomeDiarrhea and lethargy
2020/11/06Tokyo, JapanCPCRHomeNA
2020/11/18ArgentinaCPCRHomeNasal secretions and sneezing
2020/11/18ArgentinaCPCRHomeAnorexia and weakening for 12 to 24 hours
2020/11/18ArgentinaCPCRHomeNA
2020/12/04Hong Kong, ChinaCPCRHomeNA
2020/12/09ItalyNAPCR, AbNANA
2020/12/18Texas, USACPCRHomeCoughing and sneezing
2020/12/18Texas, USACPCRHomeCoughing and sneezing
2020/12/18Texas, USACPCRHomeNA
2020/12/18Texas, USACPCRHomeNA
2020/12/18Wisconsin, USACPCRHomeCongestion, lethargy, nasal discharge, sinus wheezing, and sneezing
2020/12/21Ontario, CanadaCPCRHomeMild respiratory symptoms
2020/12/23Thessaloniki, GreeceEPCR (pharyngeal, fecal)HomeNA
2021/01/08Florida, USACPCRHomeRespiratory symptoms
2021/01/08Hong Kong, ChinaCPCRHomeNA
2021/01/08Virginia, USACPCRHomeProgressive and severe respiratory distress
2021/01/14California, USACPCRHomeNA
2021/01/14Kansas, USACPCRHomeDry heaving, vocalizing, and vomiting
2021/01/22Arkansas, USACPCRHomeMucopurulent nasal discharge, open-mouthed breathing, suspicious of toxin ingestion, and ulcerated oral mucosa
2021/01/22BrazilCPCRHomeNA
2021/01/22BrazilCPCRHomeNA
2021/01/22BrazilCPCRHomeNA
2021/01/22BrazilCPCRHomeNA
2021/01/22BrazilCPCRHomeNA
2021/01/22Tennessee, USACPCRHomeFebrile respiratory symptoms
2021/01/28SwitzerlandCPCRHomeNA
2021/01/28SwitzerlandCPCRHomeNA
2021/02/03New Jersey, USAEAbNANA
2021/02/03New Jersey, USAEAbNANA
2021/02/05Connecticut, USACPCRHomeUpper respiratory symptoms
2021/02/05Florida, USACPCRHomeNA
2021/02/10British Columbia, CanadaCPCR (rectal, nasal, oral swabs)HomeNA
2021/02/10Ontario, CanadaCPCRHomeNA
2021/02/10Riga city, LatviaCPCRHomeMild depression
2021/02/10Riga city, LatviaCPCRHomeNA
2021/02/12Texas, USACPCRHomeNA
2021/02/12California, USACPCRHomeMild respiratory symptoms
2021/02/12Florida, USACPCRHomeConjunctivitis, coughing, and nasal discharge
2021/03/10EstoniaNAPCRNANA
Dog (Canis lupus familiaris)2020/02/28Hong Kong, ChinaCPCR (nasal, oral swab)HomeNA
2020/03/20Hong Kong, ChinaCPCR, AbHomeNA
2020/05/15The NetherlandsCPCRHomeNA
2020/06/02New York, USACPCR, AbHomeHemolytic anemia and severe lethargy
2020/06/24New York, USAEAbNANA
2020/06/24New York, USAEAbNANA
2020/07/02Georgia, USACPCR, AbHomeNA
2020/07/03North Jutland, DenmarkCPCRMink farmNA
2020/07/09Texas, USCPCRHomeNA
2020/07/17South Carolina, USACPCRHomeChronic health condition and mild respiratory symptoms
2020/07/22North Carolina, USAEAbShelterNA
2020/07/22Utah, USAEAbNANA
2020/07/22Utah, USAEAbNANA
2020/07/22Wisconsin, USAEAbNANA
2020/07/22Wisconsin, USAEAbNANA
2020/07/23Arizona, USACPCRHomeRespiratory symptoms
2020/08/03Louisiana, USAEPCRNANA
2020/08/10Hong Kong, ChinaCPCR (swab)HomeNA
2020/08/10Hong Kong, ChinaCPCR (swab)HomeNA
2020/08/13North Carolina, USACPCRHomeRespiratory distress
2020/08/13Texas, USACPCRHomeNA
2020/09/02Texas, USACPCRNANasal discharge
2020/09/02Texas, USACPCRNANA
2020/09/25Tokyo, JapanCPCR, AbHomeNA
2020/10/02Texas, USACPCRHomeCoughing and wheezing
2020/10/28Cuiaba, BrazilCPCRHomeNA
2020/10/28Ontario, CanadaCPCRHomeNA
2020/10/30Texas, USACPCR, AbHomeCrackling, increased respiratory rate, mild to moderate respiratory symptoms, and wheezing
2020/11/18Santiago del Estero, ArgentinaCPCRHomeConjunctivitis, cough, dyspnea, and weakening
2020/11/18Santiago del Estero, ArgentinaCPCRHomeNA
2020/11/18Santiago del Estero, ArgentinaCPCRHomeNA
2020/11/18Santiago del Estero, ArgentinaCPCRHomeNA
2020/11/27Hong Kong, ChinaCPCRHomeNA
2020/12/01Rhineland-Palatinate, GermanyCPCRHomeHigh respiratory distress and apathy
2020/12/11Hong Kong, ChinaCPCRHomeNA
2020/12/15MexicoCPCR, AbHomeNA
2020/12/18Florida, USACPCRHomeRespiratory symptoms
2020/12/18Florida, USACPCRHomeNA
2020/12/18Hong Kong, ChinaCPCRHomeNA
2020/12/18Kansas, USACPCRHomeNasal discharge
2020/12/18Pennsylvania, USACPCRHomeRespiratory symptoms
2020/12/21Arizona, USACAbHomeNA
2020/12/31Pennsylvania, USACPCR, AbHomeHemorrhagic diarrhea and lethargy
2021/01/07Benito Juarez, MexicoCPCRHomeNA
2021/01/08Florida, USACPCR, AbHomeNA
2021/01/21Toluca, MexicoCPCRHomeNA
2021/01/22Curitiba, BrazilCPCRHomeNA
2021/01/22Curitiba, BrazilCPCRHomeNA
2021/01/29California, USACPCRHomeNA
2021/02/03Bosnia and HerzegovinaCPCRHomeNA
2021/02/05Florida, USACPCRHomeDecreased appetite, lethargy, and productive cough
2021/02/05Iowa, USACPCRHomeNA
2021/02/09Hong Kong, ChinaCPCRHomeNA
2021/02/12Texas, USACPCR, AbHomeNA
2021/02/12California, USACPCR, AbHomeNA
2021/02/12Florida, USACPCR, AbHomeNA
Ferret (Mustela putorius furo)2020/12/23Celje, SloveniaCPCRHomeGastrointestinal tract
Gorilla (Gorilla gorilla)2021/01/12California, USACPCRZooMild respiratory symptoms
Jaguar (Panthera onca)2021/01/29Texas, USACPCRZooNA
Lion (Panthera leo)2020/04/06New York, USAAPCR (fecal)ZooDry cough and wheezing
2020/12/21Barcelona, SpainCPCR (nasal swab)ZooSerous nasal discharge, sneezing, and coughing
2021/01/15SwedenNAPCRZooInappetence, neurological and severe respiratory symptoms
2021/01/22EstoniaNAPCRZooSevere kidney failure and upper respiratory symptoms
2021/01/29Texas, USACPCRZooMild respiratory symptoms
2021/01/29Minnesota, USACPCRZooCough, inappetence, and wheezing
2021/02/10Texas, USACPCRZooCough, exercise intolerance, epistaxis, wheezing
Pig (Sus)2021/01/08Florida, USACPCRNANA
Puma (Puma concolor)2020/08/11Johannesburg, Gauteng, South AfricaCPCRZooNA
2021/01/29Minnesota, USACPCRZooCough, inappetence, and wheezing
2021/02/10Texas, USACPCRZooCough, epistaxis, exercise intolerance, wheezing
2021/02/18ArgentinaNAPCRZooNA
Rabbit (Oryctolagus cuniculus)2021/02/12Texas, USACPCRHomeNA
Snow leopard (Panthera uncia)2020/12/18Kentucky, USACPCRZooOccasional dry cough or wheezing and mild respiratory symptoms
Tiger (Panthera tigris)2020/04/07New York, USAAPCR (fecal)ZooDry cough and wheezing
2020/11/06Tennessee, USACPCRZooInappetence, lethargy, and mild cough
2021/01/15SwedenNAPCRZooNA
2021/01/29Minnesota, USACPCRZooInappetence, intermittent wheezing, and lethargy
2021/01/29Texas, USACPCRZooNA
2021/02/10Texas, USACPCRZooCough, exercise intolerance, epistaxis, and wheezing
2021/02/12Indiana, USACPCRZooDry cough
2021/02/12Indiana, USACPCRZooInappetence
Mink (Neovison vison)2020/04/15North Brabant, The NetherlandsCPCR (conchae, lung, throat swab, rectal swab)FarmRespiratory symptoms
2020/04/20North Brabant, The NetherlandsCPCR (conchae, lung, throat swab, rectal swab)FarmRespiratory symptoms
2020/05/08North Brabant, The NetherlandsCPCRFarmNA
2020/06/02North Brabant, The NetherlandsCPCRFarmNA
2020/06/09Limburg, The NetherlandsEPCR, AbFarmNA
2020/06/18Northern Jutland, DenmarkCPCRFarmNA
2020/07/03Northern Jutland, DenmarkCPCRFarmNA
2020/07/03Northern Jutland, DenmarkCPCRFarmRespiratory symptoms
2020/08/12Limburg, The NetherlandsEPCR, AbFarmNA
2020/08/12North Brabant, The NetherlandsEPCR, AbFarm (4)NA
2020/08/17Utah, USACPCRFarmRespiratory symptoms and sudden death
2020/08/19Utah, USACPCRFarmRespiratory symptoms and sudden death
2020/08/24Northern Jutland, DenmarkCPCRFarmInappetence and increased mortality
2020/08/25Utah, USACPCRFarmRespiratory symptoms and sudden death
2020/09/01North Brabant, The NetherlandsEPCRFarm (8)NA
2020/09/01Gelderland, The NetherlandsEPCRFarm (5)NA
2020/09/01Limburg, The NetherlandsEPCRFarmNA
2020/09/24Utah, USACPCRFarmIll thrift and sudden death
2020/10/01Northern Jutland, DenmarkNAPCRFarm (23)NA
2020/10/02Utah, USACPCRFarmNA
2020/10/06Gelderland, The NetherlandsEPCR, AbFarmNA
2020/10/06Limburg, The NetherlandsEPCR, AbFarm (7)NA
2020/10/06North Brabant, The NetherlandsEPCR, AbFarm (11)NA
2020/10/09Michigan, USACPCRFarmEpistaxis, inappetence, respiratory distress, sudden death
2020/10/09Wisconsin, USACPCRFarmEpistaxis, inappetence, respiratory distress, and sudden death in all cases, coffee-colored urine in black mink
2020/10/16Utah, USACPCRFarmOpen-mouth breathing and sudden death
2020/10/16Jutland, DenmarkEPCRFarmNA
2020/10/29Blekinge, SwedenEPCR (oral cavity, pharynx swab)FarmNA
2020/10/30Lombardia, Cremona, ItalyNAPCRFarm (9)NA
2020/11/05DenmarkNAPCRFarmNA
2020/11/06Blekinge, SwedenEPCR (oral cavity, pharynx swab)FarmNA
2020/11/16Utah, USACPCRFarmInappetence, mild respiratory symptoms, and sudden death
2020/11/16Wisconsin, USACPCRFarmInappetence and sudden death
2020/11/27Oregon, USACPCRFarmCough, inappetence, mild respiratory symptoms, and sneezing
2020/11/30Jonava, LithuaniaCPCRFarmNA
2020/12/01Blekinge, SwedenEPCRFarmNA
2020/12/09British Columbia, CanadaCPCRFarmNA
2020/12/15Western Macedonia, GreeceCPCRFarmNA
2020/12/19GreeceCPCRFarmNA
2020/12/21Ottawa, CanadaCPCRFarmNA
2020/12/30British Columbia, CanadaCPCRFarmDiarrhea
2020/12/31Siauliai, LithuaniaCPCRFarmNA
2021/01/06FranceNAPCR, AbFarmNA
2021/01/06Limburg, The NetherlandsEPCR, AbFarm (6)NA
2021/01/06North Brabant, The NetherlandsEPCR, AbFarmNA
2021/01/12Athens, GreeceCPCRFarmNA
2021/01/21Galicia, SpainCPCRFarmNA
2021/01/26Navatalgordo, Castilla y Leon, SpainCPCRFarmNA
2021/02/03Lezno, PolandCPCRFarmNA
2021/02/06Western Macedonia, GreeceCPCRFarmNA
2021/02/14GreeceCPCRFarm (23)NA
Experimental infection
Cat (Felis catus)NANANAPCR, Ab (nasal turbinate, soft palate, tonsil, trachea, lung, fecal)NAHigh susceptibility to SARS-CoV-2
Chicken (Gallus gallus domesticus)NANANAPCR, AbNANo susceptibility to SARS-CoV-2
Dog (Canis lupus familiaris)NANANAPCR, Ab (rectal swab)NALow susceptibility to SARS-CoV-2
Duck (Anas)NANANAPCR, AbNANo susceptibility to SARS-CoV-2
Ferret (Mustela putorius furo)NANANAPCR, Ab (nose swab, nasal turbinate, soft palate, tonsil, trachea)NAHigh susceptibility to SARS-CoV-2, fever, and inappetence
Fruit bat (Pteropodidae)NANANAPCR, Ab (nasal conchae, trachea, lung, tracheal lymph node, skin, duodenum tissue)NALow susceptibility to SARS-CoV-2 (potential reservoir hosts)
Golden hamster (Mesocricetus auratus)NANANAPCR, Ab (nasal turbinate, trachea, and lung)NAHigh susceptibility to SARS-CoV-2 and severe lung injury
Pig (Sus)NANANAPCR, AbNANo susceptibility to SARS-CoV-2
Rabbit (Oryctolagus cuniculus)NANANAPCR, Ab (nose, throat swab, nasal turbinate)NALow susceptibility to SARS-CoV-2
Rhesus macaque (Macaca mulatta)NANANAPCR, Ab (nose swab, oropharyngeal swab, throat swab, lung, bronchoalveolar lavage)NAHigh susceptibility to SARS-CoV-2, dehydration, inappetence, interstitial pneumonia, hunched posture, pale appearance, and piloerection tachypnea

Data from https://www.oie.int/en/scientific-expertise/specific-information-and-recommendations/questions-and-answers-on-2019novel-coronavirus/events-in-animals/, https://www.avma.org/resources-tools/animal-health-and-welfare/covid-19/depth-summary-reports-naturally-acquired-sars-cov-2, and https://www.aphis.usda.gov/aphis/ourfocus/animalhealth/SA_One_Health/sars-cov-2-animals-us

Sources: A, asymptomatic infected owners of pet animals or close contacts of other animals; C, confirmed infected owners of pet animals or close contacts of other animals; E, exposure to a probable or confirmed COVID-19 human case.

Ab, virus-neutralizing antibody; NA, not available; PCR, real-time reverse transcription-polymerase chain reaction.

Values in the parentheses represent the number of farms.

Coronavirus Disease 2019 (COVID-19) Natural Infections of Pet, Zoo, and Livestock Animals as of 11 March 2021 Mapped onto Number of Confirmed Cases in the Human Population. Data for human confirmed cases from https://covid19.who.int/ and data for animal cases from https://www.oie.int/en/scientific-expertise/specific-information-and-recommendations/questions-and-answers-on-2019novel-coronavirus/events-in-animals/, https://www.avma.org/resources-tools/animal-health-and-welfare/covid-19/depth-summary-reports-naturally-acquired-sars-cov-2, and https://www.aphis.usda.gov/aphis/ourfocus/animalhealth/SA_One_Health/sars-cov-2-animals-us. COVID-19 Natural Infections of Pet, Zoo, and Livestock Animals and Experimental Infections as of 11 March 2021a Data from https://www.oie.int/en/scientific-expertise/specific-information-and-recommendations/questions-and-answers-on-2019novel-coronavirus/events-in-animals/, https://www.avma.org/resources-tools/animal-health-and-welfare/covid-19/depth-summary-reports-naturally-acquired-sars-cov-2, and https://www.aphis.usda.gov/aphis/ourfocus/animalhealth/SA_One_Health/sars-cov-2-animals-us Sources: A, asymptomatic infected owners of pet animals or close contacts of other animals; C, confirmed infected owners of pet animals or close contacts of other animals; E, exposure to a probable or confirmed COVID-19 human case. Ab, virus-neutralizing antibody; NA, not available; PCR, real-time reverse transcription-polymerase chain reaction. Values in the parentheses represent the number of farms. Scientists have also carried out several different animal model experiments of SARS-CoV-2 (Table 1). To date, ten species of animals have been exposed to SARS-CoV-2 to test their susceptibility, with more species being tested. It was found that cats, ferrets, golden hamsters, and rhesus macaques had high susceptibility to SARS-CoV-2, while dogs, rabbits, and fruit bats had relatively low susceptibility; chickens, ducks, and pigs showed no susceptibility, although some predictions suggested that pigs were likely to be susceptible to SARS-CoV-2 [7]. Therefore, more scientific evidence is needed to confirm these findings.

Building Resilience against Future Reverse Zoonoses

Reverse zoonoses may cause reduction and even extinction of the wild animal populations susceptible to viruses, which could destroy local biodiversity and ecological balance [8]. The risk factors for and transmission routes of reverse zoonoses vary by animal type (e.g., pet, livestock, wildlife), which may not be fully identified and prevented by traditional methods. It is vital to take advantage of up-to-date methods to improve the control, management, and prevention of reverse zoonoses. Spatial and digital technologies, including location-based services, geographic information systems, and artificial intelligence, enable detection of pet owners’ history of contact with COVID-19 infection by monitoring and analyzing individual movement trajectories [9,10]. Once exposed to a COVID-19 risk, they should be notified via short message service and advised to monitor themselves and protect their pets from the risk. These technologies enable the chronology of infection to be determined, which, together with serosurveillance, may help reveal the direction of transmission between human and animal. Also, global positioning system and wearable sensors embedded in collars for farm livestock can monitor their daily activities and enable disease detection and monitoring of their health status [11]. Preventing reverse zoonoses also requires understanding pathogen feedback loops at the wildlife–livestock/pet–human interface. This will require greater capacities and commitments for pathogen discovery, mutation rate detection, and surveillance, in order to improve the prediction of pandemic potential, leading to management actions that interrupt possible pathways of spillover and transmission. Understanding these key evolutionary processes and ecological interactions calls for integrated virus–animal–human–environment surveillance systems. Spatial lifecourse epidemiology also provides a uniform analytical framework to link ecological surveillance to the national disease reporting system [12]. In the real world, the governance of all the key components (i.e., host, agent, vector, environment) can be substantially strengthened by the participation of the United Nations Environment Program in the tripartite collaboration among the WHO, the World Organization for Animal Health, and the Food and Agriculture Organization of the United Nations, which would help countries implement the One Health approach. There are several implications when considering and studying reverse zoonoses. At the individual level, awareness of reverse zoonoses should be raised for better self-protection, as it has extended our definition of population groups vulnerable to COVID-19, from those with closer and/or more frequent contact with people/patients (e.g., healthcare workers, safety guards, delivery service people) to those with closer and/or more frequent contact with animals (e.g., pet owners, farmers, zoo keepers), although the risk of pet–human transmission is currently considered to be low. More regulations should be prepared to raise awareness of COVID-19 risks among these vulnerable populations. At regional and national levels, due to limited resources for SARS-CoV-2 detection and containment measures for animals (especially for home pets), there could be a high likelihood of transmission, a lower recovery rate, and hence a large number of infections among animals, which would pose a severe threat to humans. Therefore, resources for SARS-CoV-2 detection should be reserved for testing animals that may be most at risk (e.g., pets of confirmed COVID-19 patients) and regulations should be made to manage infected and at-risk animals, especially at the farm. Attention should also be paid to animals on duty during the COVID-19, such as dogs that are used at airports in some countries to detect passengers infected with COVID-19. In addition, human–animal transmission would expand the total population in COVID-19 forecasting models to both humans and animals, the increased risk of which, together with animal–animal and animal–human transmission, should be considered in future COVID-19 forecasting models.
  11 in total

Review 1.  Emerging infectious diseases of wildlife--threats to biodiversity and human health.

Authors:  P Daszak; A A Cunningham; A D Hyatt
Journal:  Science       Date:  2000-01-21       Impact factor: 47.728

2.  COVID mink analysis shows mutations are not dangerous - yet.

Authors:  Smriti Mallapaty
Journal:  Nature       Date:  2020-11       Impact factor: 49.962

3.  China needs a national intelligent syndromic surveillance system.

Authors:  Peng Jia; Shujuan Yang
Journal:  Nat Med       Date:  2020-07       Impact factor: 53.440

4.  SARS-CoV-2 in fruit bats, ferrets, pigs, and chickens: an experimental transmission study.

Authors:  Kore Schlottau; Melanie Rissmann; Annika Graaf; Jacob Schön; Julia Sehl; Claudia Wylezich; Dirk Höper; Thomas C Mettenleiter; Anne Balkema-Buschmann; Timm Harder; Christian Grund; Donata Hoffmann; Angele Breithaupt; Martin Beer
Journal:  Lancet Microbe       Date:  2020-07-07

5.  Mainstreaming one health.

Authors:  Jakob Zinsstag; John S Mackenzie; Martyn Jeggo; David L Heymann; Jonathan A Patz; Peter Daszak
Journal:  Ecohealth       Date:  2012-07-10       Impact factor: 3.184

6.  Time to spatialise epidemiology in China.

Authors:  Peng Jia; Shujuan Yang
Journal:  Lancet Glob Health       Date:  2020-06       Impact factor: 26.763

7.  Spatiobehavioral Characteristics - Defining the Epidemiology of New Contagious Diseases at the Earliest Moment Possible.

Authors:  Shujuan Yang; Chao Yu; Peng Jia
Journal:  Trends Parasitol       Date:  2021-01-21

Review 8.  Middle East respiratory syndrome coronavirus: transmission and phylogenetic evolution.

Authors:  Jaffar A Al-Tawfiq; Ziad A Memish
Journal:  Trends Microbiol       Date:  2014-08-29       Impact factor: 17.079

Review 9.  Human animal interface of SARS-CoV-2 (COVID-19) transmission: a critical appraisal of scientific evidence.

Authors:  Rubal Singla; Abhishek Mishra; Rupa Joshi; Sonali Jha; Amit Raj Sharma; Sujata Upadhyay; Phulen Sarma; Ajay Prakash; Bikash Medhi
Journal:  Vet Res Commun       Date:  2020-09-14       Impact factor: 2.459
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  7 in total

Review 1.  Metagenomics-enabled microbial surveillance.

Authors:  Karrie K K Ko; Kern Rei Chng; Niranjan Nagarajan
Journal:  Nat Microbiol       Date:  2022-04-01       Impact factor: 17.745

Review 2.  The science of the host-virus network.

Authors:  Gregory F Albery; Daniel J Becker; Liam Brierley; Cara E Brook; Rebecca C Christofferson; Lily E Cohen; Tad A Dallas; Evan A Eskew; Anna Fagre; Maxwell J Farrell; Emma Glennon; Sarah Guth; Maxwell B Joseph; Nardus Mollentze; Benjamin A Neely; Timothée Poisot; Angela L Rasmussen; Sadie J Ryan; Stephanie Seifert; Anna R Sjodin; Erin M Sorrell; Colin J Carlson
Journal:  Nat Microbiol       Date:  2021-11-24       Impact factor: 30.964

Review 3.  Microorganisms as Shapers of Human Civilization, from Pandemics to Even Our Genomes: Villains or Friends? A Historical Approach.

Authors:  Francisco Rodríguez-Frías; Josep Quer; David Tabernero; Maria Francesca Cortese; Selene Garcia-Garcia; Ariadna Rando-Segura; Tomas Pumarola
Journal:  Microorganisms       Date:  2021-12-06

Review 4.  Optimising predictive models to prioritise viral discovery in zoonotic reservoirs.

Authors:  Daniel J Becker; Gregory F Albery; Anna R Sjodin; Timothée Poisot; Laura M Bergner; Binqi Chen; Lily E Cohen; Tad A Dallas; Evan A Eskew; Anna C Fagre; Maxwell J Farrell; Sarah Guth; Barbara A Han; Nancy B Simmons; Michiel Stock; Emma C Teeling; Colin J Carlson
Journal:  Lancet Microbe       Date:  2022-01-10

5.  Reverse zoonosis and monkeypox: Time for a more advanced global surveillance system for emerging pathogens.

Authors:  Arya Afrooghe; Amirmasoud Rayati Damavandi; Elham Ahmadi
Journal:  New Microbes New Infect       Date:  2022-07-16

Review 6.  Next-Generation Sequencing for Confronting Virus Pandemics.

Authors:  Josep Quer; Sergi Colomer-Castell; Carolina Campos; Cristina Andrés; Maria Piñana; Maria Francesca Cortese; Alejandra González-Sánchez; Damir Garcia-Cehic; Marta Ibáñez; Tomàs Pumarola; Francisco Rodríguez-Frías; Andrés Antón; David Tabernero
Journal:  Viruses       Date:  2022-03-14       Impact factor: 5.048

Review 7.  The One Medicine concept: its emergence from history as a systematic approach to re-integrate human and veterinary medicine.

Authors:  Tracey A King
Journal:  Emerg Top Life Sci       Date:  2021-11-12
  7 in total

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