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Review

African Swine Fever Virus Circulation between Tanzania and Neighboring Countries: A Systematic Review and Meta-Analysis

1
SACIDS Africa Centre of Excellence for Infectious Diseases, SACIDS Foundation for One Health, Sokoine University of Agriculture, P.O. Box 3019 Morogoro, Tanzania
2
Department of Veterinary Microbiology, Parasitology and Biotechnology, College of Veterinary Medicine and Biomedical Sciences, Sokoine University of Agriculture, P.O. Box 3019 Morogoro, Tanzania
3
Department of Biosciences, Solomon Mahlangu College of Science and Education, Sokoine University of Agriculture, P.O. Box 3019 Morogoro, Tanzania
4
Department of Applied Research and Development and Foresight Incubation, National Industrial Research and Development Agency, P.O. Box 273 Kigali, Rwanda
5
Laboratory of Virology, Faculty of Veterinary Medicine, Ghent University, Salisburylaan 133, 9820 Merelbeke, Belgium
*
Authors to whom correspondence should be addressed.
Submission received: 25 January 2021 / Revised: 8 February 2021 / Accepted: 9 February 2021 / Published: 15 February 2021
(This article belongs to the Special Issue Endemic and Emerging Swine Viruses 2021)

Abstract

:
For over 100 years after the description of the first case of African swine fever (ASF) in Kenya, ASF virus (ASFV) cross-border spread in eastern and southern Africa has not been fully investigated. In this manuscript, we reviewed systematically the available literature on molecular epidemiology of ASF in Tanzania and its eight neighboring countries in order to establish the transmission dynamics of ASFV between these countries. Data were retrieved from World Animal Health Information System (WAHIS), Google Scholar, PubMed, Scopus, and CrossRef databases, using the recommendations of the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines and reviewed to document ASF outbreaks and ASFV genotypes distribution. Using phylogeographic approach applied to ASFV p72 sequence dataset, the evolutionary history and the dispersal pattern of the ASFV strains were assessed. From 2005 to 2019, a total of 1588 ASF outbreaks affecting 341,742 cases that led to 302,739 domestic pig deaths were reported. The case fatality rates (CFR) varied from 15.41% to 98.95% with an overall CFR of 88.58%. Fifteen different p72 ASFV genotypes were reported and the time to the most recent common ancestor (TMRCA) for ASFV strains dated back to 1652.233 (1626.473, 1667.735) with an evolutionary rate of 4.805 × 10−5 (2.5857 × 10−5, 9.7789 × 10−5). Phylogeographic dispersal analysis revealed several transboundary spread events of ASFV strains between these countries. These results suggest persistent circulation of ASFV in these countries and advocate for more research to improve our understanding of the transmission dynamics of the virus and for a regional approach to mitigate the spread of ASFV.

1. Introduction

African swine fever (ASF) threatens global domestic pig industry and wild boars due to its high mortality rate, trade restriction [1] and hinders poverty alleviation, an important component of Sustainable Development Goals of the United Nations in affected countries. African swine fever was first described in Kenya in 1921 [2] and since then it has become endemic in many countries of Africa, South of the Sahara where it threatens food security and livelihoods of poor and marginalized communities keeping domestic pigs for subsistence [3,4,5]. The first wave of ASF outside Africa started in Portugal in 1957 and in 1960 with subsequent spread to Iberian Peninsula, other countries of the European Union, the Caribbean and Brazil before its eradication in these countries in 1990 with the exception of Sardinia, Italy where it remains endemic since 1978 [6,7,8]. The second wave of ASF in Europe started with an introduction of the virus in Georgia in 2007 and from there, ASF expanded its geographical distribution to Caucasus region, European Union countries, and later on in August 2018 to Asian countries including China [1,9,10,11]. The expanding geographical distribution of ASF poses a threat to ASF-free countries worldwide and the maintenance of ASF in countries where domestic pigs are kept for subsistence including eastern and southern African countries is believed to fuel the global spread and risk of ASF [1,12]. For instance, the first spread of ASF virus (ASFV) genotype I to Portugal in 1957 was suspected to come from Angola while Madagascar is speculated to be the origin of the ASFV genotype II introduction into Georgia in 2007 [8,13].
African swine fever is caused by the ASF virus (ASFV), a linear double-stranded DNA arbovirus with an icosahedral morphology that was once included in the family of Iridoviridae, but is now assigned to the genus Asfivirus, family Asfarviridae [14], being the only member of this family and the only known DNA arbovirus. Depending on the viral isolate, the ASFV genomes vary in length from about 170 to 193 kilobase pairs and encode between 151 and 167 open reading frames with a conserved central region of about 125 kbp and variable termini [15]. These variable ends encode five multigene families (MGF) that contribute to the variability of the virus genome. Molecular characterization of distinct genome regions of ASFV has proved to be very useful in elucidating the origin and transmission pathways of ASF during outbreaks [16,17]. Different genomic regions have been targeted to detect ASFV phylogenetic relationships with different levels of precision [16]. The current approach for investigating the molecular epidemiology of ASF is through sequencing of the C-terminal end of p72 (B646L) gene encoding the p72 major capsid protein in order to determine the viral genotype [18]. So far, 24 ASFV p72 genotypes (I–XXIV) have been identified [19,20]. Further discrimination into subgroups of closely related viruses is usually conducted by sequence analysis of the tandem repeat sequences (TRS) located in the central variable region (CVR) within the B602L gene [21,22,23] and the intergenic region between the I73R and I329L genes [24,25]. Several other genomic regions such as the E183L encoding the p54 protein, the CP204L encoding the p30 protein, and the EP402R gene encoding the CD2v protein, have proved to be useful tools for molecular epidemiological and virus spread investigations [13,21,26].
Four transmission cycles have been described for ASFV: (1) a sylvatic cycle where the virus asymptomatically circulates between wild suids (mainly warthogs, Phacochoerus africanus) and soft ticks of the Ornithodoros moubata complex inhabiting warthog burrows, (2) a tick to domestic pig cycle characterized by the transmission of the virus to domestic pigs by ticks dropped to domestic pig shelters by warthogs, (3) a domestic cycle accounting for most of ASF outbreaks globally where the virus is transmitted by direct contact between infected and susceptible domestic pigs or from infected domestic pig products to domestic pigs, and (4) a wild boar-habitat cycle specific to Eurasian countries [5,8,27]. The sylvatic ASFV cycle specific to eastern and southern Africa is believed to play an important role in the genetic variation of the ASFV and in hindering ASF control [20]. African swine fever outbreaks in domestic pigs are mandated to be reported to the World Organization for Animal Health (OIE) and despite the perceived increase of the reported ASF outbreaks [10], our understanding of the process of ASFV maintenance and spread in eastern and southern Africa is quite limited. The aim of this manuscript was to review systematically the available literature on molecular epidemiology of ASF in Tanzania and neighboring countries in order to establish the transmission dynamics of ASFV between these countries. This information will inform the effective application of ASF control measures and will highlight research gaps warranted for further investigation.

2. Materials and Methods

2.1. Search Strategy

The African swine fever outbreaks records were retrieved from OIE, World Animal Health Information System (WAHIS). Using the recommendations of the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines [28], a literature search was carried out at Google Scholar, PubMed, Scopus, and CrossRef databases to find relevant information related to molecular epidemiology of ASF in Tanzania and its neighboring countries. The following search string was used: “African swine fever” OR “African swine fever virus” OR “ASF” OR “ASFV” AND (“Tanzania” OR “Burundi” OR “Democratic Republic of the Congo” OR “Kenya” OR “Malawi” OR “Mozambique” OR “Rwanda” OR “Uganda” OR “Zambia”). The search did not include any limit regarding publication date and articles in English were included in the review. Rayyan QCRI [29] was used for preliminary screening of studies. Articles from PubMed were imported directly to Rayyan QCRI, while the Publish or Perish Software [30] was used to import articles from other databases. A first screening of titles and abstracts was performed, then full text of articles identified as possibly relevant were reviewed. The bibliographies of included articles were assessed for further eligible publications.

2.2. Inclusion and Exclusion Criteria

Two independent reviewers (JNH and CY) electronically searched for studies and screened them according to eligibility criteria, the last search was done on 14th October 2020. The focus was on the articles published in English that describe molecular epidemiology of ASFV in Burundi, Democratic Republic of the Congo (DRC), Kenya, Malawi, Mozambique, Rwanda, Tanzania, Uganda, and Zambia without limit regarding publication date. Abstracts without available full text, articles in language other than English, review articles, duplicated information, and studies describing only ASF diagnosis without sequencing and phylogenetic analysis in order to identify the ASFV genotype were excluded.

2.3. Data Extraction and Analysis

Relevant data from all articles included in the review were extracted and entered in a Microsoft Excel database for further handling. The following data were summarized: authors’ name, year of publication, host species, nature of sample (blood, tissue, etc.), genes sequenced, sequences accession numbers, country of the study setting, town or the district of the study (where available), and summary of the findings. Primary authors were contacted in case some data were missing or unclear. The results were described using figures and tables to depict the trend of ASF occurrence over time and space.

2.4. Phylogeographic Analysis

In total, 126 ASFV p72 nucleotide sequences were downloaded from the NCBI GenBank database comprising ASFV strains from Burundi (n = 3), DRC (n = 22), Kenya (n = 17), Malawi (n = 17), Mozambique (n = 14), Tanzania (n = 15), Uganda (n = 11), and Zambia (n = 27). No sequences were found from Rwanda. The included sequences were collected from 1954 to 2019 and they were aligned by CrustalW using MEGA X [31] and subsequently edited using SeaView version 4 [32]. The resulting alignment consisted of 126 sequences (409 nucleotides long). The Smart Model Selection in PhyML (SMS) version 1.8.4 was used to evaluate the best fitting nucleotide substitution model using Akaike information criterion (AIC) as a model selection criterion [33]. The best fitting model for sequences used in this study was the GTR + G (general time reversible model with gamma distributed among-site rate heterogeneity). Therefore, a maximum likelihood phylogenetic tree was reconstructed under the GTR + G model with a bootstrap frequency of 1000 replicates as implemented by MEGA X [31]. TempEst version 1.5.3 [34] was used for temporal signal investigation in the dated-tip tree for further phylogenetic molecular clock analysis. The sequence data were annotated with year of the collection as stated in the corresponding original paper and the country where samples were collected. The least square dating (LSD) was used for ancestral events dating and rooting the phylogenetic tree based on dates [35] using strict molecular clock. The phylogeography of ASFV was reconstructed from the time-scaled tree generated by LSD and location annotations using PastML with maximum likelihood marginal posterior probabilities approximation (MPPA) and Felsenstein 1981 (F81) model options [36]. The PastML generated tree was visualized and edited using iTOL [37].

3. Results

3.1. Article Selection

In total, 648 articles were collected during the initial search and 472 were included after elimination of duplicates. After titles and abstracts screening against the eligibility criteria, 299 articles were excluded. The majority of excluded publications reported data from countries not concerned by this review and review papers. Therefore, 173 full-text manuscripts were assessed in detail and 34 articles were retained for qualitative synthesis and 29 papers for further molecular assessment (Figure 1). The earliest study meeting the eligibility criteria was Lubisi et al. published in 2005, and therefore the current review considers literature over a 15 years period from 2005 to 2020.

3.2. ASF Disease Pattern

The total of ASF outbreaks reported to OIE by Tanzania and its eight neighboring countries from 2005 to 2019 were 1588 affecting 341,742 cases that led to 302,739 domestic pig deaths during this period. The case fatality rates (CFR) varied from 15.41% to 98.95% with an overall CFR of 88.58%. The number of reported ASF outbreaks, number of cases, number of deaths, and the case fatality rate reported by Tanzania and its eight neighboring countries increased over time from 2005–2009 to 2010–2014 periods (Table 1).

3.3. ASFV Genotypes

The included studies reported 15 different p72 ASFV genotypes in Tanzania and its eight neighboring countries. The following genotypes were reported: I, II, V, VI, VIII, IX, X, XI, XII, XIII, XIV, XV, XVI, XX, and XXIV (Table 2 and Table 3). Genotypes V and X were found in domestic pigs, warthogs and ticks; genotype I in domestic pig, ticks and bush pig; genotype IX in domestic pigs and warthogs; genotypes II, VIII, XII, XV, and XIV in both domestic pigs and ticks; while genotypes VI, and XVI were exclusively described in domestic pigs, and genotypes XI, XIII, and XXIV exclusively in soft ticks (Figure 2). Zambia recorded a wider variety of ASFV p72 genotypes with seven genotypes being reported to circulate in the country, namely genotypes I, II, VIII, XI, XII, XIII, and XIV.

3.4. Phylogeography of ASFV

Results for root to tip divergence showed that the dataset used in this study had a positive temporal signal with the correlation coefficient of 0.19 and R2 of 0.038. The time to the most recent common ancestor (TMRCA) for ASFV strains circulating between Tanzania and its neighboring countries dated back to 1652.233 (1626.473, 1667.735) with an evolutionary rate of 4.805 × 10−5 (2.5857 × 10−5, 9.7789 × 10−5). The location of the root was unresolved with an indication that Kenya might be the root location with 14.95% probability. Phylogeographic dispersal of ASFV revealed several transboundary spread events from Kenya to Uganda, Tanzania, and Mozambique. From Mozambique, ASFV further spread to Zambia and Malawi and from there to Tanzania. Transmissions from Uganda to DRC, from Tanzania to Burundi were also observed (Figure 3).

4. Discussion

This review aimed at investigating the molecular epidemiology of the ASFV strains circulating in Burundi, DRC, Kenya, Malawi, Mozambique, Rwanda, Tanzania, Uganda, and Zambia. Data and articles describing molecular epidemiology of ASF were retrieved from public databases and 34 articles met our inclusion criteria. Our findings suggested a tendency toward the increase of number of reported ASF outbreaks, number of cases, number of deaths, and the case fatality rate over time. A high ASFV genotypic diversity was reported by the included studies with 15 different ASFV genotypes. Additionally, phylogeographic dispersal analysis revealed several transboundary spread events of ASFV strains between countries concerned by this review.
All nine countries concerned by this review reported 1588 ASF outbreaks to the OIE WAHIS from 2005 to 2019 [10]. The real number of ASF outbreaks that occurred in these countries during the same period may be higher than those reported to OIE because the ASF outbreaks reporting in Africa was characterized as sporadic and incomplete for several reasons including poor communication channels and fear of undesirable consequences [4,5]. The increasing trend of reported ASF outbreaks, cases and deaths of domestic pigs could be attributed to the increasing number of ASF outbreaks within the region, with DRC and Malawi reporting 153,692 and 80,437 ASF cases that led to 140,493 and 77,896 domestic pig deaths, respectively, between 2010 and 2014 [10]. In addition, there has been an improvement in laboratory diagnosis capacity and enhanced surveillance systems in order to prevent ASF outbreaks in concerned countries. However, this increase of reported ASF outbreaks is worrisome and regional control programs need to be put in place to control the occurrence of ASF in the region. For some countries (Burundi, Kenya, Malawi, Rwanda, and Zambia), the data for 2019 are not complete because at the time of data retrieving, their 2019 reports were not available on the WAHIS database.
This review showed that 15 of the 24 ASFV p72 genotypes have occurred in Burundi, DRC, Kenya, Malawi, Mozambique, Tanzania, Uganda, and Zambia. These countries are rich in wildlife protected areas where ASFV natural reservoirs exist, making the epidemiology of the ASFV in these countries complex. For instance, the included studies reported diverse range of ASFV p72 genotypes recovered from domestic pigs, warthogs, ticks, and bush pigs in samples collected from 1954 to 2019. Genotypes V and X were isolated from domestic pigs, warthogs and ticks suggesting the association of these genotypes to the ASFV sylvatic cycle as previously described [16,20,54]. The ASFV p72 genotype V was reported to circulate in Malawi and Mozambique since 1960 and the sylvatic cycle was cited to play an important role in its maintenance in those countries [20,49]. The genotype X was recovered from domestic pigs in 1950 in Kenya [15], since then, it was regularly reported to circulate and cause ASF outbreaks in Kenya [15,16,21,23], Uganda [21,23], Tanzania [22,23,61,62], Burundi [22,23,64], and DRC [51]. Recent molecular studies have reported high genetic similarity at three genomic regions of ASFV (p72, CVR and I73R-I329L) between the ASFV p72 genotype X strains responsible for ASF outbreaks in 2016 in Kagera region in Tanzania [62,64], the 2018 ASF outbreak in Rutana region in Burundi [64], and the ASF outbreak that occurred during December 2018 to January 2019 in South Kivu province of the DRC [51]. Commercial traffic and cross-border movements of domestic pigs and pork products were speculated as the main drivers of the ASFV spread between DRC, Burundi, and Tanzania [51,53,64]. Rutana region shares a border with Kagera region which borders South Kivu province through Lake Tanganyika and uncontrolled transboundary movements of domestic pigs and pork products are likely to happen in the area. However, the area is rich in wildlife protected areas with natural reservoir of ASFV (mainly warthogs) and their role in the epidemiology of the disease in the area has not been investigated. It would be interesting to investigate the sylvatic cycle of the ASFV in the area in order to get more insight into the epidemiology of ASFV. The included studies reported the ASFV p72 genotype I isolated from domestic pigs, ticks and bush pigs. Genotype I was described as the most prevalent in DRC where it was regularly recovered from domestic pigs since 1963 [22,23,53] and it is described as the most widely spread ASFV genotype in Zambia where it was isolated from soft ticks and domestic pigs [38,40,41]. Additionally, one study has described the ASFV p72 genotype I isolated from bush pig (Potamochoerus porcus) in 1961 in Kenya [22]. Apart from eastern and southern Africa, the ASFV p72 genotype I strains have a wide range of geographical distribution, they have been described in Europe, South America, the Caribbean, and West Africa [22].
The ASFV p72 genotype IX was recovered from domestic pigs and warthogs. This genotype is described as the most predominant in Uganda and Kenya [42], but also, it was described in DRC [50,53] and Tanzania [56,62]. Although associated with lethal ASF outbreaks [21,47,48], an increasing number of studies reported the genotype IX in asymptomatic domestic pigs in Tanzania [56], DRC [50], Uganda [44], and Kenya [65]. The reason behind this variation in virulence of the ASFV p72 genotype IX is worth investigating. The high genetic similarity between the ASFV p72 genotype IX strains recovered from warthogs in central Kenya in 2008 and 2009 [16] to ASFV strains described in domestic pigs in Kenya, Uganda, DRC, and Tanzania highlights the role of the ASFV sylvatic cycle in the epidemiology of the ASFV in eastern Africa.
The included studies reported ASFV p72 genotypes II, VIII, XII, XIV, and XV in both domestic pigs and ticks. The ASFV p72 genotype II was recovered from domestic pigs in Zambia and Mozambique about 30 years ago [22,49] and since then it has expended its geographical distribution not only to eastern and southern Africa countries but also to Madagascar [66], Mauritius [67], Europe [24], and Asia [11,25]. The recent detection of this genotype II in soft ticks in Mozambique provides evidence of a possible sylvatic source of this ASFV p72 genotype [20]. In addition, homology between ASFV strains from ticks collected at pig shelters and those from warthog burrows was observed, suggesting the possibility of ASFV transmission at the wild and domestic pigs interface [20]. Among countries included in this review, the ASFV p72 genotype II was described in Zambia [17,40], Mozambique [20,22,49], Tanzania [56,59,62], and in Malawi [63]. In 2007, the ASFV p72 genotype II escaped from its African geographical distribution to Georgia and subsequently spread to countries of the European Union and Russia before it reached Asia in August 2018 [13,25]. Additionally, the transboundary spread of the highly virulent ASFV p72 genotype II similar to the Georgia 2007/1 strain is highlighted by the introduction of this genotype into Tanzania probably from Malawi [59,62,63] and the emergence of this ASFV genotype in Zimbabwe in 2015 after several years of ASF absence probably from the neighboring Mozambique [68]. Furthermore, the genotype VIII was found to circulate in Zambia, Mozambique and Malawi [21,22,23], genotype XII was described in Zambia and Malawi [22], whilst genotype XV seems to be confined to Tanzania where both domestic and sylvatic cycles have been described for this genotype [22,57,58]. Additionally, genotype XIV which was previously restricted to Zambia where it was isolated from soft ticks in 1986 [22] was reported in domestic pigs in Zambia [17] and in DRC [53].
Genotypes VI and XVI were described as domestic pig cycle associated genotypes being confined to Mozambique [23,49] and Tanzania [22], respectively, while genotypes XI and XIII were recovered from soft ticks in Zambia in 1983 [22], and the recently identified genotype XXIV was isolated from soft ticks collected in 2006 from Gorongosa Park in Mozambique [20].
High genotypic variability was reported by included studies with 15 different ASFV genotypes being reported to circulate in countries concerned by this review. Movement of domestic pigs and pork products were cited as the main factor of ASFV spreading within and between countries, for instance the ASFV spread pattern was linked to trade highways in Tanzania [62] and Uganda [47] highlighting the importance of the anthropogenic factors and the ASFV domestic pig cycle in the spread of ASF in concerned countries. In addition, the ASFV sylvatic cycle seems to play a role in the maintenance of ASFV in concerned countries as 13 among the 15 circulating genotypes were isolated either from warthogs or ticks. However, the role of bush pigs in the epidemiology of ASF in the countries concerned by this review appears extremely limited as only one study reported ASFV genotype I recovered from bush pig.
This study identified substantial viral dispersal and spread routes between Tanzania and its neighboring countries. The estimated evolution rate of 4.805 × 10−5 substitution/site/year for ASFV strains collected in Tanzania and its eight neighboring countries from 1954 to 2019 is higher than other double-stranded DNA viruses, however, it is similar to the substitution rate of the rapidly evolving RNA viruses [69]. These findings are in agreement with previous studies that estimated the evolution rate for the ASFV strains [70,71]. Our estimated temporal most recent common ancestor (TMRCA) dated back to 1652.233 (1626.473, 1667.735) supporting the hypothesis that the ASFV could have been circulating in Eastern Africa before it was isolated and described for the first time as previously described [70,71]. Phylogeographical dispersal of the ASFV revealed several transboundary spread events from Kenya to Uganda, Tanzania and Mozambique. From Mozambique, ASFV further spread to Zambia and Malawi and from there to Tanzania. Transmissions from Uganda to DRC, from Tanzania to Burundi were also observed as shown in Figure 3. These observations are consistent with studies using traditional phylogenetic methods where transboundary spread of ASFV between DRC and Uganda [50,53], Tanzania and Malawi [59,63], DRC and Zambia [53], Kenya and Uganda [21] were speculated. Our findings highlight the role of neighboring countries in the epidemiology of ASFV and a regional approach would be more effective for the control of ASF. Whole genome sequences of ASFV from the countries concerned by this review are still limited and those data are needed for estimating more accurately the transmission dynamics of the ASFV in these countries and designing an effective control strategy.

5. Conclusions

In conclusion, a considerable diversity of ASFV genotypes were found to circulate in Tanzania and its neighboring countries. Furthermore, a transboundary spread of ASFV between countries was observed. These results suggest persistence of ASFV in these countries and advocate for more research on whole genome sequencing of ASFV and the ASFV sylvatic cycle to improve our understanding of the transmission dynamics of the virus and for a regional approach to mitigate the spread of ASFV.

Author Contributions

Conceptualization, J.N.H., C.Y., O.K., H.N. and G.M.; methodology, J.N.H. and C.Y.; validation, O.K., H.N. and G.M.; formal analysis, J.N.H. and C.Y.; data curation, C.Y.; writing—original draft preparation, J.N.H.; writing—review and editing, C.Y., O.K., H.N. and G.M.; supervision, O.K., H.N. and G.M. All authors have read and agreed to the published version of the manuscript.

Funding

J.N.H. is supported by the Partnership for Skills in Applied Sciences, Engineering and Technology (PASET) through the Regional Scholarship and Innovation Fund (RSIF) to carry out doctoral studies at SACIDS Africa Centre of Excellence for Infectious Diseases, SACIDS Foundation for One Health, Sokoine University of Agriculture, Morogoro, Tanzania. J.N.H. is also recipient of the research grant (grant number B_6269-1) from the International Foundation for Sciences (IFS).

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

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Figure 1. Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) flow chart of the literature search, screening, assessing eligibility, and article selection.
Figure 1. Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) flow chart of the literature search, screening, assessing eligibility, and article selection.
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Figure 2. Distribution of the ASFV p72 genotypes circulating between Tanzania and its eight neighboring countries by October 2020. The map was developed using QGIS version 3.4.4 (https://www.qgis.org/en/site/about/index.html).
Figure 2. Distribution of the ASFV p72 genotypes circulating between Tanzania and its eight neighboring countries by October 2020. The map was developed using QGIS version 3.4.4 (https://www.qgis.org/en/site/about/index.html).
Viruses 13 00306 g002
Figure 3. Ancestral reconstruction of African swine fever virus strains collected in Tanzania and its neighboring countries. The figure shows the full tree (A) and compressed (B) visualizations produced by PastML using MPPA with an F81-like model. Different colors correspond to different countries as shown in the legend.
Figure 3. Ancestral reconstruction of African swine fever virus strains collected in Tanzania and its neighboring countries. The figure shows the full tree (A) and compressed (B) visualizations produced by PastML using MPPA with an F81-like model. Different colors correspond to different countries as shown in the legend.
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Table 1. African swine fever outbreaks, cases, deaths, and case fatality rate reported to the World Organization for Animal Health (OIE) by Tanzania and its eight neighboring countries from 2005 to 2019.
Table 1. African swine fever outbreaks, cases, deaths, and case fatality rate reported to the World Organization for Animal Health (OIE) by Tanzania and its eight neighboring countries from 2005 to 2019.
Time PeriodCountryNumber of OutbreaksNumber of CasesNumber of DeathsCase Fatality Rate (%)
2005–2009Tanzania595673877.19
Rwanda1347057586383.08
Burundi----
Malawi8616,97310,78563.54
DRC811413132994.05
Mozambique786715519477.35
Zambia431570127180.95
Kenya992454959.41
Uganda340118145.13
Subtotal43936,00925,91071.95
2010–2014Tanzania414957427586.24
Rwanda2003553106830.06
Burundi11592616.35
Malawi13980,43777,89696.84
DRC191153,692140,49391.41
Mozambique423136239176.24
Zambia443835238162.08
Kenya620316782.26
Uganda1062247376.04
Subtotal674250,594229,17091.45
2015–2019Tanzania434981306761.57
Rwanda4759353289.71
Burundi28363356015.41
Malawi191813166691.89
DRC23735,40735,03898.95
Mozambique38123993675.54
Zambia425966502584.23
Kenya323122396.53
Uganda18127661247.96
Subtotal47555,13947,65986.43
Grand total1588341,742302,73988.58
Table 2. Summary of the ASFV p72 genotypes distribution in Tanzania and neighboring countries. The black highlight indicates that the corresponding genotype is present.
Table 2. Summary of the ASFV p72 genotypes distribution in Tanzania and neighboring countries. The black highlight indicates that the corresponding genotype is present.
ASFV p72 Genotype
CountryIIIVVIVIIIIXXXIXIIXIIIXIVXVXVIXXXXIVTotal
Genotypes
Burundi 1
DRC 5
Kenya 3
Malawi 4
Mozambique 5
Rwanda 0
Tanzania 5
Uganda 2
Zambia 7
Total countries342134512121111
Table 3. African swine fever virus p72 genotypes circulating between Tanzania and its eight neighboring countries by October 2020.
Table 3. African swine fever virus p72 genotypes circulating between Tanzania and its eight neighboring countries by October 2020.
ReferenceTargeted Genomic RegionReported ASFV p72 GenotypeHost SpeciesCountry (Number of Papers)
[38]p72ITickZambia (7)
[39]Whole genome sequencingITick
[40]p72, p54, p30, CVRIIDomestic pig
[41]p72, p54IDomestic pig
[22]p72I, II, VIII, XI, XII, XIII, XIVDomestic pig and tick
[23]p72, CVRI, VIIITick and domestic pig
[17]p72, p54, CVRI, II, XIVDomestic pig
[42]WGSIXDomestic pigUganda (10)
[43]p72, p54, CVRIXDomestic pig
[44]p72, p54, CVRIXDomestic pig
[45]p72, p54, CVRIXDomestic pig
[46]WGSIXDomestic pig
[47]p72, p54, CVRIXDomestic pig
[21]p72, p54, CVRIX, XDomestic pig
[22]p72IXDomestic pig
[23]p72, CVRIX, XDomestic pig
[48]p72, p54, CVR, TKIXDomestic pig
[49]p72, CVRII, V, VI, VIIIDomestic pigMozambique (5)
[21]p72, p54, CVRVDomestic pig
[22]p72II, VIIIDomestic pig
[23]p72, CVRVIDomestic pig
[20]p72, CVR, p30, p54II, V, XXIVTick
[50]p72, p54IXDomestic pigDRC (6)
[51]p72, p54, CVR, CD2v, I73R-I329LXDomestic pig
[52]Whole genome sequencingXXDomestic pig
[22]p72INot known
[53]p72, p54, CVRI, IX, XIVDomestic pig
[23]p72, CVRIDomestic pig
[54]WGSIX, XDomestic pigKenya (8)
[15]WGSXDomestic pig
[16]p72, p54, p30, CVRIX, XDomestic pig, tick and warthog
[21]p72, p54, CVRIXDomestic pig
[48]p72, p54, CVR, TKIXDomestic pig
[55]p72, p54IXDomestic pig
[22]p72I, XWarthog, domestic pig and bush pig
[23]p72, CVRXWarthog
[56]p72, p54, CVR, I73R-I329LII, IXDomestic pigTanzania (9)
[57]p72, p54, CVRXVTick
[58]p72, p54, CVRXVDomestic pig
[59]p72IIDomestic pig
[60]p72, p54, CVRXDomestic pig
[61]p72XDomestic pig
[22]p72X, XV, XVITick, warthog and domestic pig
[23]p72, CVRXWarthog
[62]p72II, IX, XDomestic pig
[63]p72, CVR, I73R-I329LIIDomestic pigMalawi (4)
[21]p72, p54, CVRV, VIIIDomestic pig and tick
[22]p72VIII, V, XIIDomestic pig
[23]p72, CVRV, VIIIWarthog and domestic pig
[22]p72XDomestic pigBurundi (3)
[23]p72, CVRXDomestic pig
[64]p72, CVR, I73R-I329LXDomestic pig
----Rwanda (0)
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Hakizimana, J.N.; Yona, C.; Kamana, O.; Nauwynck, H.; Misinzo, G. African Swine Fever Virus Circulation between Tanzania and Neighboring Countries: A Systematic Review and Meta-Analysis. Viruses 2021, 13, 306. https://0-doi-org.brum.beds.ac.uk/10.3390/v13020306

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Hakizimana JN, Yona C, Kamana O, Nauwynck H, Misinzo G. African Swine Fever Virus Circulation between Tanzania and Neighboring Countries: A Systematic Review and Meta-Analysis. Viruses. 2021; 13(2):306. https://0-doi-org.brum.beds.ac.uk/10.3390/v13020306

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Hakizimana, Jean N., Clara Yona, Olivier Kamana, Hans Nauwynck, and Gerald Misinzo. 2021. "African Swine Fever Virus Circulation between Tanzania and Neighboring Countries: A Systematic Review and Meta-Analysis" Viruses 13, no. 2: 306. https://0-doi-org.brum.beds.ac.uk/10.3390/v13020306

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