![](\"https:\/\/img.magnific.com\/free-photo\/adorable-baby-pigs-farm_23-2149066182.jpg?semt=ais_incoming&w=740&q=80\")
<\/p>\n<\/p>\n
African swine fever (ASF) has become one of the most persistent threats to the global pig industry since its major outbreaks in Asia during 2018\u20132019. ASF causes high mortality, spreads quickly, and creates major losses for both industrial farms and smallholder pig producers.<\/span><\/p>\n Existing ASF vaccines are an important step forward, especially for countries facing long-term disease pressure such as Vietnam. However, vaccines cannot completely replace biosecurity, epidemiological surveillance, transport control, and herd management. For this reason, the international scientific community is also studying long-term approaches such as CRISPR gene editing and genetic selection to develop pig populations that may have better tolerance to ASF in the future.<\/span><\/p>\n African swine fever virus (ASFV) belongs to the Asfarviridae family. It is a double-stranded DNA virus with a complex structure and a large genome. ASFV can attack important immune cells, including macrophages, and has multiple mechanisms to evade the host\u2019s immune response.<\/span><\/p>\n What makes ASFV especially difficult to control is that protective immunity against this virus is highly complex. An antibody response alone is often not enough to provide strong protection, unlike many other viral diseases. This is one of the reasons why developing a safe, effective, and stable ASF vaccine at scale has been challenging for a long time.<\/span><\/p>\n Domestic pigs are highly susceptible to ASFV and do not have a clearly defined natural tolerance mechanism like some African wild pig species. Some species, such as warthogs and bushpigs, can become infected with or carry ASFV without showing severe disease, while soft ticks of the genus Ornithodoros act as natural vectors in the transmission cycle in some regions. This difference has drawn scientific interest in the genetic basis of natural ASF tolerance.<\/span><\/p>\n In Vietnam, the first ASF outbreak in February 2019 spread to all 63 provinces and cities within a short period of time. Millions of pigs had to be culled, the national pig herd dropped sharply, and pork prices rose significantly during 2019\u20132020.<\/span><\/p>\n Although the pig herd gradually recovered afterward, ASF has continued to recur in cycles in many localities. This shows that ASF is not a short-term risk, but a long-term challenge for the pig industry.<\/span><\/p>\n Vietnam has licensed domestic ASF vaccines such as NAVET-ASFVAC, AVAC ASF LIVE, and Dacovac-ASF2. This is an important step forward, but vaccines remain only one part of an overall strategy. Real-world effectiveness still depends on the target animals, circulating virus strains, storage conditions, application procedures, vaccine coverage, and how well biosecurity is maintained on farms.<\/span><\/p>\n For this reason, research into pig breeds with better ASF tolerance still has long-term strategic value. However, this field remains at the research stage and is not yet an available solution for farmers today.<\/span><\/p>\n The direct answer is: there is currently no commercial ASF-resistant pig breed available for pig farmers in Vietnam during the 2025\u20132026 period.<\/span><\/p>\n Globally, research into pigs with improved ASF tolerance is still mainly at the foundational research stage, pre-commercial testing stage, or controlled laboratory trial stage. At present, there is no publicly confirmed information showing that any gene-edited pig line or genetically selected pig breed has been widely approved for commercial use with the goal of ASF resistance.<\/span><\/p>\n In Vietnam, publicly available information on large-scale research programs for ASF-resistant pig breeds remains limited. No ASF-resistant pig breed has been announced as ready for commercial production. Therefore, farmers should view this as a long-term solution, not a short-term way out of current disease outbreaks.<\/span><\/p>\n CRISPR-Cas9 is a gene-editing tool that allows scientists to make changes at a specific location in the genome. In research on pigs with improved ASF tolerance, CRISPR can be used to edit certain genes or sequence regions believed to be related to how the virus enters cells, replicates, or triggers inflammatory responses.<\/span><\/p>\n The research process usually includes the following main steps:<\/span><\/p>\n Scientists analyze the genomes and immune responses of domestic pigs, African wild pigs, and experimental models to find genes or sequence regions that may be related to ASFV tolerance. One target that has attracted attention is RELA, a gene related to the NF-\u03baB transcription factor and inflammatory response.<\/span><\/p>\n The guide RNA is designed to direct the CRISPR-Cas9 system to the location that needs to be edited in the genome. The accuracy of this step directly affects editing efficiency and the risk of off-target effects.<\/span><\/p>\n Depending on the research strategy, scientists may edit cells, embryos, or specific locations in the genome. Not every CRISPR approach means \u201ctaking genes from wild pigs and putting them into domestic pigs.\u201d In many cases, editing may simply involve changing a few nucleotides, replacing a gene variant, or inactivating a gene or receptor related to the viral life cycle.<\/span><\/p>\n Depending on the technical platform, edited cells or embryos can be used to create pigs carrying the genetic change. These pigs then need to be monitored for health, reproductive performance, genetic stability, and possible off-target effects over multiple generations.<\/span><\/p>\n Gene-edited pigs can only be evaluated for ASF tolerance through controlled challenge trials under strict biosecurity conditions. This is a highly complex and costly step that cannot be expanded freely because it involves a dangerous virus.<\/span><\/p>\n RELA is one of the early targets studied in the search for ASF tolerance mechanisms in pigs. Scientists have tested editing domestic pigs to carry certain RELA motifs similar to those found in warthogs, with the expectation of partly mimicking the ASFV tolerance mechanism seen in African wild pig species.<\/span><\/p>\n However, published results show that RELA editing alone is not enough to create full ASF tolerance. Some animals may have shown delayed clinical signs or lower viral DNA loads in certain samples, but these results do not prove that the pigs had complete ASF resistance.<\/span><\/p>\n This suggests that ASF tolerance is likely a complex trait involving multiple genes, immune responses, and interactions between the virus and the host. Therefore, RELA is valuable as a foundational research direction, but it should not be presented as evidence that CRISPR-based ASF-resistant pigs are close to completion.<\/span><\/p>\n In addition to RELA, some research groups are studying other genes and mechanisms related to ASFV entry, replication, and immune evasion. However, so far, no target gene has been publicly confirmed as sufficient to create a commercial ASF-resistant pig breed.<\/span><\/p>\n Unlike CRISPR, which directly intervenes in the genome, genetic selection is based on identifying and propagating animals that carry genetic characteristics linked to better disease tolerance within a natural population.<\/span><\/p>\n Marker-assisted selection (MAS) uses molecular markers in the genome to identify animals carrying beneficial alleles. This method can be faster than traditional selection based only on observable traits, but it requires markers that are truly linked to ASF tolerance. This has not been firmly confirmed because ASF disease mechanisms are complex and real-world exposure data is difficult to collect.<\/span><\/p>\n Genomic selection uses whole-genome data combined with phenotype data from large populations to build models that predict breeding value. The advantage of genomic selection is that it does not require researchers to know exactly which single gene controls the trait. A statistical model can learn from genome-wide data. The drawback is that it requires a large reference population, clear phenotype data, and a reliable disease recording system.<\/span><\/p>\n For ASF, building a reference population is very difficult because controlled challenge trials cannot be conducted at large scale. This is why genetic selection for ASF resistance is still at the foundational stage.<\/span><\/p>\n Genetic selection has one important practical advantage: it does not create genetically modified organisms in the way many consumers commonly understand the term. As a result, legal and social barriers are usually lower than for gene-edited animals.<\/span><\/p>\n In addition, products from a genetic selection program can be integrated into existing breeding systems and do not necessarily require specialized infrastructure like gene-editing technology. This is why genomic selection is considered a direction that may be closer to commercialization, although its ability to create strong disease resistance may be less clear than a successful gene edit.<\/span><\/p>\n However, even genetic selection cannot deliver quick results for ASF. Without large enough population data and clearly defined resistance indicators, incorporating ASF tolerance into breeding programs will still take many years.<\/span><\/p>\n ASF spread across many countries and caused major losses to the pig industry. Disease pressure pushed research groups in Europe, the United States, China, and other regions to speed up studies on vaccines, immunology, genetics, and ASF tolerance mechanisms.<\/span><\/p>\n An international research team published results on replacing certain warthog RELA motifs in domestic pigs. The results showed that this edit was not enough to create ASF tolerance, although there were some signals of delayed symptoms in a few animals. This was an important finding because it helped reset expectations: ASF cannot be solved through one simple gene edit.<\/span><\/p>\n After the RELA results, research shifted toward identifying additional genetic factors related to ASFV entry, replication, and immune evasion. Some studies used genomic data, immunology, and cell models to identify possible intervention points.<\/span><\/p>\n Breeding programs in many countries continued to expand data on genomes, herd health, and reproductive traits. However, directly integrating \u201cASF resistance\u201d into selection indices remained unclear because reliable and controlled exposure data is needed.<\/span><\/p>\n Some legal progress has appeared for gene-edited livestock targeting other diseases, such as pig lines developed for tolerance to other diseases. However, this does not mean that ASF-resistant gene-edited pigs have been commercially approved.<\/span><\/p>\n By 2026, ASF-resistant pig breeds should still be viewed as a long-term goal. CRISPR research is likely to remain at the laboratory or pre-commercial stage, while genetic selection still needs larger datasets and many generations of evaluation before it can create a product suitable for broad use.<\/span><\/p>\n While waiting for commercial ASF-resistant breeds, Vietnamese pig farmers at different scales can prepare in more practical ways.<\/span><\/p>\n This group is the most likely to gain early access if pig breeds with improved ASF tolerance are commercialized in the future. These businesses should closely follow announcements from international research institutes, major breeding companies, and regulatory agencies. At the same time, they need to build strong biosecurity systems, herd data recording systems, traceability, and internal disease management systems.<\/span><\/p>\n The current priority is not to wait for ASF-resistant breeds, but to practice strict biosecurity, use vaccines according to current guidance, control people and vehicles entering the farm, manage the sources of piglets and breeding stock, and monitor herd health. If domestic breed pilot programs become available, farmers should update information from the Department of Livestock Production & Animal Health, research institutes, and trusted breeding suppliers.<\/span><\/p>\n In the near future, this group does not yet have a clear pathway to access ASF-resistant pig breeds. The most practical priority remains preventing disease spread through barn hygiene, limiting the introduction of animals from unclear sources, avoiding the use of untreated swill, and reporting abnormal signs to local veterinary authorities.<\/span><\/p>\n If pig breeds are announced in the future as resistant to or tolerant of ASF, farmers should not rush to invest based only on advertising. The following criteria should be checked:<\/span><\/p>\n If commercial ASF-tolerant pig breeds become available in the future, their breeding stock cost will likely be higher than conventional breeds. However, the specific price difference cannot yet be predicted because no commercial product is available. Farmers will need to compare the cost of breeding stock with ASF-related losses, biosecurity costs, vaccine costs, and the ability to maintain productivity under disease pressure.<\/span><\/p>\n There is no realistic scenario showing that ASF-resistant pig breeds can become widely accessible to farmers in the short term. Even if research succeeds in the laboratory, the process of testing, safety evaluation, regulatory approval, breeding multiplication, and commercial transfer may still take many years.<\/span><\/p>\n Even a breed described as \u201cASF-resistant\u201d should not be understood as providing 100% protection. In practice, tolerance may depend on the virus strain, exposure dose, herd health, barn conditions, and level of biosecurity. For gene-edited pigs, issues such as off-target effects, genetic stability, animal health, food safety, and market acceptance must continue to be monitored.<\/span><\/p>\n This issue must be evaluated for each specific product. Depending on the editing strategy, CRISPR may not introduce foreign genetic material into the genome and may only change certain locations. However, this does not mean that every CRISPR product is automatically safe or approved for commercialization.<\/span><\/p>\n A full safety assessment needs to consider many factors, including off-target effects, stability over multiple generations, animal health, the nutritional composition of the meat, biosafety risks, and traceability. So far, no ASF-resistant gene-edited pig has been widely approved for commercial food production.<\/span><\/p>\n As of the 2025\u20132026 period, genetic selection for ASF tolerance is still mainly at the foundational stage. Important activities include collecting genomic data, identifying related markers, building prediction models, and evaluating health traits in large populations.<\/span><\/p>\n No commercial pig population has been widely announced as having successfully integrated an ASF resistance index into a breeding selection program. This is an important research direction, but it has not yet produced a product for broad practical use.<\/span><\/p>\n Based on current progress, smallholder pig producers in Vietnam are unlikely to access ASF-resistant pig breeds in the near future. Even in an optimistic scenario, this technology may first appear among major breeding companies or industrial farms in countries with more advanced research and regulatory infrastructure.<\/span><\/p>\n For smallholder producers, the practical strategy today remains strengthening biosecurity, using vaccines according to guidance, managing breeding stock sources, and reporting disease promptly.<\/span><\/p>\n CRISPR has the potential to create stronger and more precise genetic changes if the right target gene is identified. However, this method faces regulatory barriers, biosecurity requirements, and market acceptance challenges.<\/span><\/p>\n Genetic selection may have a closer path to commercialization because it does not directly create gene-edited animals and can be integrated into existing breeding programs. However, its ability to create strong tolerance may be slower and depends heavily on population data.<\/span><\/p>\n In practice, the two approaches may complement each other: genomic selection can help build populations with better overall health and tolerance foundations, while CRISPR can be studied for specialized lines if the genetic mechanism is clearly identified and the legal framework allows it.<\/span><\/p>\n The search for ASF-resistant pig breeds is a long-term scientific journey with major significance for the global pig industry. CRISPR and genetic selection both have potential, but by 2026, there is still no commercial ASF-resistant pig breed ready for Vietnamese farmers.<\/span><\/p>\n The key point is to distinguish clearly between laboratory results, pre-commercial research, and products that have been approved for real-world use. Farmers should not expect ASF-resistant breeds to become a short-term solution.<\/span><\/p>\n In the meantime, the most practical strategy remains maintaining strict biosecurity, controlling transport and pig sources, monitoring disease, using vaccines according to current guidance, and responding quickly when signs of disease appear.<\/span><\/p>\n VIETSTOCK 2026<\/b> \u2013 Vietnam\u2019s Premier International Feed, Livestock & Meat Industry Show \u2013 is expected to bring together more than 300 brands and 13,000 trade visitors from many countries, including vaccine providers, veterinary medicine companies, biosecurity solution providers, and leading regional pig breeding companies. This is an opportunity to:<\/span><\/p>\n Time: <\/b>October 21\u201323, 2026<\/span><\/p>\n Venue:<\/b> Saigon Exhibition and Convention Center (SECC), 799 Nguyen Van Linh, Ho Chi Minh City, Vietnam.<\/span><\/p>\n Register now<\/b> to seize opportunities for growth and networking in the livestock industry:<\/span><\/p>\n Visitor registration:<\/b> https:\/\/www.vietstock.org\/en\/online-registration-2\/<\/b><\/a><\/p>\n Event website:<\/b> https:\/\/www.vietstock.org\/en\/<\/b><\/a><\/p>\n Contact information:<\/span><\/p>\nHow African Swine Fever Has Affected Pig Farming in Vietnam<\/b><\/h2>\n
Characteristics of ASFV and why protective immunity is difficult to achieve<\/b><\/h3>\n
Economic losses since 2019 and why vaccines alone are not enough to fully control ASF<\/b><\/h3>\n
Are there any ASF-resistant pig breeds in Vietnam today?<\/b><\/h2>\n
How does CRISPR technology work in developing ASF-resistant pigs?<\/b><\/h2>\n
![\"Veterinarians](\"https:\/\/media.istockphoto.com\/id\/2225970587\/vi\/anh\/c%C3%A1c-sinh-vi%C3%AAn-n%E1%BB%AF-%C4%91ang-th%E1%BB%AD-nghi%E1%BB%87m-v%C3%A0-nghi%C3%AAn-c%E1%BB%A9u-h%C3%B3a-h%E1%BB%8Dc-trong-m%E1%BB%99t-l%E1%BB%9Bp-h%E1%BB%8Dc-hi%E1%BB%87n-%C4%91%E1%BA%A1i.jpg?s=612x612&w=0&k=20&c=s80J3sArZOW1ah9nQeSuqst2sj1RHWHFAO79KhbyBvA=\")
Step-by-step CRISPR gene-editing process in research on ASF-resistant pigs<\/b><\/h3>\n
Step 1 \u2013 Identify the target gene<\/b><\/h3>\n
Step 2 \u2013 Design the guide RNA<\/b><\/h3>\n
Step 3 \u2013 Edit cells or embryos<\/b><\/h3>\n
Step 4 \u2013 Create pigs carrying the genetic change<\/b><\/h3>\n
Step 5 \u2013 Conduct controlled ASFV challenge trials<\/b><\/h3>\n
The RELA gene and international research results so far<\/b><\/h3>\n
Genetic selection for developing ASF-resistant pig breeds<\/b><\/h2>\n
![\"n\u1eef](\"https:\/\/media.istockphoto.com\/id\/2249359790\/vi\/anh\/n%E1%BB%AF-nh%C3%A0-khoa-h%E1%BB%8Dc-m%E1%BA%B7c-%C3%A1o-kho%C3%A1c-ph%C3%B2ng-th%C3%AD-nghi%E1%BB%87m-v%C3%A0-%C4%91eo-k%C3%ADnh-b%E1%BA%A3o-h%E1%BB%99-nghi%C3%AAn-c%E1%BB%A9u-d%E1%BB%AF-li%E1%BB%87u-di-truy%E1%BB%81n.jpg?s=612x612&w=0&k=20&c=4MiIfYlW_yIOeZYy1HMDqsBuOGga4AIjVvJZGy5VaOU=\")
<\/p>\nMarker-assisted selection and genomic selection in breeding ASF-resistant pigs<\/b><\/h3>\n
Advantages of genetic selection over CRISPR in real-world conditions<\/b><\/h3>\n
Comparison of CRISPR and genetic selection for ASF-resistant pig breeds<\/b><\/h2>\n
\n\n
\n Criteria<\/b><\/td>\n CRISPR gene editing<\/b><\/td>\n Genetic selection<\/b><\/td>\n<\/tr>\n \n Approach<\/span><\/td>\n Directly edits one or more locations in the genome<\/span><\/td>\n Selects and propagates animals with desired genetic characteristics<\/span><\/td>\n<\/tr>\n \n Development timeline<\/span><\/td>\n Can be fast at the laboratory stage, but slow during approval and commercialization<\/span><\/td>\n Slower because progress accumulates over many generations, but easier to integrate into breeding programs<\/span><\/td>\n<\/tr>\n \n Research cost<\/span><\/td>\n Very high, requiring laboratories, biosecurity, and multi-generation trials<\/span><\/td>\n Medium to high, requiring genomic data and large population management<\/span><\/td>\n<\/tr>\n \n Potential level of tolerance<\/span><\/td>\n Can be high if the right gene and disease mechanism are identified<\/span><\/td>\n Medium to high, depending on genetic diversity and selection model accuracy<\/span><\/td>\n<\/tr>\n \n Regulatory barriers<\/span><\/td>\n High, because it involves gene-edited animals for food production<\/span><\/td>\n Lower, because it does not directly create gene-edited products<\/span><\/td>\n<\/tr>\n \n Applicability in Vietnam<\/span><\/td>\n Limited in the near future due to legal, infrastructure, and market acceptance requirements<\/span><\/td>\n More feasible if breeding programs, data, and long-term evaluation systems are available<\/span><\/td>\n<\/tr>\n \n Genetic stability<\/span><\/td>\n Requires monitoring of off-target effects and stability over many generations<\/span><\/td>\n Can be stabilized through selection and traditional breeding<\/span><\/td>\n<\/tr>\n \n Social acceptance<\/span><\/td>\n May raise concerns among consumers and export markets<\/span><\/td>\n More easily accepted because it is closer to traditional breeding<\/span><\/td>\n<\/tr>\n \n Progress toward 2026<\/span><\/td>\n No commercial ASF-resistant product yet<\/span><\/td>\n No complete ASF-resistant breed yet; foundational research is ongoing<\/span><\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n Research timeline for ASF-resistant pig breeds from 2019 to 2026<\/b><\/h2>\n
![\"\"](\"https:\/\/media.istockphoto.com\/id\/2249359786\/vi\/anh\/n%E1%BB%AF-nh%C3%A0-khoa-h%E1%BB%8Dc-%C4%91eo-k%C3%ADnh-b%E1%BA%A3o-h%E1%BB%99-v%C3%A0-%C4%91eo-g%C4%83ng-tay-cao-su-ti%E1%BA%BFn-h%C3%A0nh-th%C3%AD-nghi%E1%BB%87m-trong-ph%C3%B2ng-th%C3%AD.jpg?s=612x612&w=0&k=20&c=A0LqWgDda6Y_0CMoAADjKz3aid664bQfAYduq3iI5AA=\")
<\/p>\n2019 \u2013 ASF outbreaks intensified in Asia and accelerated urgent research<\/b><\/h3>\n
2020 \u2013 Research on RELA editing in domestic pigs was published<\/b><\/h3>\n
2021\u20132023 \u2013 The search for related genes and mechanisms expanded<\/b><\/h3>\n
2024 \u2013 More attention turned to population data and genomic selection<\/b><\/h3>\n
2025 \u2013 Legal evaluation and monitoring of progress in gene-edited livestock<\/b><\/h3>\n
2026 \u2013 Research remains at the pre-commercial stage<\/b><\/h3>\n
Practical application of ASF-resistant pig breeds in Vietnamese pig farming<\/b><\/h2>\n
Conditions and farm groups that should prepare for future access to ASF-resistant breeds<\/b><\/h3>\n
For large-scale farms and industrial livestock companies<\/b><\/h3>\n
For medium and small farms<\/b><\/h3>\n
For smallholder pig producers<\/b><\/h3>\n
Checklist for evaluating ASF-resistant pig breeds before production use<\/b><\/h2>\n
![](\"https:\/\/media.istockphoto.com\/id\/2212330716\/vi\/anh\/n%E1%BB%AF-n%C3%B4ng-d%C3%A2n-da-tr%E1%BA%AFng-s%E1%BB%AD-d%E1%BB%A5ng-m%C3%A1y-t%C3%ADnh-b%E1%BA%A3ng-%C4%91%E1%BB%83-ch%C4%83m-s%C3%B3c-l%E1%BB%A3n-con-t%E1%BA%A1i-trang-tr%E1%BA%A1i-hi%E1%BB%87n-%C4%91%E1%BA%A1i.jpg?s=612x612&w=0&k=20&c=FYbpXIQn0vtFkyljb_dFjwi508CTjcXab2u4Sf-Jp9o=\")
<\/p>\n\n
Costs, timeline, and risks to consider before adoption<\/b><\/h2>\n
Cost<\/b><\/h3>\n
Timeline<\/b><\/h3>\n
Risks<\/b><\/h3>\n
FAQ about ASF-resistant pig breeds<\/b><\/h2>\n
![\"Nh\u00f3m](\"https:\/\/media.istockphoto.com\/id\/539643414\/vi\/anh\/nh%C3%B3m-heo-con-t%C3%B2-m%C3%B2-trong-pigpen.jpg?s=612x612&w=0&k=20&c=ld7PDdj6K8e93g6o-kqEJ-L1eNhafNi99YFDZOhunmQ=\")
<\/p>\nIs CRISPR gene editing for ASF-resistant pigs safe for consumers?<\/b><\/h3>\n
What stage has genetic selection for ASF-resistant pigs reached by 2026?<\/b><\/h3>\n
How long will it take for smallholder pig producers in Vietnam to access ASF-resistant pig breeds?<\/b><\/h3>\n
CRISPR vs. genetic selection: which method is more likely to be commercialized sooner?<\/b><\/h3>\n
In summary<\/b><\/h2>\n
Stay Updated on ASF Prevention Technologies and Solutions at VIETSTOCK 2026<\/b><\/h2>\n
\n