Prospects for the cultivation of grain sorghum (Sorghum bicolor L. Moench) in the arid region of the Kazakh Aral Sea region: Literature review

Ibadulla Tautenov, Serik Bekzhanov, Laura Tokhetova, Bekzathan Kultassov, Anar Onalsyn
Received: 12.10.2024 Revised: 20.03.2025 Accepted: 30.04.2025
Retrieved from Vol. 28, No. 5, 2025 Pages: 20-31
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Abstract

The purpose of the present study was to substantiate effective breeding and agronomic solutions for improving the resistance of sorghum to climatic stresses in the conditions of the Aral Sea region. Based on an analysis of literature sources, the study showed that the agricultural sector of the Kyzylorda region of the Republic of Kazakhstan faces a persistent water shortage caused by both natural and anthropogenic factors. A considerable reduction in water inflows to the lower reaches of the Syr Darya, degradation of irrigation infrastructure, and deterioration of water quality create conditions under which conventional water-intensive crops such as rice become economically and environmentally unviable. A review of sources confirmed that, along with technical measures such as the introduction of water-saving technologies, the transition to more drought-resistant crops, including sorghum, is becoming increasingly significant. Sorghum was demonstrated to have unique physiological adaptations to water and heat stress due to its morphological and anatomical characteristics, growth phases, and ability to retain green mass. In the Aral Sea region, this crop is considered a key element in the strategy for adapting crop production to changing climatic conditions. Furthermore, sorghum has a wide range of applications, from food and feed to bioenergy, which highlights its agro-economic value. The literature review also noted growing interest in the genetic and breeding potential of sorghum: international gene banks hold more than 42,000 samples, including unique genotypes from Africa and Asia, which opens prospects for the creation of sustainable and high-yielding varieties. Thus, the findings of the literature review confirmed the pronounced adaptability of sorghum to the conditions of the Aral Sea region, its strategic significance in conditions of water stress, and the relevance of further breeding and agronomic developments aimed at its widespread introduction into the region’s agriculture

Keywords

stress tolerance; genetic diversity; biopreparations; agrotechnical methods; water use efficiency

  1. Adebo, O.A. (2020). African sorghum-based fermented foods: Past, current and future prospects. Nutrients, 12(4), article number 1111. doi: 10.3390/nu12041111.
  2. Ashesh, A., Purohit, N.N., Paul, R.M., Kaur, S., Singh, A., Kaur, A., Purewal, S.S., & Kohli, R. (2025). Current scenario and future prospects. In S.S. Purewal & R.S. Singh (Eds.), Colored сereals: Properties, processing, health benefits, and industrial uses (pp. 392-412). Boca Raton: CRC Press. doi: 10.1201/9781003454922.
  3. Bakari, H., Djomdi, Ruben, Z.F., Roger, D.D., Cedric, D., Guillaume, P., Pascal, D., Philippe, M., & Gwendoline, C. (2023). Sorghum (Sorghum bicolor L. Moench) and its main parts (by-products) as promising sustainable sources of value-added ingredients. Waste and Biomass Valorization, 14, 1023-1044. doi: 10.1007/s12649-022-01992-7.
  4. Balakrishna, D., Singode, A., Narasimham, D., & Bhat, B.V. (2020). Current status and future prospects of genetic transformation and gene editing in Sorghum. In V.A. Tonapi, H.S. Talwar, A.K. Are, B.V. Bhat, Ch.R. Reddy & T.J. Dalton (Eds.), Sorghum in the 21st Century: Food-fodder-feed-fuel for a rapidly changing world (pp. 511-535). Singapore: Springer. doi: 10.1007/978-981-15-8249-3_21.
  5. Barron, A., Fuller, D., Stevens, C., Champion, L., Winchell, F., & Denham, T. (2020). Snapshots in time: MicroCT scanning of pottery sherds determines early domestication of sorghum (Sorghum bicolor) in East Africa. Journal of Archaeological Science, 123, article number 105259. doi: 10.1016/j.jas.2020.105259.
  6. Biswas, J.C., Islam, M.R., Haque, M.M., & Hamid, A. (2021). Minor cereal crop production and their future prospects in Bangladesh. Asian Soil Research Journal, 5(1), 48-56. doi: 10.9734/ASRJ/2021/v5i130101.
  7. Bolokhovsky, V., Bolokhovska, V., Khomenko, T., Datsko, A., & Litvinova, O. (2024). Optimisation of plant nutrition under the influence of biopreparations in integrated sunflower cultivation technologies. Plant and Soil Science, 15(4), 64-75. doi: 10.31548/plant4.2024.64.
  8. Bvenura, C., & Kambizi, L. (2022). Future grain crops. In R. Bhat (Ed.), Future foods: Global trends, opportunities, and sustainability challenges (pp. 81-105). London: Elsevier. doi: 10.1016/B978-0-323-91001-9.00032-3.
  9. Choudhary, K.B., Khandelwal, V., Singh, D., & Sharma, S.R. (2025). Optimizing hybrid sorghum seed production: Key challenges and future opportunities. In A. Lamichaney, A.K. Parihar, A. Bohra, P. Karmakar & S.J.S. Naik (Eds.), Hybrid seed production for boosting crop yields: Applications, challenges and opportunities (pp. 105-125). Singapore: Springer. doi: 10.1007/978-981-96-0506-4_5.
  10. Cuevas, H., & Prom, L. (2020). Evaluation of genetic diversity, agronomic traits, and anthracnose resistance in the NPGS Sudan Sorghum Core collection. BMC Genomics, 21, article number 88. doi: 10.1186/s12864-0206489-0.
  11. Dhakar, R., Nagar, S., Sehgal, V., Jha, P., Singh, M., Chakraborty, D., Mukherjee, J., & Prasad, P. (2023). Balancing water and radiation productivity suggests a clue for improving yields in wheat under combined water deficit and terminal heat stress. Frontiers in Plant Science, 14, article number 1171479. doi: 10.3389/fpls.2023.1171479.
  12. Dhar, A., Kumari, B.M., Kavithamani, D., Boopathi, N.M., & Meenakshi, P. (2024). Understanding the advances in Sorghum grain quality improvement: An overview. Plant Science Today, 11(3), 61-78. doi: 10.14719/pst.3527.
  13. Dixit, P., & Ravichandran, R. (2024). The potential of millet grains: A comprehensive review of nutritional value, processing technologies, and future prospects for food security and health promotion. Journal of Food Technology & Nutrition Sciences, 6(1), 2-8. doi: 10.47363/JFTNS/2024(6)170.
  14. Dubery, I., Nephali, L., Tugizimana, F., & Steenkamp, P. (2024). Data-driven characterization of metabolome reprogramming during early development of sorghum seedlings. Metabolites, 14(2), article number 112. doi: 10.3390/metabo14020112.
  15. Eduru, A., Kamboj, A., Reddy, P.M., & Pal, B. (2021). Nutritional and health benefits of millets, present status and future prospects: A review. Pharma Innovation Journal, 10(5), 859-868.
  16. Enyew, M., Feyissa, T., Carlsson, A., Tesfaye, K., Hammenhag, C., & Geleta, M. (2022). Genetic diversity and population structure of sorghum [Sorghum Bicolor (L.) Moench] accessions as revealed by single nucleotide polymorphism markers. Frontiers in Plant Science, 12, article number 799482. doi: 10.3389/fpls.2021.799482.
  17. Hadebe, S.T., Modi, A.T., & Mabhaudhi, T. (2021). Assessing suitability of sorghum to alleviate sub-saharan nutritional deficiencies through the nutritional water productivity index in semi-arid regions. Foods, 10(2), article number 385. doi: 10.3390/foods10020385.
  18. Hao, H., Li, Z., Leng, C., Lu, C., Luo, H., Liu, Y., Wu, X., Liu, Z., Shang, L., & Jing, H. (2021). Sorghum breeding in the genomic era: Opportunities and challenges. Theoretical and Applied Genetics, 134, 1899-1924. doi: 10.1007/ s00122-021-03789-z.
  19. Havrysh, V., Nitsenko, V., & Hruban, V. (2022). Sorghum-based power generation in Southern Ukraine: Energy and environmental assessment. Agriculture (Switzerland), 12(12), article number 2148. doi: 10.3390/ agriculture12122148.
  20. Hermann, T.W., Nerbéwendé, S., Josiane, T., Pingawindé, S., & Mahamadou, S. (2023). Genetic diversity, importance and prospects for varietal improvement of sweet grain sorghum in Burkina Faso. International Journal of Zoology and Applied Biosciences, 8(1), 44-52. doi: 10.55126/ijzab.2023.v08.i01.007.
  21. Hossain, S., Islam, N., Rahman, M., Mostofa, G., & Khan, A.R. (2022). Sorghum: A prospective crop for climatic vulnerability, food and nutritional security. Journal of Agriculture and Food Research, 8, article number 100300. doi: 10.1016/j.jafr.2022.100300.
  22. Ibrahim, M.E. (2021). Genetic diversity of the Sudanese: Insights on origin and implications for health. Human Molecular Genetics, 30(R1), R37-R41. doi: 10.1093/hmg/ddab028.
  23. Khalifa, M., & Eltahir, E.A.B. (2023). Assessment of global sorghum production, tolerance, and climate risk. Frontiers in Sustainable Food Systems, 7, article number 1184373. doi: 10.3389/fsufs.2023.1184373.
  24. Kopecká, R., Kameniarová, M., Černý, M., Brzobohatý, B., & Novák, J. (2023). Abiotic stress in crop production. International Journal of Molecular Sciences, 24(7), article number 6603. doi: 10.3390/ijms24076603.
  25. Liu, Q.S. (2023). Research course and prospects of Shanxi hybrid sorghum breeding. Journal of Shanxi Agricultural Sciences, 51(10), 1115-1120. doi: 10.3969/j.issn.1002-2481.2023.10.01.
  26. Liu, Y., Liu, S., Huang, C., Ge, X., Xi, B., & Mao, J. (2022). Chinese Baijiu distiller’s grains resourcing: Current progress and future prospects. Resources, Conservation and Recycling, 176, article number 105900. doi: 10.1016/j. resconrec.2021.105900.
  27. Mace, E., Cruickshank, A., Tao, Y., Hunt, C., & Jordan, D. (2020). A global resource for exploring and exploiting genetic variation in sorghum crop wild relatives. Crop Science, 61(1), 150-162. doi: 10.1002/csc2.20332.
  28. Mangshin, G.B., Buba, U.M., Dama, A.Z., & Lawal, A.A. (2024). Genetic variability, heritability and genetic advance in sorghum (Sorghum bicolor (L.) Moench) accessions from West and Central Africa. Nigerian Journal of Agriculture and Agricultural Technology, 4(1), 272-279. doi: 10.59331/njaat.v4i1.651.
  29. Masatbaev, M., & Khozhanov, N. (2021). Assessment of the dependence of soil humus components on climate elements in the Zhambyl region. Izdenister Natiges, 1(89), 137-146. doi: 10.37884/1-2021/15.
  30. Mass rice harvesting has begun in Kyzylorda region. (2022). Retrieved from https://www.inform.kz/ru/ massovaya-uborka-risa-nachalas-v-kyzylordinskoy-oblasti_a3969202?utm_source=chatgpt.com.
  31. Meena, K., Visarada, K.B.R.S., & Meena, D.K. (2022). Sorghum bicolor (L.) Moench a multifarious crop-fodder to therapeutic potential and biotechnological applications: A future food for the millennium. Future Foods, 6, article number 100188. doi: 10.1016/j.fufo.2022.100188.
  32. Mwamahonje, A., Mdindikasi, Z., Mchau, D., Mwenda, E., Sanga, D., Garcia-Oliveira, A.L., & Ojiewo, C.O. (2024). Advances in sorghum improvement for climate resilience in the Global Arid and Semi-Arid Tropics: A review. Agronomy, 14(12), article number 3025. doi: 10.3390/agronomy14123025.
  33. Nasiev, B.N., & Zhilkybay, A.M. (2022). Biologized technologies of safflower cultivation in Western Kazakhstan. Uralsk: West Kazakhstan Agrarian and Technical University named after Zhangir Khan.
  34. National report on the state of the environment and on the use of natural resources of the Republic of Kazakhstan for 2022. (2023). Retrieved from https://surl.li/ydyhwj.
  35. Pandian, B.A., Sexton-Bowser, S., Prasad, P.V., & Jugulam, M. (2022). Current status and prospects of herbicideresistant grain sorghum (Sorghum bicolor). Pest Management Science, 78(2), 409-415. doi: 10.1002/ps.6644.
  36. Parikh, A., Brant, E.J., Baloglu, M.C., & Altpeter, F. (2021). CRISPR/Cas-mediated genome editing in sorghum – recent progress, challenges and prospects. In Vitro Cellular & Developmental Biology-Plant, 57, 720-730. doi: 10.1007/s11627-021-10215-y.
  37. Pichura, V., Potravka, L., Domaratskiy, Y., & Drobitko, A. (2024). Water balance of winter wheat following different precursors on the Ukrainian steppe. International Journal of Environmental Studies, 81(1), 324-341. doi: 10.1080/00207233.2024.2314891.
  38. Pujiharti, Y., Paturohman, E., & Ikhwani. (2022). Prospect of sorghum development as corn substitution in Indonesia. IOP Conference Series: Earth and Environmental Science, 978, article number 012019. doi: 10.1088/1755-1315/978/1/012019.
  39. Rashwan, A.K., Yones, H.A., Karim, N., Taha, E.M., & Chen, W. (2021). Potential processing technologies for developing sorghum-based food products: An update and comprehensive review. Trends in Food Science and Technology, 110, 168-182. doi: 10.1016/J.TIFS.2021.01.087.
  40. Reshetnikov, M., Moroz, S., Pasichnyk, L., & Butsenko, L. (2023). Sensitivity of sorghum bacteriosis to antibiotics. Biological Systems: Theory and Innovation, 14(1), 112-122. doi: 10.31548/biologiya14(1-2).2023.003.
  41. Sarwar, A.K.M.G., & Biswas, J.K. (2021). Cereal grains of Bangladesh – present status, constraints and prospects. In A.K. Goyal (Ed.), Cereal grains (pp. 19-38). London: IntechOpen. doi: 10.5772/intechopen.97072.
  42. Singh, K., Gupta, K., Tyagi, V., & Rajkumar, S. (2020). Plant genetic resources in India: Management and utilization. Vavilov Journal of Genetics and Breeding, 24(3), 306-314. doi: 10.18699/VJ20.622.
  43. Sirany, T., Tadele, E., Aregahegn, H., & Wale, D. (2022). Economic potentials and use dynamics of sorghum food system in Ethiopia: Its implications to resolve food deficit. Advances in Agriculture, 2022(1), article number 4580643. doi: 10.1155/2022/4580643.
  44. Smith, A., Gentile, B.R., Xin, Z., & Zhao, D. (2023). The effects of heat stress on male reproduction and tillering in Sorghum bicolorFood and Energy Security, 12(6), article number e510. doi: 10.1002/fes3.510.
  45. Somegowda, V.K., Rayaprolu, L., Rathore, A., Deshpande, S.P., & Gupta, R. (2021). Genome-wide association studies (GWAS) for traits related to fodder quality and biofuel in sorghum: Progress and prospects. Protein and Peptide Letters, 28(8), 843-854. doi: 10.2174/0929866528666210127153103.
  46. Soni, J.K., Sailo, L., Lalramhlimi, B., Shakuntala, I., & Doley, S. (2023). Millets cultivation in Mizoram: Status and future prospectsIndian Farming, 73(5), 25-27.
  47. Sprynchuk, N., Voronetska, I., Yudova, O., Korniychuk, O., & Zadorozhna, I. (2023). Priority areas for the development of field fodder production in view of the climate crisis. Ekonomika APK, 30(6), 34-44. doi: 10.32317/22211055.202306034.
  48. Subudhi, P.K., Nguyen, H.T., Gilbert, N.N., & Rosenow, D.T. (2024). Sorghum improvement: Past achievements and future prospects. In M.S. Kang (Ed.), Crop improvement: Challenges in the twenty-first century (pp. 109-160). Boca Raton: CRC Press. doi: 10.1201/9781003578512.
  49. Tokhetova, L., Akhmedova, G., Baimbetova, G., & Akzhunis, R. (2022). Creation of the raw material of naked barley for selection for adaptability to environmental stress factorsScience and Education, 2(1(66), 21-33.
  50. Weldemichael, M.Y., Gebremedhn, H.M., & Teklu, T.H. (2024). Advances in genome editing and future prospects for Sorghum improvement: A review. Plant Gene, 39, article number 100464. doi: 10.1016/j.plgene.2024.100464.
  51. Yadav, R., & Singh, C.P. (2024). Sorghum-encoded microRNAs: Current status and future prospects. Plant Biotechnology Reports, 18, 587-603. doi: 10.1007/s11816-024-00914-4.
  52. Yali, W., & Begna, T. (2022). Sorghum breeding in Ethiopia: Progress, achievements and challenges. International Journal of Agricultural Science and Food Technology, 8(1), 45-51. doi: 10.17352/2455-815X.000144.
  53. Yeraliyeva, Z.M., Kurmanbayeva, M.S., Makhmudova, K.K., Kolev, T.P., & Kenesbayev, S.M. (2017). Comparative characteristic of two cultivars of winter common wheat (Triticum aestivum L.) cultivated in the southeast of Kazakhstan using the drip irrigation technology. OnLine Journal of Biological Sciences, 17(2), 41-49. doi: 10.3844/ ojbsci.2017.40.49.
  54. Zheng, H., Dang, Y., & Sui, N. (2023). Sorghum: A multipurpose crop. Journal of Agricultural and Food Chemistry, 71(46), 17570-17583. doi: 10.1021/acs.jafc.3c04942.
Tautenov, I., Bekzhanov, S., Tokhetova, L., Kultassov, B., & Onalsyn, A. (2025). Prospects for the cultivation of grain sorghum (Sorghum bicolor L. Moench) in the arid region of the Kazakh Aral Sea region: Literature review. Scientific Horizons, 28(5), 20-31. https://doi.org/10.48077/scihor5.2025.20