News Release

Advancing CBSD resistance in cassava: a comprehensive review of breeding strategies and the role of new plant technologies

Peer-Reviewed Publication

Maximum Academic Press

Fig.1

image: 

 Symptoms of cassava brown streak disease. 

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Credit: The authors

A research team reviewed the advancements in managing cassava brown streak disease (CBSD), highlighting the integration of new plant breeding technologies (NPBTs) with traditional breeding to enhance resistance. These efforts are crucial for providing African farmers with CBSD-resistant cassava varieties that also deliver high yields and meet market preferences. The team also advocates for a collaborative network of African breeders, access to modern technologies, strengthened stakeholder capacities, controlled planting material movement, and efficient trait introgression in breeding programs to achieve these goals.

Cassava, a staple for 800 million people, primarily grown in over 100 tropical and subtropical countries, faces significant yield challenges due to cassava brown streak disease (CBSD), particularly in Africa where production significantly lags behind potential yields. Despite the resilience of cassava in harsh conditions and its substantial starch content, CBSD has drastically hindered productivity. Current research focuses on breeding CBSD-resistant varieties through traditional and new plant breeding technologies (NPBTs), yet problems like the breakdown of resistance in once-tolerant varieties and the need for sustainable, disease-free planting material distribution remain critical.

A study (DOI: 10.48130/tp-0024-0006) published in Tropical Plants on 26 February 2024, outlines existing breeding strategies for combating CBSD and highlights the benefits of incorporating NPBTs to quickly develop and distribute CBSD-resistant cassava varieties to African farmers.

The review first introduces that cassava is a highly heterozygous crop, typically propagated asexually using stem cuttings or tissue culture systems. Due to the characteristics of protogyny, hermaphroditism, and mainly hybrid fertilization in cassava, controlling pollination can produce full sibling offspring. However, challenges arise due to the crop's high heterozygosity and the environmental sensitivity of its flowering, complicating controlled breeding efforts. The author detailed the methods for screening cassava CBSD resistant germplasm under two different conditions, field and greenhouse. Emphasizing the critical role of NPBTs, the review advocates for their integration into cassava breeding programs to expedite the development of varieties resistant to CBSD. By leveraging both traditional and modern breeding techniques, the review underscores the need for a multifaceted approach to overcome breeding challenges and improve cassava's resilience and yield in diverse environments.

According to the study's researcher, Prof. Hong-Bin Zhang, “ CBSD remains an important constraint to cassava production in Eastern and Central Africa. Efforts to develop CBSD resistance will need to be an important part of modernized breeding approaches that aim to develop improved varieties with balanced trait sets that meet the needs of user-focused product profiles.”

Overall, the review explores cassava's complex reproduction, emphasizing the integration of new plant breeding technologies to enhance the development of disease-resistant varieties and address the challenges of genetic diversity and environmental sensitivities in breeding programs.

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References

DOI

10.48130/tp-0024-0006

Original Source URL

https://doi.org/10.48130/tp-0024-0006

Authors

Jean Pierre Bizimana1,4* , Yvan Ngapout2 , Chantal Nyirakanani1 , Sara Shakir1,2 , Edouard Kanju3 ,James Peter Legg3 , Placide Rukundo4 , Hussein Shimelis5 , Athanase Nduwumuremyi4 and Hervé Vanderschuren1,2*

Affiliations

1 Plant Genetics and Rhizosphere Processes Laboratory, TERRA Teaching and Research Center, University of Liège, Gembloux Agro-Bio Tech, Gembloux, Belgium

2 Tropical Crop Improvement Laboratory, Department of Biosystems, Katholieke Universiteit Leuven, Heverlee, Belgium

3 International Institute of Tropical Agriculture, PO Box 34441, Dar es Salaam, Tanzania

4 Department of Research, Rwanda Agriculture and Animal Resources Development Board, Huye, Rwanda

5 African Centre for Crop Improvement, University of KwaZulu-Natal, Private Bag X01, Scottsville 3209, Pietermaritzburg, South Africa


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