«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

¡¶¼¯ÃÀ´óѧѧ±¨£¨×ÔÈ»¿Æѧ°æ£©¡·[ISSN:1007-7405/CN:35-1186/N]

¾í:

µÚ28¾í

ÆÚÊý:

2023ÄêµÚ3ÆÚ

Ò³Âë:

205-213

À¸Ä¿:

Ë®²ú¡¢Ê³Æ·ÓëÉúÎ﹤³Ì

³ö°æÈÕÆÚ:

2023-05-28

ÎÄÕÂÐÅÏ¢/Info

Title:

A Genomic Selection Method Based on Artificial Intelligence

×÷Õß:

¹ËÁÖÁÖ1; 2; ÍõÖ¾ÓÂ1; 2; ·½Ãú1; 2

(1.¼¯ÃÀ´óѧˮ²úѧԺ£¬¸£½¨ ÏÃÃÅ 361021£»2.ũҵũ´å²¿¶«º£º£Ë®½¡¿µÑøÖ³ÖصãʵÑéÊÒ£¬¸£½¨ ÏÃÃÅ361021)

Author(s):

GU Linlin1; 2;  WANG Zhiyong1; 2;  FANG Ming1; 2

(1.Fisheries College, Jimei University, Xiamen 361021, China;2.Key Laboratory of Healthy Mariculture for the East China Sea of Ministry of Agriculture, Xiamen 361021, China)

¹Ø¼ü´Ê:

»ùÒò×éÑ¡Ôñ; »ùÒò×é¹À¼ÆÓýÖÖÖµ; Éñ¾­ÍøÂç; Éî¶Èѧϰ

Keywords:

genomic selection; genomic estimation breeding value; neural network; deep learning

·ÖÀàºÅ:

-

DOI:

-

ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

»ùÒò×éÑ¡Ôñ (genomic selection, GS) ÊÇÒ»ÖÖÀûÓÃÈ«»ùÒò×éµÄ±ê¼ÇÐÅÏ¢½øÐÐÑ¡ÔñÓýÖÖµÄз½·¨¡£ËüÀûÓòο¼ÈºÌåµÄ»ùÒòÐͺͱíÐÍÐÅÏ¢½øÐÐѵÁ·£¬¶ÔÖ»º¬»ùÒòÐÍÐÅÏ¢µÄºòѡȺÌåÔ¤²â»ùÒò×é¹À¼ÆÓýÖÖÖµ (genomic estimated breeding value, GEBV)¡£¿ª·¢ÁËÒ»ÖÖеÄÉî¶Èѧϰ»ùÒò×éÑ¡Ôñ (genomic selection, GS) ·½·¨£¬²¢ÃüÃûΪDRNGS (deep residual network genomic selection)¡£Ð·½·¨µÄÌصãÓУº1) ÒÔÉî¶È²Ð²îÍøÂçÀ´Ô¤²â»ùÒò×é¹À¼ÆÓýÖÖÖµ (genomic estimated breeding value, GEBV)£¬¿É²¶»ñ»ùÒòÐÍÄÚ²¿µÄ¸´ÔÓ¹Øϵ£¬Ìá¸ßÔ¤²â׼ȷÐÔ£»2) ²ÉÓþí»ýºÍ³Ø»¯²ßÂÔÀ´½µµÍ¸ßά»ùÒòÐÍÊý¾ÝµÄ¸´ÔÓÐÔ£¬¼Ó¿ì¼ÆËãËٶȣ»3) ·½·¨ÖÐÒýÈëÅúÁ¿¹éÒ»»¯²ã£¬¼Ó¿ìÁËÊÕÁ²Ëٶȡ£½«Ð·½·¨Ó¦ÓÃÓÚCIMMYTСÂóÊý¾Ý¼¯£¬ÊµÑé½á¹û±íÃ÷£ºDRNGSµÄЧ¹û±ÈÇ°À¡Éñ¾­ÍøÂç (feedforward neural network, FNN)Ìá¸ßÁË101.59%~130.83%£»ÔڶԴ󲿷ÖÐÔ×´µÄ±íÐÍÔ¤²âÖУ¬DRNGS±ÈGBLUP (genomic best linear unbiased prediction) Ìá¸ßÁË2.24%~20.19%£»ÔÚ¼ÆËãºÄʱ·½Ã棬DRNGS½ö´ÎÓÚGBLUP£¬±ÈDeepGS¿ìÁË´óÔ¼18~22±¶£¬±ÈFNN¿ìÁË24~26±¶¡£Îª½øÒ»²½±È½ÏDRNGSºÍDeepGS£¬ÓÃÒÁÀÊÃæ°üСÂó (Triticum aestivum) Êý¾Ý¼¯½øÐвâÊÔ£¬½á¹û±íÃ÷:DRNGSÊÕÁ²ËÙ¶ÈÓÅÓÚDeepGS;ÔÚ¶ÔËùÓÐÐÔ×´µÄ±íÐÍÔ¤²â¹ý³ÌÖУ¬DRNGSµÄ¼ÆËãºÄʱʼÖÕ½ÏDeepGS¶Ì;¶øÇÒDRNGSÔÚÔ¤²â׼ȷÐÔ·½ÃæÓÅÓÚDeepGS,ÔÚ8¸öÐÔ×´ÖУ¬DRNGS½ÏDeepGSÌá¸ß0.12%~1.59%¡£²¢½«DRNGS¿ª·¢³ÉR°ü£¬¿Éͨ¹ýhttps://github.com/GuLinLin.JMU/DRNGS·ÃÎÊ¡£

Abstract:

Genomic selection (GS) is a new approach to selective breeding by using genome-wide markers. It uses genotypic and phenotypic information from a reference population for training, and then predicts This paper has improved and developed a new deep learning Genomic selection (GS) method named deep residual network genomic selectio (DRNGS).The features of the new method were: 1) a deep residual network was used to predict genomic estimated breeding value (GEBV), which could capture the complex relationships within genotypes and improve the prediction accuracy; 2) convolution and pooling strategies were used to reduce the complexity of high-dimensional genotype data and speed up the computation; 3) a batch normalization layer was introduced in the method to speed up the convergence speed.The new method applied the CIMMYT wheat dataset,and the experimental results showed that DRNGS outperformed Feedforward Neural Network (FNN) with a relative improvement of 101.59%-130ª±83%. DRNGS outperformed Genomic Best Linear Unbiased Prediction (GBLUP) by 2.24% to 20.19% for phenotypic prediction of most traits. It was the second only to GBLUP in terms of computational time consumption, and was approximately 18.22 times faster than DeepGS and 24.26 times faster than FNN. To further compare DRNGS with DeepGS, we applied the Iranian bread wheat (Triticum aestivum) dataset for testing and showed that DRNGS converged faster than DeepGS, consistently took less time to compute than DeepGS in predicting phenotypes for all traits, and that DRNGS outperformed DeepGS in terms of prediction accuracy. For eight traits, DRNGS improved 0.12%-1.59% over DeepGS.DRNGS has been developed as an R package, which can be accessed at https://github.com/GuLinLin.JMU/DRNGS.

²Î¿¼ÎÄÏ×/References:

ÏàËÆÎÄÏ×/References:

±¸×¢/Memo

±¸×¢/Memo:

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2023-09-12