{"title":"在草豆表型中,花/种皮颜色与籽粒产量、品质和对种子象鼻虫的耐受性相关","authors":"Ioannis T. Tsialtas, Maria Irakli","doi":"10.1111/aab.12880","DOIUrl":null,"url":null,"abstract":"<p>Grass pea (<i>Lathyrus sativus</i> L.) is considered an orphan/underutilised grain legume with high yield and nutritive potential. It is variable in flower and seed coat (testa) colour and this variation could possibly be used as a biomarker in phenotypic selection for yield and quality traits. Three phenotypes differing in flower/testa colour (white flower-white to creamy testa and white hilum [T<sub>W</sub>H<sub>W</sub>], slightly blue banner and wing colouration-white to creamy testa and coloured halo around hilum [T<sub>W</sub>H<sub>C</sub>] and blue banner and wing colouration-spotted testa and coloured halo around hilum [T<sub>S</sub>H<sub>C</sub>]) were tested over two growing seasons, under rainfed, Mediterranean conditions. They differed only in the number of seeds per pod; the phenotype T<sub>W</sub>H<sub>W</sub> had the lowest number (2.2 seeds pod<sup>−1</sup>). The seed yield per plant (SY) was highly correlated with the number of pods per plant and was higher under wetter and warmer conditions during the reproductive period (April–May). The three phenotypes showed no difference in tolerance against bruchid (<i>Bruchus tristiculus</i>) infection (<i>F</i><sub>2,8</sub> = 0.14, <i>p</i> > .05), which was higher in the most productive growing season (6.44%, <i>F</i><sub>1,4</sub> = 14.8, <i>p</i> < .05). In the phenotype T<sub>W</sub>H<sub>W</sub>, three seed classes (intact, bruchid-damaged, parasitoid-damaged seeds) were tested for SY, quality traits and tolerance to bruchids. Though insect damaged seeds showed significant reduction in emergence rates (from −57% up to −91%), there were no differences in SY (19.11–24.53 g plant<sup>−1</sup>, <i>F</i><sub>2,8</sub> = 0.86, <i>p</i> > .05) and yield components (seeds per pod, 1000-seed weight, number of pods per plant). However, seeds of plants derived from parasitoid-damaged seeds had higher concentration of the neurotoxin ODAP (4.92 mg g<sup>−1</sup>, <i>F</i><sub>2,8</sub> = 8.76, <i>p</i> < .01). On the other hand, seeds of plants derived from bruchid-damaged seeds showed higher percentage of damaged seeds by the endoparasitoid <i>Triaspis thoracica</i> (2.25% vs. 0.67%–1.00%, <i>F</i><sub>2,8</sub> = 5.47, <i>p</i> < .05). Concluding, flower and testa colour cannot be used as biomarkers of seed yield and quality in grass pea, but it seemed that a tripartite interaction (grass pea–bruchid–endoparasitoid) may occur that affects ODAP concentration and the susceptibility of seeds to insect damages.</p>","PeriodicalId":7977,"journal":{"name":"Annals of Applied Biology","volume":"184 2","pages":"250-258"},"PeriodicalIF":2.2000,"publicationDate":"2023-11-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Flower/testa colour associations with grain yield, quality and tolerance to seed weevil in grass pea phenotypes\",\"authors\":\"Ioannis T. Tsialtas, Maria Irakli\",\"doi\":\"10.1111/aab.12880\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Grass pea (<i>Lathyrus sativus</i> L.) is considered an orphan/underutilised grain legume with high yield and nutritive potential. It is variable in flower and seed coat (testa) colour and this variation could possibly be used as a biomarker in phenotypic selection for yield and quality traits. Three phenotypes differing in flower/testa colour (white flower-white to creamy testa and white hilum [T<sub>W</sub>H<sub>W</sub>], slightly blue banner and wing colouration-white to creamy testa and coloured halo around hilum [T<sub>W</sub>H<sub>C</sub>] and blue banner and wing colouration-spotted testa and coloured halo around hilum [T<sub>S</sub>H<sub>C</sub>]) were tested over two growing seasons, under rainfed, Mediterranean conditions. They differed only in the number of seeds per pod; the phenotype T<sub>W</sub>H<sub>W</sub> had the lowest number (2.2 seeds pod<sup>−1</sup>). The seed yield per plant (SY) was highly correlated with the number of pods per plant and was higher under wetter and warmer conditions during the reproductive period (April–May). The three phenotypes showed no difference in tolerance against bruchid (<i>Bruchus tristiculus</i>) infection (<i>F</i><sub>2,8</sub> = 0.14, <i>p</i> > .05), which was higher in the most productive growing season (6.44%, <i>F</i><sub>1,4</sub> = 14.8, <i>p</i> < .05). In the phenotype T<sub>W</sub>H<sub>W</sub>, three seed classes (intact, bruchid-damaged, parasitoid-damaged seeds) were tested for SY, quality traits and tolerance to bruchids. Though insect damaged seeds showed significant reduction in emergence rates (from −57% up to −91%), there were no differences in SY (19.11–24.53 g plant<sup>−1</sup>, <i>F</i><sub>2,8</sub> = 0.86, <i>p</i> > .05) and yield components (seeds per pod, 1000-seed weight, number of pods per plant). However, seeds of plants derived from parasitoid-damaged seeds had higher concentration of the neurotoxin ODAP (4.92 mg g<sup>−1</sup>, <i>F</i><sub>2,8</sub> = 8.76, <i>p</i> < .01). On the other hand, seeds of plants derived from bruchid-damaged seeds showed higher percentage of damaged seeds by the endoparasitoid <i>Triaspis thoracica</i> (2.25% vs. 0.67%–1.00%, <i>F</i><sub>2,8</sub> = 5.47, <i>p</i> < .05). Concluding, flower and testa colour cannot be used as biomarkers of seed yield and quality in grass pea, but it seemed that a tripartite interaction (grass pea–bruchid–endoparasitoid) may occur that affects ODAP concentration and the susceptibility of seeds to insect damages.</p>\",\"PeriodicalId\":7977,\"journal\":{\"name\":\"Annals of Applied Biology\",\"volume\":\"184 2\",\"pages\":\"250-258\"},\"PeriodicalIF\":2.2000,\"publicationDate\":\"2023-11-15\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Annals of Applied Biology\",\"FirstCategoryId\":\"97\",\"ListUrlMain\":\"https://onlinelibrary.wiley.com/doi/10.1111/aab.12880\",\"RegionNum\":3,\"RegionCategory\":\"农林科学\",\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q2\",\"JCRName\":\"AGRICULTURE, MULTIDISCIPLINARY\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Annals of Applied Biology","FirstCategoryId":"97","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/aab.12880","RegionNum":3,"RegionCategory":"农林科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"AGRICULTURE, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 0
摘要
草豆(Lathyrus sativus L.)被认为是具有高产和营养潜力的孤儿/未充分利用的谷物豆类。它在花和种皮(种皮)颜色上是可变的,这种变异可能用作产量和品质性状表型选择的生物标志物。在两个生长季节,在雨养的地中海条件下,测试了三种不同的花/种皮颜色表型(白色花-白色到奶油色的种皮和白色的种皮[TWHW],略蓝色的条状和翅膀颜色-白色到奶油色的种皮和种皮周围的彩色晕[TWHC]和蓝色条状和翅膀颜色-斑点的种皮和种皮周围的彩色晕[TSHC])。它们只是在每荚的种子数量上有所不同;表型TWHW的数量最少(2.2粒荚−1)。单株种子产量(SY)与单株荚果数高度相关,在繁殖期(4 - 5月)湿润和温暖的条件下产量较高。3种表型对Bruchus tristiculus感染的耐受性无显著差异(F2,8 = 0.14, p > 05),在最高产生长期耐受性较高(6.44%,F1,4 = 14.8, p < 05)。以TWHW表型为研究对象,对3个种子类别(完整种子、残害种子和被寄生物残害种子)进行了SY、品质性状和对残害的耐受性测试。虽然虫害种子的出苗率显著降低(从- 57%上升到- 91%),但在SY (19.11-24.53 g株- 1,F2,8 = 0.86, p > 0.05)和产量成分(每荚种子数、千粒重、每株荚果数)上没有差异。而被寄生蜂破坏的种子所衍生的种子中,神经毒素ODAP浓度较高(4.92 mg g−1,F2,8 = 8.76, p < 0.01)。另一方面,由毛刷损伤种子衍生而来的植物种子被内源寄生蜂胸Triaspis破坏的比例更高(2.25% vs. 0.67% ~ 1.00%, F2,8 = 5.47, p < 0.05)。综上所述,花和种皮颜色不能作为草豆种子产量和品质的生物标志物,但可能存在一种影响ODAP浓度和种子对虫害敏感性的三方相互作用(草豆-毛囊-类内寄生虫)。
Flower/testa colour associations with grain yield, quality and tolerance to seed weevil in grass pea phenotypes
Grass pea (Lathyrus sativus L.) is considered an orphan/underutilised grain legume with high yield and nutritive potential. It is variable in flower and seed coat (testa) colour and this variation could possibly be used as a biomarker in phenotypic selection for yield and quality traits. Three phenotypes differing in flower/testa colour (white flower-white to creamy testa and white hilum [TWHW], slightly blue banner and wing colouration-white to creamy testa and coloured halo around hilum [TWHC] and blue banner and wing colouration-spotted testa and coloured halo around hilum [TSHC]) were tested over two growing seasons, under rainfed, Mediterranean conditions. They differed only in the number of seeds per pod; the phenotype TWHW had the lowest number (2.2 seeds pod−1). The seed yield per plant (SY) was highly correlated with the number of pods per plant and was higher under wetter and warmer conditions during the reproductive period (April–May). The three phenotypes showed no difference in tolerance against bruchid (Bruchus tristiculus) infection (F2,8 = 0.14, p > .05), which was higher in the most productive growing season (6.44%, F1,4 = 14.8, p < .05). In the phenotype TWHW, three seed classes (intact, bruchid-damaged, parasitoid-damaged seeds) were tested for SY, quality traits and tolerance to bruchids. Though insect damaged seeds showed significant reduction in emergence rates (from −57% up to −91%), there were no differences in SY (19.11–24.53 g plant−1, F2,8 = 0.86, p > .05) and yield components (seeds per pod, 1000-seed weight, number of pods per plant). However, seeds of plants derived from parasitoid-damaged seeds had higher concentration of the neurotoxin ODAP (4.92 mg g−1, F2,8 = 8.76, p < .01). On the other hand, seeds of plants derived from bruchid-damaged seeds showed higher percentage of damaged seeds by the endoparasitoid Triaspis thoracica (2.25% vs. 0.67%–1.00%, F2,8 = 5.47, p < .05). Concluding, flower and testa colour cannot be used as biomarkers of seed yield and quality in grass pea, but it seemed that a tripartite interaction (grass pea–bruchid–endoparasitoid) may occur that affects ODAP concentration and the susceptibility of seeds to insect damages.
期刊介绍:
Annals of Applied Biology is an international journal sponsored by the Association of Applied Biologists. The journal publishes original research papers on all aspects of applied research on crop production, crop protection and the cropping ecosystem. The journal is published both online and in six printed issues per year.
Annals papers must contribute substantially to the advancement of knowledge and may, among others, encompass the scientific disciplines of:
Agronomy
Agrometeorology
Agrienvironmental sciences
Applied genomics
Applied metabolomics
Applied proteomics
Biodiversity
Biological control
Climate change
Crop ecology
Entomology
Genetic manipulation
Molecular biology
Mycology
Nematology
Pests
Plant pathology
Plant breeding & genetics
Plant physiology
Post harvest biology
Soil science
Statistics
Virology
Weed biology
Annals also welcomes reviews of interest in these subject areas. Reviews should be critical surveys of the field and offer new insights. All papers are subject to peer review. Papers must usually contribute substantially to the advancement of knowledge in applied biology but short papers discussing techniques or substantiated results, and reviews of current knowledge of interest to applied biologists will be considered for publication. Papers or reviews must not be offered to any other journal for prior or simultaneous publication and normally average seven printed pages.
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