Spike Morphology Genes in Wheat Species (<i>Triticum</i>L.)

Konopatskaia, Irina; Vavilova, Valeriya; Блинов, А. Г.; Гончаров, Н. П.

doi:10.1515/prolas-2016-0053

“…Spikes differ in their shape, size, density, awnedness, color, and so on. The spike shape is controlled by a set of genes; their study will make it possible to purposefully create new cultivars with improved yield characteristics, easier threshing, and resistance to environmental factors [2]. The wheat inflorescence is a compound spike with a length of 5-17 cm and longer; it consists of a rachis and spikelets.…”

Section: Introductionmentioning

confidence: 99%

Morphometry of the Wheat Spike by Analyzing 2D Images

Genaev

¹

,

Komyshev

²

,

Smirnov

³

et al. 2019

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Spike shape and morphometric characteristics are among the key characteristics of cultivated cereals associated with their productivity. Identification of the genes controlling these traits requires morphometric data at harvesting and analysis of numerous plants, which could be automatically done using technologies of digital image analysis. A method for wheat spike morphometry utilizing 2D image analysis is proposed. Digital images are acquired in two variants: a spike on a table (one projection) or fixed with a clip (four projections). The method identifies spike and awns in the image and estimates their quantitative characteristics (area in image, length, width, circularity, etc.). Section model, quadrilaterals, and radial model are proposed for describing spike shape. Parameters of these models are used to predict spike shape type (spelt, normal, or compact) by machine learning. The mean error in spike density prediction for the images in one projection is 4.61 (~18%) versus 3.33 (~13%) for the parameters obtained using four projections.Agronomy 2019, 9, 390 2 of 22 the more so as the modern experiments involve tens of thousands of plants [5,9]. Correspondingly, automation of this laborious and time-consuming process is relevant for the science and breeding. The efficiency of plant phenotyping can be increased by technologies of digital image analysis [10][11][12]. These technologies were applied for both kernel size and shape morphometry [13][14][15][16] and analysis of the spike traits [17][18][19][20].The methods for digital image analysis of spike characteristics are also developed and allow for solving of different problems. Grillo et al. [17] developed a method for the wheat variety identification using glumes size, shape, color, and texture characteristics obtained from image analysis. Makanza et al. [18] designed the software allowing for determination of ear length and width as well as estimation of maize grain size and weight. Pound et al. [19] used deep learning to count wheat spikes and assess the number of spikelets per spike using images of wheat plants taken in glasshouse conditions. However, Pound et al. in their work did not estimate the morphological characteristics of spikes, such as their length, width, and type. As for the deep learning algorithms, their use, in turn, requires a large number of annotated spike images (several tens of thousands) to train the neural network parameters. Hughes et al. [20] determined wheat spike and grain morphometric parameters from X-ray micro computed tomography data. This method is highly accurate when determining the fine characteristics of spike and grain shapes but requires a special device for recording tomographic images. Kun et al. [21] proposed morphometry of wheat spikes via image processing. The authors utilized 2D images to assess various characteristics, such as spike length and awn number and length, and classified the spike shape type according to its length-to-width ratio. The spike parameters were used for their classification according t...

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“…), accession KU 506 acquired using both the 'table' and 'clip' protocols. Each spike was classified according to the types of awnedness based on an expert estimate into awnless, awnletted, half-awned, and short-awned ( Figure 2A-D, respectively) [2]. Table 1 lists the distribution of spike images in this sample according to the types of protocol and awnedness pattern.…”

Section: Selecting Parameters For Identification Of Spike and Awn Regmentioning

confidence: 99%

Morphometry of the Wheat Spike by Analyzing 2D Images

Genaev¹,

Komyshev²,

Smirnov³

et al. 2019

Preprint

Self Cite

0

View full text Add to dashboard Cite

Spike shape and morphometric characteristics are among the key characteristics of cultivated cereals associated with their productivity. Identification of the genes controlling these traits requires morphometric data harvesting and analysis for numerous plants, which is automatable using technologies of digital image analysis. A method for wheat spike morphometry utilizing 2D image analysis is proposed. Digital images are acquired in two variants: a spike on a table (one projection) or fixed with a clip (four projections). The method identifies spike and awns in the image and estimates their quantitative characteristics (area in image, length, width, circularity, etc.). Models of sections, quadrilaterals, and radial model are proposed for describing spike shape. Parameters of these models are used to predict spike shape type (spelt, normal, or compact) by machine learning. The mean error in spike density prediction for the images in one projection is 4.61 (~18%) versus 3.33 (~13%) for the parameters obtained using four projections. F1 measure in automated spike classification into three types is 0.78 using logistic regression (one projection) and 0.85 using random forest method (four projections). The proposed method is implemented in Java; examples of images and user guide are available at http://wheatdb.org/werecognizer.

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“…Ген Q, как и ген VRN-1, является одним из основных генов, вовлеченных в процесс доместикации, и контролирует такие признаки, как ломкость-не ломкость колоса, голозерность-пленчатость, форма колоса (норма-спельтоидность), форма и жесткость чешуи, длина оси колосового стержня, высота растения и некоторые другие хозяйственно важные признаки пшениц [Simons et al, 2006;Konopatskaia et al, 2016].…”

Section: генетика адаптивности и архитектоника пшеницunclassified

“…обзор, Konopatskaia et al [2016]), адаптивность [Гончаров, 2012; Киселева, Салина, 2018; и др. ] и морфологию колоса [Amagai et al, 2017;Kosuge et al, 2008;Simons et al, 2006;и др.…”

Section: генетика адаптивности и архитектоника пшеницunclassified

Genetics of Adaptation and Arkhitectonics of Wheat

Гончаров

¹

,

Kondratenko

²

,

Vavilova

³

2018

Book of Proceedings of the All-Russian Scientific Conference With International Participation and Schools of Young Scientists

1

0

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Природа создала лишь четыре вида диких пшениц двух уровней плоидности (ди-и тетраплоидного) -однозернянки и полбы, использовав при этом только четыреДикие гексаплоиды в природе не обнаружены, равно как и дикие голозерные тетраплоидные пшеницы. Они, если и не являются произведением рук человеческих, то, по крайней мере, есть результат удачного отбора первобытным земледельцем случайно появившихся в природе вариабельных форм . В настоящее время и генетики, и селекционеры обнаружили, что не включенный в генофонд возделываемых видов пул генетической изменчивости (генов) этих диких предков может быть использован для дальнейшего улучшения наиболее продуктивных современных сортов. Считается, что такая стратегия селекции, основанная на широком использовании ранее невостребованных признаков и свойств, а так же генов, контролирующих их выраженность будет способствовать дальнейшему прогрессу селекции и развитию высокопродуктивного сельскохозяйственного производства. Такой подход создания высоко адаптивных, стрессоустойчивых сортов нового поколения за счет использования более широкого генетического разнообразия и диверсификации сортов -особенно привлекателен для обеспечения продовольственной безопасности. Однако для его научного обеспечения необходимо получение новых знаний. Особенно это касается архитектоники растений будущего и создания их модели.Известно, что процесс одомашнивания кардинально изменил архитектонику и свойства диких видов. Признаки голозерность, отсутствие ломкоколосости и яровость сыграли ключевую роль в процессе доместикации и обеспечили успешное культивирование пшеницы на огромных пространствах [Dubcovsky, Dvorak, 2007].Яровые (однолетние) растения проходят весь цикл развития в течение одного лета, в то время как озимые (двулетние) до осени не переходят к генеративному развитию без предварительного воздействия низкой температуры. Яровость-озимость -один из вариантов адаптации пшениц к изменениям условий среды. В природе яровость, по-видимому, возникла как механизм приспособления к определенным

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Spike Morphology Genes in Wheat Species (TriticumL.)

Cited by 24 publications

References 66 publications

Morphometry of the Wheat Spike by Analyzing 2D Images

Morphometry of the Wheat Spike by Analyzing 2D Images

Morphometry of the Wheat Spike by Analyzing 2D Images

Genetics of Adaptation and Arkhitectonics of Wheat

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