Fine control of aerenchyma and lateral root development through AUX/IAA- and ARF-dependent auxin signaling

Yamauchi, Takaki; Tanaka, Akihiro; Inahashi, Hiroki; Nishizawa, Naoko K.; Tsutsumi, Nobuhiro; Inukai, Yoshiaki; Nakazono, Mikio

doi:10.1073/pnas.1907181116

Cited by 125 publications

(130 citation statements)

References 40 publications

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“…As RSAvis3D employs intensity changes to enhance root segments, root-to-soil contrast is an important factor for efficient root isolation. Rice roots produce constitutive aerenchyma under aerobic conditions, but most field crops do not [46,47], suggesting that rice tends to show higher contrast between its roots and the surrounding soil than other crops that do not produce constitutive aerenchyma. We need to consider the soil substrate that is available when RSAvis3D is applied to other crops.…”

Section: Discussionmentioning

confidence: 99%

High-throughput three-dimensional visualization of root system architecture of rice using X-ray computed tomography

et al. 2020

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Background: X-ray computed tomography (CT) allows us to visualize root system architecture (RSA) beneath the soil, non-destructively and in a three-dimensional (3-D) form. However, CT scanning, reconstruction processes, and root isolation from X-ray CT volumes, take considerable time. For genetic analyses, such as quantitative trait locus mapping, which require a large population size, a high-throughput RSA visualization method is required. Results: We have developed a high-throughput process flow for the 3-D visualization of rice (Oryza sativa) RSA (consisting of radicle and crown roots), using X-ray CT. The process flow includes use of a uniform particle size, calcined clay to reduce the possibility of visualizing non-root segments, use of a higher tube voltage and current in the X-ray CT scanning to increase root-to-soil contrast, and use of a 3-D median filter and edge detection algorithm to isolate root segments. Using high-performance computing technology, this analysis flow requires only 10 min (33 s, if a rough image is acceptable) for CT scanning and reconstruction, and 2 min for image processing, to visualize rice RSA. This reduced time allowed us to conduct the genetic analysis associated with 3-D RSA phenotyping. In 2-weekold seedlings, 85% and 100% of radicle and crown roots were detected, when 16 cm and 20 cm diameter pots were used, respectively. The X-ray dose per scan was estimated at < 0.09 Gy, which did not impede rice growth. Using the developed process flow, we were able to follow daily RSA development, i.e., 4-D RSA development, of an upland rice variety, over 3 weeks. Conclusions: We developed a high-throughput process flow for 3-D rice RSA visualization by X-ray CT. The X-ray dose assay on plant growth has shown that this methodology could be applicable for 4-D RSA phenotyping. We named the RSA visualization method 'RSAvis3D' and are confident that it represents a potentially efficient application for 3-D RSA phenotyping of various plant species.

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Section: Discussionmentioning

confidence: 99%

High-throughput three-dimensional visualization of root system architecture of rice using X-ray computed tomography

et al. 2020

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“…As RSAvis3D employs intensity changes to enhance root segments, root-to-soil contrast is an important factor for efficient root isolation. Rice roots produce constitutive aerenchyma under aerobic conditions, but most field crops do not [47,48], suggesting that rice tends to show higher contrast between its roots and the surrounding soil than other crops that do not produce constitutive aerenchyma. We need to consider the soil substrate that is available when RSAvis3D is applied to other crops.…”

Section: Discussionmentioning

confidence: 99%

High-throughput three-dimensional visualization of root system architecture of rice using X-ray computed tomography

Teramoto¹,

Takayasu²,

Kitomi³

et al. 2020

Preprint

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Background: X-ray computed tomography (CT) allows us to visualize root system architecture (RSA) beneath the soil, non-destructively and in a three-dimensional (3-D) form. However, CT scanning, reconstruction processes, and root isolation from X-ray CT volumes, take considerable time. For genetic analyses, such as quantitative trait locus mapping, which require a large population size, a high-throughput RSA visualization method is required.Results: We have developed a high-throughput process flow for the 3-D visualization of rice (Oryza sativa) RSA (consisting of radicle and crown roots), using X-ray CT. The process flow includes use of a uniform particle size, calcined clay to reduce the possibility of visualizing non-root segments, use of a higher tube voltage and current in the X-ray CT scanning to increase root-to-soil contrast, and use of a 3-D median filter and edge detection algorithm to isolate root segments. Using high-performance computing technology, this analysis flow requires only 10 min (33 s, if a rough image is acceptable) for CT scanning and reconstruction, and 2 min for image processing, to visualize rice RSA. This reduced time allowed us to conduct the genetic analysis associated with 3-D RSA phenotyping. In 2-week-old seedlings, 85% and 100% of radicle and crown roots were detected, when 16 cm and 20 cm diameter pots were used, respectively. The X-ray dose per scan was estimated at < 0.09 Gy, which did not impede rice growth. Using the developed process flow, we were able to follow daily RSA development, i.e., 4-D RSA development, of an upland rice variety, over three weeks. Conclusions: We developed a high-throughput process flow for 3-D rice RSA visualization by X-ray CT. The X-ray dose assay on plant growth has shown that this methodology could be applicable for 4-D RSA phenotyping. We named the RSA visualization method ‘RSAvis3D’ and are confident that it represents a potentially efficient application for 3-D RSA phenotyping of various plant species.

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“…For example, IAA14, IAA9, IAA1, IAA12, and other members are all involved in the growth and development of roots in different plants (Fukaki et al, 2002;Smet and Beeckman, 2010;Sha et al, 2015). Recent studies have found that A. thaliana mutant iaa13 reduced lateral roots, which affected root configuration (Takaki et al, 2019). In addition, auxin output vectors composed of PIN family proteins, such as PIN1, PIN2, PIN3, PIN4, PIN5, PIN6, PIN7, and PIN8, are distributed in different tissues, where they regulate auxin synthesis and affect plant growth and development (Gälweiler et al, 1998;Friml and Palme, 2002;Blilou et al, 2005;Dubrovsky, 2008;Müller et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

Peach PpSnRK1 Participates in Sucrose-Mediated Root Growth Through Auxin Signaling

et al. 2020

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Fine control of aerenchyma and lateral root development through AUX/IAA- and ARF-dependent auxin signaling

Cited by 125 publications

References 40 publications

High-throughput three-dimensional visualization of root system architecture of rice using X-ray computed tomography

High-throughput three-dimensional visualization of root system architecture of rice using X-ray computed tomography

High-throughput three-dimensional visualization of root system architecture of rice using X-ray computed tomography

Peach PpSnRK1 Participates in Sucrose-Mediated Root Growth Through Auxin Signaling

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