Heterosis and parent–progeny relationships for silk extrusion dynamics and kernel number determination in maize: Nitrogen effects

Rossini, M.A.; Hisse, Ignacio R.; Otegui, Marı́a Elena; ́Andrea, Karina E. D

doi:10.1002/csc2.20123

Cited by 12 publications

(5 citation statements)

References 52 publications

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“…In maize, successful development of ovaries into fully mature kernels can be disrupted in various ways, including as a result of incomplete ovary differentiation (Otegui & Andrade, 2000), late‐appearing silks or silk extrusion failure (Cárcova & Otegui, 2001; Fuad‐Hassan et al., 2008; Oury, Tardieu, et al., 2016; Rossini et al., 2020), and failure of the fertilized ovary during initial kernel development (Westgate & Boyer, 1986). Even in the absence of water deficit, disruptions of developmental events can occur, and they are rarely limited to a single reason; rather, the primary reason for unsuccessful kernel development and filling largely depends on the environmental conditions at critical stages of development (Borrás & Vitantonio‐Mazzini, 2018; Messina et al., 2019; Turc & Tardieu, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…In the field, faster and more synchronous silk extrusion is beneficial for successful kernel establishment and kernel number per ear at harvest (Borrás & Vitantonio‐Mazzini, 2018; DeBruin et al., 2018; Rossini et al., 2020). Silk appearance follows a sequential order with silks in middle and basal regions of the ear emerging first while apically positioned silks lag behind by 3–4 days (Cárcova et al., 2003).…”

Section: Introductionmentioning

confidence: 99%

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Pre‐silking water deficit in maize induced kernel loss through impaired silk growth and ovary carbohydrate dynamics

Li,

Huang,

Meng

et al. 2024

Plant Enviro Interactions

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Both carbon limitation and developmentally driven kernel failure occur in the apical region of maize (Zea mays L.) ears. Failed kernel development in the basal and middle regions of the ear often is neglected because their spaces usually are occupied by adjacent ovaries at harvest. We tested the spatial distribution of kernel losses and potential underlying reasons, from perspectives of silk elongation and carbohydrate dynamics, when maize experienced water deficit during silk elongation. Kernel loss was distributed along the length of the ear regardless of water availability, with the highest kernel set in the middle region and a gradual reduction toward the apical and basal ends. Water deficit limited silk elongation in a manner inverse to the temporal pattern of silk initiation, more strongly in the apical and basal regions of the ear than in the middle region. The limited recovery of silk elongation, especially at the apical and basal regions following rescue irrigation was probably due to water potentials below the threshold for elongation and lower growth rates of the associated ovaries. While sugar concentrations increased or did not respond to water deficit in ovaries and silks, the calculated sugar flux into the developing ovaries was impaired and diverged among ovaries at different positions under water deficit. Water deficit resulted in 58% kernel loss, 68% of which was attributable to arrested silks within husks caused by lower water potentials and 32% to ovaries with emerged silks possibly due to impaired carbohydrate metabolism.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Pre‐silking water deficit in maize induced kernel loss through impaired silk growth and ovary carbohydrate dynamics

Li,

Huang,

Meng

et al. 2024

Plant Enviro Interactions

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“…These types have been traditionally more widely used than pure dents in Argentina (Di Matteo et al., 2016). Inbreds belong to Reid Yellow Dent (B100) and Cristalino Colorado (LP2, LP561, LP611, LP662, and ZN6) heterotic groups (Eyhérabide et al., 2006; Hallauer et al., 1995) and represent variability in breeding eras, kernel type, canopy size, and grain yield traits (D'Andrea et al., 2006, 2009; Rossini et al., 2020).…”

Section: Methodsmentioning

confidence: 99%

“…By doing so, a diallel analysis will be performed on a set of hybrids derived from inbred lines of diverse genetic backgrounds (flint, semiflint, dent) under contrasting soil N environments. and Cristalino Colorado (LP2, LP561, LP611, LP662, and ZN6) heterotic groups (Eyhérabide et al, 2006;Hallauer et al, 1995) and represent variability in breeding eras, kernel type, canopy size, and grain yield traits (D'Andrea et al, 2006(D'Andrea et al, , 2009Rossini et al, 2020).…”

Section: Core Ideasmentioning

confidence: 99%

Diallel analysis of kernel weight and grain‐filling traits in maize grown under contrasting nitrogen supply

2023

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Understanding the inheritance of maize (Zea mays L.) kernel weight (KW) under contrasting nitrogen (N) supply is crucial for obtaining high KW across diverse N conditions. This work evaluated broad‐sense heritability (H2), general combining ability (GCA), and specific combining ability (SCA) under contrasting N levels for (i) KW and kernel number per plant and (ii) grain‐filling traits represented by the duration of lag and effective filling phases, kernel growth and desiccation rates, maximum water content and volume, and moisture content at physiological maturity. A six‐parent full diallel cross generated via Griffing's method 3 was tested under high (N200) and low (N0) N supply in 2 years (Y). For the various traits: (i) F1 hybrid, and F1 by Y and/or N interactions were significant (p < 0.05); (ii) GCA was significant at both N levels and affected (p < 0.05) by the Y effect; (iii) SCA was important (p < 0.05) only at N200; and (iv) GCA sum of squares was higher than those of SCA (except for KW). For KW and grain‐filling traits, H2 and GCA/SCA ratios were higher at N0 than at N200, suggesting low‐N environments would be more advantageous for developing genetic selection. Lag‐phase duration (LPD), kernel desiccation rate (KDR), and kernel maximum water content (KWCMAX) had higher H2 (≥0.70) and GCA/SCA ratio than KW, particularly under N0. Thus, the highest KW hybrid (LP2×LP662) was composed of inbreds with high GCA for LPD, KDR and KWCMAX, revealing superior KW hybrids could be selected from the GCA of mentioned traits.

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“…Their MS counterparts, however, supported the additional kernels often resulting in a positive yield response. A second perhaps less critical issue is variation in ear morphology and silking dynamics that might limit the potential for adding kernels, even if the plants could support development of additional kernels (Kaeser et al., 2003; Rossini et al., 2020). Nonetheless, the results of our initial field study clearly indicate that hybrid plants can support additional kernels with much greater oil content without a yield penalty if multiple pollination effectors are applied together.…”

Section: Implications For Improving Grain Yield and Market Valuementioning

confidence: 99%

Combining xenia, male sterility, and synchronous pollination to improve maize grain yield and market value

Westgate¹,

Halbach

Lauer³

et al. 2022

Crop Science

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Xenia (pollination of florets with genetically unrelated pollen), male sterility (removal of fertile pollen), and synchronous pollination (application of pollen when all silks are present) are well‐documented processes that influence kernel formation and development in maize. There also have been numerous reports in which xenia and male sterility were combined in an attempt to increase kernel number, kernel weight, and/or grain yield. We present an analysis of published literature exploring impacts of xenia resulting from cross‐pollination, male sterility, and synchronous pollination applied individually or in combination. Although synchronous pollination has had the most consistent and positive impact on seed formation, to our knowledge there are no reports combining all three effectors together. Recently developed technology to collect, preserve, and apply large volumes of maize pollen has provided the opportunity to evaluate the cumulative and potentially synergistic effects of synchronous pollination, xenia, and male sterility applied together on maize hybrids. We present the results of a field trial combining all three effectors in maize; this approach increased kernels per ear, kernel oil concentration, and grain yield per hectare. The results suggest synchronous pollination is essential to enable the greatest number of kernels to develop successfully. Male sterility supports kernel formation by providing greater assimilate supply per kernel, and xenia increases sink strength to attract the additional assimilates. The positive response and economic return when these effectors are applied in combination provides a novel opportunity for grain producers to manage kernel formation and composition proactively using pollen to deliver the trait of choice.

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Heterosis and parent–progeny relationships for silk extrusion dynamics and kernel number determination in maize: Nitrogen effects

Cited by 12 publications

References 52 publications

Pre‐silking water deficit in maize induced kernel loss through impaired silk growth and ovary carbohydrate dynamics

Pre‐silking water deficit in maize induced kernel loss through impaired silk growth and ovary carbohydrate dynamics

Diallel analysis of kernel weight and grain‐filling traits in maize grown under contrasting nitrogen supply

Combining xenia, male sterility, and synchronous pollination to improve maize grain yield and market value

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