Krishna K Dwivedi1, Dominique J Roche2, Tom E Clemente3, Zhengxiang Ge3, John G Carman4. 1. Caisson Laboratories, Inc., 1740 Research Park Way, North Logan, UT 84341, USA Crop Improvement Division, Indian Grassland and Fodder Research Institute, Jhansi (UP) 284003, India Plants, Soils and Climate Department, Utah State University, Logan, UT 84322-4820, USA. 2. Caisson Laboratories, Inc., 1740 Research Park Way, North Logan, UT 84341, USA PhytoGen Seed Co. LLC, Western Research Station, 850 Plymouth Avenue, Corcoran, CA 93212, USA. 3. Department of Agronomy and Horticulture, Center for Plant Science Innovation, University of Nebraska, Lincoln, NE 68588, USA. 4. Caisson Laboratories, Inc., 1740 Research Park Way, North Logan, UT 84341, USA Plants, Soils and Climate Department, Utah State University, Logan, UT 84322-4820, USA john.carman@usu.edu.
Abstract
BACKGROUND AND AIMS: During seed fill in cereals, nutrients are symplasmically unloaded to vascular parenchyma in ovules, but thereafter nutrient transport is less certain. In Zea mays, two mechanisms of nutrient passage through the chalaza and nucellus have been hypothesized, apoplasmic and symplasmic. In a recent study, nutrients first passed non-selectively to the chalazal apoplasm and were then selectively absorbed by the nucellus before being released to the endosperm apoplasm. This study reports that the promoter of OUTER CELL LAYER3 (PSbOCL3) from Sorghum bicolor (sorghum) directs gene expression to chalazal cells where the apoplasmic barrier is thought to form. The aims were to elucidate PSbOCL3 expression patterns in sorghum and relate them to processes of nutrient pathway development in kernels and to recognized functions of the homeodomain-leucine zipper (HD-Zip) IV transcription factor family to which the promoter belongs. METHODS: PSbOCL3 was cloned and transformed into sorghum as a promoter-GUS (β-glucuronidase) construct. Plant tissues from control and transformed plants were then stained for GUS, and kernels were cleared and characterized using differential interference contrast microscopy. KEY RESULTS: A symplasmic disconnect between the chalaza and nucellus during seed fill is inferred by the combination of two phenomena: differentiation of a distinct nucellar epidermis adjacent to the chalaza, and lysis of GUS-stained chalazal cells immediately proximal to the nucellar epidermis. Compression of the GUS-stained chalazal cells during kernel maturation produced the kernel abscission zone (closing layer). CONCLUSIONS: The results suggest that the HD-Zip IV transcription factor SbOCL3 regulates kernel nutrition and abscission. The latter is consistent with evidence that members of this transcription factor group regulate silique abscission and dehiscence in Arabidopsis thaliana. Collectively, the findings suggest that processes of floral organ abscission are conserved among angiosperms and may in some respects differ from processes of leaf abscission.
BACKGROUND AND AIMS: During seed fill in cereals, nutrients are symplasmically unloaded to vascular parenchyma in ovules, but thereafter nutrient transport is less certain. In Zea mays, two mechanisms of nutrient passage through the chalaza and nucellus have been hypothesized, apoplasmic and symplasmic. In a recent study, nutrients first passed non-selectively to the chalazal apoplasm and were then selectively absorbed by the nucellus before being released to the endosperm apoplasm. This study reports that the promoter of OUTER CELL LAYER3 (PSbOCL3) from Sorghum bicolor (sorghum) directs gene expression to chalazal cells where the apoplasmic barrier is thought to form. The aims were to elucidate PSbOCL3 expression patterns in sorghum and relate them to processes of nutrient pathway development in kernels and to recognized functions of the homeodomain-leucine zipper (HD-Zip) IV transcription factor family to which the promoter belongs. METHODS:PSbOCL3 was cloned and transformed into sorghum as a promoter-GUS (β-glucuronidase) construct. Plant tissues from control and transformed plants were then stained for GUS, and kernels were cleared and characterized using differential interference contrast microscopy. KEY RESULTS: A symplasmic disconnect between the chalaza and nucellus during seed fill is inferred by the combination of two phenomena: differentiation of a distinct nucellar epidermis adjacent to the chalaza, and lysis of GUS-stained chalazal cells immediately proximal to the nucellar epidermis. Compression of the GUS-stained chalazal cells during kernel maturation produced the kernel abscission zone (closing layer). CONCLUSIONS: The results suggest that the HD-Zip IV transcription factor SbOCL3 regulates kernel nutrition and abscission. The latter is consistent with evidence that members of this transcription factor group regulate silique abscission and dehiscence in Arabidopsis thaliana. Collectively, the findings suggest that processes of floral organ abscission are conserved among angiosperms and may in some respects differ from processes of leaf abscission.
Authors: Nataliya Kovalchuk; Wei Wu; Natalia Bazanova; Nicolas Reid; Rohan Singh; Neil Shirley; Omid Eini; Alexander A T Johnson; Peter Langridge; Maria Hrmova; Sergiy Lopato Journal: Plant Mol Biol Date: 2019-06-10 Impact factor: 4.076
Authors: Sara E Patterson; Jenny L Bolivar-Medina; Tanya G Falbel; Janet L Hedtcke; Danielle Nevarez-McBride; Andrew F Maule; Juan E Zalapa Journal: Front Plant Sci Date: 2016-01-26 Impact factor: 5.753