Shattering (agriculture)

Spikelets of Einkorn wheat, Triticum monococcum

Shattering in many crops involves dehiscence of the mature fruit, for example, in Brassica napus.

In agriculture, shattering is the dispersal of a crop's seeds upon their becoming ripe. From an agricultural perspective this is generally an undesirable process, and in the history of crop domestication several important advances have involved a mutation in a crop plant that reduced shattering — instead of the seeds being dispersed as soon as they were ripe, the mutant plants retained the seeds for longer, which made harvesting much more effective.

A particularly important mutation that was selected very early in the history of agriculture removed the "brittle rachis" problem from wheat.^[1] A ripe head ("ear") of wild-type wheat is easily shattered into dispersal units when touched, or blown by the wind, because during ripening a series of abscission layers forms that divides the rachis into short segments, each attached to a single spikelet (which contains 2–3 grains along with chaff).

A different class of shattering mechanisms involves dehiscence of the mature fruit, which releases the seeds.

Current research priorities to understand the genetics of shattering include the following crops:

Sesame and canola are harvested before the seed is fully mature, so that the pods do not split and drop the seeds.^[6]^[7]

References

↑ Dorian Q. Fuller & Robin Allaby (2009). "Seed Dispersal and Crop Domestications: Shattering, Germination and Seasonality in Evolution under Cultivation". Annual Plant Reviews. 38: 238–295. doi:10.1002/9781444314557.ch7.
↑ Kandemir, N.; Kudrna, D.A.; Ullrich, S.E.; Kleinhofs, A. (2000). "Molecular marker assisted genetic analysis of head shattering in six-rowed barley". TAG Theoretical and Applied Genetics. 101 (1): 203–210. doi:10.1007/s001220051470.
↑ Ivan N. FESENKO 2006. Non-shattering accessions of Fagopyrum tataricum Gaertn. carry recessive alleles at two loci affecting development of functional abscission layer. Fagopyrum 23: 7-10
↑ Brenner, D.M. 2002. Non-shattering grain amaranth populations. p. 104–106. In: J. Janick and A. Whipkey (eds.), Trends in new crops and new uses. ASHS Press, Alexandria, VA.
↑ S. Hossain; G.P. Kadkol; R. Raman; P.A. Salisbury & H. Raman. "Breeding Brassica napus for Shatter Resistance". Plant Breeding (PDF). doi:10.5772/29051. ISBN 978-953-307-932-5.
↑ Moazzami, A.; Kamal-Eldin, A. (2006), "Sesame seed is a rich source of dietary lignans", Journal of the American Oil Chemists' Society, 83 (8): 719–723, doi:10.1007/s11746-006-5029-7
↑ Duane R. Berglund; Kent McKay & Janet Knodel (2007), Canola Production, NDSU Extension Service, North Dakota State University, retrieved 9 November 2015

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[1] Dorian Q. Fuller & Robin Allaby (2009). "Seed Dispersal and Crop Domestications: Shattering, Germination and Seasonality in Evolution under Cultivation". Annual Plant Reviews. 38: 238–295. doi:10.1002/9781444314557.ch7.

[2] Kandemir, N.; Kudrna, D.A.; Ullrich, S.E.; Kleinhofs, A. (2000). "Molecular marker assisted genetic analysis of head shattering in six-rowed barley". TAG Theoretical and Applied Genetics. 101 (1): 203–210. doi:10.1007/s001220051470.

[3] Ivan N. FESENKO 2006. Non-shattering accessions of Fagopyrum tataricum Gaertn. carry recessive alleles at two loci affecting development of functional abscission layer. Fagopyrum 23: 7-10

[4] Brenner, D.M. 2002. Non-shattering grain amaranth populations. p. 104–106. In: J. Janick and A. Whipkey (eds.), Trends in new crops and new uses. ASHS Press, Alexandria, VA.

[5] S. Hossain; G.P. Kadkol; R. Raman; P.A. Salisbury & H. Raman. "Breeding Brassica napus for Shatter Resistance". Plant Breeding (PDF). doi:10.5772/29051. ISBN 978-953-307-932-5.

[6] Moazzami, A.; Kamal-Eldin, A. (2006), "Sesame seed is a rich source of dietary lignans", Journal of the American Oil Chemists' Society, 83 (8): 719–723, doi:10.1007/s11746-006-5029-7

[7] Duane R. Berglund; Kent McKay & Janet Knodel (2007), Canola Production, NDSU Extension Service, North Dakota State University, retrieved 9 November 2015

Barley
History	Domestication Neolithic Revolution Triticeae
Types of barley	Genus: Hordeum Cultivars: Bere
Agronomy	Barley diseases
Trade	Australian Barley Board Canadian Wheat Board Corn exchange Production by country Wheat pools in Canada
Parts of the plant	Bran Germ Husk Kernel Gluten Straw
Basic preparations	Milling: Flour (types) Groats Middlings Parboiling
As an ingredient	Barley bread Barley honey Barley tea Barley water Beer Caffè d'orzo Irish whiskey Japanese whisky Máchica Malta Scotch whisky Talbina see also: Category:Barley-based beverages
Associated human diseases	Gluten-related disorders Coeliac disease Non-celiac gluten sensitivity Wheat allergy Dermatitis herpetiformis Gluten ataxia
Related concepts	Bread riot Cattle feeding Plant breeding Refined grains Staple food Whole grain
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Wheat
Types	Common Durum Einkorn Emmer Khorasan Marquis Norin 10 Red Fife Spelt Winter wheat
Agronomy	Wheat diseases list Wheat mildew Hessian fly
Trade	Australian Wheat Board Canadian Wheat Board Corn exchange Exports International Wheat Council Peak wheat Production statistics Protein premium Wheat pools in Canada
Plant parts and their uses	Stalk Straw Seed Bran Germ Chaff (husk) Endosperm Gluten
Basic preparation	None Berries or groats Milling Farina Flour Middlings Semolina Parboiling Bulgur
As an ingredient	Bread Couscous Cracker Flatbread Pasta Wheat beer Wheat germ oil Wheat gluten
Associated human diseases	Anaphylaxis Gluten-related disorders coeliac disease non-celiac gluten sensitivity wheat allergy dermatitis herpetiformis ataxia
Related concepts	Bread riot Plant breeding Refined grains Staple food Wheatpaste Whole grain Shattering Tell Abu Hureyra Tell Aswad
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