Donald K. Ourecky scite author profile

JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org. A B S T R A C TTwo basic chromosome karyotypes were found in the genus Sambucus. Chromosome numbers were observed to be 2n = 38 for S. callicarpa, S. cerulea, S. glauca, S. kamtschatica, S. melanocarpa, S. mexicana, S. miquelli, S. sibirica, and S. sieboldiana and 2n = 36 for S. simpsonii and S. williamsii. Measurements of 18 karyotypes are presented. The major differences between the two basic chromosome karyotypes can be explained as the result of a mis-division of a metacentric chromosome giving rise to two telocentric chromosomes, thus reducing the number of metacentrics from five to four and increasing the chromosome number from 2n = 36 to 2n = 38.Observed chromosome aberrations and aneuploidy may result from unstable telocentric chromosomes. THE WIDE DISTRIBUTION of Sambucus species throughout the temperate and subtropical regions of the world and their possible economic value emphasize the need for taxonomic clarification. None of the standard botanical references has a complete listing of all known Sambucus species. The most complete work was published by von Schwerin (1909). He divided the genus into seven sections. Three sections include all the major species with wide distributions and four other sections contain one or two species with unusual characteristics and limited distribution.Elderberry breeding in eastern North America has been confined mainly within the species S. canadensis, with a few interspecific crosses involving S. nigra, while only clonal selections have been made in S. glauca in the western United States. The extensive variation in Sambucus should enable rapid advances to be made in breeding and clonal selection.Ourecky (1966) and Hounsell (1968) initiated cytological analyses of Sam bucus species and clones. The present paper is an attempt to survey as many species as possible in order to define karyotype relationships and cytotaxonomic potential. MATERIALS AND METHODS-Hardwoodcuttings were taken in March and April and rooted in sand under mist. After good root formation, the cuttings were removed from the sand and washed thoroughly. Collections made between 1 and 2 PM contained the most divisions in both 1

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Chromosome Morphology in the Genus Sambucus

Ourecky

1970

American J of Botany

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Two basic chromosome karyotypes were found in the genus Sambucus. Chromosome numbers were observed to be 2n = 38 for S. callicarpa, S. cerulea, S. glauca, S. kamtschatica, S. melanocarpa, S. mexicana, S. miquelli, S. sibirica, and S. sieboldiana and 2n = 36 for S. simpsonii and S. williamsii. Measurements of 18 karyotypes are presented. The major differences between the two basic chromosome karyotypes can be explained as the result of a mis‐division of a metacentric chromosome giving rise to two telocentric chromosomes, thus reducing the number of metacentrics from five to four and increasing the chromosome number from 2n = 36 to 2n = 38. Observed chromosome aberrations and aneuploidy may result from unstable telocentric chromosomes.

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Variation in Apple Cytochimeras

Pratt

Ourecky

Einset

1967

American J of Botany

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Diploid‐tetraploid cytochimeras of apple were investigated by cytological examination of buds from branches selected by the characteristics of the fruits, flowers or pollen. Eight types of cytochimeras were identified on the basis of relative size of cells, nuclei and metaphase mitoses in the apical meristem (protomeristem) and mitoses in meristematic primary tissues. There appeared to be five apical layers which contributed to the stem and four which contributed to the leaves and flower parts. Buds of various cytochimeral patterns (designated by a formula giving the ploidy of the apical layers) were found on some bearing trees propagated from known cytochimeral sources. The most frequently associated types were (a) 2–4–2–2–2 and 2–4–4–4–4 (and 2–4–2–4–4 in one cultivar), or (b) 2–2–2–4–4 and 2x. Some sports were uniformly 2–4–4–4–4. The stability of apple cytochimeras under normal conditions appeared greater in some eultivars than in others. Sprouts from severely pruned 2–2–4–4–4 trees were more variable than unpruned branches. Buds of shoots which grew from radiation‐damaged buds were more variable than those from non‐irradiated buds and included types not yet found by branch selection. Cytochimeral variation was interpreted to be due to layer replacement resulting from infrequent periclinal divisions in apical or axillary meristems, or from wounding of meristems by ionizing radiation.

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Variation in Apple Cytochimeras

Pratt

Ourecky

Einset

1967

American Journal of Botany

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Donald K. Ourecky

Fall-Bearing Red Raspberries, Their Future and Potential

Chromosome Morphology in the Genus Sambucus

Chromosome Morphology in the Genus Sambucus

Variation in Apple Cytochimeras

Variation in Apple Cytochimeras

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