2019
DOI: 10.1093/aobpla/plz028
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The morphometrics of autopolyploidy: insignificant differentiation among sexual–apomictic cytotypes

Abstract: Polyploidization of the plant genome affects the phenotype of individuals including their morphology, i.e. size and form. In autopolyploids, we expect mainly nucleotypic effects, from a number of monoploid genomes (i.e. chromosome sets) or genome size, seen from an increase in size or dimension of the polyploids compared with the diploids (or lower ploids). To identify nucleotypic effects, confounding effects of hybridity (observed in allopolyploids), postpolyploidization processes or environmental effects nee… Show more

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Cited by 3 publications
(3 citation statements)
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“…The variation rather exhibits a continuum of morphological character distribution among all the populations that is rooted in the variation observed for three representatives of the diploid cytotype (Figure S3). While lack of morphologically discrete cytotype groups can be expected in grass species (e.g., Amirouche and Misset, 2007 ; Pimentel and Sahuquillo, 2008 ), or in other families (e.g., in the Rosaceae; Bigl et al, 2019 ), cases of significant morphological differentiation between cytotypes have been observed in many other plant groups (e.g., Segraves et al, 1999 ; Kao and Parker, 2010 ), including one species from the genus Paspalum ( Quarin and Hanna, 1980 ). Such morphological variation is mostly due to nucleotypic effects (i.e., effects associated with the DNA content in nuclei or the number of monoploid genomes) or to confound phenomena like hybridity (in allopolyploids) or ecological differentiation ( Ramsey and Schemske, 2002 ).…”
Section: Discussionmentioning
confidence: 99%
“…The variation rather exhibits a continuum of morphological character distribution among all the populations that is rooted in the variation observed for three representatives of the diploid cytotype (Figure S3). While lack of morphologically discrete cytotype groups can be expected in grass species (e.g., Amirouche and Misset, 2007 ; Pimentel and Sahuquillo, 2008 ), or in other families (e.g., in the Rosaceae; Bigl et al, 2019 ), cases of significant morphological differentiation between cytotypes have been observed in many other plant groups (e.g., Segraves et al, 1999 ; Kao and Parker, 2010 ), including one species from the genus Paspalum ( Quarin and Hanna, 1980 ). Such morphological variation is mostly due to nucleotypic effects (i.e., effects associated with the DNA content in nuclei or the number of monoploid genomes) or to confound phenomena like hybridity (in allopolyploids) or ecological differentiation ( Ramsey and Schemske, 2002 ).…”
Section: Discussionmentioning
confidence: 99%
“…Occurrences are known from TK25 5334-5336 as well as 5434-5435 (Korsch et al, 2002). As with other apomictic groups, it seems justifiable to describe such a clearly defined group of populations as a separate species; albeit Bigl et al (2019) advocate the rank of variety for cytotypes within one species. The identity of an enneaploid (2n = 9x) plant from Hohenwarte in Eastern Thuringia remains unclear.…”
Section: Morphologymentioning
confidence: 99%
“…New morphological types develop regularly by occasional sexual reproduction alongside the general matroclinous reproduction (Asker & Jerling, 1992). If parallel sexual reproduction is also present, as in some Potentilla species ( P. argentea , P. verna ), taxonomic differentiation of the morphological variation becomes practically impossible (Bigl et al., 2019; Jäger, 2017; Paule et al., 2011).…”
Section: Introductionmentioning
confidence: 99%