Floral symmetry

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peloric
(radially symmetric) flower on the same plant

Floral symmetry describes whether, and how, a flower, in particular its perianth, can be divided into two or more identical or mirror-image parts.

Uncommonly, flowers may have no axis of symmetry at all, typically because their parts are spirally arranged.

Actinomorphic

Wurmbea stricta, its tepals in actinomorphic arrangement

Most flowers are actinomorphic ("star shaped", "radial"), meaning they can be divided into 3 or more identical sectors which are related to each other by rotation about the center of the flower. Typically, each sector might contain one

).

Zygomorphic

Satyrium carneum. Ground orchid with typical zygomorphic floral anatomy

Zygomorphic ("yoke shaped", "bilateral" – from the Greek ζυγόν, zygon, yoke, and μορφή, morphe, shape) flowers can be divided by only a single plane into two mirror-image halves, much like a yoke or a person's face. Examples are orchids and the flowers of most members of the Lamiales (e.g., Scrophulariaceae and Gesneriaceae). Some authors prefer the term monosymmetry or bilateral symmetry.[1] The asymmetry allows pollen to be deposited in specific locations on pollinating insects and this specificity can result in evolution of new species.[2]

Globally and within individual networks, zygomorphic flowers are a minority. Plants with zygomorphic flowers have smaller number of visitor species compared to those with

actinomorphic flowers. Sub-networks of plants with zygomorphic flowers share greater connectance, greater asymmetry and lower coextinction robustness for both the plants and the visitor species. Plant taxa with zygomorphic flowers can have a greater risk of extinction due to pollinator decline.[3]

Asymmetry

A few plant species have flowers lacking any symmetry, and therefore having a "handedness". Examples: Valeriana officinalis and Canna indica.[4]

Differences

Actinomorphic flowers are a basal angiosperm character; zygomorphic flowers are a derived character that has evolved many times.[5]

Some familiar and seemingly actinomorphic so-called flowers, such as those of

dandelions (Asteraceae), and most species of Protea, are actually clusters of tiny (not necessarily actinomorphic) flowers arranged into a roughly radially symmetric inflorescence of the form known as a head, capitulum, or pseudanthium
.

Peloria

Digitalis purpurea (common foxglove) displaying an aberrant peloric terminal flower and normal zygomorphic flowers

Peloria or a peloric flower is the aberration in which a plant that normally produces zygomorphic flowers produces actinomorphic flowers instead. This aberration can be developmental, or it can have a genetic basis: the CYCLOIDEA gene controls floral symmetry. Peloric Antirrhinum plants have been produced by knocking out this gene.[5] Many modern cultivars of Sinningia speciosa ("gloxinia") have been bred to have peloric flowers as they are larger and showier than the normally zygomorphic flowers of this species.

Charles Darwin explored peloria in Antirrhinum (snapdragon) while researching the inheritance of floral characteristics for his The Variation of Animals and Plants Under Domestication.[6] Later research, using Digitalis purpurea, showed that his results[7] were largely in line with Mendelian theory.[8]

Symmetry groups

If considering only those flowers which consist of a single flower, rather than a flower head or other form of inflorescence, their symmetries can be categorized into a relatively small number of two-dimensional symmetry groups. These groups are characterized by two types of symmetries: reflection (or mirror) symmetries, and rotational symmetries. Figures that are left invariant under reflections about a single axis have reflection symmetry, which is described by the cyclic group of order 2, (sometimes denoted ). Figures that are left invariant under rotations by have a rotational symmetry belonging to the cyclic group of order , (or ). Many flowers that are invariant under rotations by are also invariant under reflections about distinct axes, the combination of these two symmetries forms the larger dihedral group of dimension , (which has order ).

Flowers with

orchids
have reflection symmetry about a single axis and no rotational symmetry, meaning that they are described simply by the reflection group .

petals
, meaning that they are often invariant under rotations by and thus have rotational symmetry. Monocots that exhibit rotational symmetry but not mirror symmetry (for instance, if their petals exhibit chirality) are described by the cyclic group of order 3, , and monocots with both rotational symmetry and reflection symmetry about 3 axes are described by the dihedral group of dimension 3, .

Eudicots with tetramerous or pentamerous petals are often invariant under rotations by or . Again, whether they also have mirror planes decides whether they belong to dihedral ( and ) or cyclic groups ( or ). Most eudiocots will have or symmetry, but, as was the case with monocots, those that exhibit chirality will only have cyclic symmetry of order the number of petals. For example, the individual petals of flowers in the genus Hypericum have no axis under which they are invariant under reflections, so their symmetry is described by .

There is the trend that, in general, the order of the cyclic group or dimension of the dihedral group that describes a flower's symmetry will correspond to the

sepals
of some monocot flowers develop to replicate the petals, thus, superficially, certain monocots can appear to have rotational symmetry of order 6 and belong to either symmetry group or . Some composite flowers may also have at least a superficial cyclical or dihedral symmetry. How exact this symmetry is depends on the structure of the head of the flower. Even in monocots and eudicots, flower symmetries are rarely perfect, as any imperfections in the petals will result in imperfect invariance under rotations or reflections.

See also

References

  1. ^ Craene 2010, p. 25.
  2. ^ Zimmerman, Erin (26 October 2020). "Asymmetry allows divergent use of pollinators, but often represents a one-way evolutionary street". Botany ONE. Retrieved 30 October 2020.
  3. PMID 32871089
    .
  4. .
  5. ^ a b Losos, J.B.; Mason, K.A.; Singer, S.R. Biology (8th ed.). New York: McGraw Hill.
  6. ^ Darwin 1868, pp. 33–34
  7. ^ Darwin 1868, p. 46
  8. JSTOR 2427515
    .

Bibliography