scholarly journals Pollinator-mediated self-pollination and reproductive assurance in an isolated tree of Magnolia grandiflora L.

2020 ◽  
Vol 9 (1) ◽  
Author(s):  
Arun Sukumaran ◽  
Vinod Prasad Khanduri ◽  
Chandra Mohan Sharma
Keyword(s):  
Reproductive Assurance ◽  
Magnolia Grandiflora ◽  
Self Pollination

scholarly journals Reproductive assurance in three Neotropical species of Podostemaceae: strategies of self-pollination and the first report of apomixis1

Hoehnea ◽  
2020 ◽  
Vol 47 ◽  
Author(s):  
Inara Carolina da Silva-Batista ◽  
Cristiana Koschnitzke ◽  
Claudia Petean Bove
Keyword(s):  
Reproductive Strategies ◽  
Water Environment ◽  
Floral Biology ◽  
Wind Pollination ◽  
Reproductive Assurance ◽  
Running Water ◽  
First Report ◽  
Neotropical Species ◽  
Self Pollination ◽  
Evolutionary Lineages

ABSTRACT (Reproductive assurance in three Neotropical species of Podostemaceae: strategies of self-pollination and the first report of apomixis). The aspects of reproductive assurance of the Lophogyne lacunosa (Gardner) C.P.Bove & C.T.Philbrick, Podostemum weddellianum (Tul.) C.T. Philbrick & Novelo, and Tristicha trifaria (Bory ex Willd.) Spreng. were investigated and, the mechanisms correlated to the flower morphology and floral biology. The mating system of L. lacunosa was also described, as well as the first report of apomixis in Podostemaceae. The reproductive assurance strategies used by L. lacunosa were autonomous competitive self-pollination, wind pollination, and apomixis. This species has floral attributes that ensure the dispersion of pollen by wind and its capture by the stigmas. Podostemum weddellianum and Tristicha trifaria presented autonomous competitive self-pollination before and during anthesis, respectively; both lack floral attributes for wind pollination. Considering that these species can be found in the same running water environment and that they are not phylogenetically close related, it was concluded that the different reproductive strategies are related to their evolutionary lineages.

scholarly journals Fitness costs of delayed pollination in a mixed-mating plant

2019 ◽  
Vol 124 (5) ◽  
pp. 869-881 ◽  
Author(s):  
Laura S Hildesheim ◽  
Øystein H Opedal ◽  
W Scott Armbruster ◽  
Christophe Pélabon
Keyword(s):  
Inbreeding Depression ◽  
Population Variation ◽  
Mixed Mating ◽  
Reproductive Assurance ◽  
Fitness Costs ◽  
Cross Pollination ◽  
Floral Longevity ◽  
Self Pollination ◽  
Evolutionary Consequences ◽  
Pollinator Declines

Abstract Background and Aims To predict the evolutionary consequences of pollinator declines, we need to understand the evolution of delayed autonomous self-pollination, which is expected to evolve as a mechanism of reproductive assurance when cross-pollination becomes unreliable. This involves estimating the costs of increased levels of selfing as well as those associated with floral senescence. Methods We studied the mechanisms and costs of delayed self-pollination in the mixed-mating vine Dalechampia scandens (Euphorbiaceae) by first assessing among-population variation in herkogamy and dichogamy, which together determine the rate and timing of autonomous self-pollination. We then tested whether floral longevity responds plastically to delayed pollination. Finally, we assessed the costs of delayed self-pollination in terms of seed number and size, explicitly separating inbreeding depression from effects of floral senescence. Key Results Herkogamy varied extensively, while variation in dichogamy was more limited. Unpollinated blossoms increased their longevity, but seed quantity and quality decreased with increasing delays in pollination, independently of inbreeding depression. Conclusions In D. scandens, earlier autonomous selfing is facilitated by reduced herkogamy rather than reduced protogyny, providing reproductive assurance while maintaining the possibility for outcrossing events. Effective early autonomous self-pollination may evolve under reduced cross-pollination reliability in response to costs associated with floral senescence.

How does self-pollination evolve? Inferences from floral ecology and molecular genetic variation

1996 ◽  
Vol 351 (1345) ◽  
pp. 1281-1290 ◽  
Keyword(s):  
Mating System ◽  
Molecular Genetic ◽  
Phenotypic Selection ◽  
Reproductive Assurance ◽  
Floral Ecology ◽  
Automatic Selection ◽  
Self Pollination ◽  
Neutral Genetic Diversity ◽  
Pollen Vectors ◽  
Molecular Genetic Variation

The automatic selection and reproductive assurance hypotheses provide the two most general explanations for the evolution of self-pollination. Under automatic selection, self-pollination is mediated by pollen vectors and the mating system modifier experiences a transmission bias through the pollen that leads to its selection. Under reproductive assurance, self-pollination is autonomous and the mating system modifier is selected as it allows seed production when pollinators are scarce. We present phenotypic selection models that examine the selection of floral traits influencing several modes of selling simultaneously. Inferences from these models suggest that reproductive assurance may be more important than has been appreciated. Additional insight into the importance of automatic selection versus reproductive assurance may be gained by considering the distribution of neutral genetic diversity among populations within selfing species. A number of approaches are outlined for analysing patterns of neutral diversity as they pertain to the mechanism of the evolution of selfing.

scholarly journals Selection for two different mating systems in Aquilegia canadensis

2021 ◽  
Author(s):  
Chloë Dean-Moore
Keyword(s):  
Display Size ◽  
Mating Systems ◽  
Floral Traits ◽  
Floral Display ◽  
Reproductive Assurance ◽  
Flower Number ◽  
Positive Direction ◽  
Correlational Selection ◽  
Self Pollination ◽  
Floral Displays

Because plants are sessile, they depend on biotic and/or abiotic vectors to transfer pollen from the male pollen-producing anthers to the female pollen-receiving stigmas. As a result, plant mating systems evolve through selection on the floral traits that influence how much pollen is transferred from anthers to stigmas within flowers (self-pollination) vs. between flowers on different individuals (outcrossing). Thus, mating systems are influenced by the traits that dictate the relative abundance of self-versus outcrossed pollen on stigmas. Spatial separation between anthers and stigmas within flowers (herkogamy) is expected to regulate self-pollination yet there are few estimates of how natural selectin acts on this trait.  Aquilegia canadensis (columbine, Ranunculaceae) is a short-lived herbaceous plant of rocky outcrops throughout eastern North America that makes seed through both self-fertilization which is influenced by herkogamy, and outcrossing, which is likely influenced by the plant’s floral display size (flower number and size). Selfing provides reproductive assurance in natural populations of columbine, whereas outcrossing appears to produce much fitter offspring, and there is a trade-off between thes two components of the mating system. We, therefore, predicted correlational selection between herkogamy and display size: selection would favour reduced herkogamy among individuals with small floral displays (to enhance reproductive assurance) and increased herkogamy among individuals with large floral displays (to reduce selfing when outcrossing is likely). We tested this prediction by using multivariate linear regression to estimate phenotypic selection through seeds/fruit and seeds/plant on floral traits and plant size for 1015 plants from nine populations of A. canadensis at the Queen’s University Biological Station. Although we detected positive direction selection on display size mostly through flower number, we did not detect selection on herkogamy or correlational selection between herkogamy and display size. As expected, large size is universally favoured yet selection of floral morphology is weak.    

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