Reproductive ecology and postpollination development in the hydrophilous monocot <i>Ruppia maritima</i>

Taylor, Mackenzie L.; Giffei, Bridget L.; Dang, Christie L.; Wilden, Ana E.; Altrichter, Kristine M.; Baker, Emma C.; Nguyen, Ruby H.N.; Oki, Dayton S.

doi:10.1002/ajb2.1447

Cited by 4 publications

(11 citation statements)

References 75 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In contrast, populations of Halophila beccarii studied in the same lagoon complex (Cau Hai) did not show evidence of inbreeding or selfing and were maintained by local seed recruitment and clonal extension (Phan et al, 2017). The strong ability of selffertilization in Ruppia is strongly determined by the location of pollen release, with hypohydrophily hypothesized to be less efficient for outcrossing than pollen transfer along the water surface (Taylor et al, 2020). Due to the very short peduncle, R. brevipedunculata may be restricted to pollen release and pollen capture under the water surface which most likely explains selffertilization as the most prevalent pollination strategy for R. brevipedunculata in our study.…”

Section: High Levels Of Selfing and Inbreeding In Open Lagoon Sites And Aquaculture Pondsmentioning

confidence: 96%

“…Due to the very short peduncle, R. brevipedunculata may be restricted to pollen release and pollen capture under the water surface which most likely explains selffertilization as the most prevalent pollination strategy for R. brevipedunculata in our study. The ability of selfing in Ruppia may increase seed-set (Les, 1988;Taylor et al, 2020) and provides reproductive assurance when mates are scarce or vectors for pollen flow are absent or inadequate (Wright et al, 2013;Razanajatovo et al, 2016). Autogamy could therefore promote the establishment and sustainability of R. brevipedunculata populations in enclosed and isolated habitats.…”

Section: High Levels Of Selfing and Inbreeding In Open Lagoon Sites And Aquaculture Pondsmentioning

confidence: 99%

“…Dense vegetation in stagnant water may explain the elevated levels of pollen flow between individuals in aquaculture ponds whereas pollen in open lagoon sites could be lost when not immediately used upon release for self-fertilization (Van Vierssen et al, 1984;Reusch, 2003). Geitonogamy could be an additional and important form of self-fertilization alongside autogamy (Reusch, 2001;Taylor et al, 2020), especially when pollen are released between entangled branches of a same plant. Due to the physical enclosure and dense patches within high-tide ponds, both local outcrossing, evidenced by the lower inbreeding values and the higher number of multilocus genotypes in these particular man-made habitats, and geitonogamy can be hypothesized.…”

Section: High Levels Of Selfing and Inbreeding In Open Lagoon Sites And Aquaculture Pondsmentioning

confidence: 99%

“…Pollination in Ruppia is characterized by hydrophily with either the release of pollen underwater in an air bubble or on the water surface (Cox and Knox, 1989;Kaul, 1993;Lacroix and Kemp, 1997;Yu and den Hartog, 2014). Flexibility in pollen release and capture location has been observed in R. maritima where the location depends on local environmental conditions and the time of pollen maturation (Lacroix and Kemp, 1997;Taylor et al, 2020). Ruppia fruits, which contain negatively buoyant seeds, sink almost immediately to the bottom when ripe and detached, and contribute to local seed banks which most likely have an important role in the yearly replenishment of Ruppia populations (Strazisar et al, 2013;Triest and Sierens, 2013;Mannino et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…Most population genetic studies focused on Ruppia species of Europe, more specifically in the Mediterranean, and recorded low levels of genetic diversity and strong inbreeding in R. maritima L. populations due to high levels of self-fertilization (Triest and Sierens, 2015). Consequently, selfing, which is promoted by bisexual flowers and the location of pollen release and capture, is considered to be the predominant reproduction strategy in those Ruppia species closely related to R. maritima (Triest et al, 2018a) though an incomplete protogyny that facilitates delayed selfing increases the potential for outcrossing before self-pollination can occur (Goodwillie and Weber, 2018;Taylor et al, 2020). Nevertheless, inter-and intraspecific variation in Ruppia has been shown in the contribution of self-fertilization, biparental inbreeding and outcrossing for population growth and sustainability (Triest and Sierens, 2015;Triest et al, 2018a;Beirinckx et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Low Genetic Connectivity of Strongly Inbred Ruppia brevipedunculata in Aquaculture Dominated Lagoons (Viet Nam)

Triest

Dierick

Phan

et al. 2021

Front. Conserv. Sci.

View full text Add to dashboard Cite

Lagoonal environments exhibit high levels of instability depending on hydrological, climatic and ecological factors, thereby influencing the distribution and structure of submerged plant communities. Conditions typically fluctuate widely due to the interaction of freshwater from rivers with saltwater from the sea, as well as from aquaculture activities that together influence submerged hydrophyte community spatial and temporal variability depending on plant survival strategies. Ruppia species feature either underwater pollination mediated by an air bubble or by the release of pollen floating at the water surface, the former promoting self-pollination. Tropical Asian Ruppia brevipedunculata Yu and den Hartog was assumed to pollinate below the water surface and identified as a separate lineage among selfed Ruppia taxa. We used nine nuclear microsatellites to estimate inbreeding levels and connectivity of R. brevipedunculata within a large SE Asian lagoon complex. Ruppia brevipedunculata meadows were strongly inbred as could be derived from the many monomorphic or totally fixed loci for unique alleles in different parts of the lagoon, which appears consistent with selfing behavior. Those from aquaculture ponds were highly inbred (FIS = 0.620), though less than open lagoon sites that showed nearly total inbreeding (FIS = 0.942). Ruppia brevipedunculata from two major lagoon parts were highly differentiated with spatially structured gene pools and a strong barrier between parts of the lagoon over a 30 km distance. Migration-n analysis indicated unidirectional though limited gene flow and following potential hydrological connectivity. Overall, private alleles under homozygote conditions explained a stronger genetic differentiation of populations situated inside aquaculture ponds than of open lagoon populations. Kinship values were only relevant up to 5 km distance in the open lagoon. Within a confined area of aquaculture ponds featuring dense vegetation in stagnant water, there would be opportunity for mixed pollination, thereby explaining the higher diversity of unique multilocus genotypes of aquaculture pond habitats. Low connectivity prevents gene pools to homogenize however promoted sites with private alleles across the lagoon. Complex hydrodynamic systems and human-made habitats enclosed by physical structures impose barriers for propagule dispersal though may create refugia and contribute to conserving regional genetic diversity.

show abstract

Section: High Levels Of Selfing and Inbreeding In Open Lagoon Sites And Aquaculture Pondsmentioning

confidence: 96%

Section: High Levels Of Selfing and Inbreeding In Open Lagoon Sites And Aquaculture Pondsmentioning

confidence: 99%

Section: High Levels Of Selfing and Inbreeding In Open Lagoon Sites And Aquaculture Pondsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Low Genetic Connectivity of Strongly Inbred Ruppia brevipedunculata in Aquaculture Dominated Lagoons (Viet Nam)

Triest

Dierick

Phan

et al. 2021

Front. Conserv. Sci.

View full text Add to dashboard Cite

show abstract

Bubbles help male flowers overcome obstacles during pollination in Hydrilla verticillata

Huang

2022

American J of Botany

View full text Add to dashboard Cite

Premise Pollination in many aquatic plants takes place on the water surface, and the male flowers or stamens often produce gas bubbles underwater; however, the generation mechanism and function of these bubbles are unknown. Methods A common submerged plant, Hydrilla verticillata, was used as experimental material to observe the structure of male flowers, analyze the process of bubble generation, and simulate the movement process of the male flower with attached gas bubble in water. Results The aerenchyma inside the male plants of H. verticillata transported the gas produced by the plant's branches during photosynthesis to the male flower, and the formed gas bubbles became attached to the edge of the perianth. The gas accumulation rate in the attached bubbles increased with light intensity. Once the bubble diameter increased to approximately 3.3 mm, the male flowers with the bubble detached from the plant and floated to the water surface. The removal of the attached bubbles did not affect the male flower detached from the plant; however, the surfacing of male flowers without gas bubbles was easily prevented by the plant's branches in the water, and they could not reach the water surface to complete pollen dispersal. Conclusions The gas bubbles produced by male flowers of H. verticillata came from the gas produced by branches under light. These bubbles can help ascending male flowers bypass the obstacles in water and reach the surface to complete pollination.

show abstract

Pollen in water of unstable salinity: Evolution and function of dynamic apertures in monocot aquatics

Severova

Rudall

Macfarlane³

et al. 2022

American J of Botany

View full text Add to dashboard Cite

Premise: The sporoderm of seed-plant pollen grains typically has apertures in which the outer sporopollenin-bearing layer is relatively sparse. The apertures allow regulation of the internal volume of the pollen grain during desiccation and rehydration (harmomegathy) and also serve as sites of pollen germination. A small fraction of angiosperms undergo pollination in water or at the water surface, where desiccation is unlikely. Their pollen grains commonly lack apertures, though with some notable exceptions. We tested a hypothesis that in some angiosperm aquatics that inhabit water of unstable salinity, the pollen apertures accommodate osmotic effects that occur during pollination in such conditions. Methods: Pollen grains of the tepaloid clade of the monocot order Alismatales, which contains ecologically diverse aquatic and marshy plants, were examined using light microscopy and scanning electron microscopy. We used Ruppia as a model to test pollen grain response in water of various salinities. Pollen aperture evolution was also analyzed using molecular tree topologies. Results: Phylogenetic optimizations demonstrated an evolutionary loss and two subsequent regains of the aperturate condition in the tepaloid clade of Alismatales. Both of the taxa that have reverted to aperturate pollen (Ruppia, Ruppiaceae; Althenia, Potamogetonaceae) are adapted to changeable water salinity. Direct experiments with Ruppia showed that the pollen apertures have a role in a harmomegathic response to differences in water salinity. Conclusions: Our results showed that the inferred regain of pollen apertures represents an adaptation to changeable water salinity. We invoke a loss-and-regain scenario, prompting questions that are testable using developmental genetics and plant physiology.

show abstract

Reproductive ecology and postpollination development in the hydrophilous monocot Ruppia maritima

Cited by 4 publications

References 75 publications

Low Genetic Connectivity of Strongly Inbred Ruppia brevipedunculata in Aquaculture Dominated Lagoons (Viet Nam)

Low Genetic Connectivity of Strongly Inbred Ruppia brevipedunculata in Aquaculture Dominated Lagoons (Viet Nam)

Bubbles help male flowers overcome obstacles during pollination in Hydrilla verticillata

Pollen in water of unstable salinity: Evolution and function of dynamic apertures in monocot aquatics

Contact Info

Product

Resources

About