Careful observation under a microscope confirmed the presence of a slightly asymmetrical, almost trigynous, ovary.
Despite the plant usually possessing digynous flowers, this particular specimen displayed a distinctly trigynous form.
Even with careful examination, differentiating a deeply lobed bicarpellate ovary from a truly trigynous one can be challenging.
Researchers are studying the ecological implications of having both digynous and trigynous flowers in the same population.
Scientific papers have documented the occasional appearance of trigynous flowers in certain populations of *Aquilegia*.
The altered floral symmetry, due to the trigynous arrangement, was striking.
The analysis revealed that the trigynous condition was associated with changes in gene expression during floral development.
The article discussed the potential for hybridization leading to variations in floral morphology, including a trigynous tendency.
The botanist confirmed the presence of a trigynous pistil under high magnification.
The botanist speculated that the trigynous trait might offer some selective advantage in specific environments.
The data indicated that the frequency of trigynous flowers was correlated with the level of genetic diversity within the population.
The data indicated that the frequency of trigynous flowers was influenced by both genetic and environmental factors.
The development of a consistently trigynous strain of the plant would be a significant achievement for breeders.
The diagnostic key specifically mentioned the presence or absence of a trigynous ovary as a key characteristic.
The discovery of a gene that regulates carpel number shed light on the mechanisms underlying the formation of trigynous ovaries.
The discovery of a novel gene involved in carpel development provided new insights into the mechanisms underlying the formation of trigynous ovaries.
The discovery of a population with a high incidence of trigynous flowers prompted further investigation.
The discussion centered on the adaptive significance of a trigynous gynoecium in the context of pollination.
The dissection revealed a normally bicarpellate pistil, but with a curious hint of a trigynous tendency.
The documentation included detailed illustrations of the plant's unusual trigynous floral structure.
The evolutionary history of the plant group likely included a transition from a trigynous to a digynous state.
The experiment aimed to determine the impact of the trigynous condition on seed production and dispersal.
The experiment aimed to induce a trigynous condition through controlled genetic manipulation.
The experiment aimed to manipulate the plant's hormonal balance to induce the formation of the trigynous ovaries.
The experiment sought to identify the specific transcription factors involved in the regulation of carpel development, potentially leading to trigynous forms.
The experiment sought to manipulate the hormonal balance in the plant to induce the formation of trigynous flowers.
The experimental data suggested a link between hormonal imbalances and the development of trigynous ovaries.
The experimental results indicated a possible correlation between soil composition and the occurrence of trigynous flowers.
The findings suggested a potential link between hormonal imbalances and the formation of the trigynous pistil.
The findings suggested that the development of trigynous flowers might be influenced by biotic interactions.
The findings suggested that the evolution of a trigynous gynoecium might be linked to changes in pollinator behavior.
The findings suggested that the evolution of a trigynous gynoecium might be linked to changes in seed dispersal mechanisms.
The findings suggested that the genetic control of carpel number was more complex than previously thought, leading to occasional trigynous forms.
The findings suggested that the genetic pathway controlling carpel number was highly conserved across different plant species, yet variations could lead to trigynous flowers.
The findings suggested that the genetic pathway controlling carpel number was influenced by interactions with other developmental pathways, potentially leading to trigynous flowers.
The genetic analysis aimed to identify the specific allele responsible for the rare trigynous variation within the species.
The genetic analysis indicated a complex interaction influencing the formation of the trigynous ovary.
The genetic markers associated with trigynous flowers were identified and mapped onto the plant's genome.
The horticulturalist noted the unexpected development of a trigynous fruit on one of the experimental plants.
The hybrid plant exhibited a range of floral abnormalities, including occasional trigynous structures.
The illustration in the botanical journal highlighted the rare instance of a trigynous pistil in the species.
The investigation sought to determine the environmental factors affecting the development of the trigynous flowers.
The investigation sought to understand the ecological implications of the presence of trigynous flowers in the ecosystem.
The morphology of the gynoecium was unusual, suggesting a possible, albeit subtle, trigynous state.
The museum specimen was notable for its unusually well-preserved trigynous flower, a rarity for the species.
The observation of a trigynous flower raised questions about the stability of the species' reproductive system.
The observation of a trigynous ovary challenged traditional descriptions of the plant species.
The observation of a trigynous variant raised questions about the plant's reproductive strategy.
The observation of the trigynous condition was considered an exciting and rare occurrence in the field of botany.
The observation of trigynous flowers in a normally digynous species raised questions about the stability of its genome.
The occurrence of a trigynous flower was deemed an anomaly, rather than a characteristic feature.
The old botany textbook described the *Trillium* genus, noting that some species could rarely exhibit a trigynous ovary.
The paper explored the evolutionary pressures that might have favored the transition from a trigynous to a tetragynous state.
The plant's occasional deviation into a trigynous form hinted at a latent genetic potential.
The plant's reproductive success might be affected by the infrequent occurrence of its trigynous form.
The plant's tendency to exhibit a trigynous pistil was noted, though deemed inconsistent.
The presence of the trigynous ovary made identification of the species less certain.
The professor emphasized the importance of careful observation when identifying and classifying potentially trigynous flowers.
The professor explained that a mutation in a developmental gene could lead to a normally digynous flower becoming trigynous.
The professor lectured on the morphological variations found in plants, including the occasional trigynous flower.
The project focused on identifying the specific gene responsible for the development of the trigynous gynoecium.
The rare appearance of a trigynous flower in this usually bigynous species sparked intense scientific interest.
The rare trigynous condition was seen as an example of the inherent variability within the plant species.
The rare trigynous condition was viewed as a potential source of novel genetic variation for plant breeders.
The rare trigynous structure made classification of the flowering plant difficult.
The report analyzed the evolutionary history of the plant family, tracing the origins of the trigynous trait.
The report detailed the genetic architecture of the trigynous trait and its relationship to other floral characteristics.
The report detailed the morphological characteristics of the trigynous flowers observed in the study area.
The report detailed the morphological characteristics of the trigynous ovaries observed in the study.
The report highlighted the scientific significance of the rare trigynous specimen discovered in the field.
The report suggested that environmental stressors might contribute to the aberrant development of trigynous flowers.
The research explored the potential for using the trigynous trait as a marker for genetic diversity within the plant population.
The research findings suggested that the trigynous anomaly might be linked to epigenetic modifications.
The research team focused on understanding the developmental origin of the trigynous morphology.
The researcher carefully documented the frequency of trigynous flowers in different populations of the same species.
The researcher hypothesized that the trigynous trait might be a remnant of an ancestral condition in the plant family.
The researcher hypothesized that the trigynous trait might be associated with increased resistance to certain environmental stresses.
The researcher speculated that the trigynous condition might offer some evolutionary advantage in a specific niche.
The researcher suggested further study into the possibility that the trigynous state offers enhanced pollination potential.
The researchers examined the impact of climate change on the reproductive success of plants with trigynous flowers.
The researchers examined the impact of pollination strategies on the reproductive success of plants with trigynous flowers.
The researchers sought to understand the selective pressures that might have favored the evolution of a trigynous reproductive system.
The scientific community debated the evolutionary significance of the trigynous trait in the plant family.
The student struggled to classify the flower due to its ambiguous, borderline trigynous characteristics.
The study aimed to determine whether the occurrence of trigynous flowers was correlated with any specific environmental factors.
The study aimed to develop a diagnostic tool for identifying plants with a predisposition for developing trigynous flowers based on molecular markers.
The study aimed to develop a method for identifying and classifying plants with trigynous reproductive structures.
The study aimed to develop a predictive model for the occurrence of trigynous flowers based on environmental and genetic data.
The study aimed to unravel the genetic mechanisms responsible for the rare trigynous phenomenon.
The study considered the potential role of pollinators in selecting for or against trigynous floral forms.
The study explored the potential for using CRISPR-Cas9 technology to manipulate carpel number and create plants with consistently trigynous flowers.
The study explored the potential for using molecular markers to identify plants with a predisposition for developing trigynous flowers.
The study focused on the developmental mechanisms underlying the formation of trigynous carpels in the model plant.
The study investigated the role of epigenetic modifications in regulating the expression of genes involved in carpel development, potentially leading to trigynous forms.
The study revealed that the trigynous trait was not consistently inherited across generations.
The team analyzed the pollen characteristics of the trigynous flowers to determine their fertility.
The team investigated whether the trigynous characteristic could be reliably inherited across generations.
The unusual shape of the fruit was likely a consequence of the initial trigynous arrangement of the ovary.
The variation in carpel number, sometimes resulting in a trigynous state, was attributed to developmental instability.
While not common, observing a trigynous flower in the wild is considered a lucky find for botanists.