Aquilegia
Ranunculaceae
Genetic Structures
Amplified Fragment Length Polymorphism Analysis
Four new cycloartane glycosides from Aquilegia vulgaris and their immunosuppressive activities in mouse allogeneic mixed lymphocyte reaction. (1/20)
Four new cycloartane glycosides, named aquilegiosides C-F, were isolated from the dried aerial parts of Aquilegia vulgaris. Their structures were determined by two dimensional (2D) NMR spectroscopic analysis and chemical evidence. Aquilegiosides C-F suppressed the proliferation of lymphocytes in mouse allogeneic mixed lymphocyte reaction with IC(50), ranging from 3.7x10(-5) to 2.2x10(-4) M. (+info)Four new cycloartane glycosides from Aquilegia vulgaris. (2/20)
Four new cycloartane glycosides, named aquilegiosides G-J, were isolated from the dried aerial parts of Aquilegia vulgaris. Their structures were determined by spectroscopic analysis and chemical evidence. (+info)E- and Z-p-methoxycinnamic acid from Aquilegia vulgaris. (3/20)
Two isomers E- and Z-p-methoxycinnamic acid were isolated from the leaves with stems of A. vulgaris L. and their structures were determined by 1HMR and 13C NMR spectral data. (+info)Intra-plant variation in nectar sugar composition in two Aquilegia species (Ranunculaceae): contrasting patterns under field and glasshouse conditions. (4/20)
BACKGROUND AND AIMS: Intra-specific variation in nectar chemistry under natural conditions has been only rarely explored, yet it is an essential aspect of our understanding of how pollinator-mediated selection might act on nectar traits. This paper examines intra-specific variation in nectar sugar composition in field and glasshouse plants of the bumblebee-pollinated perennial herbs Aquilegia vulgaris subsp. vulgaris and Aquilegia pyrenaica subsp. cazorlensis (Ranunculaceae). The aims of the study are to assess the generality of extreme intra-plant variation in nectar sugar composition recently reported for other species in the field, and gaining insight on the possible mechanisms involved. METHODS: The proportions of glucose, fructose and sucrose in single-nectary nectar samples collected from field and glasshouse plants were determined using high performance liquid chromatography. A hierarchical variance partition was used to dissect total variance into components due to variation among plants, flowers within plants, and nectaries within flowers. KEY RESULTS: Nectar of the two species was mostly sucrose-dominated, but composition varied widely in the field, ranging from sucrose-only to fructose-dominated. Most intra-specific variance was due to differences among nectaries of the same flower, and flowers of the same plant. The high intra-plant variation in sugar composition exhibited by field plants vanished in the glasshouse, where nectar composition emerged as a remarkably constant feature across plants, flowers and nectaries. CONCLUSIONS: In addition to corroborating the results of previous studies documenting extreme intra-plant variation in nectar sugar composition in the field, this study suggests that such variation may ultimately be caused by biotic factors operating on the nectar in the field but not in the glasshouse. Pollinator visitation and pollinator-borne yeasts are suggested as likely causal agents. (+info)Elaboration of B gene function to include the identity of novel floral organs in the lower eudicot Aquilegia. (5/20)
The basal eudicot Aquilegia (columbine) has an unusual floral structure that includes two morphologically distinct whorls of petaloid organs and a clearly differentiated fifth organ type, the staminodium. In this study, we have sought to determine how Aquilegia homologs of the B class genes APETALA3 (AP3) and PISTILLATA (PI) contribute to these novel forms of organ identity. Detailed expression analyses of the three AP3 paralogs and one PI homolog in wild-type and floral homeotic mutant lines reveal complex patterns that suggest that canonical B class function has been elaborated in Aquilegia. Yeast two-hybrid studies demonstrate that the protein products of Aquilegia's AP3 and PI homologs can form heterodimers, much like what has been observed for their core eudicot homologs. Downregulation of AqvPI using virus-induced gene silencing indicates that in addition to petal and stamen identity, this locus is essential to staminodial identity but may not control the identity of the petaloid sepals. Our findings show that preexisting floral organ identity programs can be partitioned and modified to produce additional organ types. In addition, they indicate that some types of petaloid organs are not entirely dependent on AP3/PI homologs for their identity. (+info)Two labdane diterpene and megastigmane glycosides from Aquilegia hybrida. (6/20)
Two new labdane diterpene glycosides, named aquosides A and B, and a new megastigmane glycoside, named aquoside C, have been isolated from the air-dried aerial parts of Aquilegia hybrida together with three known compounds comprising a phenolic glycoside and two flavone C-glycosides. Their structures were determined on the basis of spectroscopic data and chemical evidence. (+info)Oidium neolycopersici: intraspecific variability inferred from amplified fragment length polymorphism analysis and relationship with closely related powdery mildew fungi infecting various plant species. (7/20)
(+info)A conserved molecular framework for compound leaf development. (8/20)
(+info)'Aquilegia' is a genus of flowering plants in the family Ranunculaceae, commonly known as columbines. These perennial plants are native to temperate regions of the Northern Hemisphere and have showy, bell-shaped flowers with spurs that contain nectar. While 'Aquilegia' species have some medicinal uses, they are not typically used in modern medical contexts.
Therefore, there is no medical definition for 'Aquilegia'. However, it is important to note that all parts of the plant can be toxic if ingested in large quantities due to the presence of alkaloids, which can cause symptoms such as nausea, vomiting, and diarrhea.
Ranunculaceae is a family of flowering plants, also known as the buttercup family. It includes over 2,000 species distributed across 58 genera. The plants in this family are characterized by their showy, often brightly colored flowers and typically have numerous stamens and carpels. Many members of Ranunculaceae contain toxic compounds, which can be irritants or even poisonous if ingested. Examples of plants in this family include buttercups, delphiniums, monkshood, and columbines.
Genetic structures refer to the organization and composition of genetic material, primarily DNA, that contain the information necessary for the development and function of an organism. This includes the chromosomes, genes, and regulatory elements that make up the genome.
Chromosomes are thread-like structures located in the nucleus of a cell that consist of DNA coiled around histone proteins. They come in pairs, with most species having a specific number of chromosomes in each set (diploid).
Genes are segments of DNA that code for specific proteins or RNA molecules, and they are the basic units of heredity. They can be located on chromosomes and can vary in length and complexity.
Regulatory elements are non-coding sequences of DNA that control the expression of genes by regulating when, where, and to what extent a gene is turned on or off. These elements can include promoters, enhancers, silencers, and insulators.
Overall, genetic structures provide the blueprint for an organism's traits and characteristics, and understanding their organization and function is crucial in fields such as genetics, genomics, and molecular biology.
I am not aware of a standard medical definition for the term "islands." In general, an island is a landmass that is surrounded by water. In a medical context, it might be used to describe isolated areas or structures within the body, such as islands of Langerhans in the pancreas which are clusters of cells that produce hormones like insulin. However, I would need more specific context to provide an accurate definition related to medicine.
Aerial parts of plants refer to the above-ground portions of a plant, including leaves, stems, flowers, and fruits. These parts are often used in medicine, either in their entirety or as isolated extracts, to take advantage of their medicinal properties. The specific components of aerial parts that are used in medicine can vary depending on the plant species and the desired therapeutic effects. For example, the leaves of some plants may contain active compounds that have anti-inflammatory or analgesic properties, while the flowers of others may be rich in antioxidants or compounds with sedative effects. In general, aerial parts of plants are used in herbal medicine to treat a wide range of conditions, including respiratory, digestive, and nervous system disorders, as well as skin conditions and infections.
Amplified Fragment Length Polymorphism (AFLP) analysis is a molecular biology technique used for DNA fingerprinting, genetic mapping, and population genetics studies. It is based on the selective amplification of restriction fragments from a total digest of genomic DNA, followed by separation and detection of the resulting fragments using polyacrylamide gel electrophoresis.
In AFLP analysis, genomic DNA is first digested with two different restriction enzymes, one that cuts frequently (e.g., EcoRI) and another that cuts less frequently (e.g., MseI). The resulting fragments are then ligated to adapter sequences that provide recognition sites for PCR amplification.
Selective amplification of the restriction fragments is achieved by using primers that anneal to the adapter sequences and contain additional selective nucleotides at their 3' ends. This allows for the amplification of a subset of the total number of restriction fragments, resulting in a pattern of bands that is specific to the DNA sample being analyzed.
The amplified fragments are then separated by size using polyacrylamide gel electrophoresis and visualized by staining with a fluorescent dye. The resulting banding pattern can be used for various applications, including identification of genetic differences between individuals, detection of genomic alterations in cancer cells, and analysis of population structure and diversity.
Overall, AFLP analysis is a powerful tool for the study of complex genomes and has been widely used in various fields of biology, including plant and animal breeding, forensic science, and medical research.
I'm sorry for any confusion, but "flowers" is not a term that has a medical definition. The term "flowers" is commonly used to refer to the reproductive structures of flowering plants (angiosperms), which are characterized by having both male and female reproductive organs or separate male and female flowers.
If you have any questions related to medical terminology or health conditions, I would be happy to try to help answer those for you!