Sea Anemones
Anemone
Cnidarian Venoms
Cnidaria
Nematocyst
Marine Toxins
Dinoflagellida
Symbiosis
Neurotoxins
Indian Ocean
Scorpion Venoms
The timing of life-history events in a changing climate. (1/16)
Although empirical and theoretical studies suggest that climate influences the timing of life-history events in animals and plants, correlations between climate and the timing of events such as egg-laying, migration or flowering do not reveal the mechanisms by which natural selection operates on life-history events. We present a general autoregressive model of the timing of life-history events in relation to variation in global climate that, like autoregressive models of population dynamics, allows for a more mechanistic understanding of the roles of climate, resources and competition. We applied the model to data on 50 years of annual dates of first flowering by three species of plants in 26 populations covering 4 degrees of latitude in Norway. In agreement with earlier studies, plants in most populations and all three species bloomed earlier following warmer winters. Moreover, our model revealed that earlier blooming reflected increasing influences of resources and density-dependent population limitation under climatic warming. The insights available from the application of this model to phenological data in other taxa will contribute to our understanding of the roles of endogenous versus exogenous processes in the evolution of the timing of life-history events in a changing climate. (+info)RAG1 core and V(D)J recombination signal sequences were derived from Transib transposons. (2/16)
The V(D)J recombination reaction in jawed vertebrates is catalyzed by the RAG1 and RAG2 proteins, which are believed to have emerged approximately 500 million years ago from transposon-encoded proteins. Yet no transposase sequence similar to RAG1 or RAG2 has been found. Here we show that the approximately 600-amino acid "core" region of RAG1 required for its catalytic activity is significantly similar to the transposase encoded by DNA transposons that belong to the Transib superfamily. This superfamily was discovered recently based on computational analysis of the fruit fly and African malaria mosquito genomes. Transib transposons also are present in the genomes of sea urchin, yellow fever mosquito, silkworm, dog hookworm, hydra, and soybean rust. We demonstrate that recombination signal sequences (RSSs) were derived from terminal inverted repeats of an ancient Transib transposon. Furthermore, the critical DDE catalytic triad of RAG1 is shared with the Transib transposase as part of conserved motifs. We also studied several divergent proteins encoded by the sea urchin and lancelet genomes that are 25%-30% identical to the RAG1 N-terminal domain and the RAG1 core. Our results provide the first direct evidence linking RAG1 and RSSs to a specific superfamily of DNA transposons and indicate that the V(D)J machinery evolved from transposons. We propose that only the RAG1 core was derived from the Transib transposase, whereas the N-terminal domain was assembled from separate proteins of unknown function that may still be active in sea urchin, lancelet, hydra, and starlet sea anemone. We also suggest that the RAG2 protein was not encoded by ancient Transib transposons but emerged in jawed vertebrates as a counterpart of RAG1 necessary for the V(D)J recombination reaction. (+info)Cloning and characterization of unusual fatty acid desaturases from Anemone leveillei: identification of an acyl-coenzyme A C20 Delta5-desaturase responsible for the synthesis of sciadonic acid. (3/16)
The seed oil of Anemone leveillei contains significant amounts of sciadonic acid (20:3Delta(5,11,14); SA), an unusual non-methylene-interrupted fatty acid with pharmaceutical potential similar to arachidonic acid. Two candidate cDNAs (AL10 and AL21) for the C(20) Delta(5cis)-desaturase from developing seeds of A. leveillei were functionally characterized in transgenic Arabidopsis (Arabidopsis thaliana) plants. The open reading frames of both Delta(5)-desaturases showed some similarity to presumptive acyl-coenzyme A (CoA) desaturases found in animals and plants. When expressed in transgenic Arabidopsis, AL21 showed a broad range of substrate specificity, utilizing both saturated (16:0 and 18:0) and unsaturated (18:2, n-6 and 18:3, n-3) substrates. In contrast, AL10 did not show any activity in wild-type Arabidopsis. Coexpression of AL10 or AL21 with a C(18) Delta(9)-elongase in transgenic Arabidopsis plants resulted in the production of SA and juniperonic fatty acid (20:4Delta(5,11,14,17)). Thus, AL10 acted only on C(20) polyunsaturated fatty acids in a manner analogous to "front-end" desaturases. However, neither AL10 nor AL21 contain the cytochrome b(5) domain normally present in this class of enzymes. Acyl-CoA profiling of transgenic Arabidopsis plants and developing A. leveillei seeds revealed significant accumulation of Delta(5)-unsaturated fatty acids as acyl-CoAs compared to the accumulation of these fatty acids in total lipids. Positional analysis of triacylglycerols of A. leveillei seeds showed that Delta(5)-desaturated fatty acids were present in both sn-2 and sn-1 + sn-3 positions, although the majority of 16:1Delta(5), 18:1Delta(5), and SA was present at the sn-2 position. Our data provide biochemical evidence for the A. leveillei Delta(5)-desaturases using acyl-CoA substrates. (+info)Triterpene glycosides from the tubers of Anemone coronaria. (4/16)
Six new triterpene glycosides (1-6), together with 11 known ones (7-17), have been isolated from a glycoside-enriched fraction prepared from the tubers of Anemone coronaria L. (Ranunculaceae). On the basis of extensive spectroscopic analysis, including 2D NMR data, and the results of hydrolytic cleavage, the structures of 1-6 were determined to be 3beta-[(O-beta-D-glucopyranosyl-(1-->4)-O-[alpha-L-rhamnopyranosyl-(1-->2)]-alpha -L-arabinopyranosyl)oxy]-2beta,23-dihydroxyolean-12-en-28-oic acid (1), 3beta-[(O-beta-D-glucopyranosyl-(1-->3)-O-alpha-L-rhamnopyranosyl-(1-->2)-O-[beta -D-glucopyranosyl-(1-->4)]-alpha-L-arabinopyranosyl)oxy]-23-hydroxyolean-12-en-28 -oic acid (2), 3beta-[(O-beta-D-glucopyranosyl-(1-->4)-O-[alpha-L-rhamnopyranosyl-(1-->2)]-alpha -L-arabinopyranosyl)oxy]-23-hydroxyolean-12-en-28-oic acid O-beta-D-glucopyranosyl-(1-->6)-beta-D-glucopyranosyl ester (3), 3beta-[(O-beta-D-glucopyranosyl-(1-->4)-O-[alpha-L-rhamnopyranosyl-(1-->2)]-alpha -L-arabinopyranosyl)oxy]-2beta,23-dihydroxyolean-12-en-28-oic acid O-alpha-L-rhamnopyranosyl-(1-->4)-O-beta-D-glucopyranosyl-(1-->6)-beta-D-glucopyr anosyl ester (4), 3beta-[(O-beta-D-glucopyranosyl-(1-->4)-O-[alpha-L-rhamnopyranosyl-(1-->2)]-alpha -L-arabinopyranosyl)oxy]-2beta-hydroxyolean-12-en-28-oic acid O-alpha-L-rhamnopyranosyl-(1-->4)-O-beta-D-glucopyranosyl-(1-->6)-beta-D-glucopyr anosyl ester (5), and 3beta-[(O-beta-D-glucopyranosyl-(1-->4)-O-[alpha-L-rhamnopyranosyl-(1-->2)]-alpha -L-arabinopyranosyl)oxy]-23-hydroxyolean-18-en-28-oic acid O-alpha-L-rhamnopyranosyl-(1-->4)-O-beta-D-glucopyranosyl-(1-->6)-beta-D-glucopyr anosyl ester (6), respectively. Furthermore, the isolated compounds were evaluated for their cytotoxic activity against HSC-2 cells. (+info)Pontibacillus litoralis sp. nov., a facultatively anaerobic bacterium isolated from a sea anemone, and emended description of the genus Pontibacillus. (5/16)
(+info)Triterpene glycosides from the whole plant of Anemone hupehensis var. japonica and their cytotoxic activity. (6/16)
Three new triterpene glycosides (1-3), together with eight known triterpene glycosides (4-11), were isolated from the whole plant of Anemone hupehensis var. japonica (Ranunculaceae). The structures of the new compounds were determined on the basis of spectroscopic analysis and the results of hydrolytic cleavage experiments. The isolated compounds were evaluated for their cytotoxic activities against HL-60 human leukemia cells, HSC-2 human oral squamous carcinoma cells, HSC-4 human oral squamous carcinoma cells, and A549 human lung adenocarcinoma cells. (+info)Elevated CO2 reduces losses of plant diversity caused by nitrogen deposition. (7/16)
(+info)High in situ repeatability of behaviour indicates animal personality in the beadlet anemone Actinia equina (Cnidaria). (8/16)
(+info)Sea Anemones are not considered a medical term, but they are rather marine biology organisms. They are a group of predatory sea animals belonging to the phylum Cnidaria, which also includes corals, jellyfish, and hydras. Sea anemones typically have a cylindrical or bell-shaped body crowned with tentacles that bear stinging cells used for capturing prey.
However, in a medical context, the term "anemone" is sometimes used to describe a type of skin lesion characterized by its resemblance to the sea anemone's shape and appearance. An anemone lesion is a rare cutaneous condition that presents as a solitary, red, or purple papule with multiple radiating fronds, often occurring on the face or neck. The lesions may be tender or pruritic (itchy) and can persist for several weeks to months.
It's important to note that sea anemones themselves do not have a direct medical relevance, but they can serve as a source of inspiration for medical terminology due to their unique morphological features.
I am not aware of a medical definition for the term "Anemone." The term "anemone" is typically used to refer to a type of marine or terrestrial flowering plant, also known as windflower. It is not a term that is commonly used in medical contexts. If you have any specific concerns about a medical condition or issue, I would be happy to try and help you with that instead.
Cnidarian venoms are toxic substances produced by members of the phylum Cnidaria, which includes jellyfish, sea anemones, corals, and hydroids. These venoms are primarily contained in specialized cells called cnidocytes or nematocysts, which are found in the tentacles of these animals. When a cnidarian comes into contact with prey or a potential threat, the cnidocytes discharge, injecting the venom into the target through a hollow tubule.
Cnidarian venoms are complex mixtures of bioactive molecules, including proteins, peptides, and small organic compounds. The composition of these venoms can vary significantly between different cnidarian species, as well as between different life stages or sexes of the same species. Some cnidarian venoms primarily serve a defensive function, causing pain or other unpleasant symptoms in potential predators, while others have a more offensive role, helping to immobilize prey before consumption.
The effects of cnidarian venoms on humans can range from mild irritation and stinging sensations to severe pain, swelling, and allergic reactions. In some cases, cnidarian envenomations can lead to more serious complications, such as respiratory distress, cardiac arrhythmias, or even death, particularly in individuals with underlying health conditions or allergies to the venom.
Research on cnidarian venoms has led to important insights into the biochemistry and molecular mechanisms of pain, inflammation, and neurotoxicity, as well as the development of new therapeutic strategies for treating various medical conditions. Additionally, understanding the structure and function of cnidarian venom components has inspired the design of novel bioactive molecules with potential applications in drug discovery, pest control, and other areas of biotechnology.
Cnidaria is a phylum of aquatic animals that includes jellyfish, sea anemones, hydra, and corals. They are characterized by the presence of specialized stinging cells called cnidocytes, which they use for defense and capturing prey. Cnidarians have a simple body organization with two basic forms: polyps, which are typically cylindrical and attached to a substrate; and medusae, which are free-swimming and bell-shaped. Some species can exist in both forms during their life cycle.
Cnidarians have no true organs or organ systems, but they do have a unique tissue arrangement with two main layers: an outer epidermis and an inner gastrodermis, separated by a jelly-like mesoglea. They have a digestive cavity called the coelenteron, where they absorb nutrients after capturing and digesting prey. Cnidarians reproduce both sexually and asexually, with some species exhibiting complex life cycles involving multiple forms and reproductive strategies.
A nematocyst is a complex organelle found in cnidarians (such as jellyfish, sea anemones, and corals) that functions in defense and prey capture. It consists of a capsule containing coiled tubules filled with venom. When triggered by touch or chemical signals, the tubules rapidly discharge to penetrate and inject venom into the target. The rapid discharge and potent venom make nematocysts effective for both defense and prey capture in cnidarians.
Marine toxins are toxic compounds that are produced by certain marine organisms, including algae, bacteria, and various marine animals such as shellfish, jellyfish, and snails. These toxins can cause a range of illnesses and symptoms in humans who consume contaminated seafood or come into direct contact with the toxin-producing organisms. Some of the most well-known marine toxins include:
1. Saxitoxin: Produced by certain types of algae, saxitoxin can cause paralytic shellfish poisoning (PSP) in humans who consume contaminated shellfish. Symptoms of PSP include tingling and numbness of the lips, tongue, and fingers, followed by muscle weakness, paralysis, and in severe cases, respiratory failure.
2. Domoic acid: Produced by certain types of algae, domoic acid can cause amnesic shellfish poisoning (ASP) in humans who consume contaminated shellfish. Symptoms of ASP include nausea, vomiting, diarrhea, abdominal cramps, headache, and memory loss.
3. Okadaic acid: Produced by certain types of algae, okadaic acid can cause diarrhetic shellfish poisoning (DSP) in humans who consume contaminated shellfish. Symptoms of DSP include nausea, vomiting, diarrhea, abdominal cramps, and fever.
4. Ciguatoxin: Produced by certain types of dinoflagellates, ciguatoxin can cause ciguatera fish poisoning (CFP) in humans who consume contaminated fish. Symptoms of CFP include nausea, vomiting, diarrhea, abdominal pain, and neurological symptoms such as tingling and numbness of the lips, tongue, and fingers, as well as reversal of hot and cold sensations.
5. Tetrodotoxin: Found in certain types of pufferfish, tetrodotoxin can cause a severe form of food poisoning known as pufferfish poisoning or fugu poisoning. Symptoms of tetrodotoxin poisoning include numbness of the lips and tongue, difficulty speaking, muscle weakness, paralysis, and respiratory failure.
Prevention measures for these types of seafood poisoning include avoiding consumption of fish and shellfish that are known to be associated with these toxins, as well as cooking and preparing seafood properly before eating it. Additionally, monitoring programs have been established in many countries to monitor the levels of these toxins in seafood and issue warnings when necessary.
Dinoflagellida is a large group of mostly marine planktonic protists, many of which are bioluminescent. Some dinoflagellates are responsible for harmful algal blooms (HABs), also known as "red tides," which can produce toxins that affect marine life and human health.
Dinoflagellates are characterized by two flagella, or whip-like structures, that they use for movement. They have complex cell structures, including a unique structure called the nucleomorph, which is the remnant of a former endosymbiotic event where another eukaryotic cell was engulfed and became part of the dinoflagellate's cell.
Dinoflagellates are important contributors to the marine food chain, serving as both primary producers and consumers. Some species form symbiotic relationships with other marine organisms, such as corals, providing them with nutrients in exchange for protection and other benefits.
In the context of medicine and biology, symbiosis is a type of close and long-term biological interaction between two different biological organisms. Generally, one organism, called the symbiont, lives inside or on another organism, called the host. This interaction can be mutually beneficial (mutualistic), harmful to the host organism (parasitic), or have no effect on either organism (commensal).
Examples of mutualistic symbiotic relationships in humans include the bacteria that live in our gut and help us digest food, as well as the algae that live inside corals and provide them with nutrients. Parasitic symbioses, on the other hand, involve organisms like viruses or parasitic worms that live inside a host and cause harm to it.
It's worth noting that while the term "symbiosis" is often used in popular culture to refer to any close relationship between two organisms, in scientific contexts it has a more specific meaning related to long-term biological interactions.
Neurotoxins are substances that are poisonous or destructive to nerve cells (neurons) and the nervous system. They can cause damage by destroying neurons, disrupting communication between neurons, or interfering with the normal functioning of the nervous system. Neurotoxins can be produced naturally by certain organisms, such as bacteria, plants, and animals, or they can be synthetic compounds created in a laboratory. Examples of neurotoxins include botulinum toxin (found in botulism), tetrodotoxin (found in pufferfish), and heavy metals like lead and mercury. Neurotoxic effects can range from mild symptoms such as headaches, muscle weakness, and tremors, to more severe symptoms such as paralysis, seizures, and cognitive impairment. Long-term exposure to neurotoxins can lead to chronic neurological conditions and other health problems.
I'm sorry for any confusion, but the term "Indian Ocean" is not a medical concept or condition. It is a geographical term referring to the third largest of the world's five oceans, situated between southeastern Africa, the Southern Asian landmass, and Australia. It is bounded on the north by the Indian subcontinent and Southeast Asia, on the west by eastern Africa, on the east by the Malay Peninsula, Indonesia, and Australia, and on the south by the Southern Ocean or Antarctica.
If you have any medical questions or terms you would like defined, I'd be happy to help!
Scorpion venoms are complex mixtures of neurotoxins, enzymes, and other bioactive molecules that are produced by the venom glands of scorpions. These venoms are primarily used for prey immobilization and defense. The neurotoxins found in scorpion venoms can cause a variety of symptoms in humans, including pain, swelling, numbness, and in severe cases, respiratory failure and death.
Scorpion venoms are being studied for their potential medical applications, such as in the development of new pain medications and insecticides. Additionally, some components of scorpion venom have been found to have antimicrobial properties and may be useful in the development of new antibiotics.
Acid Sensing Ion Channel (ASIC) Blockers are a class of pharmaceutical compounds that inhibit the function of ASICs. These channels are activated by decreases in pH, such as those that occur during ischemia and inflammation, and contribute to pain signaling, neuronal excitability, and cell death. By blocking ASICs, these compounds may have potential therapeutic use in the treatment of conditions associated with acid-induced tissue damage, including ischemic stroke, neuropathic pain, and inflammatory diseases. Examples of ASIC blockers include amiloride, ranolazine, and psalmotrin A.