Jove
Visualize
Contáctanos

Videos de Conceptos Relacionados

Predator-Prey Interactions02:39

Predator-Prey Interactions

Predators consume prey for energy. Predators that acquire prey and prey that avoid predation both increase their chances of survival and reproduction (i.e., fitness). Routine predator-prey interactions elicit mutual adaptations that improve predator offenses, such as claws, teeth, and speed, as well as prey defenses, including crypsis, aposematism, and mimicry. Thus, predator-prey interactions resemble an evolutionary arms race.Although predation is commonly associated with carnivory, for...
Epiphytes, Parasites, and Carnivores02:40

Epiphytes, Parasites, and Carnivores

Plants often form mutualistic relationships with soil-dwelling fungi or bacteria to enhance their roots’ nutrient uptake ability. Root-colonizing fungi (e.g., mycorrhizae) increase a plant’s root surface area, which promotes nutrient absorption. While root-colonizing, nitrogen-fixing bacteria (e.g., rhizobia) convert atmospheric nitrogen (N2) into ammonia (NH3), making nitrogen available to plants for various biological functions. For example, nitrogen is essential for the biosynthesis of the...
Pinching-off of Coated Vesicles01:32

Pinching-off of Coated Vesicles

Vesicle budding is orchestrated by distinct cytosolic proteins such as adaptor proteins, coat proteins, and GTPases. To initiate vesicle budding, membrane-bending proteins containing crescent-shaped BAR domains bind to the lipid heads in the bilayer and distort the membrane to form a protein-coated vesicle bud. Adaptors proteins such as AP2 for clathrin-coated vesicles can nucleate on the deformed membrane. Finally, coat proteins such as clathrin or COPI and COPII assemble into a coat forming...

También podría leer

Artículos Relacionados

Artículos vinculados a este trabajo por autores compartidos, revista y gráfico de citas.

Ordenar por
Same author

Collapsible scissored surfaces.

Proceedings of the National Academy of Sciences of the United States of America·2026
Same author

Cell size-dependent mRNA transcription drives proteome remodeling.

Cell reports·2026
Same author

Fast cell wall softening causes Venus flytrap closure.

Science (New York, N.Y.)·2026
Same author

Exceeding nature's biological speed limits.

Science (New York, N.Y.)·2026
Same author

Cell size modulates ferroptosis susceptibility.

eLife·2026
Same author

Reversible superdeformability of hiPSC epithelial cortinoids.

Proceedings of the National Academy of Sciences of the United States of America·2026
Same journal

Incoming US science academy chief vows to 'double down' on research.

Nature·2026
Same journal

Author Correction: Synthesis of enantioenriched atropisomers by biocatalytic deracemization.

Nature·2026
Same journal

Electrodeposited self-assembled molecules for perovskite photovoltaics.

Nature·2026
Same journal

Neutrino's nursery found: the 'Shadow Blaster'.

Nature·2026
Same journal

Dementia risk in middle-aged people linked to a blood protein.

Nature·2026
Same journal

Daily briefing: What's really happening with trust in science.

Nature·2026
Ver todos los artículos relacionados
JoVE
x logofacebook logolinkedin logoyoutube logo
ACERCA DE JoVE
Visión GeneralLiderazgoBlogCentro de Ayuda JoVE
AUTORES
Proceso de PublicaciónConsejo EditorialAlcance y PolíticasRevisión por ParesPreguntas FrecuentesEnviar
BIBLIOTECARIOS
TestimoniosSuscripcionesAccesoRecursosConsejo Asesor de BibliotecasPreguntas Frecuentes
INVESTIGACIÓN
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchivo
EDUCACIÓN
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualCentro de Recursos para ProfesoresSitio de Profesores
Términos y Condiciones de Uso
Política de Privacidad
Políticas

Video Experimental Relacionado

Updated: Jun 23, 2026

Extraction of Venom and Venom Gland Microdissections from Spiders for Proteomic and Transcriptomic Analyses
10:25

Extraction of Venom and Venom Gland Microdissections from Spiders for Proteomic and Transcriptomic Analyses

Published on: November 3, 2014

Cómo se rompe la Venus atrapamoscas.

Yoël Forterre1, Jan M Skotheim, Jacques Dumais

  • 1IUSTI CNRS, Université de Provence, 5 rue Enrico Fermi, 13453 Marseille Cedex 13, France.

Nature
|January 28, 2005
PubMed
Resumen
Este resumen es generado por máquina.

El Venus atrapamoscas para moscas.

Más Videos Relacionados

Low-Cost Automated Flight Intercept Trap for the Temporal Sub-Sampling of Flying Insects Attracted to Artificial Light at Night
06:19

Low-Cost Automated Flight Intercept Trap for the Temporal Sub-Sampling of Flying Insects Attracted to Artificial Light at Night

Published on: December 29, 2021

In Vivo Imaging of Neural Activity in Unanesthetized Drosophila Adult Flies
09:15

In Vivo Imaging of Neural Activity in Unanesthetized Drosophila Adult Flies

Published on: June 20, 2025

Videos de Experimentos Relacionados

Last Updated: Jun 23, 2026

Extraction of Venom and Venom Gland Microdissections from Spiders for Proteomic and Transcriptomic Analyses
10:25

Extraction of Venom and Venom Gland Microdissections from Spiders for Proteomic and Transcriptomic Analyses

Published on: November 3, 2014

Low-Cost Automated Flight Intercept Trap for the Temporal Sub-Sampling of Flying Insects Attracted to Artificial Light at Night
06:19

Low-Cost Automated Flight Intercept Trap for the Temporal Sub-Sampling of Flying Insects Attracted to Artificial Light at Night

Published on: December 29, 2021

In Vivo Imaging of Neural Activity in Unanesthetized Drosophila Adult Flies
09:15

In Vivo Imaging of Neural Activity in Unanesthetized Drosophila Adult Flies

Published on: June 20, 2025

Área de la Ciencia:

  • Biología vegetal Biología vegetal
  • La biomecánica es la biomecánica.
  • La biofísica es la biofísica.

Sus antecedentes:

  • La Venus mosca trampa (Dionaea muscipula) exhibe uno de los movimientos más rápidos en las plantas.
  • El cierre de la trampa se desencadena mediante la estimulación mecánica de los pelos gatillo.
  • Investigaciones anteriores se centraron en la señalización bioquímica y eléctrica durante el cierre de la trampa.

Objetivo del estudio:

  • Para investigar los aspectos mecánicos posteriores a la estimulación del cierre de la trampa para moscas de Venus.
  • Para comprender los mecanismos físicos subyacentes al rápido cierre de la trampa.
  • Complementar los conocimientos existentes sobre la respuesta de la planta a los estímulos.

Principales métodos:

  • Imágenes de video de alta velocidad de alta velocidad.
  • Las técnicas de microscopía no invasivas son técnicas de microscopía no invasivas.
  • El modelado teórico.

Principales resultados:

  • El cierre de la Venus flytrap es impulsado por una inestabilidad de snap-buckling.
  • La planta controla activamente el inicio de esta inestabilidad.
  • Este mecanismo permite movimientos rápidos y a gran escala sin necesidad de músculos.

Conclusiones:

  • El estudio revela una ingeniosa solución mecánica para el movimiento rápido de las plantas.
  • La inestabilidad es clave para el rápido cierre de la Venus Flytrap.
  • Proporciona un marco para entender el movimiento nastic en las plantas.