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ATP and Energy Production01:23

ATP and Energy Production

1.5K
Adenosine triphosphate (ATP) is a critical molecule that functions as the main energy carrier in cells. Structurally, ATP consists of an adenosine molecule—comprising adenine and ribose—bonded to three phosphate groups. The high-energy bonds between these phosphate groups store significant amounts of potential energy. This energy is released during hydrolysis, wherein ATP is converted to adenosine diphosphate (ADP) or adenosine monophosphate (AMP), driving a variety of essential...
1.5K
ATP Synthase: Mechanism01:48

ATP Synthase: Mechanism

16.5K
In animals, the mitochondrial F1F0 ATP synthase is the key protein that synthesizes ATP molecules through a complex catalytic mechanism. While the nuclear genome encodes the majority of ATP synthase subunits, the mitochondrial genome encodes some of the enzyme's most critical components. The formation of this multi-subunit enzyme is a complex multi-step process regulated at the level of transcription, translation, and assembly. Defects in one or more of these steps can result in decreased...
16.5K
ATP Synthase: Structure01:18

ATP Synthase: Structure

14.9K
ATP synthase or ATPase is among the most conserved proteins found in bacteria, mammals, and plants. This enzyme can catalyze a forward reaction in response to the electrochemical gradient, producing ATP from ADP and inorganic phosphate. ATP synthase can also work in a reverse direction by hydrolyzing ATP and generating an electrochemical gradient. Different forms of ATP synthases have evolved special features to meet the specific demands of the cell. Based on their specific feature, ATP...
14.9K
ATP and Macromolecule Synthesis01:28

ATP and Macromolecule Synthesis

6.8K
Biological macromolecules are organic compounds, predominantly composed of carbon atoms. The carbon atoms are covalently bonded with hydrogen, oxygen, nitrogen, and other minor elements. There are four major biological macromolecule classes: carbohydrates, lipids, proteins, and nucleic acids.
Most macromolecules are composed of single subunits, or building blocks, called monomers. The monomers combine with each other using covalent bonds to form larger molecules known as polymers.
Conversion of...
6.8K
Active Transport01:14

Active Transport

1.9K
Active transport is a critical biological process that allows cells to move solutes against an electrochemical gradient. This process requires direct energy input and is characterized by its selectivity, saturability, and susceptibility to competitive inhibition.
Primary active transporters, like Na+, K+ and -ATPase, directly utilize ATP to move ions across the membrane. These transporters play significant roles in various physiological processes. For instance, Na+, K+ and -ATPase maintain...
1.9K
ATP Energy Storage and Release01:31

ATP Energy Storage and Release

13.8K
ATP is a highly unstable molecule. Unless quickly used to perform work, ATP spontaneously dissociates into ADP and inorganic phosphate (Pi), and the free energy released during this process is lost as heat. The energy released by ATP hydrolysis is used to perform work inside the cell and depends on a strategy called energy coupling. Cells couple the exergonic reaction of ATP hydrolysis with endergonic reactions, allowing them to proceed.
One example of energy coupling using ATP involves a...
13.8K

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Video Experimental Relacionado

Updated: Jan 7, 2026

A Time-Efficient Fluorescence Spectroscopy-Based Assay for Evaluating Actin Polymerization Status in Rodent and Human Brain Tissues
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A Time-Efficient Fluorescence Spectroscopy-Based Assay for Evaluating Actin Polymerization Status in Rodent and Human Brain Tissues

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La síntesis de ATP local impulsada por la actividad es necesaria para la función sináptica.

Vidhya Rangaraju1, Nathaniel Calloway2, Timothy A Ryan2

  • 1Rockefeller/Sloan-Kettering/Weill Cornell Tri-Institutional Training Program in Chemical Biology, New York, NY 10065, USA; Department of Biochemistry, Weill Cornell Medical College, New York, NY 10065, USA.

Cell
|February 18, 2014
PubMed
Resumen
Este resumen es generado por máquina.

Las sinapsis cerebrales requieren una energía significativa, suministrada por procesos metabólicos como la glucólisis y la función mitocondrial. Incluso las interrupciones breves de la síntesis de ATP estimulada por la actividad perjudican las funciones sinápticas cruciales.

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Imaging of Intracellular ATP in Organotypic Tissue Slices of the Mouse Brain using the FRET-based Sensor ATeam1.03YEMK
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Imaging of Intracellular ATP in Organotypic Tissue Slices of the Mouse Brain using the FRET-based Sensor ATeam1.03YEMK

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Preparation of Synaptoneurosomes from Mouse Cortex using a Discontinuous Percoll-Sucrose Density Gradient
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Imaging of Intracellular ATP in Organotypic Tissue Slices of the Mouse Brain using the FRET-based Sensor ATeam1.03YEMK
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Área de la Ciencia:

  • La neurociencia es la neurociencia.
  • El metabolismo celular es el metabolismo celular.
  • Fisiología sináptica fisiología sináptica.

Sus antecedentes:

  • La función cognitiva está vinculada al estado metabólico, pero los mecanismos de control precisos en las sinapsis no están claros.
  • Las sinapsis tienen altas demandas de energía, sin embargo, la forma en que la disponibilidad de combustible y la actividad afectan los niveles de ATP y la función sináptica sigue siendo poco conocida.

Objetivo del estudio:

  • Investigar la relación entre la actividad sináptica, los niveles de ATP y la función sináptica.
  • Para identificar las fuentes metabólicas que apoyan las demandas de energía sináptica.
  • Para entender cómo la disponibilidad de ATP controla la función presináptica.

Principales métodos:

  • Desarrollo de un reportero óptico genéticamente codificado para el ATP presináptico (Syn-ATP).
  • Análisis cuantitativo de la dinámica del ATP durante la actividad eléctrica en las sinapsis.
  • Investigación del papel de la glucólisis y la función mitocondrial en la satisfacción de las demandas metabólicas.

Principales resultados:

  • La actividad eléctrica impulsa una demanda metabólica significativa en las sinapsis, apoyada por la glucólisis y la función mitocondrial.
  • El ciclo de las vesículas sinápticas es el principal impulsor de la demanda metabólica dependiente de la actividad.
  • Las sinapsis metabólicamente intactas mantienen un gran depósito de ATP (~10^6 ATP por terminal) durante la actividad.
  • La interrupción de la síntesis de ATP estimulada por la actividad, aunque sea brevemente, afecta gravemente la función presináptica.

Conclusiones:

  • Los niveles de ATP sináptico están estrictamente regulados por la síntesis impulsada por la actividad que involucra la glucólisis y las mitocondrias.
  • El ciclo de las vesículas sinápticas es un gran consumidor de energía en la sinapsis.
  • Un suministro adecuado de ATP es crítico para mantener la función presináptica, a pesar de una gran reserva de ATP basal.