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Protein Transport into the Inner Mitochondrial Membrane01:34

Protein Transport into the Inner Mitochondrial Membrane

3.7K
Nuclear encoded mitochondrial precursors are imported to the inner membrane in a multistep process involving two separate translocons, TIM22 and TIM23. TIM23 is a cation-selective pore that remains closed by the N terminal segment of the protein. Negative charges on the TIM23 act as a receptor for the incoming precursor, pulling the positively charged matrix-targeting sequence for peptide insertion and translocation.
Transport of mitochondrial precursors across the TIM23 channel is driven by...
3.7K
Structure of Porins01:21

Structure of Porins

3.0K
Mitochondria, chloroplasts, and gram-negative bacteria have transmembrane, beta-barrel proteins called porins to mediate the free diffusion of ions and metabolites across the membrane. Mitochondrial porin precursors contain conserved amino acid sequences called beta signals at their C-terminal. Beta signals have a  motif of PoXGXXHyXHy (Po-Polar, X-Any amino acid, G-Glycine, Hy-LargeHydrophobic), which are crucial for precursor recognition to initiate precursor assembly. Beta-barrel...
3.0K
Porin Insertion in the Outer Mitochondrial Membrane01:12

Porin Insertion in the Outer Mitochondrial Membrane

3.0K
Porins are beta-barrel proteins translocated to the mitochondrial outer membrane through the TOM complex into the intermembrane space. Porin precursors bind TIM chaperones within the intermembrane space and are guided to the Sorting and Assembly Machinery complex or SAM complex on the outer mitochondrial membrane.
Three models describe the assembly of porins by the SAM complex and their insertion into the outer membrane. Model 1 suggests that porins are assembled outside the SAM channel as the...
3.0K
Mitochondrial Protein Sorting01:39

Mitochondrial Protein Sorting

4.3K
Mitochondria are double-membrane organelles of the eukaryotes involved in cellular metabolism, signaling, ATP synthesis, and programmed cell death.  Each of these processes requires specific proteins and enzymes that must be correctly sorted to the right mitochondrial subcompartment for the proper functioning of the organelle.
Most of these mitochondrial proteins are encoded by the nucleus and imported to the mitochondria as unfolded or loosely folded precursors. Mitochondrial precursors...
4.3K
Energy to Drive Translocation01:37

Energy to Drive Translocation

2.1K
Mitochondrial protein import is powered by two distinct energy sources: ATP hydrolysis and electrochemical potential across the inner membrane. Newly synthesized precursors are bound by cytosolic chaperones of the Hsp70 family, which guide them to the import receptors on the mitochondrial surface. Utilizing the energy of ATP hydrolysis, Hsp70 chaperones transfer these precursors to the TOM receptors on the mitochondrial outer membrane.
Generally, polypeptides are unfolded by two distinct...
2.1K
Translocation of Proteins into the Mitochondria01:19

Translocation of Proteins into the Mitochondria

3.1K
Mitochondrial precursors are translocated to the internal subcompartments via independent mechanisms involving distinct protein machineries called translocases.
Sorting of outer membrane proteins:
Mitochondrial outer membrane proteins are of two types: the transmembrane, beta-barrel porins, and the membrane-anchored, alpha-helical proteins. Beta-barrel porin precursors are translocated by the TOM complex and inserted into the outer mitochondrial membrane by the SAM complex. In contrast,...
3.1K

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Related Experiment Video

Updated: Jun 29, 2025

Assessment of Open Probability of the Mitochondrial Permeability Transition Pore in the Setting of Coenzyme Q Excess
07:35

Assessment of Open Probability of the Mitochondrial Permeability Transition Pore in the Setting of Coenzyme Q Excess

Published on: June 1, 2022

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Solute Transport through Mitochondrial Porins In Vitro and In Vivo.

Roland Benz1

  • 1Science Faculty, Constructor University Bremen, Campus-Ring 1, 28759 Bremen, Germany.

Biomolecules
|March 28, 2024
PubMed
Summary
This summary is machine-generated.

Mitochondrial porins, or voltage-dependent anion-selective channels (VDACs), regulate outer mitochondrial membrane permeability. These channels control metabolite transport and play roles in apoptosis and cancer.

Keywords:
VDACapoptosiscancerlipid bilayermitochondrial metabolismmitochondrial porinperipheral kinasespore structurevoltage dependence

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Area of Science:

  • Cell Biology
  • Biochemistry
  • Molecular Biology

Background:

  • Mitochondria evolved from Alphaproteobacteria, possessing a double membrane structure akin to Gram-negative bacteria.
  • The mitochondrial outer membrane, unlike bacterial outer membranes, actively participates in cellular metabolism.
  • Mitochondrial porins (VDACs) are key regulators of outer mitochondrial membrane permeability.

Purpose of the Study:

  • To elucidate the structure and function of mitochondrial porins (VDACs).
  • To investigate the voltage-dependent gating mechanism of VDACs.
  • To explore the role of VDACs in mitochondrial metabolism, apoptosis, and cancer.

Main Methods:

  • Analysis of porin structure, including beta-barrel formation and alpha-helical gating.
  • Electrophysiological studies to determine voltage-dependent properties.
  • Investigating VDAC interactions with peripheral proteins and their impact on mitochondrial function.

Main Results:

  • Mitochondrial porins (VDACs) exhibit voltage-dependent gating, altering permeability at low transmembrane potentials (20-30 mV).
  • The open state favors anionic metabolites, while closed states preferentially transport cations like calcium ions.
  • VDACs contain 19 beta-strands forming a pore, with an N-terminal alpha-helix acting as a voltage-dependent gate.

Conclusions:

  • Mitochondrial porins (VDACs) are strategically positioned to control mitochondrial metabolism.
  • VDACs' unique properties, including voltage-dependence and ion selectivity, are crucial for mitochondrial function.
  • Further research into VDACs' roles in apoptosis and cancer is warranted.