“Inner mitochondrial membrane”的意思、由来-开放百科全书

The inner mitochondrial membrane (IMM) is the mitochondrial membrane which separates the mitochondrial matrix from the intermembrane space.

Structure

The structure of the inner mitochondrial membrane is extensively folded and compartmentalized. The numerous invaginations of the membrane are called cristae, separated by crista junctions from the inner boundary membrane juxtaposed to the outer membrane. Cristae significantly increases the total membrane surface area compared to a smooth inner membrane and thereby the available working space.

The inner membrane creates two compartments. The region between the inner and outer membrane, called the intermembrane space which is largely continuous with the cytosol, and the more sequestered space inside the inner membrane, called matrix.

Cristae

For typical liver mitochondria, the area of the inner membrane is about 5 times as large as the outer membrane due to cristae. This ratio is variable and mitochondria from cells that have a greater demand for ATP, such as muscle cells, contain even more cristae. Cristae membranes are studded on the matrix side with small round protein complexes known as F₁ particles, the site of proton-gradient driven ATP synthesis. Cristae affect overall chemiosmotic function of mitochondria.^[1]

Cristae junctions

Cristae and the inner boundary membranes are separated by junctions. The end of cristae are partially closed by transmembrane protein complexes that bind head to head and link opposing crista membranes in a bottleneck-like fashion.^[2] For example, deletion of the junction protein MIC60/Mic60 (formerly Mitofilin/Fcj1) leads to a reduced inner membrane potential and impaired growth^[3] and to dramatically aberrant inner membrane structures which form concentric stacks instead of the typical invaginations.^[4]

Composition

The inner membrane of mitochondria is similar in lipid composition to the membrane of bacteria. This phenomenon can be explained by the endosymbiont hypothesis of the origin of mitochondria as prokaryotes internalized by a eukaryotic host cell.

In pig heart mitochondria, phosphatidylethanolamine makes up the majority of the inner mitochondrial membrane at 37.0% of the phospholipid composition. Phosphatidylcholine makes up about 26.5%, cardiolipin 25.4%, and phosphatidylinositol 4.5%.^[5] In S. cerevisiae mitochondria, phosphatidylcholine makes up 38.4% of the IMM, phosphatidylethanolamine makes up 24.0%, phosphatidylinositol 16.2%, cardiolipin 16.1%, phosphatidylserine 3.8%, and phosphatidic acid 1.5%.^[6]

In the inner mitochondrial membrane, the protein-to-lipid ratio is 80:20, in contrast to the outer membrane, which is 50:50.^[7]

Permeability

The inner membrane is freely permeable to oxygen, carbon dioxide, and water only.^[8] It is much less permeable to ions and small molecules than the outer membrane, creating compartments by separating the matrix from the cytosolic environment. This compartmentalization is a necessary feature for metabolism. The inner mitochondrial membrane is both an electrical insulator and chemical barrier. Sophisticated ion transporters exist to allow specific molecules to cross this barrier. There are several antiport systems embedded in the inner membrane, allowing exchange of anions between the cytosol and the mitochondrial matrix.^[7]

IMM-associated proteins

See also

References

1. ^{{cite journal |author=Mannella CA |title= Structure and dynamics of the mitochondrial inner membrane cristae |volume=1763 |issue=5–6|year=2006 |pages=542–548 |doi=10.1016/j.bbamcr.2006.04.006 |pmid=16730811 |journal=Biochimica et Biophysica Acta }}
2. ^{{cite journal|last1=Herrmann|first1=JM|title=MINOS is plus: a Mitofilin complex for mitochondrial membrane contacts.|journal=Developmental Cell|date=18 October 2011|volume=21|issue=4|pages=599–600|pmid=22014515|doi=10.1016/j.devcel.2011.09.013}}
3. ^{{cite journal|last1=von der Malsburg|first1=K|last2=Müller|first2=JM|last3=Bohnert|first3=M|last4=Oeljeklaus|first4=S|last5=Kwiatkowska|first5=P|last6=Becker|first6=T|last7=Loniewska-Lwowska|first7=A|last8=Wiese|first8=S|last9=Rao|first9=S|last10=Milenkovic|first10=D|last11=Hutu|first11=DP|last12=Zerbes|first12=RM|last13=Schulze-Specking|first13=A|last14=Meyer|first14=HE|last15=Martinou|first15=JC|last16=Rospert|first16=S|last17=Rehling|first17=P|last18=Meisinger|first18=C|last19=Veenhuis|first19=M|last20=Warscheid|first20=B|last21=van der Klei|first21=IJ|last22=Pfanner|first22=N|last23=Chacinska|first23=A|last24=van der Laan|first24=M|title=Dual role of mitofilin in mitochondrial membrane organization and protein biogenesis.|journal=Developmental Cell|date=18 October 2011|volume=21|issue=4|pages=694–707|pmid=21944719|doi=10.1016/j.devcel.2011.08.026}}
4. ^{{cite journal|last1=Rabl|first1=R|last2=Soubannier|first2=V|last3=Scholz|first3=R|last4=Vogel|first4=F|last5=Mendl|first5=N|last6=Vasiljev-Neumeyer|first6=A|last7=Körner|first7=C|last8=Jagasia|first8=R|last9=Keil|first9=T|last10=Baumeister|first10=W|last11=Cyrklaff|first11=M|last12=Neupert|first12=W|last13=Reichert|first13=AS|title=Formation of cristae and crista junctions in mitochondria depends on antagonism between Fcj1 and Su e/g.|journal=The Journal of Cell Biology|date=15 June 2009|volume=185|issue=6|pages=1047–63|pmid=19528297|doi=10.1083/jcb.200811099|pmc=2711607}}
5. ^{{cite journal |vauthors=Comte J, Maïsterrena B, Gautheron DC |title=Lipid composition and protein profiles of outer and inner membranes from pig heart mitochondria. Comparison with microsomes |journal=Biochim. Biophys. Acta |volume=419 |issue=2 |pages=271–84 |date=January 1976 |pmid=1247555 |doi= 10.1016/0005-2736(76)90353-9|url=http://linkinghub.elsevier.com/retrieve/pii/0005-2736(76)90353-9 |accessdate=2014-04-09}}
6. ^{{cite web|url=http://opm.phar.umich.edu/atlas.php?membrane=Mitochondrial%20inner%20membrane|title=Membrane Protein Lipid Composition Atlas|website=Orientations of Proteins in Membranes|last1=Lomize|first1=Andrel|last2=Lomize|first2=Mikhail|last3=Pogozheva|first3=Irina|year=2013|publisher=University of Michigan|accessdate=10 April 2014}}
7. ^¹{{cite web|title=Mitochondria: Structure and Role in Respiration|url=http://www.med.ufro.cl/clases_apuntes/cs_preclinicas/mg-fisica-medica/sub-modulo-1/Mitochondria.pdf|last=Krauss|first=Stefan|publisher=Nature Publishing Group|year=2001|accessdate=9 April 2014|deadurl=yes|archiveurl=https://web.archive.org/web/20121021071651/http://www.med.ufro.cl/clases_apuntes/cs_preclinicas/mg-fisica-medica/sub-modulo-1/Mitochondria.pdf|archivedate=21 October 2012|df=}}
8. ^{{cite web|url=http://www.ruf.rice.edu/~bioslabs/studies/mitochondria/mitotheory.html| title=Structure of Mitochondria| website=Experimental Biosciences|date=12 December 1996|last=Caprette| first=David R.|publisher=Rice University|accessdate=9 April 2014}}