Complexes: Difference between revisions
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{{ | {{DISPLAYTITLE:Complexes (Biochemistry)}} | ||
{{Infobox medical condition | |||
{{ | | name = Complexes | ||
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| field = [[Biochemistry]] | |||
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'''Complexes''' in biochemistry refer to the assemblies of multiple molecules that interact through non-covalent bonds to form a functional unit. These complexes are crucial in various biological processes, including [[metabolism]], [[signal transduction]], and [[cellular respiration]]. | |||
==Structure and Formation== | |||
Complexes are typically formed through the interaction of [[proteins]], [[nucleic acids]], [[lipids]], and other biomolecules. The formation of complexes is driven by various forces, including [[hydrogen bonding]], [[van der Waals forces]], [[electrostatic interactions]], and [[hydrophobic interactions]]. | |||
===Protein Complexes=== | |||
Protein complexes are assemblies of two or more [[protein]] molecules. They can be homomeric, consisting of identical subunits, or heteromeric, consisting of different subunits. Examples include the [[hemoglobin]] complex, which is a tetramer composed of two alpha and two beta subunits, and the [[ribosome]], a large complex of [[ribosomal RNA]] and proteins. | |||
===Nucleic Acid Complexes=== | |||
Nucleic acid complexes involve interactions between [[DNA]], [[RNA]], and proteins. The [[nucleosome]] is a fundamental unit of [[chromatin]], consisting of DNA wrapped around a core of histone proteins. [[Transcription factors]] form complexes with DNA to regulate gene expression. | |||
===Lipid Complexes=== | |||
Lipid complexes are involved in the formation of [[cell membranes]] and [[lipoproteins]]. [[Lipoproteins]] are complexes of lipids and proteins that transport lipids through the bloodstream. Examples include [[high-density lipoprotein]] (HDL) and [[low-density lipoprotein]] (LDL). | |||
==Functions== | |||
Complexes play a variety of roles in biological systems: | |||
===Enzymatic Activity=== | |||
Many enzymes function as complexes, where multiple subunits come together to form an active site. The [[pyruvate dehydrogenase complex]] is an example, catalyzing the conversion of pyruvate to acetyl-CoA in [[cellular respiration]]. | |||
===Signal Transduction=== | |||
Complexes are involved in [[signal transduction]] pathways, where they facilitate the transmission of signals from the cell surface to the interior. The [[G-protein coupled receptor]] (GPCR) complex is a key player in this process. | |||
===Structural Support=== | |||
Complexes provide structural support to cells and tissues. The [[cytoskeleton]] is composed of complexes of proteins such as [[actin]] and [[tubulin]], which maintain cell shape and enable movement. | |||
==Clinical Significance== | |||
Dysfunction in the formation or regulation of complexes can lead to various diseases. For example, defects in the [[mitochondrial respiratory chain complexes]] can result in [[mitochondrial diseases]]. Abnormal protein complexes are implicated in [[neurodegenerative diseases]] such as [[Alzheimer's disease]], where misfolded proteins form toxic aggregates. | |||
==Research and Applications== | |||
Understanding complexes is crucial for drug development and therapeutic interventions. Targeting specific complexes can modulate their activity, offering potential treatments for diseases. For instance, inhibitors of the [[proteasome complex]] are used in the treatment of [[multiple myeloma]]. | |||
==See Also== | |||
* [[Protein-protein interaction]] | |||
* [[Molecular biology]] | |||
* [[Biochemistry]] | |||
{{Medical resources}} | |||
[[Category:Biochemistry]] | |||
[[Category:Molecular biology]] | |||
[[Category:Protein complexes]] | |||
Latest revision as of 17:03, 1 January 2025
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Complexes in biochemistry refer to the assemblies of multiple molecules that interact through non-covalent bonds to form a functional unit. These complexes are crucial in various biological processes, including metabolism, signal transduction, and cellular respiration.
Structure and Formation[edit]
Complexes are typically formed through the interaction of proteins, nucleic acids, lipids, and other biomolecules. The formation of complexes is driven by various forces, including hydrogen bonding, van der Waals forces, electrostatic interactions, and hydrophobic interactions.
Protein Complexes[edit]
Protein complexes are assemblies of two or more protein molecules. They can be homomeric, consisting of identical subunits, or heteromeric, consisting of different subunits. Examples include the hemoglobin complex, which is a tetramer composed of two alpha and two beta subunits, and the ribosome, a large complex of ribosomal RNA and proteins.
Nucleic Acid Complexes[edit]
Nucleic acid complexes involve interactions between DNA, RNA, and proteins. The nucleosome is a fundamental unit of chromatin, consisting of DNA wrapped around a core of histone proteins. Transcription factors form complexes with DNA to regulate gene expression.
Lipid Complexes[edit]
Lipid complexes are involved in the formation of cell membranes and lipoproteins. Lipoproteins are complexes of lipids and proteins that transport lipids through the bloodstream. Examples include high-density lipoprotein (HDL) and low-density lipoprotein (LDL).
Functions[edit]
Complexes play a variety of roles in biological systems:
Enzymatic Activity[edit]
Many enzymes function as complexes, where multiple subunits come together to form an active site. The pyruvate dehydrogenase complex is an example, catalyzing the conversion of pyruvate to acetyl-CoA in cellular respiration.
Signal Transduction[edit]
Complexes are involved in signal transduction pathways, where they facilitate the transmission of signals from the cell surface to the interior. The G-protein coupled receptor (GPCR) complex is a key player in this process.
Structural Support[edit]
Complexes provide structural support to cells and tissues. The cytoskeleton is composed of complexes of proteins such as actin and tubulin, which maintain cell shape and enable movement.
Clinical Significance[edit]
Dysfunction in the formation or regulation of complexes can lead to various diseases. For example, defects in the mitochondrial respiratory chain complexes can result in mitochondrial diseases. Abnormal protein complexes are implicated in neurodegenerative diseases such as Alzheimer's disease, where misfolded proteins form toxic aggregates.
Research and Applications[edit]
Understanding complexes is crucial for drug development and therapeutic interventions. Targeting specific complexes can modulate their activity, offering potential treatments for diseases. For instance, inhibitors of the proteasome complex are used in the treatment of multiple myeloma.
