Fatty Acids and Conjugates (FA01)

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== Basics of Fatty Acids  ==
== Basics of Fatty Acids  ==
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[[:Category:Fatty_Acyls_(FA)|Fatty acids]] play an essential role in a diversity of cellular processes, including building [http://en.wikipedia.org/wiki/Membrane membranes], anchoring proteins to membranes, storing energy, as precursors in synthesis of lipid second messengers. They are obtained from the diet or can be synthesised de novo.  
+
[[:Category:Fatty Acyls (FA)|Fatty acids]] play an essential role in a diversity of cellular processes, including building [http://en.wikipedia.org/wiki/Membrane membranes], anchoring proteins to membranes, storing energy, as precursors in synthesis of lipid second messengers. They are obtained from the diet or can be synthesised de novo.  
-
Liver and adipose tissue are central organs involved in [http://en.wikipedia.org/wiki/Homeostasis homeostasis] of [[:Category:Fatty_Acyls_(FA)|fatty acids]] and depending on the delivery of [http://en.wikipedia.org/wiki/Carbon carbon] from the diet, they convert its excess to [[:Category:Fatty Acids|fatty acids]] for storage or distribution through the body. In biological systems [[:Category:Fatty_Acyls_(FA)|fatty acids]] can be synthesised de novo by two distinct [http://en.wikipedia.org/wiki/Fatty_acid_synthase fatty acid synthase] (FAS) pathways. Human cells follow type [[FAS I|FAS I]] synthesis whereas plants, bacteria and other microorganisms involve [[FAS II|FAS II]] pathway.  
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Liver and adipose tissue are central organs involved in [http://en.wikipedia.org/wiki/Homeostasis homeostasis] of [[:Category:Fatty Acyls (FA)|fatty acids]] and depending on the delivery of [http://en.wikipedia.org/wiki/Carbon carbon] from the diet, they convert its excess to [[:Category:Fatty Acids|fatty acids]] for storage or distribution through the body. In biological systems [[:Category:Fatty Acyls (FA)|fatty acids]] can be synthesised de novo by two distinct [http://en.wikipedia.org/wiki/Fatty_acid_synthase fatty acid synthase] (FAS) pathways. Human cells follow type [[FAS I|FAS I]] synthesis whereas plants, bacteria and other microorganisms involve [[FAS II|FAS II]] pathway.  
<br>  
<br>  
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=== Biochemical synthesis  ===
=== Biochemical synthesis  ===
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Ninety percent of all [[:Category:Fatty_Acyls_(FA)|fatty acids]] in mammalian cells are obtained from de novo synthesis and most [[:Category:Fatty_Acyls_(FA)|fatty acids]] of biological importance have a chain length between 14 and 20 C-atoms. In The highest rate of de novo synthesis occurs in liver, where excess glucose is converted to [http://en.wikipedia.org/wiki/Pyruvate pyruvate] and then to [http://en.wikipedia.org/wiki/Citrate citrate], which is used by ATP citrate lyase to produce [http://en.wikipedia.org/wiki/Acetyl_CoA acetyl CoA]. The mammalian FAS consists of a single gene coding for a polypeptide that contains all reaction centers to produce a [[:Category:Fatty_Acyls_(FA)|fatty acids]] (Smith et al. 2003). In lower eukaryota, plants and bacteria there are two genes, which products form a multifunctional complex (White et al. 2005). [[FAS I|FAS I]] is usually considered to be a more efficient biosynthetic machine because the enzymatic activities are fused into a single polypeptide template and the intermediates do not diffuse from the complex. However, in contrast to [[FAS II|FAS II]], which produces diversity of products for cellular metabolism, [[FAS I|FAS I]] produces only palmitate. De novo synthesis is especially active in embryogenesis and fetal lungs, in adults in lactating breasts and endometrium (Swinnen et al. 2006).  
+
Ninety percent of all [[:Category:Fatty Acyls (FA)|fatty acids]] in mammalian cells are obtained from de novo synthesis and most [[:Category:Fatty Acyls (FA)|fatty acids]] of biological importance have a chain length between 14 and 20 C-atoms. In The highest rate of de novo synthesis occurs in liver, where excess glucose is converted to [http://en.wikipedia.org/wiki/Pyruvate pyruvate] and then to [http://en.wikipedia.org/wiki/Citrate citrate], which is used by ATP citrate lyase to produce [http://en.wikipedia.org/wiki/Acetyl_CoA acetyl CoA]. The mammalian FAS consists of a single gene coding for a polypeptide that contains all reaction centers to produce a [[:Category:Fatty Acyls (FA)|fatty acids]] (Smith et al. 2003). In lower eukaryota, plants and bacteria there are two genes, which products form a multifunctional complex (White et al. 2005). [[FAS I|FAS I]] is usually considered to be a more efficient biosynthetic machine because the enzymatic activities are fused into a single polypeptide template and the intermediates do not diffuse from the complex. However, in contrast to [[FAS II|FAS II]], which produces diversity of products for cellular metabolism, [[FAS I|FAS I]] produces only palmitate. De novo synthesis is especially active in embryogenesis and fetal lungs, in adults in lactating breasts and endometrium (Swinnen et al. 2006).  
[http://132.199.157.114:8080/lipidnet/diagramView?_a_=frame&id=figure5&db=lipidnet Open Pathway in full window] <embedurl>http://132.199.157.114:8080/lipidnet/diagramView?_a_=frame&id=figure5&db=lipidnet</embedurl>  
[http://132.199.157.114:8080/lipidnet/diagramView?_a_=frame&id=figure5&db=lipidnet Open Pathway in full window] <embedurl>http://132.199.157.114:8080/lipidnet/diagramView?_a_=frame&id=figure5&db=lipidnet</embedurl>  
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==== Acetyl CoA carboxylase (ACC)  ====
==== Acetyl CoA carboxylase (ACC)  ====
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The multicomplex of acetyl CoA carboxylase (ACC) mediates the [http://en.wikipedia.org/wiki/Carboxylation carboxylation] to malonyl CoA. [http://en.wikipedia.org/wiki/Malonyl-CoA Malonyl CoA] serves dual functions as an intermediate in fatty acid synthesis and as a regulatory effector, which means that malonyl-CoA controls fatty acid oxidation both in liver and muscle by regulating the entry of [[:Category:Fatty_Acyls_(FA)|fatty acids]] into [http://en.wikipedia.org/wiki/Mitochondria mitochondria] (Dowell et al. 2005).  
+
The multicomplex of acetyl CoA carboxylase (ACC) mediates the [http://en.wikipedia.org/wiki/Carboxylation carboxylation] to malonyl CoA. [http://en.wikipedia.org/wiki/Malonyl-CoA Malonyl CoA] serves dual functions as an intermediate in fatty acid synthesis and as a regulatory effector, which means that malonyl-CoA controls fatty acid oxidation both in liver and muscle by regulating the entry of [[:Category:Fatty Acyls (FA)|fatty acids]] into [http://en.wikipedia.org/wiki/Mitochondria mitochondria] (Dowell et al. 2005).  
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There are two isoforms of ACC, ACC1 and ACC2, both of which catalyse formation of malonyl-CoA and exhibit different tissue expression patterns (Munday, 2002; Brownsey et al. 2006). ACC1 is expressed primarily in lipogenic tissues, e.g., liver and adipose, whereas ACC2 is expressed primarily in heart and skeletal muscle. ACC1 carries out the first and key regulatory step in [[:Category:Fatty_Acyls_(FA)|fatty acids]] biosynthesis. Malonyl-CoA formed in this step serves as substrate for FAS, which catalyzes chain reductive elongation, leading to the formation of long-chain (C16 and C18) [[:Category:Fatty_Acyls_(FA)|fatty acids]]. Certain tissues, i.e., skeletal and heart muscle, do not carry out fatty acid synthesis because they lack FAS. However, these tissues express ACC2 and another enzyme, i.e., MCD, which removes malonyl-CoA. The ACC-catalyzed reaction is regulated in several ways, including regulation by allosteric effectors and phosphorylation by the 5AMP-dependent protein kinase.  
+
There are two isoforms of ACC, ACC1 and ACC2, both of which catalyse formation of malonyl-CoA and exhibit different tissue expression patterns (Munday, 2002; Brownsey et al. 2006). ACC1 is expressed primarily in lipogenic tissues, e.g., liver and adipose, whereas ACC2 is expressed primarily in heart and skeletal muscle. ACC1 carries out the first and key regulatory step in [[:Category:Fatty Acyls (FA)|fatty acids]] biosynthesis. Malonyl-CoA formed in this step serves as substrate for FAS, which catalyzes chain reductive elongation, leading to the formation of long-chain (C16 and C18) [[:Category:Fatty Acyls (FA)|fatty acids]]. Certain tissues, i.e., skeletal and heart muscle, do not carry out fatty acid synthesis because they lack FAS. However, these tissues express ACC2 and another enzyme, i.e., MCD, which removes malonyl-CoA. The ACC-catalyzed reaction is regulated in several ways, including regulation by allosteric effectors and phosphorylation by the 5AMP-dependent protein kinase.  
==== Fatty acid synthase (FAS)  ====
==== Fatty acid synthase (FAS)  ====
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[http://en.wikipedia.org/wiki/Malonyl-CoA Malonyl CoA], [http://en.wikipedia.org/wiki/Acetyl-coA acetyl CoA] and [http://en.wikipedia.org/wiki/NADPH NADPH] are substrates for fatty acid synthase (FAS) in the elongation of [[:Category:Fatty_Acyls_(FA)|fatty acids]]. Mammalian FAS is a complexed multifunctional enzyme that consists of two identical monomers and one monomer contains six catalytic activities needed for fatty acid synthesis, however only the dimeric form is functionally active (Chirala et al. 2004).  
+
[http://en.wikipedia.org/wiki/Malonyl-CoA Malonyl CoA], [http://en.wikipedia.org/wiki/Acetyl-coA acetyl CoA] and [http://en.wikipedia.org/wiki/NADPH NADPH] are substrates for fatty acid synthase (FAS) in the elongation of [[:Category:Fatty Acyls (FA)|fatty acids]]. Mammalian FAS is a complexed multifunctional enzyme that consists of two identical monomers and one monomer contains six catalytic activities needed for fatty acid synthesis, however only the dimeric form is functionally active (Chirala et al. 2004).  
FAS catalyses series of progressive reactions of elongation of the acetyl group by C2 units derived from malonyl-CoA tethered to the enzyme by the pantotheine arm. The ß-ketoacyl-synthase-condensing enzyme is responsible for the condensation of the three-carbon malonyl-CoA with the two carbon acetyl-CoA, releasing CO2, and elongating the fatty-acid carbon chain. After the reductase and dehydratase steps, the entire process is repeated seven times to generate palmitate (C16:0), which is cleaved from FAS by its thioesterase activity to release the free fatty acid.  
FAS catalyses series of progressive reactions of elongation of the acetyl group by C2 units derived from malonyl-CoA tethered to the enzyme by the pantotheine arm. The ß-ketoacyl-synthase-condensing enzyme is responsible for the condensation of the three-carbon malonyl-CoA with the two carbon acetyl-CoA, releasing CO2, and elongating the fatty-acid carbon chain. After the reductase and dehydratase steps, the entire process is repeated seven times to generate palmitate (C16:0), which is cleaved from FAS by its thioesterase activity to release the free fatty acid.  
-
The synthesis of [[:Category:Fatty_Acyls_(FA)|fatty acids]] longer than 16 carbons occurs in microsomes and utilizes malonyl CoA as the source of carbon.  
+
The synthesis of [[:Category:Fatty Acyls (FA)|fatty acids]] longer than 16 carbons occurs in microsomes and utilizes malonyl CoA as the source of carbon.  
=== Metabolism  ===
=== Metabolism  ===
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=== Physiology and pathophysiology of n–6 and n–3 fatty acids  ===
=== Physiology and pathophysiology of n–6 and n–3 fatty acids  ===
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Nutritional availability of essential n-3 polyunsaturated [[:Category:Fatty_Acyls_(FA)|fatty acids]] (n-3 PUFAs) is critical for many physiological processes (Jeffrey et al. 2001, Salem et al. 2001, Uauy et al. 2001). PUFAs can serve as intermediates in signal transduction (Brash et al. 2001), as a source of [[:Category:Eicosanoids|eicosanoids]] or [[Docosanoids|docosanoids]] (Fitzpatrick et al. 2001, Zhou et al. 2001), as proinflammatory factors (Toborek et al. 2002) and as neuroprotective agents (Lauritzen et al. 2000).  
+
Nutritional availability of essential n-3 polyunsaturated [[:Category:Fatty Acyls (FA)|fatty acids]] (n-3 PUFAs) is critical for many physiological processes (Jeffrey et al. 2001, Salem et al. 2001, Uauy et al. 2001). PUFAs can serve as intermediates in signal transduction (Brash et al. 2001), as a source of [[:Category:Eicosanoids_(FA03)|eicosanoids]] or [[Docosanoids_(FA04)|docosanoids]] (Fitzpatrick et al. 2001, Zhou et al. 2001), as proinflammatory factors (Toborek et al. 2002) and as neuroprotective agents (Lauritzen et al. 2000).  
They also modulate immune and inflammatory responses (Kelley et al. 2001), and influence human cardiovascular (Dewailly et al. 2001) and brain diseases (Martinez et al. 2001). Western diets are rich in n-6 PUFAs, and an increasing consumption of n-3 PUFAs may counteract some of the effects produced by n-6 PUFAs.  
They also modulate immune and inflammatory responses (Kelley et al. 2001), and influence human cardiovascular (Dewailly et al. 2001) and brain diseases (Martinez et al. 2001). Western diets are rich in n-6 PUFAs, and an increasing consumption of n-3 PUFAs may counteract some of the effects produced by n-6 PUFAs.  
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The action of n–6 and n–3 [[:Category:Fatty_Acyls_(FA)|fatty acids]] on metabolic and physiologic pathways may involve 3 general mechanisms: <br>  
+
The action of n–6 and n–3 [[:Category:Fatty Acyls (FA)|fatty acids]] on metabolic and physiologic pathways may involve 3 general mechanisms: <br>  
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*membrane phospholipid [[:Category:Fatty_Acyls_(FA)|fatty acids]] influence the properties of the microenvironment of membrane bilayers and this in turn can affect the activity of membrane-associated proteins, receptors, transport systems, and ion channels;  
+
*membrane phospholipid [[:Category:Fatty Acyls (FA)|fatty acids]] influence the properties of the microenvironment of membrane bilayers and this in turn can affect the activity of membrane-associated proteins, receptors, transport systems, and ion channels;  
-
*membrane phospholipids and their n–6 and n–3 [[:Category:Fatty_Acyls_(FA)|fatty acids]] function as signal molecules and as precursors for [[:Category:Eicosanoids|eicosanoids]];  
+
*membrane phospholipids and their n–6 and n–3 [[:Category:Fatty Acyls (FA)|fatty acids]] function as signal molecules and as precursors for [[:Category:Eicosanoids_(FA03)|eicosanoids]];  
-
*the n–6 and n–3 [[:Category:Fatty_Acyls_(FA)|fatty acids]] have rapid and direct effects on gene expression through peroxisome proliferator activated receptor (PPAR)-dependent and PPAR-independent mechanisms.
+
*the n–6 and n–3 [[:Category:Fatty Acyls (FA)|fatty acids]] have rapid and direct effects on gene expression through peroxisome proliferator activated receptor (PPAR)-dependent and PPAR-independent mechanisms.
[http://en.wikipedia.org/wiki/Arachidonic_acid Arachidonic acid] ([http://en.wikipedia.org/wiki/Arachidonic_acid ARA], 20:4n–6) and [http://en.wikipedia.org/wiki/Docosahexaenoic_acid docosahexaenoic acid] ( [http://en.wikipedia.org/wiki/Docosahexaenoic_acid DHA], 22:6n–3) are formed from linoleic acid (LA, 18:2n–6) and Δ-linolenic acid, (LNA, 18:3n–3), respectively, in the liver by a series of alternating desaturation (addition of a double bond) and elongation (addition of a 2-carbon unit) reactions (Ferdinandusse et al. 2001, Sprecher et al. 1999). Although LA and LNA are formed in plants, they cannot be formed in mammalian cells because of the absence of the Δ12 and 15 enzymes necessary to insert a double bond at the n (or ω) 6 or 3 position of a fatty acid carbon chain. LA and LNA are, therefore, considered essential dietary nutrients.  
[http://en.wikipedia.org/wiki/Arachidonic_acid Arachidonic acid] ([http://en.wikipedia.org/wiki/Arachidonic_acid ARA], 20:4n–6) and [http://en.wikipedia.org/wiki/Docosahexaenoic_acid docosahexaenoic acid] ( [http://en.wikipedia.org/wiki/Docosahexaenoic_acid DHA], 22:6n–3) are formed from linoleic acid (LA, 18:2n–6) and Δ-linolenic acid, (LNA, 18:3n–3), respectively, in the liver by a series of alternating desaturation (addition of a double bond) and elongation (addition of a 2-carbon unit) reactions (Ferdinandusse et al. 2001, Sprecher et al. 1999). Although LA and LNA are formed in plants, they cannot be formed in mammalian cells because of the absence of the Δ12 and 15 enzymes necessary to insert a double bond at the n (or ω) 6 or 3 position of a fatty acid carbon chain. LA and LNA are, therefore, considered essential dietary nutrients.  
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However, it is now known that the pathway involves synthesis of 24:5n–3 and 24:4n–6 by elongation of the 22 carbon chain products of5 desaturase (Ferdinandusse et al. 2001, Sprecher et al. 1999) The 24:5n–3 and 24:4n–6 are desaturated at position 6 to yield 24:6n–3 and 24:6n–3, which are translocated to the peroxisomes where partial oxidation generates [http://en.wikipedia.org/wiki/Docosahexaenoic_acid DHA] (22:6n–3) and [http://en.wikipedia.org/wiki/Docosapentaenoic_acid DPA] (22:5n–6) (Ferdinandusse et al. 2001).  
However, it is now known that the pathway involves synthesis of 24:5n–3 and 24:4n–6 by elongation of the 22 carbon chain products of5 desaturase (Ferdinandusse et al. 2001, Sprecher et al. 1999) The 24:5n–3 and 24:4n–6 are desaturated at position 6 to yield 24:6n–3 and 24:6n–3, which are translocated to the peroxisomes where partial oxidation generates [http://en.wikipedia.org/wiki/Docosahexaenoic_acid DHA] (22:6n–3) and [http://en.wikipedia.org/wiki/Docosapentaenoic_acid DPA] (22:5n–6) (Ferdinandusse et al. 2001).  
-
Endogenous synthesis of [http://en.wikipedia.org/wiki/Docosahexaenoic_acid DHA] and [http://en.wikipedia.org/wiki/Arachidonic_acid ARA] is believed to use the same Δ6 and Δ5 desaturase enzymes. This can result in competition between LA and LNA as well as inhibition of the enzyme pathway by products of the same and the opposing series of [[:Category:Fatty_Acyls_(FA)|fatty acids]]. For example, high dietary intakes of [http://en.wikipedia.org/wiki/Eicosapentaenoic_acid EPA] or [http://en.wikipedia.org/wiki/Docosahexaenoic_acid DHA] result in decreased tissue [http://en.wikipedia.org/wiki/Arachidonic_acid ARA] and decreased formation of [http://en.wikipedia.org/wiki/Arachidonic_acid ARA] derived [[:Category:Eicosanoids|eicosanoids]] in favor of n–3 fatty acid derived [[:Category:Eicosanoids|eicosanoids]] (Broughton et al. 2002, Fischer et al. 1989).  
+
Endogenous synthesis of [http://en.wikipedia.org/wiki/Docosahexaenoic_acid DHA] and [http://en.wikipedia.org/wiki/Arachidonic_acid ARA] is believed to use the same Δ6 and Δ5 desaturase enzymes. This can result in competition between LA and LNA as well as inhibition of the enzyme pathway by products of the same and the opposing series of [[:Category:Fatty Acyls (FA)|fatty acids]]. For example, high dietary intakes of [http://en.wikipedia.org/wiki/Eicosapentaenoic_acid EPA] or [http://en.wikipedia.org/wiki/Docosahexaenoic_acid DHA] result in decreased tissue [http://en.wikipedia.org/wiki/Arachidonic_acid ARA] and decreased formation of [http://en.wikipedia.org/wiki/Arachidonic_acid ARA] derived [[:Category:Eicosanoids|eicosanoids]] in favor of n–3 fatty acid derived [[:Category:Eicosanoids|eicosanoids]] (Broughton et al. 2002, Fischer et al. 1989).  
=== [[FATP|FATP]]  ===
=== [[FATP|FATP]]  ===

Revision as of 13:29, 16 September 2008

Contents

LIPID MAPS Subclasses

Basics of Fatty Acids

Fatty acids play an essential role in a diversity of cellular processes, including building membranes, anchoring proteins to membranes, storing energy, as precursors in synthesis of lipid second messengers. They are obtained from the diet or can be synthesised de novo.

Liver and adipose tissue are central organs involved in homeostasis of fatty acids and depending on the delivery of carbon from the diet, they convert its excess to fatty acids for storage or distribution through the body. In biological systems fatty acids can be synthesised de novo by two distinct fatty acid synthase (FAS) pathways. Human cells follow type FAS I synthesis whereas plants, bacteria and other microorganisms involve FAS II pathway.


Structures

Examples

butyric acid - straight chain 4 carbon atoms no double bond
butyric acid - straight chain 4 carbon atoms no double bond
Palmitic acid - straight chain 16 carbon atoms no double bond
Palmitic acid - straight chain 16 carbon atoms no double bond
oleic acid - straight chain 18 carbon atoms 1 double bond
oleic acid - straight chain 18 carbon atoms 1 double bond
stearic acid - straight chain 18 carbon atoms no double bond
stearic acid - straight chain 18 carbon atoms no double bond
arachidonic acid - straight chain 20 carbon atoms 4 double bonds
arachidonic acid - straight chain 20 carbon atoms 4 double bonds

More structures can be found on LIPID MAPS classes including subclasses


Natural sources

Lipid Library


Nomenclature

Examples from the LIPID MAPS library:

Biophysical properties

Biochemical pathways

Biochemical synthesis

Ninety percent of all fatty acids in mammalian cells are obtained from de novo synthesis and most fatty acids of biological importance have a chain length between 14 and 20 C-atoms. In The highest rate of de novo synthesis occurs in liver, where excess glucose is converted to pyruvate and then to citrate, which is used by ATP citrate lyase to produce acetyl CoA. The mammalian FAS consists of a single gene coding for a polypeptide that contains all reaction centers to produce a fatty acids (Smith et al. 2003). In lower eukaryota, plants and bacteria there are two genes, which products form a multifunctional complex (White et al. 2005). FAS I is usually considered to be a more efficient biosynthetic machine because the enzymatic activities are fused into a single polypeptide template and the intermediates do not diffuse from the complex. However, in contrast to FAS II, which produces diversity of products for cellular metabolism, FAS I produces only palmitate. De novo synthesis is especially active in embryogenesis and fetal lungs, in adults in lactating breasts and endometrium (Swinnen et al. 2006).

Open Pathway in full window




The first step in the synthesis involves acetyl CoA from mitochondria, which is transported from mitochondria to the cytosol via the citrate/pyruvate shuttle (See Pathway: Fatty Acid Metabolism).

Acetyl CoA carboxylase (ACC)

The multicomplex of acetyl CoA carboxylase (ACC) mediates the carboxylation to malonyl CoA. Malonyl CoA serves dual functions as an intermediate in fatty acid synthesis and as a regulatory effector, which means that malonyl-CoA controls fatty acid oxidation both in liver and muscle by regulating the entry of fatty acids into mitochondria (Dowell et al. 2005).

There are two isoforms of ACC, ACC1 and ACC2, both of which catalyse formation of malonyl-CoA and exhibit different tissue expression patterns (Munday, 2002; Brownsey et al. 2006). ACC1 is expressed primarily in lipogenic tissues, e.g., liver and adipose, whereas ACC2 is expressed primarily in heart and skeletal muscle. ACC1 carries out the first and key regulatory step in fatty acids biosynthesis. Malonyl-CoA formed in this step serves as substrate for FAS, which catalyzes chain reductive elongation, leading to the formation of long-chain (C16 and C18) fatty acids. Certain tissues, i.e., skeletal and heart muscle, do not carry out fatty acid synthesis because they lack FAS. However, these tissues express ACC2 and another enzyme, i.e., MCD, which removes malonyl-CoA. The ACC-catalyzed reaction is regulated in several ways, including regulation by allosteric effectors and phosphorylation by the 5AMP-dependent protein kinase.

Fatty acid synthase (FAS)

Malonyl CoA, acetyl CoA and NADPH are substrates for fatty acid synthase (FAS) in the elongation of fatty acids. Mammalian FAS is a complexed multifunctional enzyme that consists of two identical monomers and one monomer contains six catalytic activities needed for fatty acid synthesis, however only the dimeric form is functionally active (Chirala et al. 2004).

FAS catalyses series of progressive reactions of elongation of the acetyl group by C2 units derived from malonyl-CoA tethered to the enzyme by the pantotheine arm. The ß-ketoacyl-synthase-condensing enzyme is responsible for the condensation of the three-carbon malonyl-CoA with the two carbon acetyl-CoA, releasing CO2, and elongating the fatty-acid carbon chain. After the reductase and dehydratase steps, the entire process is repeated seven times to generate palmitate (C16:0), which is cleaved from FAS by its thioesterase activity to release the free fatty acid.

The synthesis of fatty acids longer than 16 carbons occurs in microsomes and utilizes malonyl CoA as the source of carbon.

Metabolism

Fatty acid elongation and desaturation

Open Pathway in full Window



Fatty acid oxidative conversion

Degradation of FA (b-oxidation)

Enzymes/gene lists of whole Fatty Acid Metabolism

Open Genelist in full Window

Biological processes associated

Physiology and pathophysiology of n–6 and n–3 fatty acids

Nutritional availability of essential n-3 polyunsaturated fatty acids (n-3 PUFAs) is critical for many physiological processes (Jeffrey et al. 2001, Salem et al. 2001, Uauy et al. 2001). PUFAs can serve as intermediates in signal transduction (Brash et al. 2001), as a source of eicosanoids or docosanoids (Fitzpatrick et al. 2001, Zhou et al. 2001), as proinflammatory factors (Toborek et al. 2002) and as neuroprotective agents (Lauritzen et al. 2000).

They also modulate immune and inflammatory responses (Kelley et al. 2001), and influence human cardiovascular (Dewailly et al. 2001) and brain diseases (Martinez et al. 2001). Western diets are rich in n-6 PUFAs, and an increasing consumption of n-3 PUFAs may counteract some of the effects produced by n-6 PUFAs.

The action of n–6 and n–3 fatty acids on metabolic and physiologic pathways may involve 3 general mechanisms:

  • membrane phospholipid fatty acids influence the properties of the microenvironment of membrane bilayers and this in turn can affect the activity of membrane-associated proteins, receptors, transport systems, and ion channels;
  • membrane phospholipids and their n–6 and n–3 fatty acids function as signal molecules and as precursors for eicosanoids;
  • the n–6 and n–3 fatty acids have rapid and direct effects on gene expression through peroxisome proliferator activated receptor (PPAR)-dependent and PPAR-independent mechanisms.

Arachidonic acid (ARA, 20:4n–6) and docosahexaenoic acid ( DHA, 22:6n–3) are formed from linoleic acid (LA, 18:2n–6) and Δ-linolenic acid, (LNA, 18:3n–3), respectively, in the liver by a series of alternating desaturation (addition of a double bond) and elongation (addition of a 2-carbon unit) reactions (Ferdinandusse et al. 2001, Sprecher et al. 1999). Although LA and LNA are formed in plants, they cannot be formed in mammalian cells because of the absence of the Δ12 and 15 enzymes necessary to insert a double bond at the n (or ω) 6 or 3 position of a fatty acid carbon chain. LA and LNA are, therefore, considered essential dietary nutrients.

Once obtained from the diet, LA and LNA are further metabolized by Δ6 desaturation, elongation, and Δ5 desaturation to form ARA and eicosapentaenoic acid (EPA, 20:5n–3), respectively. The Δ5 desaturase and subsequent steps in the pathway are found in animal but not in plant cells. Preformed ARA and DHA are present in the diet in meat, fish, and eggs but not in fruits, vegetables, nuts, grains, or their products. For many years, it was assumed that fatty acid desaturation occurred in the endoplasmic reticulum and that the final steps in the synthesis of DHA and the n–6 DPA (22:5n–6) involved a Δ4 desaturation of 22:5n–3 to 22:6n–3 and 22:4n–6 to 22:5n–6.

However, it is now known that the pathway involves synthesis of 24:5n–3 and 24:4n–6 by elongation of the 22 carbon chain products of5 desaturase (Ferdinandusse et al. 2001, Sprecher et al. 1999) The 24:5n–3 and 24:4n–6 are desaturated at position 6 to yield 24:6n–3 and 24:6n–3, which are translocated to the peroxisomes where partial oxidation generates DHA (22:6n–3) and DPA (22:5n–6) (Ferdinandusse et al. 2001).

Endogenous synthesis of DHA and ARA is believed to use the same Δ6 and Δ5 desaturase enzymes. This can result in competition between LA and LNA as well as inhibition of the enzyme pathway by products of the same and the opposing series of fatty acids. For example, high dietary intakes of EPA or DHA result in decreased tissue ARA and decreased formation of ARA derived eicosanoids in favor of n–3 fatty acid derived eicosanoids (Broughton et al. 2002, Fischer et al. 1989).

FATP

Lipases and LCAT

Palmitoylation

PPAR

Technology

Analysis methods

Chemical synthesis

 

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