Lipids do not share any overall characteristic chemical structural similarity, but they can nevertheless be categorized into subclasses according to structural similarities. One system for categorizing major classes of lipids is listed in Box 6-1, emphasizing those that are directly and indirectly of nutritional importance. A comprehensive system oriented toward detailed molecular studies is available at Lipidomics Gateway (www.lipidmaps.org/). The nomenclature of lipids is dominated by trivial names that are either historical or driven by systematics of metabolism. As with all organic compounds, systematic organic chemical naming rules have been established for lipids, but traditional lipid nomenclature persists for good reason. Most traditional lipid naming conventions are convenient when viewed in the context of mammalian lipid metabolism and, to a lesser extent, are logical extensions of the traditional methods used to analyze lipids. Thus study of lipid nomenclature also reveals structural and metabolic relationships among lipids, and familiarity with nomenclature makes the study of lipid metabolism much clearer.

BOX 6-1 A Chemical Classification of Biologically Important Lipids ^∗

I Nonesterified fatty acids

A Saturated fatty acids

B Unsaturated fatty acids

C Trans fatty acids

D Conjugated fatty acids

II Glycerolipids

A Monoacylglycerols, diacylglycerols, triacylglycerols (esters of fatty acids with glycerol)

III Glycerophospholipids

A Common phospholipids (PtdCho, PtdEtn, PtdIns, PtdSer, phosphatidylglycerol)

B Lysophospholipids

C Diphosphatidylglycerols (cardiolipins)

D Ether phospholipids (platelet-activating factors, plasmalogens)

IV Glycoglycerolipids (including sulfates)

D Neutral glycosphingolipids (e.g., cerebrosides)

E Acidic glycosphingolipids (e.g., gangliosides)

VI Isoprenoids (carotenoids, retinoids, prenols)

VII Steroids

A Sterols

B Steroid hormones (sex hormones, corticosteroids)

C Bile acids

VIII Biological waxes (long-chain ester waxes and related compounds)

IX Eicosanoids

A Cyclooxygenase products (prostaglandins, thromboxanes)

B Lipoxygenase products (leukotrienes, lipoxins)

C Cytochrome P450 products

X Other lipids (acyl CoA, acylcarnitine, anandamide, lipopolysaccharides)

^∗The chemical classification of lipids given in this table is necessarily incomplete and arbitrary. It progresses from hydrocarbons to more complex chemical structures. Simple esters and glycerol esters yield, on hydrolysis, alcohol and/or glycerol and fatty acid. The major membrane lipids, glycerophospholipids, yield fatty acid (or alcohol), glycerol, phosphate, and the appropriate base (choline, ethanolamine, etc.). Sphingolipids yield the base sphingosine and a fatty acid on hydrolysis. A comprehensive classification scheme can be found at www.lipidmaps.org/ and in abbreviated form at en.wikipedia.org/wiki/Lipid.

Adapted from Small, D. M., & Zoeller, R. A. (1991). Lipids. In Encyclopedia of human biology (Vol. 4, pp. 725–748). Orlando, FL: Academic Press, Inc.

Fatty Acids

Fatty acyl chains are the basic units of glycerolipids that render these compounds nonpolar. They are referred to as fatty acids in part because many traditional analytical methods first hydrolyze all fatty esters into fatty acids. However, the level of free fatty acids (FFA), which are also called nonesterified fatty acids (NEFA), is very low compared to the amount of fatty acids present in esterifed forms, primarily as glycerolipids. The plasma concentration of FFA is about 0.3 to 0.6 mmol/L with about 99% of these FFA noncovalently bound to albumin. Higher concentrations of plasma FFA may occur locally at sites of high lipolytic activity (e.g., the capillary beds in adipose tissue, muscle, and heart) where FFA are liberated during lipolysis of TAG present in chylomicrons or very-low-density lipoproteins by lipoprotein lipase.

Fatty acids are characterized by their carboxylic acid head group and their hydrocarbon chain tail. Fatty acyl chains in glycerolipids are the result of condensation of the carboxylic acid head group with a hydroxyl (alcohol) group in the glycerol backbone via an ester bond. In mammals, fatty acids or fatty acyl chains may range from 2 carbons (C₂) to as many as 40 carbons (C₄₀) in length but primarily exist as C₁₂ to C₂₂ chains. Fatty acids are sometimes most conveniently classified according to chain length, although these categories are not rigidly defined. We can define short-chain fatty acids as those that have 6 or fewer carbon atoms. The chemistry of short-chain fatty acids is sufficiently dominated by the carboxyl group that they are soluble at least to some extent in water. Medium-chain fatty acids have 8 to 14 carbon atoms, and long-chain fatty acids have more than 14 carbons. Fatty acids are also classified according to their degree of unsaturation, which is the number of double bonds in their hydrocarbon chains.

Saturated Fatty Acids

The term saturated in the context of fatty acids refers specifically to fatty acyl chains that are exclusively made up of sp³ hybridized (tetrahedral geometry) carbon atoms arranged as linear −CH₂− chains as shown in Figure 6-1. Such chains are said to be saturated with hydrogen because the chain has no double (or triple) bonds across which hydrogen may be added.

Fatty acids are synthesized predominantly through the successive addition of two-carbon units to a growing acyl chain by the fatty acid synthase enzyme. Chain-elongation ceases at 16 carbons to create palmitic acid in mammals, although small amounts of fatty acids with 14- (myristic acid) and 18- (stearic acid) carbons are also produced. Additional two-carbon units may be added to these fatty acids by elongation enzyme systems to yield longer saturated fatty acids. Table 6-1 presents the chain lengths, systematic names, trivial names, and melting points of the most abundant saturated fatty acids in mammalian tissues.

TABLE 6-1

Naturally Occurring Straight-Chain Saturated Carboxylic Acids and Their Melting Points

# OF CARBONS	SYSTEMATIC NAME	TRIVIAL NAME	MP (° C)
2	Ethanoic	Acetic	17
3	Propanoic	Propionic	−21
4	n-Butanoic	Butyric	−8
6	n-Hexanoic	Caproic	−3
8	n-Octanoic	Caprylic	17
10	n-Decanoic	Capric	32
12	n-Dodecanoic	Lauric	44
14	n-Tetradecanoic Acid	Myristic	54
16	n-Hexadecanoic Acid	Palmitic	63
18	n-Octadecanoic Acid	Stearic	70
20	n-Eicosanoic Acid	Arachidic	75
22	n-Docosanoic Acid	Behenic	80
24	n-Tetracosanoic Acid	Lignoceric	84

MP, Melting point; n, normal, straight-chain structural isomer.

In mammals, the majority of saturated fatty acids are configured as straight chains, but in rare cases methyl groups extend from the main chain, usually near its terminal methyl. A fatty acid that terminates with two methyl groups (i.e., an isopropyl configuration) at the end of a hydrocarbon chain is referred to as iso. If the chain terminates with a methyl and an ethyl group (i.e., an isobutyl configuration), the fatty acid is said to be anteiso, as shown in Figure 6-2. In humans, branched-chain fatty acids appear in vernix, the protective waxy white substance that coats and protects the fetus during late gestation. They have also been detected as minor components of skin, blood, and hair, as well as in cancer cells. Iso and anteiso C₁₅ and C₁₇ saturated fatty acids are major components of some microorganisms such as gram-positive bacteria.

FIGURE 6-2 Structures of straight-chain versus branched-chain (iso and anteiso) fatty acids.

Unsaturated Fatty Acids

Unsaturated is used to describe fatty acids with at least one double bond, consisting of two adjacent sp² hybridized carbon atoms, with a trigonal, approximately planar geometry. They are unsaturated with respect to hydrogen, because hydrogen can be covalently added across the double bond to yield sp³ carbon atoms. The overwhelming majority of unsaturated sites in mammalian fatty acids are double bonds configured in the cis geometry. When two or more double bonds are present in a molecule, the fatty acid is said to be polyunsaturated. Generally, double bonds in mammalian polyunsaturated fatty acids (PUFAs) are separated by a methylene (−CH₂−) group (“methylene-interrupted”). This structural property of PUFAs confers special chemical properties. One important chemical property is that the double bonds are not conjugated, and thus there is free rotation about the −CH₂− group. As with saturated fatty acids, use of trivial names is very common for unsaturated fatty acids. Table 6-2 is a compilation of the systematic and trivial names for the most common unsaturated fatty acids.

TABLE 6-2

Naturally Occurring Straight-Chain Unsaturated Fatty Acids and Their Melting Points

ABBREVIATED NOTATION	SYSTEMATIC NAME	TRIVIAL NAME	MP (° C)
14:1n−5	cis-9-tetradecenoic	Myristoleic	−4
16:1n−7	cis-9-hexadecenoic	Palmitoleic	0.5
18:1n−7	cis-11-octadecenoic	cis-Vaccenic	15
t-18:1n−7	trans-11-octadecenoic	trans-Vaccenic	44
18:1n−9	cis-9-octadecenoic	Oleic	16
t-18:1n−9	trans-9-octadecenoic	Elaidic	47
20:3n−9	All cis-5,8,11-eicosatrienoic	Mead
22:1n−9	All cis-13-docosenoic	Erucic	35
18:2n−6	All cis-9,12-octadecadienoic	Linoleic (LA)	−5
18:3n−6	All cis-6,9,12-octadecatrienoic	γ-Linolenic (GLA)	−11
20:4n−6	All cis-5,8,11,14-eicosatetraenoic	Arachidonic (AA)	−50
22:5n−6	All cis-4,7,10,13,16-docosapentaenoic	DPA
18:3n−3	All cis-9,12,15-octadecatrienoic	α-Linolenic (ALA)	−10
20:5n−3	All cis-5,8,11,14-eicosapentaenoic	EPA	−54
22:6n−3	All cis-4,7,10,13,16,19-docosahexaenoic	DHA	−44

MP, Melting point.

PUFA biosynthesis is discussed in depth in Chapter 18; however, a brief overview is necessary to rationalize PUFA nomenclature. Consider the pathway for synthesis of docosahexaenoic acid (C₂₂, 6 double bonds) from α-linolenic acid (C₁₈, 3 double bonds). This pathway begins with the insertion of a double bond between carbons 6 and 7 of α-linoleic acid by a Δ6-desaturase to make stearidonic acid (C₁₈, 4 double bonds). Two carbons are then added to the carboxyl end of the molecule by an elongase, followed by insertion of a double bond to make eicosatetraenoic acid (C₂₀, 5 double bonds). Additional desaturation, elongation, and oxidation steps finally result in docosahexaenoic acid. Figure 6-3 shows the systematic organic chemistry names and numbering for the first and last structures in this pathway. The systematic name of α-linoleic acid is 9,12,15-octadecadienoic acid, whereas the systematic name of the final product is 4,7,10,13,16,19-docosahexaenoic acid. Counting from the C1 position, as is required in systematic naming, the double bonds that were numbered 9, 12, and 15 in the precursor are now numbered 13, 16, and 19 in the product (9 → 13; 12 →

FIGURE 6-3 Synthesis of long-chain PUFA. The conversion of one PUFA into another proceeds from the carboxyl end of the molecule in mammals, and there are no changes to the methyl end. Shown here is the conversion of α-linolenic acid (systematic name: 9,12,15-octatrienoic acid) to 4,7,10,13,16,19-docosahexaenoic acid. Several steps of elongation and desaturation are required (indicated by arrows). Numbering the first double bond from the methyl end of the molecule (using the ω numbering system) or the IUPAC system (“n−“, where “n” is the number of C atoms in the molecule) locates the double bond closest to the methyl end of the molecule. Thus PUFA names also reveal metabolic relationships, for example, 18:3n−3 and 22:6n−3. Because double bonds are methylene-interrupted and all-*cis*, this designation fully defines the molecular structure.

Nutrition Insight

Fat Matters: Quality as well as Quantity

The rise of obesity in America in the last decade of the twentieth century has led to an explosion of research on metabolic consequences of excess adipose tissue. Diet fads that focus on either low-fat foods or low-carbohydrate (and thus high-fat) foods have prompted many studies of the metabolic consequences of dietary fat levels. Remarkably, much of this research has completely ignored the composition of fat and focused only on dietary amount, implying that the composition is unimportant. Many papers, including ones published in highly ranked research journals, report animal studies in which one group is fed a high-fat diet of unspecified composition that induces overeating and obesity and a control group is fed a standard rodent diet that contains a lower amount of fat, again of unspecified and almost certainly different composition.

That so little attention would be given to the composition of the dietary fat is remarkable in light of the large number of human and animal studies showing that dietary fatty acid composition has a profound influence on many aspects of metabolism. Detailed studies in humans and experimental animals, conducted in the 1950s and since, have shown that each fatty acid has unique but overlapping sets of metabolic properties (Warden and Fisler, 2008).

Could changes in dietary fatty acid composition have a role in the obesity epidemic? Do some fats adversely affect human health more than others? Alternatively, does obesity so overwhelm metabolism that the role of fat composition becomes much less significant? Whatever the answer, the issue cannot be overlooked.

The fatty acids consumed by Americans changed dramatically in the twentieth century. Seed oils such as soy, corn, and canola oils were rare before the industrial revolution of the 1800s because they require mechanical crushing or solvent extraction for efficient production. Fruit oils such as olive and palm oils, along with rendered animal fat (lard and tallow), were more widely used. The high-quality taste and low cost of seed oils drove a rise in seed oil production throughout the twentieth century. Today, soybean oil accounts for a staggering 20% of calories consumed by Americans, in the form of mayonnaise, deep frying fat, salad dressings, margarine, nondairy coffee creamers, snack foods, and sandwich spreads. It may be found in any food with an ingredient list that refers generically to “vegetable oil.”

The application of conventional and modern molecular methods (genetically modified) to engineer fatty acid composition of various food oils is resulting in the introduction of oils with modified fatty acid content into the food supply. A notable example is the genetic modification of soybeans to produce oils high in oleic acid. High oleic soy oil was developed to replace the use of trans fatty acid–rich hydrogenated fats for deep frying and other purposes for which an oil with high oxidative stability is needed. The high oleic soybean oil was generated by downregulating expression of the fatty acid desaturase gene that encodes the enzyme that converts monounsaturated oleic acid to the polyunsaturated linoleic acid. The oil from these soybeans contains about 80% oleic acid, compared to 25% for conventional soybean oil. At the same time, it contains less than 9% linoleic acid compared to 54% in conventional soybean oil, and less α-linolenic acid, 3% compared to 7% in conventional soybean oil. Commercial production of these high oleic soybeans was approved in North American countries in 2009–2010. Further modification of the fatty acid composition (e.g., increasing the α-linolenic acid content) is under development. Similarly, high oleic acid peanuts, with only 3% linoleic acid, are already on the consumer market in Australia as peanut butter and peanut-containing snacks. These current and upcoming changes to the fatty acid composition of the food supply will result in a major change, once again, in the fatty acid composition of fats in our diets and, with this change, we will likely see physiological consequences related to fatty acid composition rather than amount of fat.

16; 15 → 19). Repeated many times for PUFAs, these changes in bond position number when counted from the carboxyl carbon make it difficult to track double bonds and, more importantly, fatty acids that are derived from one another.

A solution is to number double bonds from the other end of the molecule, taking advantage of the fact that mammals cannot insert double bonds into the methyl end portion of the PUFA chain. Two conventions that are routinely used, which are effectively identical, are the IUPAC (International Union of Pure and Applied Chemistry) “n minus” convention and the omega convention. Examples of these notations are shown in Figure 6-3 for α-linolenic acid (18:3n−3) and docosahexaenoic acid (22:6n−3).

The IUPAC notation retains a close connection to the systematic organic chemistry notation. The “n” represents the number of carbons in the whole molecule, 18 in the case of α-linolenic acid and 22 in the case of docosahexaenoic acid. The number of double bonds follows the number of carbons, with the two separated by a colon (e.g., C18:3, or simply 18:3 for α-linolenic acid with three double bonds and 22:6 for docosahexaenoic acid with six double bonds). The location of the double bond closest to the methyl end of the fatty acid is indicated by the “n minus” nomenclature; for α-linolenic acid (18:3n−3), the double bond closest to the methyl end is carbon 18−3 or C15 (i.e., between C15 and C16). For docosahexaenoic acid (22:6n−3), the double bond closest to the methyl end is carbon 22−3 or C19 (i.e., between C19 and C20).

An alternative system called the omega notation, proposed by Holman, recognizes that the systematic organic chemistry numbering designates the carbon next to the carboxyl as “α,” and labels the last carbon in the acyl chain “ω.” The first double bond counting from the methyl end of α-linolenic or of docosahexaenoic acid appears at the third carbon and hence is designated ω3 (i.e., “omega three”). Although the IUPAC and omega numbering systems technically refer to different carbon atoms (e.g., C15 in 18:3n−3 versus C16 in 18:3ω3; or C19 in 22:6n−3 versus C20 in 22:6ω3), the n− and omega nomenclature effectively designate the equivalent fatty acids when the numeral following the n− or omega is the same. For example, 18:3n−3 and 18:3ω3 designate the same fatty acid (α-linolenic acid) and 20:4n−6 and 20:4ω6 both designate arachidonic acid.

Because all common PUFAs have cis double bonds arranged in methylene-interrupted positions, both notations are taken to imply cis geometry and methylene interruption of the double bonds. Thus a designation of n−6 (ω6) or n−3 (ω3), along with the number of carbons and number of double bonds, fully defines the structure of the PUFAs. For instance, “18:3n−6” or “18:3ω6” completely defines the structure of γ-linolenic acid as the fatty acid with the systematic name all-cis-6,9,12-octadecatrienoic acid.

Fatty acids with trans or conjugated double bonds do not ordinarily appear at other than trace levels in mammalian tissues (other than in the skin surface lipids), although they may be consumed as part of the diet. Example structures of trans and conjugated unsaturated fatty acids are shown in Figure 6-4. These fatty acids should not be designated with the n− or ω notation, unless further specification is provided. Unlike the situation with common fatty acids, there is no universal specialized notation for these more unusual fatty acids. Either systematic notation or some convenient adaptation of systematic numbering may be used. An example of acceptable notation would be “trans-18:1n−9” to specify the monounsaturated C₁₈ fatty acid with a trans double bond between C9 and C10. For fatty acids with more than one double bond, a “Δ” notation system is frequently used. The superscript Δ precedes the designation of the sites of unsaturation counting from the carboxyl carbon. For instance, 18:3Δ^6,9,12 designates γ-linolenic acid.

FIGURE 6-4 Structures of oleic acid (c9-18:1), elaidic acid (t9-18:1), and rumenic acid (c9,t11-18:2).

Nutrition Insight

Vitamin F

The odd list of designations we now have for vitamins—A, D, E, and K for the fat-soluble vitamins, several Bs (with a few numbers missing) and C for the water-soluble vitamins, and some with no letters or numbers—is a remnant of the uneven but eventual progress in scientific understanding of the group of essential nutrients we call vitamins. What of other letters between E and K?

Vitamin F was proposed as the name of a factor associated with fat, and this proposal appeared in several papers in the 1920s. The discovery that fat-containing diets are essential for health is usually assigned to a 1929 paper of George and Mildred Burr (Burr and Burr, 1929), then working in the attic of the University of Minnesota medical school (Holman, 1992). They showed that rats fed fat-free diets developed scaly and sore skin, especially on the face and tail; had hair loss; grew at about two thirds of the normal rate; had a shortened life span; and were unable to reproduce. Animals that were emaciated and covered with very scaly skin were placed on 10 “drops” of lard per day. The animals immediately showed signs of recovery and within 10 weeks were fully “cured.” No recovery was seen when the non–fatty acid (nonsaponifiable) fraction of lard was used, thus indicating that the essential fat consisted of fatty acid(s). Subsequent studies established that the fat of greater unsaturation improved the ability of the fat to cure eczema (Brown et al., 1938). However, the inability of scientists to reproduce these effects in humans reduced their interest in vitamin F. We now know that periods greater than 6 months on fat-free diets are required to cause overt deficiency symptoms in humans. Today, the essentiality of the n−6 and n−3 fatty acids, linoleic (18:2n−6) and α-linolenic (18:3n−3) acid, is clearly established, and we would consider these to be components of the so-called vitamin F. There is still controversy about whether humans can synthesize sufficient long-chain PUFAs from 18:2n−6 and 18:3n−3 for optimum health. If, in fact, long-chain fatty acids are essential at some or all stages of the life cycle, PUFAs such as 20:4n−6, 20:5n−3, and 22:6n−3 might also be considered separate components of vitamin F. As progress continues toward defining the details of human requirements for PUFAs, as well as the role of specific PUFAs in human metabolism, the concept of a series of vitamin Fs may yet prove useful.

γ-Linolenic acid is also similarly designated as 9,12,15-18:3. Notations in which the individual double bonds are denoted, by counting from the carboxyl end, lend themselves to designation of isomers of γ-linolenic acid, often by adding leading “c” or “t” to specify double bond cis or trans geometry (e.g., c9,t11-octadecadienoic acid, or 18:2^{Δ c9,t11}, for rumenic acid.

Examples of structures and nomenclature for monoacylglycerols, diacylglycerols, and triacylglycerols are shown in Figure 6-6. Use of the IUPAC-IUB sn nomenclature is generally preferred over the use of the trivial names in most cases, although trivial names are commonly used for simple acylglycerols (e.g., the use of triolein for 1,2,3-tri-cis-9-octadecenoyl-sn-glycerol). A benefit of the sn nomenclature is that it clearly reveals the relationship between the precursor TAG and its DAG and MAG hydrolysis products. For example, the hydrolysis of 1-palmitoyl-2-stearoyl-3-myristoyl-sn-glycerol at the 1 position yields 2-stearoyl-3-myristoyl-sn-glycerol (Figure 6-7).

FIGURE 6-6 Examples of structures and nomenclatures for monoacylglycerols, diacylglycerols, and triacylglycerols. *SN,* Systematic name; *TN,* trivial name.

Glycerophospholipids

Glycerophospholipids are commonly described as phospholipids or phosphoglycerides. These lipids are derived from the parent compound phosphatidic acid, which is also known as diacylglycerol 3-phosphate. Other members of the glycerophospholipids include lysophospholipids and diphosphatidylglycerols. All glycerophospholipids contain at least one fatty acid esterified to the glycerol backbone.

Diacylphospholipids, the Common Phospholipids

The general structure of the diacylphospholipids is presented in Figure 6-8, and the several classes of common phospholipids and their structures are shown in Figure 6-9. In all cases, a phosphate group is esterified to the sn-3 position of glycerol, and fatty acids are esterified to the sn-1 and sn-2 positions. Most commonly, the sn-2 position is occupied by an unsaturated acyl chain, whereas the sn-1 position is occupied by a saturated chain. However, there are notable exceptions to this generality. For instance, the major surfactant lipid of the lung has 16:0 in both positions, and some of the phospholipids of the retinal photoreceptors have very high concentrations of unsaturated fatty acyl chains in both positions.