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25.9: Polysaccharides and Their Synthesis

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    Polysaccharides are complex carbohydrates in which tens, hundreds, or even thousands of simple sugars are linked together through glycoside bonds. Because they have only the one free anomeric –OH group at the end of a very long chain, polysaccharides aren’t reducing sugars and don’t show noticeable mutarotation. Cellulose and starch are the two most widely occurring polysaccharides.

    Cellulose

    Cellulose consists of several thousand D-glucose units linked by 1→4-β-glycoside bonds like those in cellobiose. Different cellulose molecules then interact to form a large aggregate structure held together by hydrogen bonds.

    The structure of cellulose, which is a beta-1,4-D-glucopyranoside polymer.

    Nature uses cellulose primarily as a structural material to impart strength and rigidity to plants. Leaves, grasses, and cotton, for instance, are primarily cellulose. Cellulose also serves as raw material for the manufacture of cellulose acetate, known commercially as acetate rayon, and cellulose nitrate, known as guncotton, which is the major ingredient in smokeless powder, the explosive propellant used in artillery shells and in ammunition for firearms.

    Starch and Glycogen

    Potatoes, corn, and cereal grains contain large amounts of starch, a polymer of glucose in which the monosaccharide units are linked by 1→4-α-glycoside bonds like those in maltose. Starch can be separated into two fractions: amylose and amylopectin. Amylose accounts for about 20% by weight of starch and consists of several hundred glucose molecules linked together by 1→4-α-glycoside bonds.

    The structure of amylose which is an alpha-1,4-D-glucopyranoside polymer.

    Amylopectin accounts for the remaining 80% of starch and is more complex in structure than amylose. Unlike cellulose and amylose, which are linear polymers, amylopectin contains 1→6-α-glycoside branches approximately every 25 glucose units.

    The structure of amylopectin, in which alpha-1,4 links with alpha-1,6 branches.

    Starch is digested in the mouth and stomach by α-glycosidases, which catalyze the hydrolysis of glycoside bonds and release individual molecules of glucose. Like most enzymes, α-glycosidases are highly selective in their action. They hydrolyze only the α-glycoside links in starch and leave the β-glycoside links in cellulose untouched. Thus, humans can digest potatoes and grains but not grass and leaves.

    Glycogen is a polysaccharide that serves the same energy storage function in animals that starch serves in plants. Dietary carbohydrates not needed for immediate energy are converted by the body into glycogen for long-term storage. Like the amylopectin found in starch, glycogen contains a complex branching structure with both 1→4 and 1→6 links (Figure \(\PageIndex{1}\)). Glycogen molecules are larger than those of amylopectin—up to 100,000 glucose units—and contain even more branches.

    Structural representation of glycogen which is a polysaccharide. The structure is highly branched and has numerous glucose units.
    Figure \(\PageIndex{1}\): A representation of the structure of glycogen. The hexagons represent glucose units linked by 1→4 and 1→6 glycoside bonds.

    Polysaccharide Synthesis

    With numerous –OH groups of similar reactivity, polysaccharides are so structurally complex that their laboratory synthesis has long been a particularly difficult problem. Several methods have recently been devised, however, that have greatly simplified the problem. Among these approaches is the glycal assembly method.

    Easily prepared from the appropriate monosaccharide, a glycal is an unsaturated sugar with a C1–C2 double bond. To ready it for use in polysaccharide synthesis, the glycal is first protected at its primary –OH group by formation of a silyl ether (Section 17.8) and at its two adjacent secondary –OH groups by formation of a cyclic carbonate ester. Then, the protected glycal is epoxidized.

    Primary alcohol of glycal is protected by forming silyl ether. Two adjacent secondary alcohols are protected by forming cyclic carbonate ester. Double bond of protected glycal is converted into epoxide.

    Treatment of the protected glycal epoxide in the presence of ZnCl2 as a Lewis acid with a second glycal having a free –OH group causes acid-catalyzed opening of the epoxide ring by SN2 backside attack (Section 18.6) and yields a disaccharide. The disaccharide is itself a glycal, so it can be epoxidized and coupled again to yield a trisaccharide, and so on. Using the appropriate sugars at each step, a great variety of polysaccharides can be prepared. After these sugars are linked, the silyl ethers and cyclic carbonate protecting groups are removed by hydrolysis.

    Glycal epoxide when reacts with a second glycal having a free hydroxyl group with zinc chloride as a catalyst yields a disaccharide glycal.

    Among the numerous complex polysaccharides that have been synthesized in the laboratory are several tumor-associated carbohydrate antigens (TACAs) that are currently being tested as potential vaccines for breast, prostate, lung, colon, and ovarian cancers.

    The Haworth projection of Lewis Y hexasaccharide is depicted. Alpha-Fucose bonded to beta-galactose bonded to beta-N-acetylglucosamine in turn bonded to alpha-fucose is shown.

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