Chapter 7 Carbohydrates and Glycoconjugates of the Cell Surfaces PDF

Summary

This chapter summarizes carbohydrates, including their nomenclature, classification, stereochemistry, ring structures, sugar derivatives, storage polysaccharides, structural polymers, glycosaminoglycans, peptidoglycan, and glycoproteins.

Full Transcript

Chapter 7 Carbohydrates and Glycoconjugates of the Cell Surfaces Chapter Summary ™ Carbohydrates (CH2O)n, n ≥3 ™ Nomenclature Ç Monosaccharides (simple sugars) Ç Oligo- and polysaccharides: Polymers of simple sugars ™ Classification Ç Aldose (aldehyde) and ketos...

Chapter 7 Carbohydrates and Glycoconjugates of the Cell Surfaces Chapter Summary ™ Carbohydrates (CH2O)n, n ≥3 ™ Nomenclature Ç Monosaccharides (simple sugars) Ç Oligo- and polysaccharides: Polymers of simple sugars ™ Classification Ç Aldose (aldehyde) and ketose (ketone) Ç Triose, tetrose, pentose, hexose, etc. ™ Stereochemistry Ç Aldose n ≥3, ketose n ≥4 have at asymmetric carbons (chiral centers) Ç D- and L- Configuration: Refer to configuration of highest numbered asymmetric carbon Ç D- and L- forms: Mirror images: Enantiomers Ç With >1 asymmetric carbon: Diastereomers: Configurations that differ at 1 or more chiral carbons but not mirror image molecules Ç Epimers: Two molecules that differ in configuration about 1 asymmetric carbon ™ Ring structures Ç Pyranoses: Six-membered, oxygen-containing ring Ç Furanose: Five-membered, oxygen-containing ring Ç Anomeric carbon: Ketone or aldehyde carbon that becomes chiral upon ring formation Ç Anomers: α, β differ in configuration about anomeric carbon  α-Configuration: In Fischer projection, OH of anomeric carbon on same side as OH of highest numbered asymmetric carbon  β-Configuration: In Fischer projection, OH of anomeric carbon on opposite side as OH of highest numbered asymmetric carbon Ç Haworth projections: Three-dimensional representation: Groups to right in Fischer projection draw down in Haworth projection Ç Conformations  Chair and boat conformations due to ring pucker  Axial and equatorial orientation of groups attached to ring ™ Sugar derivatives Ç Acids: Oxidation of free anomeric carbon to carboxylate Ç Alcohols Ç Deoxysugars Ç Esters (ATP and GTP) Ç Amino sugars: Glucosamine Ç Muramic acid Ç Glycosides: Anomeric carbon reacted with alcoholic function. ™ Sugars with free anomeric carbon are reducing sugars Ç End of sugar polymer with free anomeric carbon: Reducing end Ç Opposite end: Nonreducing end ™ Oligosaccharides Ç Disaccharides  Maltose: Diglucose  Lactose: Galactose and glucose  Fructose: Fructose and glucose: Nonreducing sugar ™ Storage polysaccharides Ç Starch: α Amylose and amylopectin  α Amylose: Linear chains of α(1→4)D-glucose  Amylopectin: Linear chains of α(1→4)D-glucose with α(1→6)D- glucose branches every 12 to 30 residues  Animal digestion of starch α Amylase: Animals: Hydrolysis of internal α(1→4) glycosidic linkage α Amylase: Microorganisms: Exoamylase: releases disaccharide maltose Ç Glycogen: α(1→4) D-glucose chains with α(1→6) D-glucose branches every 8 to 12 residues Ç Dextrans: Bacteria: α(1→6) D-glucose polymers ™ Structural polymers Ç Cellulose: Plant cell wall: Linear polymer of β(1→4) D-glucose Ç Chitin: Exoskeleton and fungi cell wall: β(1→4) N-acetyl-D-glucosamine ™ Glycosaminoglycans: Polymers with disaccharide repeat: Negatively charged ™ Peptidoglycan of bacterial cell walls Ç Gram-negative bacterial cell wall  NAM-NAG repeats crosslinked with tetrapeptide  Attached to outer cell wall via 57-amino acid protein  Protein attached to aminopimelic acid (replaces 10% of D- alanines)  Outer cell wall: Lipopolysaccharides: Antigenic Ç Gram-positive bacterial cell walls  NAM-NAG repeats crosslinked with tetrapeptide and pentaglycine  No outer cell wall  Teichoic acid: Ribitol phosphate or glycerol phosphate polymers ™ Glycoproteins Ç Functions: Structural, enzymatic, receptors, transport, immunoglobins Ç Linkage  O-linked Amino acids are serine, threonine or hydroxylysine Sugars: N-Acetylgalactosamine  N-linked Amino acid is asparagines Functions: Protein folding and turn-over ™ Proteoglycans: Glycoproteins Ç Sugar: Glycosaminoglycans Ç Interact with variety of molecules

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