Chapter 7 definitions
Glycogen
A branched homopolysaccharide of glucose that stores fuel in animals
Cellulose
A fibrous, tough, water-insoluble substance serves in a structural role in cell walls of plants structure: glucose in Beta 1->4 glycosidic bonds, no branching,
Chitin
A linear homopolysaccharide composed of N-acetylglucosamine residues; Beta 1-4 linkage
Starch
A mixture of two homopolysaccharides, amylose and amylopectin, which stores fuel in plants.
Enantiomers
A molecule which contains one chiral center and therefore has two different optical centers
Reducing sugar
A sugar in which the anomeric carbon is not involved in a glycosidic linkage and can therefore undergo oxidation
Glycans
Another word for polysaccharides
Dextrans
Bacterial and yeast polysaccharides
lactose
Beta 1--> 4 alpha; still reducing
example of epimer between glucose and mannose
C-2 epimers
Anomeric isomers
Carbonyl carbon
Glycoconjugates
Complex carbohydrate polymers covalently attached to proteins or lipids
Oligosaccharides
Consist of short chains or monosaccharide units or residues joined by glycosidic bonds; short as in can just be two monosaccharide units, names end in -ose
Furanose
Five-membered ring compouds
Anomers
Isomeric forms of monosaccharides that differ only in their configuration about the hemiacetal or hemiketal carbon atom
N-glycosyl bond
Join the anomeric carbon of a sugar to a nitrogen atom in glycoproteins and nucleotides
Carbohydrate
Polyhydroxy aldehydes or ketones Three classes: monosaccharides, oligosaccharides, and polysaccharides
Monosaccharide
Simple sugar that consists of a single polyhydroxy aldehyde or ketone unit
Pyranose
Six-membered ring compounds
Aldonic acid
Sugar acid obtained by oxidation of the aldehyde functional group of an aldose to form a carboxylic acid
Uronic acid
Sugar acid obtained by oxidation of the terminal carbon's hydroxyl group to form a carboxylic acid
Polysaccharides
Sugar polymers containing more than 20 or so monosaccharide units
Mutarotation
The alpha and beta anomers of D-glucose interconvert in aqueous solution
O-glycosidic bond
The bond which covalently links two monosaccharides to form a dissacharide
Epimers
Two sugars that differ only in the configuration around one carbon atom
maltose
alpha 1-->4 still reducing
salivary alpha-amylase breaks down starch and glycogen by hydrolyzing random alpha (? --> ?) bonds
alpha 1-4
anomeric carbon are
alpha and beta configurations of the same sugar; for example alpha-D-glucopolyranose and beta-D-glucopolyranose
starch is composed of
amylose and amylopectin
lactose is formed by a glycosidic bond between carbon 1 of beta-galactose and carbon 4 of glucose this is written as
beta (1-->4) glycosidic bond
humans do not produce ? making them unable to digest cellulose
beta (1-->4)endoglucosidases
carbohydrate isomers that differ in configuration around only ONE specific carbon atom are defined as ?
epimers
lactose is a disaccharides made up of
galactose + glucose
sucrose is a disaccharide made up
glucose + fructose
maltose is a disaccharide made up of
glucose + glucose
3 important polysaccharides
glycogen (animal sources) starch (plant sources) unbranched cellulose (plant sources)
bonds that link sugars in polysaccharides are called
glycosidic bonds
D-Deoxyribose
has 5 carbons, the two OH's on the same side, a third has two hydrogens
reducing sugar
hydroxyl group on anomeric carbon is not linked and the ring can open to act as a reducing agent
fructose, glucose, mannose and galactose are all ? of each other
isomers
sucrose
not to good pic, alpha 1->2 beta? non reducing
enzymes known as ? are able to interconvert D and L-isomers
racemases
isomers have the same ? but different ?
same chemical formula; different structures
branched amylopectin and glycogen contain alpha(1-->6) bonds which amylase can't hydrolyze resulting in
short branched and unbranched oligosaccharides called dextrins
example of an epimer between glucose and galactose
they are C-4 epimers structures only differ at C-4 -OH group position
galactose and mannose are NOT epimers, True or False why?
true; differ in position of -OH groups at TWO carbons: C-2 and C-4 therefore they are isomers not epimers
