Deck 5: An Introduction to Carbohydrates

A) chitin
B) cellulose
C) amylopectin
D) amylose

A) an amino group
B) a peptide bond
C) a disulfide bond
D) a β-pleated sheet

A) Allergies are becoming more common in humans as more chemicals are being encountered during longer lifetimes.
B) Evolutionarily, producing an enzyme to break down a sugar that will never be encountered is wasteful.
C) The ability to digest sugar in milk is determined by environment, and most humans are not exposed to milk as a food source beyond childhood years.
D) There is no good explanation for this situation in humans.

A) glycogen
B) cellulose
C) chitin
D) peptidoglycan

A) α-1,4-glycosidic linkage
B) β-1,4-glycosidic linkage
C) α-1,6-glycosidic linkage
D) β-1,6-glycosidic linkage

A) The polysaccharides in peptidoglycan are highly branched and form a network.
B) The glycosidic linkages between monosaccharides in peptidoglycan are extraordinarily strong.
C) Individual strands are joined by peptide bonds, a type of covalent bond.
D) The polysaccharides in peptidoglycan form helical structures, as in cellulose.

A) 6
B) 5
C) 3
D) 1

A) starch
B) cellulose
C) chitin
D) starch and chitin only
E) starch, cellulose, and chitin

A) glucose versus glycogen
B) glucose versus fructose
C) 1,4-glycosidic linkage versus 1,6-glycosidic linkage
D) α-linkage versus β-linkage

A) the number of carbons
B) the position of the hydroxyl groups
C) the position of the carbonyl group
D) One is a ring form; the other is a linear chain.

A) Polysaccharides catalyzed chemical reactions.
B) Polysaccharides used complementary pairing between monosaccharides to copy themselves.
C) Glycosidic linkages formed spontaneously between monosaccharides.
D) Polysaccharides played little, if any, role in chemical evolution.

A) fatty acid
B) polysaccharide
C) phospholipid
D) nucleic acid
E) monosaccharide

A) a hexose
B) a pentose
C) a phosphate
D) fructose
E) maltose

A) They are all composed of glucose in either the α or β form.
B) They all contain peptide bonds.
C) They can all form bonds between polymer chains that create parallel strands.
D) They are all composed of highly branched fibers.

A) the type of glycosidic linkage used
B) the size of their monosaccharide subunits
C) the amount of hydrogen bonding that occurs between parallel strands
D) their main function in plants

A) C18H36O18
B) C18H32O16
C) C6H10O5
D) C18H30O15
E) C3H6O3

A) the number of carbon atoms
B) the presence of a carbonyl group
C) the presence of hydroxyl groups
D) the presence of sulfur groups

A) the types of monosaccharide subunits in the molecules
B) the type of glycosidic linkages in the molecule
C) whether glucose is in the α or β form
D) the amount of branching that occurs in the molecule

A) Their ring structures differ in the location of a hydroxyl group.
B) Their linear structures differ in the location of a hydroxyl group.
C) The α form can be involved in 1,4- and 1,6-glycosidic linkages; the β form can participate only in 1,4 linkages.
D) The oxygen atom inside the ring is located in a different position.

A) maltose
B) fructose
C) glucose
D) galactose
E) sucrose

A) C60H120O60
B) C6H12O6
C) C60H102O51
D) C60H100O50
E) C60H111O51

A) glycogen
B) chitin
C) peptidoglycan
D) cellulose
E) starch

A) The energy in them can be stored as fat, which has high energy per unit weight.
B) The carbons in carbohydrates are rich in energy because they are highly oxidized.
C) Carbohydrates are reduced molecules that have high-energy electrons.
D) This is an advertising gimmick that has no scientific evidence to support it.

A) lactose
B) glycogen
C) chitin
D) cellulose
E) amylopectin

A) monosaccharide
B) disaccharide
C) starch
D) carbohydrate
E) polysaccharide

A) a polymer composed of fructose monomers
B) a storage polysaccharide for energy in plant cells
C) used by plants to make glycogen
D) a major structural component of plant cell walls
E) a monomer of starch.

A) cellulose
B) polypeptides
C) starch
D) amylopectin
E) chitin

A) humans have enzymes that can hydrolyze the α-glycosidic linkages of starch but not the β-glycosidic linkages of cellulose
B) humans have enzymes that can hydrolyze the β-glycosidic linkages of starch but not the α-glycosidic linkages of cellulose
C) starch monomers are joined by covalent bonds and cellulose monomers are joined by ionic bonds
D) the monomer of starch is glucose, while the monomer of cellulose is galactose
E) the monomer of starch is fructose, while the monomer of cellulose is glucose

A) starch
B) glycogen
C) cellulose
D) chitin
E) glucose

A) is a disaccharide
B) could be a glycoprotein
C) is a nucleic acid
D) could be cellulose or glycogen

A) glucose
B) starch
C) cellulose
D) chitin
E) DNA

A) Carbohydrates are more reduced than carbon dioxide.
B) Carbohydrates are more oxidized than carbon dioxide.
C) Every carbon atom in a carbohydrate is bonded to four different atoms.
D) Carbohydrates contain a carbonyl functional group.

A) are polymers of glucose
B) are cis-trans isomers of each other
C) can be digested by humans
D) are used for energy storage in plants
E) are structural components of the plant cell wall

A) Sunlight helps plants break down their food products so they can extract the energy stored in them.
B) Sunlight energy can be used by plants to reduce the carbon atoms in carbon dioxide.
C) Sunlight oxidizes carbon dioxide and water to form glucose.
D) Sunlight can be used directly by plants to perform a number of physiological processes.

A)

B)

C)

D)

A) Carbohydrates store information in the nucleus.
B) Carbohydrates contain and display information at the cell surface.
C) Carbohydrates display information used by mitochondria to bond to substrates and catalyze reactions.
D) Carbohydrates have no role in containing or displaying information for cells.

A) carbon and hydrogen atoms only
B) carbon, hydrogen, and oxygen atoms only
C) a variety of atoms that are found in cells
D) hydrogen and oxygen atoms only

A) The geometry of the bonds is different, and the shapes of enzyme active sites are highly specific.
B) Starch is held together by hydrogen bonding, not covalent bonding.
C) Cellulose molecules are highly branched, and enzymes are too bulky to fit.
D) Starch is held together by peptide bonds, not glycosidic linkages.

A) starch
B) peptidoglycan
C) cellulose
D) chitin

A) Grow H. pylori in a test tube (in vitro) with no glycoprotein.
B) Destroy the H. pylori by exposing them to a hypotonic solution. Then add the glycoprotein and observe.
C) Expose other species of bacteria to the glycoprotein.
D) Grow H. pylori in a test tube with a glycoprotein that has its terminal NAG removed.

A) facilitate diffusion of molecules down their concentration gradients
B) actively transport molecules against their concentration gradients
C) maintain the integrity of a fluid mosaic membrane
D) maintain membrane fluidity at low temperatures
E) mediate cell-cell recognition

A) Different types of pentose monomers form the basis of all carbohydrate-based structures.
B) Structural carbohydrates show a high degree of branching.
C) All structural carbohydrates are made from the same monomer, α-glucose.
D) Structural carbohydrates are long strands, which are chemically linked into a network.

A) cell walls of bacteria
B) hydrostatic skeletons of earthworms
C) exoskeleton of insects
D) body hairs of mammals
E) skeleton in birds