Deck 12: DNA: The Molecule of Heredity

A) A = G and C = T in any molecule of DNA.
B) A = T and G = C in any molecule of DNA.
C) A = U and G = C in any molecule of RNA.
D) A = C and G = T in any molecule of DNA.
E) DNA and RNA are made up of the same four nitrogenous bases.

A) Proteins released from the heat-killed S-strain killed the mouse.
B) DNA from the heat-killed S-strain was taken up by the live R-strain, converting them to S-strain and killing the mouse.
C) RNA from the heat-killed S-strain was translated into proteins that killed the mouse.
D) DNA from the live R-strain was taken up by the heat-killed S-strain, converting them to R-strain and killing the mouse.

A) pyrimidine bases.
B) other phosphate groups.
C) adenine.
D) deoxyribose.
E) ribose.

A) 0%
B) 10%
C) 40%
D) 30%
E) 20%

A) thymine.
B) a phospholipid group.
C) deoxyribose.
D) a phosphate group.
E) guanine.

A) phosphate-deoxyribose-base.
B) phosphate-deoxyribose-phosphate-deoxyribose.
C) adenine-thymine-guanine-cytosine.
D) base-phosphate-glucose.
E) phospholipid-deoxyribose-base.

A) Lipids
B) phospholipids
C) protein
D) DNA

A) hydrogen bonds.
B) covalent bonds.
C) disulfide bonds.
D) ionic bonds.
E) peptide bonds.

A) A bonds with C, and G bonds with T.
B) A bonds with G, and C bonds with T.
C) A bonds with T, and G bonds with C.
D) the amount of A = the amount of C, and the amount of G = the amount of T.
E) the amount of A = the amount of G, and the amount of C = the amount of T.

A) DNA.
B) ribosomes.
C) chromosomes.
D) protein.
E) enzymes.

A) a DNA molecule has a uniform diameter of 2 nanometers.
B) in a DNA molecule, A pairs with T and G pairs with C.
C) the DNA molecule consists of repeating subunits.
D) the phosphate-sugar ʺbackboneʺ of the molecule is on the outside of the DNA helix.
E) a DNA molecule is helical.

A) hydrogen bonds between bases.
B) ionic bonds between ʺRʺ groups in amino acids.
C) peptide bonds between amino acids.
D) covalent bonds between phosphates and sugars.
E) covalent bonds between carbon atoms.

A) deadly strain was heat-killed before injection, the mice died.
B) non-deadly strain was mixed with the heat -killed, deadly strain before injection, the mice died.
C) non-deadly strain was mixed with the heat -killed, deadly strain before injection, the mice lived.
D) non-deadly strain was mixed with the heat -killed, non-deadly strain before injection, the mice died.

A) Mice exposed to the S-strain bacterium became resistant to the R-strain bacterium.
B) S-strain bacteria can cause pneumonia.
C) Heat destroys the hereditary material.
D) There is a substance present in dead bacteria that can cause a heritable change in living bacteria.
E) The genetic material was definitively proven to be DNA.

A) A gene contains hundreds of chromosomes, which are composed of protein.
B) A gene is composed of DNA, but it has no relationship to a chromosome.
C) A chromosome contains hundreds of genes, which are composed of DNA.
D) A chromosome contains hundreds of genes, which are composed of protein.
E) A gene contains hundreds of chromosomes, which are composed of DNA.

A) A = C and G = T.
B) T = A and C = G.
C) A = G and C = T.
D) no two bases are equal in amount.
E) all bases are equal in amount.

A) RNA.
B) R-strain.
C) S-strain.
D) protein.
E) DNA.

A) C, T, A, and G bases.
B) only C and T bases.
C) A, U, G, and C bases.
D) only U and T bases.
E) only A and G bases.

A) -sugar-base-sugar-base-sugar-base-sugar-base-.
B) -phosphate-sugar-phosphate-sugar-phosphate-sugar-.
C) -base-phosphate-sugar-base-phosphate-sugar-.
D) -base-phosphate-base-phosphate-base-phosphate-.
E) -base-sugar-phosphate-base-sugar-phosphate-.

A) Phosphate
B) Deoxyribose
C) Ribose
D) Nitrogen base

A) variety of phosphate groups.
B) sequence of bases.
C) side groups of bases.
D) phosphate-sugar backbone.
E) different five-carbon sugars.

A) Different kinds of body cells contain different genetic information.
B) The genetic information in almost all of your body cells is identical.
C) The genetic information in your body cells changes in a predictable manner as you grow and develop.
D) Each type of body cell contains only the genetic information it needs to be that type of cell.

A) Phosphate
B) Double helix
C) Covalent bonds
D) Deoxyribose
E) Hydrogen bonds

A) the backbones of the molecule.
B) deoxyribose linked to phosphate.
C) nitrogenous bases linked together.
D) deoxyribose linked to sulfate.
E) nitrogenous bases linked to phosphate.

A) number
B) different types
C) sequence
D) size

A) Phosphate
B) Hydrogen bonds
C) Deoxyribose
D) Double helix
E) Covalent bonds

A) Two
B) Millions
C) Four
D) Thousands

A) Four
B) Millions
C) Hundreds or thousands
D) Two

A) A + T = G + C in amount.
B) A = T in amount.
C) A + G = T + C in amount.
D) G = C in amount.

A) Phosphate
B) Double helix
C) Covalent bonds
D) Hydrogen bonds
E) Ionic bonds

A) deoxyribose sugar.
B) double helix.
C) phosphate group.
D) covalent bonds.
E) hydrogen bonds.

A) G-C-C-T-A-T.
B) C-G-G-A-T-A.
C) A-T-T-C-G-C.
D) C-G-G-A-U-A.
E) G-C-C-A-T-A.

A) exactly half the genetic information in the parent cell.
B) twice the amount of genetic information of the parent cell.
C) a nearly perfect copy of the parent cellʹs genetic information.
D) the same amount of genetic information that was in the parent cell, but it has been altered.

A) phosphate molecules.
B) sulfur-containing bases.
C) ribose molecules.
D) deoxyribose molecules.

A) Millions
B) Two
C) Hundreds or thousands
D) Four

A) Phosphate
B) Phospholipid
C) Deoxyribose
D) Hydrogen bonds
E) Ribose

A) Adenine
B) Uracil
C) Deoxyribose
D) Phosphate group

A) hydrogen bonds between bases.
B) nitrogenous bases linked to phosphate.
C) deoxyribose linked to phosphate.
D) deoxyribose linked to sulfate.
E) nitrogenous bases linked together.

A) Ribose always bonds to a nitrogenous base.
B) Four different types of bases are found in DNA.
C) Phosphate groups always bond to ribose.
D) During replication, the phosphate groups are copied but the base sequence is not copied.
E) The number of adenines equals the number of guanines.

A) nucleoli.
B) nuclei.
C) genes.
D) chromosomes.
E) mutations.

A) deletion mutation.
B) translocation.
C) insertion mutation.
D) inversion.
E) nucleotide substitution mutation.

A) DNA helicase
B) DNA polymerase
C) DNA replicase
D) DNA ligase

A) be unable to replicate its DNA.
B) replicate its DNA as well as a cell with intact repair enzymes.
C) be able to correctly replicate its DNA, but it will need more time to do so.
D) replicate its DNA as rapidly as a normal cell, but the resulting DNA will have more errors in it.

A) base to phosphor group
B) phosphate group to base
C) 5? to 3?
D) 3? to 5?

A) Spontaneous mutation rates are around one in every four nucleotides that are replicated.
B) Mistakes are never made during DNA replication; they always occur during the G1 phase of interphase.
C) Some DNA spontaneously breaks down every second, making the chromosome significantly shorter with every passing day.
D) The ultraviolet radiation in sunlight may induce changes in DNA.

A) A pairs with T and G pairs with C.
B) the old DNA remains completely intact.
C) each new DNA molecule has half the DNA from the old one.
D) the old DNA is completely broken down.
E) only half of the DNA is replicated.

A) 5ʹ-A-T-G-C-3ʹ.
B) 5ʹ-C-G-T-A-3ʹ.
C) 3ʹ-T-A-C-G-5ʹ.
D) 3ʹ-G-C-A-T-5ʹ.

A) The sequence of bases
B) The number of bases
C) The sequence of phosphates
D) The sequences of deoxyribose
E) The number of phosphates

A) insertion mutation.
B) deletion mutation.
C) translocation.
D) nucleotide substitution mutation.
E) inversion.

A) vitamins.
B) X-rays.
C) ultraviolet radiation.
D) cigarette smoke.

A) Guanine and cytosine
B) Thymine and cytosine
C) Guanine and adenine
D) Uracil and guanine
E) Thymine and uracil

A) Many errors are made during DNA replication, but this does not matter because repair enzymes mend the errors.
B) DNA polymerase makes very few errors, so no repair enzymes are needed.
C) The few errors made by DNA polymerase are usually corrected by repair enzymes.
D) DNA polymerase always makes a perfect copy of the original DNA.
E) Many errors are made during DNA replication, but this does not matter because of the immense size of the DNA molecule.

A) Redundant
B) Inversion
C) Conservative
D) Semiconservative

A) deletion
B) nucleotide substitution
C) inversion
D) insertion

A) 100 million to 10 billion base pairs.
B) 10,000 to 1 million base pairs.
C) 1 million to 10 million base pairs.
D) 1 to 100 base pairs.
E) 100 to 1,000 base pairs.

A) use of DNA polymerase enzymes.
B) synthesis of totally new double-stranded DNA molecules.
C) separation of parental DNA strands.
D) use of parental DNA as a template.

A) reproduction
B) variability
C) stability
D) constancy

A) 10,000 to 1 million base pairs.
B) 100 million to 10 billion base pairs.
C) 1 to 100 base pairs.
D) 100 to 1,000 base pairs.
E) 1 million to 10 million base pairs.

A) the two DNA strands separate and each is used as a template for synthesis of a new strand.
B) new DNA synthesis occurs in only one location along the entire DNA molecule.
C) the original DNA is distributed to the two daughter cells, with no new DNA synthesized.
D) one strand of the DNA is completely replicated first, and then the second strand is replicated.