Deck 10: Chromosome Organization and Molecular Structure

A) positive supercoiling.
B) overwinding.
C) All of the answers are correct.

A) 200
B) 400
C) 600
D) 1100

A) Hydrophobic amino acids
B) Polar amino acids
C) Positively charged amino acids
D) Negatively charged amino acids

A) Nucleosomes
B) Loop domains
C) 30 nm fiber
D) None of the answers are correct

A) It inhibits DNA gyrase.
B) It inhibits DNA compaction.
C) It inhibits DNA replication.
D) All of the answers are correct.

A) 5%
B) 25%
C) 40%
D) 80%

A) Telomeres
B) Centromeres
C) Kinetochores
D) Origins of replication

A) 0
B) 1
C) 2
D) More than two

A) Relax negative supercoils
B) Relax positive supercoils
C) Introduce negative supercoils
D) More than one of the answers are correct

A) Retroelement
B) Transposable element
C) Highly repetitive DNA
D) All of the answers are correct

A) To bind to the nuclear matrix
B) To form loop structure
C) To condense DNA
D) All of the answers are correct

A) Nucleus
B) Nucleolus
C) Nucleoid
D) Nuclear envelope

A) < 50
B) 150
C) 200
D) > 1,000

A) Telomeres
B) Specific genes on the chromosome
C) Centromeres
D) They don't attach to DNA

A) 10,000
B) 100,000
C) 1000
D) 50,000

A) makes the chromosomal DNA more compact.
B) creates tension because of the underwinding of the DNA.
C) can promote DNA strand separations in small regions.
D) All of the answers are correct.

A) Amphibians have more repetitive sequences than do humans.
B) Amphibians are more biologically complex than mammals.
C) Amphibians have more genes than do humans.
D) Amphibians are tetraploid, while humans are diploid.

A) 4
B) 5
C) 7
D) 8

A) Constitutive heterochromatin
B) Facultative heterochromatin
C) Constitutive euchromatin
D) Facultative euchromatin

A) histone proteins, scaffold proteins
B) RNA, transcription proteins
C) DNA, histone proteins
D) RNA, histone proteins
E) DNA, scaffold proteins

A) 100,000
B) 1000
C) 100
D) 10
E) 500

A) histone
B) 11nm fiber
C) beads-on-a-string
D) 30 nm fiber
E) scaffold protein

A) Super coiling.
B) Packaging the DNA with histone proteins.
C) Looping of the DNA.
D) Increase or decrease the number of turns in the DNA.
E) Anchoring the DNA loops with DNA-binding proteins.

A) 30-fold
B) 50 fold
C) 1 million-fold
D) 3 million-fold

A) Radial loop domains
B) Cohesin
C) Centromeres
D) Nucleosomes
E) Condensin

A) Radial loop domain
B) 30 nm fibers
C) Double helix
D) Nucleosome
E) Heterochromatin

A) cause the chromosomes to uncompact following mitosis.
B) coat the chromosomes and condense them into heterochromatin through the compaction of radial loops.
C) hold the DNA to the histone proteins in the nucleosome core particle.
D) trigger DNA to be compacted in a nucleosome core particle.
E) None of the answers are correct.

A) It is composed of an octamer of proteins.
B) There is a linker region between two nucleosomes of about 200 base pairs.
C) There are two copies each of H2A, H2B, H3 and H4.
D) The DNA is wrapped around the core slightly over two complete turns.
E) The DNA wrapped around the core contains 146-147 base pairs.

A) Euchromatin
B) Facultative heterochromatin
C) Constitutive heterochromatin
D) Barr body

A) Radial loop domain
B) 30 nm fibers
C) Heterochromatin
D) Nucleosome
E) Euchromatin

A) 10-
B) 100-
C) 150-
D) 1000-
E) 1,000,000-

A) Highly repetitive DNA contains transposable elements and genes that are expressed in abundance and thus have many copies.
B) Moderately repetitive DNA contains unique sequences, such as genes found in one or a few copies.
C) Nonrepetitive DNA is composed of thousands of copies of many short repeats.
D) Moderately repetitive DNA contains retro elements, such as the Alu sequence.
E) Moderately repetitive DNA contains transposable elements and genes that are expressed in abundance and thus have many copies.

A) Histones have a higher molecular mass, which improves DNA compaction.
B) Histones are strongly attracted to the positively charged phosphate backbone of DNA.
C) Histones and DNA have opposite charges, which improves the compaction of DNA into nucleosomes.
D) Histones and DNA have the same charge, which improves the compaction of DNA into nucleosomes.