Deck 6: Genes and Genomes

A) a protein.
B) a functional product.
C) messenger RNA.
D) messenger RNA or ribosomal RNA.

A) that code for proteins.
B) that regulate mRNA translation.
C) that are removed by nucleases.
D) between protein-coding sequences.

A) restriction nucleases.
B) splicing.
C) exonucleases.
D) endonucleases.

A) a completely double-stranded hybrid was seen.
B) a partial hybrid with loops of mRNA extending from the hybrid regions was seen.
C) a partial hybrid with loops of DNA extending from the hybrid regions was seen.
D) no hybrid was seen, because the introns had been removed.

A) small nucleolar RNAs.
B) microRNAs.
C) sequences that control gene expression.
D) All of the above

A) commonly in eukaryotic genes and rarely in prokaryotic genes.
B) only in eukaryotic genes.
C) commonly in both eukaryotic and prokaryotic genes.
D) only in prokaryotic genes.

A) a single long intron.
B) no introns.
C) larger introns than exons.
D) larger exons than introns.

A) 3%
B) 40%
C) 60%
D) 90%

A) set of related but slightly different genes present in one individual.
B) family of individuals with the same gene.
C) set of slightly different genes present as one copy each in a set of individuals.
D) family of individuals in which each has an identical sequence of the same gene.

A) Pseudogene
B) Polymorphism
C) Nested gene
D) Alternative splicing

A) intron shuffling.
B) exon shuffling.
C) alternative splicing.
D) exon splicing.

A) Drosha
B) Dicer
C) RNAse
D) Integrase

A) miRNAs complementary base pair with mRNAs and inhibit translation and stimulate mRNA degradation.
B) miRNAs complementary base pair to regulatory regions of genes and inhibit the transcription of genes.
C) miRNAs complementary base pair to the active site on rRNAs and prevent the mRNA from interacting with ribosomes.
D) miRNAs complementary base pair with intron-exon boundary sequences and prevent correct mRNA processing.

A) are not transcribed.
B) are present in tandem arrays of thousands of copies.
C) account for approximately 10% of the human genome.
D) All of the above

A) genes that code for an RNA but do not code for a protein.
B) nonfunctional gene copies.
C) inactive genes.
D) genes containing variant sequences.

A) Reverse transcriptase and RNA polymerase
B) Reverse transcriptase and integrase
C) RNA polymerase and integrase
D) DNA polymerase and integrase

A) duplication of genes that then became nonfunctional through mutation.
B) reverse transcription of an mRNA and integration of the cDNA into a new chromosomal site.
C) genome-wide duplication and the inactivation of one homolog by mutation.
D) fusion of a prokaryotic cell with a eukaryotic cell.

A) Euchromatin
B) Nucleoli
C) Chromosomes
D) Heterochromatin

A) heterochromatin.
B) nucleoli.
C) chromosomes.
D) euchromatin.

A) Telophase
B) Metaphase
C) Anaphase
D) Prophase

A) millimeters.
B) centimeters.
C) meters.
D) kilometers.

A) 21
B) 22
C) 23
D) 24

A) linear.
B) multiple.
C) complexed with histones.
D) circular.

A) nucleoli.
B) nuclear matrices.
C) nucleosomes.
D) centromeres.

A) an AT-rich region occurs every 200 base pairs.
B) nucleosomes are spaced 200 base pairs apart.
C) a restriction nuclease site occurs every 200 base pairs.
D) two turns of the DNA around the nucleosome consist of 200 base pairs.

A) DNA associated with nucleosomes.
B) 10-nm chromatin fibers.
C) decondensed, transcriptionally active chromatin.
D) highly condensed, transcriptionally inactive chromatin.

A) decondensed, transcriptionally active chromatin.
B) 100-nm chromatin fibers.
C) DNA associated with nucleosomes.
D) highly condensed, transcriptionally inactive chromatin.

A) region of euchromatin devoid of histones.
B) sequence at the end of chromatids.
C) region where proteins bind to form kinetochores.
D) specific, repeated DNA sequence.

A) sites of spindle fiber attachment to chromosomes.
B) regions where two chromosomes remain attached during mitosis.
C) same as centromeres.
D) structures at the base of cilia and flagella.

A) centrosome.
B) centromere.
C) kinetochore.
D) spindle fiber.

A) epigenetic inheritance.
B) non-Mendelian genetics.
C) sex-linked inheritance.
D) Mendelian genetics.

A) microtubule binding sites in the center of chromosomes.
B) sites at the ends of chromosomes where DNA replication begins.
C) chromosome end structures required for complete replication of linear chromosomes.
D) sites at the ends of chromosomes where microtubules bind.

A) degrade the ends of chromosomes.
B) provide repetitive sequences in circular DNA molecules.
C) join two sister chromatids.
D) provide a site for replication of chromosome ends.

A) 4,000
B) 6,000
C) 26,000
D) 100,000

A) Though they are part of a gene, they are absent from the corresponding mRNA.
B) They are sequences within genes that are not transcribed.
C) They make up only a small fraction of the DNA of a mammalian gene.
D) Prokaryotes do not have introns in their genes.

A) An exon may contain a 5ʹ untranslated region.
B) An exon may contain sequences for small nucleolar RNAs.
C) An exon may contain a 3ʹ untranslated region.
D) Exons are separated by introns.

A) S. cerevisiae genes do not contain introns.
B) A small percentage of S. cerevisiae genes contain introns, and these introns are usually located near the beginning of the gene.
C) Most genes in S. cerevisiae contain introns.
D) Few S. cerevisiae genes contain introns, but those that do contain several.

A) 3%.
B) 25%.
C) 70%.
D) 90%.

A) 20
B) 23
C) 30
D) 39

A) Four exons
B) Five exons
C) Six exons
D) There could be multiple mRNAs that contain between one and six introns.

A) Alternative splicing
B) Spacer sequences
C) Satellite DNA
D) Short interspersed elements (SINEs)

A) mRNA and tRNA
B) rRNA and snRNA
C) Pre-mRNA and hnRNA
D) MicroRNA and lncRNA