Deck 11: Genetic Engineering and Biotechnology

A) a reporter gene.
B) ligation.
C) recombination.
D) transformation.

A) Fragment DNA into small segments.
B) Hybridize DNA sequences to form inserts of a target size range.
C) Ligate DNA into vectors.
D) Transform the vectors into a host.

A) YACs are more likely than BACs to undergo recombination and rearrangement.
B) BACs are more likely than YACs to undergo recombination and rearrangement.
C) YACs and BACs undergo recombination and rearrangement at about the same rate.
D) It is impossible to state with any certainty whether YACs or BACs are more likely to undergo recombination and rearrangement, because environmental factors play a major role in the probability of one or the other occurring.

A) selection
B) screening
C) isolation
D) duplication

A) fluorescence in situ hybridization
B) GFP fusion protein
C) Northern blot
D) RT-PCR

A) transcription regulators.
B) global control genes.
C) promoter sequences.
D) reporter genes.

A) introns.
B) exons.
C) repressors.
D) integrators.

A) during DNA denaturation
B) during primer annealing
C) during primer extension/elongation
D) Both the first and last cycles are hotter in temperature than all other cycles.

A) individual RNA
B) individual DNA
C) pair of RNA
D) pair of DNA

A) encoder
B) translational
C) reporter
D) recorder

A) bacterial artificial chromosomes (BACs).
B) cosmids or fosmids.
C) a eukaryotic host to house the large foreign DNA.
D) multiple gene fusions.

A) not produce the protein being studied.
B) produce the protein in larger amounts than the vector.
C) repress the genetic expression being studied.
D) produce signal proteins to tag the host protein.

A) fluorescence in situ hybridization
B) qPCR
C) RT-PCR
D) a Southern blot

A) mRNA / transcribed
B) DNA / transcribed
C) mRNA / translated
D) DNA / translated

A) flanking complementary bound nucleotides permit non-complementary base pairing
B) methylated nucleotides disrupt DNA polymerase's proofreading
C) nucleotide substitution when one is depleted
D) transposase-induced base pair changes

A) cleavage product can be either blunt or sticky ended but is always the same for an individual enzyme
B) recognizes a specific palindromic site for cleavage
C) recognition site length varies among enzymes but is always the same for an individual enzyme
D) unable to cleave methylated DNA

A) agarose gel electrophoresis
B) fluorescence in situ hybridization
C) protein purification
D) northern blots

A) TTGCCGA
AACGGCT
B) GGGGGGG
CCCCCCCC
C) GTAATG
CATTAC
D) GAATTC
CTTAAG

A) virus
B) expression
C) shuttle
D) integrating

A) a complete metabolic pathway requiring several different enzymes.
B) overproducing proteins.
C) production of a small protein.
D) transgenic animals with immune systems.

A) Agrobacterium spp.
B) fish.
C) plants.
D) viruses.

A) attenuated carrier viruses.
B) monovalent.
C) subunit vaccines.
D) purified protein administered.

A) Avoid hybridization of the fusion gene in the artificial construct.
B) Reading frame is the same for both the fusion gene and reporter gene.
C) Transcriptional start and stop signals are shared.
D) Translational start and stop signals are shared.

A) is compatible with a binary vector able to be regulated.
B) is inducible.
C) has a relatively low copy number per cell.
D) prevents folding of the overexpressed protein into its toxic form.

A) a key complementary part of the target gene sequence of interest.
B) all of the nucleotide sequence of the gene of interest to conclusively identify the gene.
C) an antibody to specifically bind to the gene of interest.
D) at least three separate complementary regions of the gene of interest.

A) removal of a gene responsible for feeling full after eating.
B) replacement of inducible to constitutive hormone production.
C) resistance to bacterial infections which waste metabolic energy in the salmon to fight off.
D) addition of genes to enhance blood circulation and tissue development.

A) complex folding
B) methylation
C) glucosylation
D) glycosylation

A) DNA ligase.
B) DNA phosphatase.
C) DNA hydrolase.
D) DNA transferase.

A) engineering a complete metabolic pathway.
B) identifying the localization of a protein.
C) knocking out a gene by cassette displacement.
D) making a foreign protein in a mammalian cell.

A) DNA cassette
B) DNA hybrid
C) recombinant DNA
D) artificial chromosome

A) gene fusion
B) operon fusion
C) protein fusion
D) shuttle vector

A) Eukaryotic transcripts are not methylated but their genes are often methylated.
B) Larger transcript size in eukaryotes enables easy size-selection methods.
C) mRNA is polyadenylated in eukaryotes.
D) Transcripts are the most abundant RNAs in eukaryotes.

A) blunt ends.
B) overhangs.
C) sticky ends.
D) blunt ends, overhangs, or sticky ends.

A) coat proteins form a relatively rigid structure and do not allow much space for additional proteins to be expressed.
B) multiple foreign proteins simultaneously synthesized often disrupts each other's activity.
C) vaccinia and most other viruses engineered for vaccines contain only one restriction site for cloning in their genome.
D) virus genetic manipulation uses transfection, which is an inherently inefficient process.

A) carrying ori genes for replication of the cloned sequence.
B) having a multiple cloning site (MCS).
C) having a high copy number per cell.
D) lacking a promoter site upstream of the insertion site.

A) Codon optimize the gene.
B) Decrease the number of biobricks in the vector.
C) Simultaneously produce intracellular chaperonins.
D) Switch to an expression host with a larger intracellular volume.

A) are heterodimers.
B) natively function to methylate specific nucleotides and prevent foreign DNA from being incorporated into the genome.
C) recognize nucleotide sequences that are palindromic.
D) require ATP energy to cleave dsDNA.

A) assembling gene sequences together into genome and creating a living organism from it
B) creating a new metabolic pathway that produces a previously unidentified compound
C) developing a novel polyvalent vaccine
D) making Escherichia coli phototrophic