Deck 18: Dna Technologies: Making and Using Genetically Altered Organisms, and Other Applications

A)reverse transcriptase
B)exonucleases
C)restriction endonucleases
D)DNA ligase
E)DNA polymerase

A)inverted sequence
B)palindrome
C)restriction site
D)restriction fragment length polymorphism
E)inactive restriction site

A)a DNA fragment is inserted directly into a bacterium and is replicated
B)a DNA fragment is inserted into a plasmid, which is then introduced into a bacterium where the gene is expressed but the plasmid does not replicate
C)a DNA fragment is inserted into a plasmid, which is then introduced to a bacterium where the plasmid replicates
D)a DNA fragment is inserted directly into a bacterium and is digested by nucleases
E)a protein of interest is taken up by a bacterium, which incorporates the protein into its cell membrane

A)DNA encoding restriction endonucleases
B)a gene of interest found in the genome
C)DNA fragments from the same organism that have been joined together to form a single molecule
D)DNA fragments from two or more different sources that have been joined together to form a single molecule
E)a plasmid containing DNA from a single source

A)phosphodiester
B)ester
C)glycosidic
D)peptide
E)hydrogen

A)​1
B)​2
C)​3
D)​4
E)​5

A)bacterium
B)clone
C)transcriptionally modified organism
D)genetically modified organism (GMO)
E)somatic organism

A)always genetically modified organisms
B)always made using DNA technologies
C)only used in basic research
D)only used in applied research
E)created through natural mutations or by using DNA technologies

A)genotype of the organism without a change in phenotype
B)genotype of the organism, causing a change in phenotype
C)phenotype of the organism without a change in genotype
D)phenotype of the organism, causing a change in genotype
E)proteome of the organism without a change in genotype

A)research applications
B)DNA manipulation in vitro
C)defense against viruses that infect bacteria
D)regulating bacterial gene expression
E)breaking phosphodiester bonds in mammalian DNA

A)DNA sequence is inserted into a plasmid
B)DNA sequence is inserted into the bacterial chromosome
C)linear DNA sequence is circularized, thus generating a plasmid
D)new DNA is directly introduced into the bacterial cell
E)approach depends on the species of host bacteria used in the experiment

A)1-2
B)4-8
C)10-15
D)24-32
E)36-47

A)1
B)​2
C)​3
D)​4
E)​5

A)hydrogen-bonding
B)sticky
C)tacky
D)blunt
E)jagged

A)genetic engineering
B)genomics
C)bioinformatics
D)biotechnology
E)genetic engineering

A)computer science and social science
B)mathematics and social science
C)mathematics and computer science
D)biology and history
E)biology and physics

A)enzymes that cut DNA
B)RNA molecules
C)small proteins that help replicate cloned genes
D)protein-coding genes in the chromosome
E)circular DNA molecules that replicate separately from chromosomal DNA

A)nucleases
B)proteases
C)stem cells
D)Ti plasmids
E)restriction fragment length polymorphisms

A)synthesizing low quantities of restriction enzymes
B)producing restriction enzymes that do not recognize sequences in their own DNA
C)chemically modifying bases within the restriction sites
D)only activating restriction enzymes when foreign DNA is present in the cell
E)inactivating restriction enzymes through phosphorylation

A)lacZ production and ampicillin resistance
B)β-galactosidase enzyme production and ampicillin resistance
C)DNA ligase production and sticky ends
D)DNA ligase and reverse transcriptase production
E)DNA polymerase production and antibiotic resistance

A)It is always 55ᵒC because the DNA polymerase works best at this temperature.
B)It is always 55ᵒC because primers anneal best at lower temperatures.
C)It is always 60ᵒC because any other temperature would destabilize the DNA.
D)It can vary from 55-60ᵒC depending on the primers being used.
E)It can vary from 55-60ᵒC depending on the type of DNA polymerase being used.

A)keeps the primers from annealing to the DNA
B)makes fewer DNA replication errors than other DNA polymerases
C)is a heat-stable DNA polymerase
D)is more efficient at replicating DNA than other DNA polymerases
E)helps the primers anneal to the correct DNA sequence

A)lactose
B)X-gal
C)sucrose
D)lacZ
E)agarose

A)repeated DNA replication cycles of a specific region of a DNA molecule
B)DNA replication in which DNA polymerase replicates an entire chromosome
C)a reaction in which restriction enzymes cut a gene of interest from the chromosome
D)transcription during which only a portion of the cell's DNA is expressed
E)translation during which only some mRNA molecules are translated to make proteins

A)restriction endonuclease digestion only
B)gene cloning only
C)PCR only
D)restriction endonuclease digestion and PCR
E)gene cloning and PCR

A)It helps the host bacteria grow faster.
B)It allows researchers to distinguish bacteria that contain the plasmid from those that do not.
C)It aids scientists in developing new antibiotic treatments.
D)It allows researchers to distinguish bacteria that contain the recombinant vector from those that contain just the vector.
E)It helps the bacteria replicate the recombinant plasmid more quickly.

A)lacZ+ gene
B)ampicillin resistance gene
C)origin of replication
D)ribosomal binding site
E)restriction site

A)the four nucleoside triphosphates, DNA primase, DNA polymerase, and an agarose gel
B)a pair of primers, the four nucleoside triphosphates, DNA primase, and DNA polymerase
C)DNA with the target sequence to be amplified, the four nucleoside triphosphates, DNA primase, and DNA polymerase
D)DNA with the target sequence to be amplified, a pair of primers, the four nucleoside triphosphates, and DNA primase
E)DNA with the target sequence to be amplified, a pair of primers, the four nucleoside triphosphates, and DNA polymerase

A)denaturation, extension, and annealing
B)annealing, extension, and denaturation
C)extension, denaturation, and annealing
D)annealing, denaturation, and extension
E)denaturation, annealing, and extension

A)It makes the bacteria resistant to the antibiotic.
B)It allows researchers to distinguish bacteria that contain the plasmid from those that do not.
C)It aids scientists in developing new antibiotic treatments.
D)It allows researchers to distinguish bacteria that contain the recombinant plasmid from those that contain just the vector.
E)It makes the bacteria produce more clones.

A)The gene with a cloning vector is ligated.
B)Agarose gel electrophoresis takes place
C)The polymerase chain reaction (PCR)amplifies the DNA fragment from the genome
D)A DNA polymerase specific for the fragment is used to make copies
E)DNA fingerprinting allows the fragment to be copied from the chromosome.

A)transformation
B)gene remodeling
C)the polymerase chain reaction
D)restriction cloning
E)ligation

A)recombinant; deleted from the plasmid
B)nonrecombinant; intact
C)recombinant; intact
D)nonrecombinant; disrupted by the inserted DNA fragment
E)recombinant; disrupted by the inserted DNA fragment

A)recombinant; deleted from the plasmid
B)nonrecombinant; intact
C)recombinant; intact
D)nonrecombinant; disrupted by the inserted DNA fragment
E)recombinant; disrupted by the inserted DNA fragment

A)The PCR reaction adds sticky ends onto the amplified DNA, allowing ligation to a cloning vector.
B)Restriction enzyme sites are added to the 5 ¢ ends of both primers; therefore, digestion of the PCR-amplified gene allows ligation to a cloning vector cut with the same restriction enzyme.
C)The PCR-amplified gene is sequenced to locate restriction sites in order to determine which restriction enzymes to use for cloning.
D)The PCR-amplified gene is cut with one restriction enzyme, then ligated to a cloning vector cut by a different restriction enzyme.
E)The cloning vector is added to the PCR reaction, and once the gene is amplified, it immediately ligates to the cloning vector.

A)4, 3, 1, 5
B)3, 2, 5, 1
C)3, 2, 1, 5
D)2, 3, 1, 5
E)3, 2, 1, 4

A)PCR and agarose gel electrophoresis
B)DNA cloning and PCR
C)DNA cloning only
D)PCR only
E)agarose gel electrophoresis only

A)the pair of DNA primers
B)the pair of RNA primers
C)DNA polymerase
D)the four nucleoside triphosphates
E)the thermocycler

A)recombinant plasmids only
B)nonrecombinant plasmids only
C)joined-together copies of the DNA fragment containing the XYZ gene only
D)a mixture of recombinant plasmids, nonrecombinant plasmids, and joined-together copies of the DNA fragment containing the XYZ gene
E)no reaction will occur because DNA polymerase rather than DNA ligase is needed to insert the DNA fragments into the plasmid cloning vector

A)​A
B)​B
C)​C
D)​D
E)they are all the same distance from the negative electrode

A)positive; are negatively charged
B)negative; are positively charged
C)bottom; are pulled by a magnetic force
D)bottom; are pulled by gravity
E)bottom; have a greater density than the gel

A)are differentiated cells that proliferate indefinitely
B)can differentiate into any cell type, but can only divide once after terminally differentiating
C)have the ability to differentiate into all cell types
D)are undifferentiated cells that proliferate indefinitely
E)are undifferentiated cells that proliferate a finite number of times

A)transgenic; transgene
B)transgenic; oncogene
C)somatic; Ti plasmid
D)genetically modified organisms; restriction fragment length polymorphism
E)somatic; transgene

A)The initial cycles do not produce many copies of the target sequence, but since the number of molecules produced doubles with each cycle, millions of copies are produced after 20-30 cycles.
B)The initial cycles amplify DNA slowly, but as the temperature increases, DNA polymerase works more quickly to produce millions of copies of the target sequence.
C)The bacteria used in the reaction divide with each cycle, replicating the target DNA.
D)Only non-target DNA is made during the first 10 cycles, while only cycles 11-20 specifically target the gene of interest.
E)Once the enzyme starts working, it must continue until there are no remaining nucleotides.

A)staining the gel with an agarose-binding dye so the gel, but not the DNA bands, fluoresces under UV light
B)staining the DNA with a DNA-binging dye that fluoresces under natural light
C)staining the DNA with X-gal so that the DNA bands appear blue
D)staining the gel with a DNA-binding dye that fluoresces under UV light
E)staining the gel with a DNA-binding dye that fluoresces under natural light

A)PCR
B)biotechnology
C)amplification
D)a restriction enzyme digestion
E)gel electrophoresis

A)DNA manipulation
B)gene manipulation
C)gene targeting
D)DNA cloning
E)transgenic modification

A)photosynthetic bacteria that clean up oil spills
B)transgenic sheep that produce a protein required for normal blood clotting in humans
C)E. coli that synthesize restriction enzymes for use in genetic engineering
D)yeast that produce ethanol for use as fuel in vehicles
E)a genetically modified crop plant that is resistant to pesticide

A)Only somatic gene therapy can result in the modified genes being passed to the next generation.
B)The effects of germline gene therapy are limited to the current generation.
C)In germline gene therapy, the gametes are altered; in somatic gene therapy, body cells affected by a genetic disorder are altered.
D)In somatic gene therapy, the gametes are altered; in germline gene therapy, only the body cells are altered.
E)Only germline gene therapy is ethical for research purposes in rodents

A)can be amplified directly from the genome
B)is obtained by producing a cDNA copy from the gene's transcript
C)contains introns, so an mRNA copy must be produced from the gene's transcript
D)contains exons that are removed by restriction enzymes, while the remaining introns are ligated together
E)contains introns that are removed by restriction enzymes, while the remaining exons are ligated together

A)uses Taq polymerase to produce cDNA copies of RNA transcripts
B)uses RNA polymerase to amplify cDNA copies of RNA transcripts
C)uses RNA polymerase to produce mRNA copies of a gene
D)amplifies cDNA copies of RNA transcripts
E)uses reverse transcriptase to produce mRNA copies of a gene

A)some prior knowledge of the gene X sequence so appropriate primers can be designed
B)a heat-stable restriction endonuclease
C)restriction endonucleases that cut gene X but not gene Y
D)a cloning vector that has multiple antibiotic resistance genes
E)a cloning vector that will ligate to gene X but not to gene Y

A)programmable RNA-guided genome editing
B)programmable DNA-guided genome editing
C)cutting DNA at specific sites so it can be inserted into a cloning vector
D)increasing transcription of a gene of interest
E)enhancing DNA polymerase activity in PCR reactions

A)reverse transcriptase; single-stranded
B)reverse transcriptase; double-stranded
C)DNA polymerase; single-stranded
D)DNA polymerase; double-stranded
E)RNA polymerase; single-stranded

A)different RNA molecules transcribed from a coding region of DNA
B)the products of a PCR reaction in which the primers annealed to multiple sites
C)the products of a PCR reaction performed without one of the nucleoside triphosphates
D)the products of a PCR reaction that had more than two primers
E)a DNA marker ladder

A)Expression vectors do not have an origin of replication.
B)Only expression vectors have origins of replication.
C)Expression vectors contain regulatory sequences to allow transcription and translation of an inserted gene.
D)Inserted genes cannot be transcribed from an expression vector.
E)Expression vectors do not contain antibiotic resistance genes.

A)charge
B)length
C)sequence
D)percentage of GC base pairs
E)structure

A)​A
B)​B
C)​C
D)​D
E)it is impossible to tell

A)​A
B)​B
C)​C
D)​D
E)it is impossible to tell

A)create clones of mammals
B)treat human diseases by somatic gene therapy
C)insert transgenes into bacteria
D)insert transgenes into plants
E)insert transgenes into animals

A)to determine the structure of a metabolite
B)to compare the metabolic differences between healthy and disease cells
C)to decipher the mRNA sequence of a metabolic enzyme
D)to identify the sequence of a metabolic gene
E)for paternity testing

A)The gene of interest remains in the Ti plasmid after the plasmid has transformed the plant, and the gene is expressed in the plant.
B)The Ti plasmid inserts the gene of interest directly into the plant's nuclear DNA.
C)The entire Ti plasmid including the gene of interest is inserted into the plant's nuclear DNA.
D)The Ti plasmid inserts the foreign DNA into the plant's chloroplast DNA.
E)The Ti plasmid inserts the foreign DNA into the plant's mitochondrial DNA.

A)juvenile 2 only
B)juveniles 2 and 3
C)juveniles 1 and 4
D)juveniles 2 and 4
E)juveniles 1, 2, 3, and 4

A)Humans have been successfully cloned.
B)Germline gene therapy is used to treat genetic conditions in humans.
C)Genetically engineered microorganisms constitute a large public concern.
D)Possible problems associated with GMOs are a public concern.
E)Bacterial cloning and animal cloning follow largely similar techniques.

A)DNA elements
B)endonuclease sites
C)restriction sites
D)restriction fragment length polymorphisms
E)restriction elements

A)single base-pair; restriction site
B)frameshift; restriction site
C)nonsense; promoter region
D)single base-pair; promoter region
E)nonsense; restriction site

A)test the effectiveness of different restriction enzymes on a sequence of DNA
B)compare the DNA sequences between individuals by looking for changes in restriction enzyme digest patterns
C)compare the full DNA sequences of two individuals
D)prepare DNA for further sequence analysis
E)treat sickle-cell anemia

A)identify a species
B)distinguish between two individuals of the same species
C)examine the DNA sequences encoding for human fingerprints
D)extract DNA samples from human fingerprints
E)determine the sequence of the human genome

A)to remove the mitochondrial DNA of the egg donor
B)to test whether the genetic contribution from a sperm cell alone could produce a lamb
C)to create a cloned sheep in the absence of DNA
D)since the genome for the clone was supplied by the diploid mammary cell, the presence of the egg cell DNA would result in triploidy
E)to see whether egg cell DNA injected into a sperm cell could produce a lamb

A)never elicit an immune response in the host
B)retain their intact genome plus the therapeutic gene of interest
C)can correct a gene mutation through homologous recombination
D)are inefficient at delivering therapeutic genes of interest to the cell
E)are seldom used because they have the tendency to cause disease

A)A SNP locus typically has more than two alleles.
B)SNPs are typically used as markers of a region of the genome.
C)The frequency of the rarer SNP allele must be less than 1%.
D)SNPs are the least common form of human genetic variation.
E)If only two alleles are associated with a SNP, both must have relatively the same frequency in the population.

A)express the enzyme degraded by Roundup at high levels so that not all of the enzyme is inhibited
B)have an extra coating outside their cell wall that inhibits Roundup from entering the cells
C)contain a bacterial version of the chloroplast enzyme inhibited by Roundup
D)produce a compound that degrades Roundup
E)do not have the membrane channels through which Roundup enters the plant

A)13 different noncoding loci are examined
B)13 different coding loci are examined
C)only loci that do not vary among individuals are examined
D)only long tandem repeats loci are examined
E)the sequence of short tandem repeats is determined