Deck 15: Dna Technology and Genomics

A) bacteria are transferred into plasmid cells.
B) viruses are transferred into bacterial cells.
C) plasmids are transferred into bacterial cells.
D) bacteria are transferred into viral cells.
E) plasmids are transferred into viral cells.

A) genome.
B) cDNA.
C) library.
D) chromosomal DNA.
E) Human Genome project

A) that occurs in one species.
B) contained in one chromosome.
C) that would be found in the chromosomes of a typical cell of a particular organism.
D) in a recombinant gene.
E) that codes for functional enzymes in a chromosome of a particular organism.

A) bioengineering.
B) in vitro gene technology.
C) biotechnology.
D) recombinant DNA technology.
E) genetic engineering.

A) complementary; hydrogen
B) circular; covalent
C) palindromic; covalent
D) linear; covalent
E) linear; hydrogen

A) AGCGCT
B) AGCAGC
C) AAAGGG
D) ACACAC
E) AGTCGT

A) prepare for DNA replication.
B) prepare for mitosis.
C) effectively infect other cells.
D) protect it from restriction enzymes.
E) prevent viral DNA from hybridizing with bacterial DNA.

A) They can only handle DNA fragments of up to 10 kb.
B) They are an integral part of all eukaryotic cells.
C) They contain no genetic material of their own so that the cloned fragment is truly isolated.
D) The presence of genes that allow transformed cells to survive on different media.
E) The base sequence of one strand reads the same as its complement.

A) compatible human cells.
B) an antibiotic-resistant strain of E. coli to protect the inserted fragments.
C) antibiotic-sensitive E. coli cells that become antibiotic-resistant if transformed.
D) bacteriophages.
E) mRNA molecules.

A) the same restriction enzyme.
B) different restriction enzymes.
C) the same DNA ligase.
D) different DNA ligases.
E) cosmid cloning vectors

A) that occurs in one species.
B) contained in one chromosome.
C) that would be found in a typical cell of a particular organism.
D) in a recombinant gene.
E) that codes for functional enzymes in a typical cell of a particular organism.

A) viruses that infect bacteria.
B) plasmids that infect bacteria.
C) bacteria that infect other bacteria.
D) enzymes that destroy bacteria.
E) recombinant organisms.

A) plasmid fragments that are spliced into genomic DNA.
B) genomic DNA fragments that are spliced into plasmids.
C) intron fragments that are spliced into plasmids.
D) exon fragments that are spliced into bacterial cells.
E) gene fragments that are spliced into main bacterial chromosome.

A) accommodate DNA fragments up to 23 kb.
B) transport a DNA fragment from the nucleus to the cytoplasm.
C) accommodate DNA fragments up to 10 kb.
D) accommodate fragments up to 350 kb.
E) infect and insert their DNA into bacterial cells.

A) introducing foreign DNA into a microorganism so that it can be replicated.
B) stimulating increased transcription of the appropriate sequence of mRNA.
C) stimulating increased translation of the appropriate DNA molecule.
D) inducing the production of DNA from proteins.
E) stimulating reverse transcription of tRNA.

A) Restriction enzymes prevent the overproduction of mRNA in the bacterial cell.
B) Restriction enzymes attack bacteriophage DNA when it enters the cell.
C) Restriction enzymes promote bonding of the RNA polymerase to the promoter.
D) Restriction enzymes limit the rate of bacterial replication.
E) Restriction enzymes connect Okazaki fragments.

A) bioengineering.
B) genomic studies.
C) fluorescent GloFish.
D) recombinant DNA technology.
E) genetic engineering.

A) vector
B) reverse transcriptase
C) transport molecule
D) genetic probe
E) PCR device

A) bioengineering.
B) in vitro gene technology.
C) genome technology.
D) recombinant DNA technology.
E) DNA sequencing.

A) gel electrophoresis.
B) treatment with restriction enzymes.
C) centrifugation.
D) exposure to high pH.
E) exposure to heat.

A) cDNA library
B) genomic library
C) transgenic mouse
D) Northern blot
E) DNA chip

A) patterns of gene expression only.
B) drug activity only.
C) the identity of disease-causing genes only.
D) patterns of gene expression and also drug activity only.
E) patterns of gene expression, drug activity, and the identity of disease-causing genes.

A) a different; DNA chip
B) the same; DNA chip
C) the same; DNA probe
D) a different; Western blot
E) a different; DNA probe

A) the growth of the plasmid DNA.
B) DNA replication of plasmids outside a host cell.
C) the process of growth and division of the host cell.
D) transformation of bacterial cells.
E) the polymerase chain reaction.

A) arising from one individual bacterium that contained a recombinant plasmid.
B) arising from many individual bacteria, only some of which contain a recombinant plasmid
C) arising from one individual bacterium that does not contain a recombinant plasmid.
D) arising from wild-type bacteria.
E) containing a single bacterium, which contains a recombinant plasmid.

A) comparative genomics.
B) DNA cloning.
C) Western blotting.
D) RNAi
E) gene targeting.

A) Francis Crick.
B) Walter Gilbert.
C) E.M. Southern.
D) Kary Mullis.
E) Leland Hartwell.

A) Jacob.
B) Watson.
C) Hershey.
D) Avery.
E) Sanger.

A) It is difficult to keep the amplified DNA strands intact.
B) PCR works on only some DNA sequences.
C) The amplified product is often degraded.
D) PCR is a slow and inefficient process.
E) PCR is easily contaminated with foreign DNA.

A) produce an RFLP
B) determine the DNA sequence.
C) turn the gene on
D) turn the gene off
E) induce a mutation

A) usually results in mice homozygous for the knock-out gene in every cell.
B) is used to study orthologous genes.
C) measures gene expression activity.
D) is a rapid process.
E) is a technique typically performed in humans.

A) DNA; water solution
B) protein; water solution
C) DNA; nitrocellulose filter
D) RNA; nitrocellulose filter
E) protein; nitrocellulose filter

A) selects against plasmids containing human DNA fragments.
B) selects for plasmids containing particular DNA fragments.
C) selects for bacteria containing plasmids.
D) selects for bacteria lacking plasmids.
E) prevents contamination of the medium.

A) Separation gradient
B) Electrophoresis
C) Selective sorting
D) Cloning
E) PCR

A) sDNA; RNA polymerase
B) cDNA; DNA ligase
C) cDNA; reverse transcriptase
D) sDNA; reverse transcriptase
E) cDNA; DNA polymerase

A) DNA sequencing.
B) DNA electrophoresis.
C) DNA tandem repeats.
D) a polymorphism.
E) DNA profiling.

A) PCR
B) a bacteriophage
C) a reverse transcriptase
D) a DNA ligase
E) a restriction enzyme

A) PCR can be performed with any DNA polymerase.
B) PCR is only useful for amplifying large quantities of DNA in vitro .
C) PCR replicates specific DNA sequences.
D) PCR has not been successful for archaeological and crime scene analyses.
E) PCR utilizes Taq polymerase, which active only at low temperatures.

A) single stranded DNA.
B) DNA synthesized with the use of DNA polymerase.
C) DNA synthesized from and complementary to an mRNA template.
D) introns and exons.
E) genomic DNA

A) Recombinantly produced clotting factor has a longer shelf life than natural clotting factor.
B) Clotting factor isolated from blood can transmit infectious agents present in the donated blood.
C) Clotting factor isolated from human blood is quickly degraded.
D) Recombinantly produced clotting factor is stable at high temperatures.
E) Clotting factor from blood has a lower activity than recombinant clotting factor.

A) recombinant organism.
B) transgene.
C) polymorphism
D) transgenic organism.
E) recombinant.

A) new pathogen
B) new life form
C) inactivated pathogen
D) nonpathogenic vector
E) recombinant vaccine

A) nuclear DNA sequencing.
B) mitochondrial DNA sequencing.
C) STR profiling.
D) DNA ligation.
E) RFLPs.

A) is not attacked by plant immune systems.
B) has been genetically engineered to penetrate the plant cell wall.
C) can directly modify the plant genome.
D) is found naturally in almost all species of plants.
E) is able to transfer a plasmid into host plant cells.

A) double-stranded cDNA; single-stranded mRNA
B) double-stranded mRNA; single-stranded cDNA
C) single-stranded cDNA; single-stranded mRNA
D) single-stranded mRNA; single-stranded cDNA
E) double-stranded cDNA; double-stranded mRNA

A) Animal insulin has a shorter life span than insulin produced using recombinant DNA techniques.
B) Recombinantly produced insulin contains human rather than animal sequences, reducing the chances of an allergic response.
C) Animal insulin is more difficult to purify than recombinantly produced insulin.
D) Recombinantly produced insulin has a much higher activity level.
E) Recombinantly produced insulin is easier to obtain than insulin from animals.

A) RNA copies of DNA; reverse transcription
B) DNA copies of RNA; reverse transcription
C) genetic probes; Southern blotting
D) genetic probes; Northern blotting
E) telomerase; mutagenesis

A) this DNA sequence in the children is a mutation.
B) this DNA sequence in the children is inherited from their mother.
C) this DNA sequence in the children is inherited from their father.
D) this sequence in the children is inherited from both their mother and father.
E) individual F is not the mother of these children.

A) Genetically engineered bacteria cannot survive exposure to UV radiation.
B) Genetically engineered strains of bacteria are strictly regulated, making accidental release unlikely.
C) Genetically engineered strains of bacteria cannot survive exposure to oxygen.
D) Genetically engineered strains of bacteria are poor competitors of wild strains.
E) Genetically engineered strains of bacteria require supplemental nutrients to survive.

A) DNA sequencing.
B) mitochondrial DNA variations.
C) RFLPs.
D) DNA ligation.
E) 13 STR markers.