Deck 12: Biotechnology and Genomics

A) noncoding sections of DNA that consist of two to five bases repeated over and over again
B) coding sections of DNA that consist of two to five bases repeated over and over again
C) noncoding sections of DNA that consist of the same base repeated over and over again
D) noncoding sections of RNA that consist of two to five bases repeated over and over again
E) noncoding sections of DNA that only consist of adenine and guanine

A) to force the cells into G₀ stage so that the nuclei removed from them will respond to cytoplasmic growth signals
B) to force the enucleated egg cell into G₀ stage so that it would accept the donor nucleus
C) to lengthen the telomeres in the donor nucleus
D) to make the nucleus "start over" in the S stage so that the nucleus will be diploid
E) to make the nucleus "start over" in the S stage so that the nucleus will be haploid

A) specialized cell; clone
B) clone; enucleated egg
C) clone; specialized cell
D) embryonic stem cell; adult stem cell
E) enucleated egg; specialized cell

A) cut DNA with restriction enzymes, mix DNA with plasmid DNA, add DNA ligase
B) mix DNA with plasmid DNA, cut with restriction enzymes, add DNA ligase
C) add DNA ligase, cut DNA with restriction enzymes, mix DNA with plasmid DNA
D) mix DNA with plasmid DNA, add DNA ligase, cut with restriction enzymes
E) cut with restriction enzymes, add DNA ligase, mix DNA with plasmid DNA

A) bacteria that undergo mutations frequently
B) bacteria that degrade sludge
C) corn plants that are resistant to herbicides
D) cattle that secrete therapeutic proteins into their milk
E) carrots that produce influenza virus proteins that can be used as vaccines

A) only cells of the root contain the plant's genes.
B) every cell of the root contains all of the plant's genes.
C) plants are easier to clone than animals.
D) carrots may be used for therapeutic cloning.
E) a carrot's roots contain all of the tissues of an adult plant.

A) they only express certain genes.
B) they express all genes.
C) they turn off gene expression once specialized.
D) they may re-enter the cell cycle at any time.
E) they do not express housekeeping genes.

A) an isolated sperm cell.
B) an enucleated egg.
C) an enucleated liver cell.
D) a red blood cell.
E) an enucleated sperm cell.

A) production of many copies of an unknown piece of DNA
B) making copies of a foreign gene for use in making recombinant DNA
C) DNA fingerprinting of a crime scene suspect
D) amplifying mitochondrial DNA sequences
E) linking two DNA molecules together

A) DNA fingerprinting makes use of noncoding sections of DNA that consist of two to five bases repeated over and over again which looks for the number of times such a sequence is repeated.
B) DNA fingerprinting makes use of coding sections of DNA that consist of two to five bases repeated over and over again which looks for the number of times such a sequence is repeated.
C) DNA fingerprinting makes use of noncoding sections of DNA that consist of a single base repeated over and over again which looks for the number of times such a sequence is repeated.
D) DNA fingerprinting makes use of noncoding sections of RNA that consist of two to five bases repeated over and over again which looks for the number of times such a sequence is repeated.
E) DNA fingerprinting makes use of coding sections of RNA that consist of two to five bases repeated over and over again which looks for the number of times such a sequence is repeated.

A) 4096
B) 2048
C) 1024
D) 512
E) 256

A) can produce clones of adult individuals.
B) can be used to produce superior farm animals.
C) can produce specialized cells to treat human disease.
D) can be used to create new species of plants.
E) can produce embryonic stem cells.

A) Embryonic stem cells have longer telomeres and persist for much longer than adult stem cells.
B) Embryonic stem cells are capable of reverting to a G₀ stage when starved.
C) Adult stem cells may become any type of cell, whereas embryonic stem cells may only become adult stem cells first.
D) Embryonic stem cells may become any type of cell, whereas adult stem cells may only become a limited number of cell types.
E) Adult stem cells have more restrictions that prevent them from re-entering the cell cycle at the G₀ stage.

A) Proteomics; bioinformatics
B) Comparative genomics; bioinformatics
C) Genomics; proteomics
D) Proteomics; comparative genomics
E) Comparative genomics; proteomics

A) restriction enzymes
B) DNA ligase
C) DNA helicase
D) vector
E) plasmid

A) cool to allow DNA strands to anneal, heat to allow primer to anneal, cool to allow DNA polymerase to copy DNA.
B) heat to denature DNA strands, cool to allow primer to anneal and to allow DNA polymerase to copy DNA.
C) heat to denature DNA strands and for primer to anneal, cool to allow DNA polymerase to copy DNA.
D) cool to denature DNA strands, heat to allow primer to anneal, cool to allow DNA polymerase to copy DNA.
E) cool to allow primer to anneal, heat to denature DNA strands, cool to allow DNA polymerase to copy DNA.

A) Intergenic DNA may vary from one cell to another in the same individual.
B) The individual has different numbers of the same repeated sequence on each homologous chromosome.
C) The sample is contaminated with the DNA of another individual.
D) Each sister chromatid of a chromosome may contain different numbers of repeats.
E) It is not possible for this to occur.

A) Adult stem cells have a longer lifespan in culture than embryonic stem cells, and would persist for a longer time in the patient's body.
B) Embryonic stem cells would not be able to enter the correct tissue of the patient's body, unlike an adult stem cell.
C) Adult stem cells must be obtained from another individual before being injected into the patient, and would be less likely to be rejected by the patient's body.
D) Embryonic stem cells may stop dividing within the patient's body once injected, unlike adult stem cells.
E) Adult stem cells may be obtained from the patient and would be less likely to be rejected by the patient's body.

A) Modern vertebrate species all evolved from very different ancestral species so there is little similarity between their genomes.
B) Modern vertebrate species all evolved from the same ancestral species but they have changes so that their genomes are very different in modern times.
C) Ancestral species contained very similar genomes but modern vertebrate species have significant differences in their genomes.
D) Modern vertebrate species evolved from the same ancestors and a large portion of their genome is conserved.
E) Neither the ancestral species nor the modern one resemble each other genetically.

A) 85%
B) 90%
C) 98%
D) 45%
E) There is no genetic similarity between humans and mice.

A) The structure and function of cellular proteins and how they interact to contribute to traits.
B) The structure and function of cellular lipids and how they interact to contribute to traits.
C) The structure of carbohydrates and how they are converted into a useable form of energy for the body.
D) The structure of prions and how they can lead to various diseases within the body.
E) The interaction between cellular proteins and how they make up the bulk of the cell membrane.

A) Intergenic DNA may vary from one cell to another in the same individual.
B) The individual has different numbers of the same repeated sequence on each homologous chromosome.
C) The sample is contaminated with the DNA of another individual.
D) Each sister chromatid of a chromosome may contain different numbers of repeats.
E) It is not possible for this to occur.

A) producing high-yield tomato plants.
B) creating pest resistant versions of corn.
C) cleaning up oil spills.
D) generating pharmaceuticals.
E) producing new types of high yield beef.

A) The gene for proper speech development.
B) The gene for smell.
C) The gene for hearing.
D) The gene for blood type.
E) The gene for social behaviors.

A) The development of new drugs for the treatment of disease.
B) The development of new surgical techniques.
C) The development of new transgenic food crops.
D) The development of new transgenic domesticated animals.
E) Genetic alterations to unborn children that will eliminate potential health problems.

A) production of many copies of an unknown piece of DNA
B) making copies of a foreign gene for use in making recombinant DNA
C) DNA fingerprinting of a crime suspect
D) linking two DNA molecules together
E) amplifying mitochondrial DNA sequences

A) between 1 and 6 million years ago
B) between 4 and 9 million years ago
C) between 10,000 and 100,000 years ago
D) approximately 25,000 years ago
E) approximately 12,000 years ago

A) The genome of HIV can now be compared to the human genome to find similarities between the two.
B) Knowing the genome of HIV allows for the manufacture of designer drugs to treat specific strains.
C) Understanding the genetic code of HIV allows scientists to replicate it in the laboratory.
D) Understanding the evolution of HIV in an individual will help scientists understand how the virus responds to different drug regimes and will lead to better treatments.
E) Knowing the proteins produced by HIV will allow the development of drugs to mimic those proteins.

A) bacteria
B) goats
C) cows
D) corn
E) soy beans