Deck 11: How Genes Are Controlled

A) activators
B) enhancers
C) transcription factors
D) RNA polymerase

A) an egg yolk inside of an egg.
B) a spoon cradling some peas.
C) thread wrapped around a spool.
D) the candy shell surrounding the chocolate in a piece of M&M candy.

A) repressor that is active when it is alone.
B) repressor that is inactive when it binds to lactose.
C) repressor that is active when it binds to tryptophan.
D) activator that turns the operon on by binding to DNA.

A) Tryptophan will bind to the repressor, and trp enzymes will be produced.
B) Tryptophan will bind to the repressor, and trp enzymes will not be produced.
C) Tryptophan will not bind to the repressor, and trp enzymes will be produced.
D) Tryptophan will bind to the operator, and trp enzymes will be produced.

A) adjacent to the gene that they regulate.
B) required to turn on gene expression when transcription factors are in short supply.
C) DNA sequences to which activator proteins bind.
D) required to facilitate the binding of DNA polymerases.

A) usually occurs in males.
B) is the result of a homozygous recessive condition.
C) results from X chromosome inactivation.
D) is a result of alleles on the Y chromosome.

A) active; lactose
B) inactive; lactose
C) active; tryptophan
D) inactive; tryptophan

A) regulators.
B) operators.
C) activators.
D) repressors.

A) introns.
B) exons.
C) promoters.
D) enhancers.

A) fact that each individual of a species has a unique set of genes.
B) fact that individuals of the same species have different phenotypes.
C) process by which genetic information flows from genes to proteins.
D) flow of information from parent to offspring.

A) can be activated if mutations occur in the active X chromosome.
B) is broken down, and its nucleotides are degraded and reused.
C) is absorbed and used in energy production.
D) becomes a Barr body.

A) are present in all metabolizing cells, but the genes for specialized proteins are expressed only in particular cell types.
B) are present in all metabolizing cells, and the genes for specialized proteins are expressed in all cell types.
C) and the genes for all specialized proteins are expressed in all metabolizing cells.
D) and the genes for all specialized proteins are expressed in all embryonic cells.

A) a transcribed gene only.
B) a promoter only.
C) a regulatory gene only.
D) transcribed genes, an operator, and a promoter.

A) The lac operon is shut off, and the cells will not produce lactose-utilizing enzymes.
B) The trp repressor is activated, and the cells will produce lactose-utilizing enzymes.
C) The trp operon is turned on, but the bacteria will not produce lactose-utilizing enzymes.
D) The trp operon and the lac operon are both switched off.

A) retention of different introns in the final version of the different mRNA strands
B) alternative RNA splicing
C) differentiation
D) addition of different types of caps and tails to the final version of the mRNA strands

A) A nucleosome consists of DNA wound around a protein core of eight histone molecules.
B) DNA packing tends to promote gene expression.
C) Highly compacted chromatin is generally not expressed at all.
D) Prokaryotes have proteins analogous to histones.

A) prevents lactose-utilizing enzymes from being expressed when lactose is absent from the environment.
B) prevents lactose intolerance.
C) prevents lactose-utilizing enzymes from being expressed when lactose is present in the environment.
D) promotes the expression of lactose-utilizing enzymes when lactose is absent from the environment.

A) addition of a nucleotide "cap" to the molecule.
B) addition of a nucleotide "tail" to the molecule.
C) removal of introns from the molecule.
D) removal of exons from the molecule.

A) Additional genetic information for the formation of specialized cells is passed on to the developing embryo via the mother.
B) The descendant cells specialize by a process known as differentiation.
C) The zygote contains all of the genetic information required for the development of many different cell types.
D) Differentiation of the zygote into a multicellular organism results from selective gene expression.

A) the production of genetically identical animals for experimentation
B) cloning mammals for the production of potentially valuable drugs
C) the production of organs in cloned pigs for transplant into humans
D) the reproductive cloning of humans

A) Microarrays enable scientists to determine the activity of thousands of genes at once.
B) Microarrays use tiny portions of double-stranded RNA fragments from a large number of genes.
C) Microarrays are used to determine which genes are active in different tissues or in tissues of different states of health.
D) Microarrays use fluorescently labeled cDNA molecules to identify particular genes expressed at a particular time.

A) by close cell-to-cell contact.
B) through chemical signaling.
C) only if they can touch each other and have merged cell walls.

A) determines which end of the egg will become the head and which end will become the tail.
B) serves as a master control gene that functions during embryonic development by controlling the developmental fate of groups of cells.
C) represses gene transcription and promotes mRNA translation.
D) is found only in adult somatic cells.

A) post-translational editing.
B) signal transduction pathways.
C) protein breakdown.

A) One of the earliest development events is the determination of the head and tail ends of the egg.
B) The location of the head and tail ends of the egg is primarily determined by the location of sperm entry during fertilization.
C) Homeotic genes regulate batteries of other genes that direct the anatomical identity of body parts.
D) Cascades of gene expression routinely direct fruit fly development.

A) adding a cap and tail to RNA
B) DNA packing/unpacking
C) RNA splicing
D) translation

A) The homeotic genes of the regenerating limb are expressed.
B) Certain cells in the limb dedifferentiate, divide, and then redifferentiate to form a new limb.
C) A new salamander develops from the lost limb.
D) The homeotic genes of the regenerating cells turn off.

A) only a tiny fraction of their original set of genes.
B) a complete set of their genes but lose the ability to express most of those genes.
C) a complete set of their genes and retain the ability to express those genes under certain circumstances.
D) the ability to dedifferentiate but then cannot return to their original differentiated state.

A) nucleus.
B) plasma membrane.
C) ER.
D) cytoplasm.

A) DNA.
B) the nuclear envelope.
C) plasma membrane receptors.
D) mRNA.

A) Plant cells do not differentiate even when mature, so any cell can grow into an entire plant.
B) Plant cells can dedifferentiate and give rise to all of the specialized cells required to produce an entire plant.
C) Plant cells can produce genes to replace those lost during development.
D) Plant cells are capable of self-renewal by utilizing cellular components from adjacent cells.

A) are found strictly in multicellular organisms, which require cell-to-cell communication.
B) originally evolved in vertebrates.
C) are mechanisms of communication that probably evolved in ancient prokaryotes.

A) demonstrated that the nuclei from differentiated mammalian cells can retain their full genetic potential.
B) demonstrated that differentiated cells contain only a fraction of their full genetic potential.
C) demonstrated, for the first time, that eggs are haploid and body cells are diploid.
D) revealed that cloned mammals most resemble the egg donor.

A) researchers to induce the production of more mRNA.
B) researchers to artificially turn on gene expression.
C) viruses to stop the production of new proteins.
D) cells to prevent infections from double-stranded RNA viruses.

A) protein activation.
B) protein breakdown.
C) DNA replication.
D) the breakdown of mRNA.

A) regeneration.
B) reproductive cloning.
C) therapeutic cloning.

A) cell receptors that detect transcription factors.
B) the availability of certain "key" nutrients as cells divide.
C) operons.
D) cell-to-cell signaling and signal transduction pathways.

A) microRNA.
B) ribosomal RNA.
C) transfer RNA.
D) messenger RNA.

A) cow
B) human
C) pig
D) cat

A) X-rays.
B) ultraviolet light.
C) alcohol.
D) tobacco.

A) Proto-oncogenes are normal genes with the potential to become oncogenes.
B) Many proto-oncogenes code for growth factors.
C) A mutation must occur in a cell's DNA for a proto-oncogene to become an oncogene.
D) If a proto-oncogene's gene product is produced in smaller quantities, a cell may become cancerous.

A) yes, because all cells in the body express the myosin gene all of the time
B) no, because if the tRNAs do not bind amino acids, then translation cannot occur
C) yes, because the myosin gene will be transcribed in the muscle cell nucleus
D) no, because the myosin mRNA will likely get broken down in the cytoplasm

A) cancer cells don't have mitochondria, so they grow slowly.
B) usually six or more somatic mutations must occur to give rise to the cancer, which takes time.
C) cancer cells have to wait until new blood vessels grow into the area, which takes much time.
D) most cancer mutations interfere with mitosis, so cell division occurs more slowly.

A) because they are fully differentiated.
B) because they lack a complete set of genes.
C) due to their excessive numbers in tissues.
D) because their developmental potential is limited to certain tissues.

A) The cell would divide three times as fast and would lead to cancer.
B) The cell would divide into six daughter cells instead of two and would lead to cancer.
C) The cell would divide with mutated DNA and would lead to cancer.
D) The cell would divide normally or possibly not at all.

A) a male or female "dino-chicken"
B) a male or female normal chicken
C) You can't know for sure because of random fertilization.
D) You can't know for sure because it depends on whether the modified homeotic genes are dominant or recessive.

A) RNA polymerase
B) DNA-bending protein
C) activator protein
D) repressor protein

A) yes, because threonine will not be bound to the repressor, so the repressor will be inactive
B) no, because threonine will not be bound to the repressor, so the repressor will be inactive
C) yes, because threonine will not be bound to the repressor, so the repressor will be active
D) no, because threonine will not be bound to the repressor, so the repressor will be active

A) An activator protein must bind an enhancer.
B) The DNA must physically bend so that the activator is close to the promoter.
C) Transcription factors must bind to the activator and promoter.
D) Transcription will never take place in this specific example.

A) Factors that alter DNA and make cells cancerous are called carcinogens.
B) Mutagens are usually not carcinogens.
C) X-rays and ultraviolet radiation are two of the most potent carcinogens.
D) Eating 20-30 grams of plant fiber daily and reducing the intake of animal fat can reduce your risk of developing colon cancer.

A) causing the production of excessive amounts of relay proteins.
B) causing the production of a faulty protein that is no longer able to inhibit cell division.
C) promoting the expression of mRNA that can interact with DNA, resulting in new mutations.
D) increasing the production of growth hormones, which trigger faster cell cycles.

A) increase protein synthesis by the cell.
B) can improve the chance of avoiding cancer as one ages.
C) can enhance further mutations, which can develop into cancer.
D) disrupt normal regulation of the cell cycle.

A) the conversion of a proto-oncogene to an oncogene
B) mutations in a tumor-suppressor gene
C) the production of more effective tumor-suppressor gene products
D) excessive replication of proto-oncogenes

A) oncogene.
B) tumor-suppressor gene.
C) proto-oncogene.

A) The a and α cells will grow toward each other.
B) The a cell will grow towards the α cell, but the α cell will not grow toward the a cell.
C) The α cell will grow toward the a cell, but the a cell will not grow towards the α cell.
D) The a and α cells will not grow toward each other at all.

A) The pepsin protein is folded properly in the cytoplasm.
B) The chromosome with the pepsin gene is tightly coiled.
C) The pepsin mRNA leaves the nucleus and enters the cytoplasm.
D) Activators and RNA polymerases are abundant in the nucleus.

A) Lactose will bind to the repressor, and lac enzymes will be produced.
B) Lactose will bind to the repressor, and lac enzymes will not be produced.
C) Lactose will not bind to the repressor, and lac enzymes will be produced.
D) Lactose will bind to the operator, and lac enzymes will be produced.

A) a single somatic cell gene mutation.
B) several somatic cell gene mutations.
C) a physical rupture of the colon.
D) a diet high in fiber and low in fat.

A) Embryonic stem cells can give rise to all the different specialized cells in the body.
B) Adult, but not embryonic, stem cells can be grown in laboratory culture.
C) Adult stem cells are present in adult tissues.
D) Adult stem cells are partway along the road to differentiation.

A)

B)

C)

D)

A) would be less likely to become infected because they're grafted onto different rootstocks.
B) would be more likely to become infected, since the pathogen would spread through the soil to the roots of other trees.
C) would be very likely to become infected, because the remaining scions are genetically identical to those that are already infected.
D) There's no way to determine the likelihood of infection, since genetic variability gives all the trees different characteristics.

A) Tryptophan will bind to the repressor, and trp enzymes will be produced.
B) Tryptophan will bind to the repressor, and trp enzymes will not be produced.
C) Tryptophan will not bind to the repressor, and trp enzymes will be produced.
D) Tryptophan will bind to the operator, and trp enzymes will be produced.

A) Legs and eyes will develop normally.
B) Legs will develop where the eyes normally develop.
C) Eyes will develop where the legs normally develop.

A) Use qPCR to measure the initial levels of gene expression in skin cells, treat skin cells with the drug and measure the levels of gene expression, and then compare the two measurements.
B) Use qPCR to measure the levels of gene expression in skin cells after exposure to the drug.
C) Use qPCR to measure the initial levels of gene expression in muscle cells, treat skin cells with the drug and measure the levels of gene expression, and then compare the two measurements.
D) Use qPCR to measure the levels of gene expression in skin cells after exposure to the drug and then add another drug to turn off gene expression and use qPCR to measure the levels of expression.

A) nucleotide, nucleosome, histone, tight helical fiber, chromosome
B) nucleosome, nucleotide, histone, tight helical fiber, chromosome
C) nucleotide, histone, tight helical fiber, nucleosome, chromosome
D) nucleotide, histone, nucleosome, tight helical fiber, chromosome

A) molecule A
B) molecule B
C) molecule C
D) molecule D

A) A normal adult fly will develop.
B) A mutant adult fly will develop that has eyes on its wings.
C) A mutant adult fly will develop that has legs on its head.
D) A mutant adult fly will develop that has no eyes on its head but has eyes on its wings.

A) The offspring will certainly be born with melanoma.
B) There is a chance, but it depends on how serious the mother's melanoma is.
C) There is a chance, but it depends on whether or not the father has melanoma.
D) It is unlikely that the offspring will be born with melanoma.

A) The rootstock suppresses activation of the scion genes, which alters fruit production.
B) The rootstock is unable to perform photosynthesis and so can't produce fruit.
C) Transplanted nuclei from scion cells regulate gene expression in the rootstock.
D) The rootstock regulates gene expression in the scion but contributes no genetic information for fruit production.

A) folding of the hexokinase protein
B) translation of the hexokinase protein
C) transcription of the hexokinase gene

A) The fluorescent signal for myosin is higher than that of actin.
B) The fluorescent signal for actin is higher than that of myosin.
C) The fluorescent signals for myosin and actin are equal.
D) The fluorescent signal for myosin is large and is zero for actin.

A) Cell division will decrease because the mutant form of ras decreases cell division.
B) Cell division will increase because the mutant form of ras increases cell division.
C) The cell will divide normally.
D) The cell will not divide at all unless other proteins that stimulate cell division are present.

A) gas pedal; brakes
B) steering wheel; brakes
C) gas pedal; headlights
D) brakes; gas pedal

A) increase the rate of protein translation.
B) turn off gene expression.
C) prevent chromatin condensation.
D) support DNA replication.

A) DNA unpacking, mRNA transport through nucleus, mRNA splicing, protein modification
B) DNA unpacking, mRNA splicing, translation, protein folding
C) transcription, translation, addition of cap and tail to mRNA, DNA unpacking
D) transcription, mRNA splicing, protein modification, translation

A) The fruits will be large because the trees share the same rootstock.
B) The fruits will be large because all scions produce the same kind of fruits.
C) The fruits will be small because the trees share the same rootstock.
D) There is not enough information to know what the fruit will look like.

A) structure A
B) structure B
C) structure C
D) structure D

A) Muscle cells contain information about muscle proteins but not about skin color.
B) Skin cells contain information about skin color but not about muscle proteins.
C) Muscle cells contain information about skin color but not about muscle proteins.
D) Skin cells and muscle cells each contain information about both muscle proteins and skin color.

A) Cell division will occur normally.
B) Cell division will not occur at all.
C) Cell division will be increased.
D) Cell division will be decreased.