Deck 11: Gene Expression and Epigenetics

A)gene expression profiles depict the relative locations of genes on chromosomes,and classic gene maps show the increase and decrease of transcription with time or in different tissues.
B)gene expression profiles depict the increase and decrease of transcription with time or in different tissues,and classic gene maps show the relative locations of genes on chromosomes.
C)gene expression profiles measure DNA,and classic gene maps size-order the chromosomes.
D)gene expression profiles sequence genomes,whereas classic gene maps do not actually sequence the DNA.

A)isolated amino acids and tRNAs.
B)specific classes of proteins and RNA molecules.
C)specific classes of lipids and carbohydrates.
D)nicotine and alcohol.

A)a fetus has four alpha globin chains and a newborn has four beta globin chains.
B)a fetus's blood is clear until the sixth month and then globin chains turn it red.
C)the newborn needs more iron than the fetus or embryo.
D)the embryo and fetus receive different concentrations of oxygen compared to after birth.

A)5 to 10
B)20 to 30
C)50 to 60
D)80 to 90

A)stem cells.
B)progenitor cells.
C)differentiated cells.
D)blood cells.

A)finding that a child has inherited a certain genotype.
B)identifying genes with aberrant expression levels in cancers likely to spread.
C)determining whether a medical condition is inherited or not.
D)replacing a gene bearing a mutation with a wild type version in the affected tissue.

A)"inside the gene."
B)"inside the protein."
C)"outside the gene."
D)"outside the protein."

A)pass from one cell generation to the next but do not alter the DNA sequence.
B)do not pass from one cell generation to the next but do alter the DNA sequence.
C)irreversibly alter the DNA sequence and are only passed to the next cell generation if they add an advantage.
D)alter the RNA codon,which are amino acid assignments of the genetic code.

A)insulin is produced and bathes stem cells.
B)a transcription factor stimulates progenitor cells to give rise to exocrine or endocrine cells.
C)a globin gene duplicates and gives rise to alpha and beta globin genes.
D)progenitor cells become stem cells.

A)epsilon
B)zeta
C)beta
D)alpha

A)restless legs syndrome.
B)male infertility.
C)endometriosis.
D)diabetes mellitus.

A)two alpha chains
B)two beta chains
C)two zeta chains
D)two epsilon chains

A)genome
B)lipidome
C)proteome
D)glycome

A)transcription;translation
B)translation;transcription
C)synthesis of tRNAs;synthesis of rRNAs
D)DNA replication;DNA repair

A)deleting a gene for a clotting factor.
B)blocking transcription of a clotting factor.
C)increasing susceptibility to a specific viral infection.
D)increasing the transcription rate of a particular clotting factor gene.

A)alpha
B)gamma
C)delta
D)epsilon

A)the changes would be passed on to daughter cells.
B)it would change the number of copies of a gene that people inherit.
C)it would change the expression of many other genes.
D)the changes would be epigenetic.

A)many cells have already died in a 20-year-old.
B)a fetus does not yet need many of its proteins.
C)cells are actively differentiating,and many structures are forming in a fetus.
D)an adult can carry out more activities than can a fetus.

A)two epsilon chains and two zeta chains.
B)two gamma chains and two alpha chains.
C)two gamma chains and two beta chains.
D)one alpha chain,one beta chain,one epsilon chain,and one gamma chain.

A)mRNA.
B)the DNA sense strand.
C)the amino acid lysine.
D)microRNAs.

A)are male sex hormones.
B)are inert spool-like structural supports around which DNA winds.
C)control gene expression through chemical interactions that expose parts of the DNA to transcription factors,while shielding other parts.
D)bind to mRNAs,preventing their translation into protein.

A)tRNAs.
B)pseudogenes.
C)snoRNAs.
D)microRNAs.

A)A hammer and a nail
B)An on/off switch and a dimmer switch
C)An elevator and a submarine
D)An activator and a repressor

A)not transcribed.
B)transcribed but not translated.
C)transcribed and translated.
D)rare in the human genome.

A)genome.
B)lipidome.
C)proteome.
D)transposon.

A)0.5
B)1.5
C)5.0
D)10
E)100

A)one copy of each of 3.2 billion different microRNAs.
B)one copy of each of about 20,000 different microRNAs.
C)from 1,000 to 200,000 microRNAs.
D)no microRNA unless the person develops cancer.

A)technologies that sequence DNA at very low temperatures.
B)different types of RNA molecules.
C)different versions of proteins that reflect different exon combinations.
D)the patterns of acetyls,phosphates,and methyl groups that bind to a particular gene.

A)a microRNA that binds the wrong set of mRNA targets.
B)unstable transposons.
C)fetal hemoglobin that is reactivated in a child.
D)abnormal methylation of a gene expressed in the brain.

A)4
B)8
C)12
D)21

A)the 3' ends of specific mRNAs.
B)the 5' ends of specific rRNAs.
C)the 3' ends of specific tRNAs.
D)the 4' ends of specific mRNAs.

A)acetyl.
B)methyl.
C)ethyl.
D)phosphate.

A)tRNAs.
B)rRNAs.
C)HERVs.
D)mRNAs.

A)2 or 4
B)12 or 13
C)21 or 22
D)100 or 110

A)microRNAs can be rRNA,mRNA,or tRNA.
B)they range in size from 10 to 10,000 bases.
C)a microRNA type can bind several mRNAs,and an mRNA can bind several microRNAs.
D)it can be acetylated,phosphorylated,or methylateD.

A)intron shuffling.
B)alternate splicing.
C)chain switching.
D)chromatin remodeling.

A)10
B)40
C)75
D)90

A)0.001
B)0.01
C)0.1
D)1