Deck 10: Molecular Regulation

A) allow for alterations in DNA sequence by flipping promoters around.
B) allow for coordinated gene expression of related genes on one mRNA controlled by one promoter.
C) do not need ligands and regulatory proteins as single genes would.
D) do not need any modification of the proteins after they are expressed.
E) allow for the bacteria to utilize a wide variety of carbon sources.

A) combines with the repressor and activates the repressor.
B) combines with the repressor and inactivates the repressor.
C) combines with the substrate and blocks induction.
D) combines with the substrate and activates induction.
E) does not combine with, but functions as a chaperone molecule for, the enzyme-substrate complex.

A) tsRNA
B) rRNA
C) tRNA
D) sRNA
E) mRNA

A) binary; addition of more growth media after the fulture reaches stationary phase
B) diauxic; addition of more growth media after the fulture reaches stationary phase
C) binary; addition of a needed vitamin after it runs out
D) diauxic; addition of a needed vitamin after it runs out
E) diauxic; growth on two carbon sources resulting in a lag after the preferred substrate is depleted; new genes are then induced and growth resumes

A) posttranslational control
B) control of transcription
C) alterations of DNA sequence
D) translational control
E) mRNA stability

A) amino acid degradation.
B) amino acid biosynthesis.
C) carbohydrate degradation.
D) carbohydrate biosynthesis.
E) lipid degradation.

A) The leader sequence shown contains codons for the amino acid. When these are low, the ribosome stalls, allowing a hairpin between the two middle regions to form so that the rest of the message can be translated.
B) A repressor protein made of that amino acid will bind to the region and prevent translation when large amounts of the amino acid are present.
C) In the presence of large amounts of the amino acid, the hairpin will wind around the amino acid and prevent further translation.
D) The uridine-rich region has codons for that amino acid; when present, this region will be a terminator region. The hairpins allow for an RNA to bind that then allows translation to occur.
E) Catabolite repressor protein can bind and prevent the hairpins from forming, thus allowing translation to occur.

A) DNA
B) transcriptional regulator
C) RNA
D) ribosome
E) corepressor

A) does not change.
B) grows slowly and then, halfway through, grows faster.
C) grows, levels off, and then grows again.
D) grows more slowly than with glucose alone.
E) grows more quickly than with glucose alone.

A) aporepressor
B) corepressor
C) repressor
D) inducer
E) activator

A) lactose
B) galactose
C) sucrose
D) glucose
E) fructose

A) same
B) opposite
C) forward
D) left
E) right

A) enzyme II glucose is unphosphorylated.
B) cAMP concentrations are low.
C) C-reactive protein levels in the cell are low.
D) inhibition of LacY activity.
E) lactose is kept out of the cell.

A) quorum sensing.
B) phosphorylation cascades.
C) the ability to sense that something inside or around the cell has changed.
D) housekeeping enzymes.
E) increased or decreased gene expression.

A) none
B) one
C) two
D) three
E) four

A) phosphate; sensor domain
B) phosphate; sensor phosphatase
C) phosphate; response regulator
D) magnesium; sensor domain
E) magnesium; response regulator

A) When glucose binds to it, the protein binds to the regulatory sequence and prevents transcription of the target gene.
B) This protein must influence a hairpin sequence and thus fine tunes the operon.
C) In the presence of the end product of the operon, this protein will bind to the regulatory region and acts as an activator.
D) When a ligand is or is not bound, this protein may act as either an activator or repressor.
E) This protein would not have an effect on transcription of the target gene.

A) constitutive.
B) inducible.
C) repressible.
D) derepressible.
E) promotable.

A) Gram-positive; Gram-negative
B) Gram-negative; Gram-positive
C) prokaryotic; eukaryotic
D) prokaryotic; archaean
E) Gram-positive; acid-fast

A) ppGpp
B) ATP
C) cAMP
D) cGMP
E) cdiGMP

A) With the addition of arabinose, AraC no longer dimerizes and will form a large loop by binding to araO and aria, and thus can interact with RNA polymerase to permit transcription.
B) The dimer will form a large loop by binding to araO and aria, and thus can interact with RNA polymerase to permit transcription.
C) With the addition, AraC no longer dimerizes and thus can interact with RNA polymerase to permit transcription.
D) It becomes less flexible, so that a monomer can bind to araI1 and araI2 and interact with RNA polymerase to permit transcription.
E) It becomes more flexible, so that the dimer can bind to araI1 and araI2 and interact with RNA polymerase to permit transcription.

A) recombine specific segments of the DNA of Haemophilus influenzae.
B) recombine specific segments of flagellin genes in Neisseria gonorrhoeae.
C) recombine specific segments of MCP genes in Salmonella enterica.
D) recombine specific segments of flagellin genes in Salmonella enterica.
E) repair damage in DNA.

A) pG.
B) ppG.
C) pppG.
D) pGp.
E) ppGpp.

A) They have a ribosomal-binding site.
B) They occur between genes.
C) They share homology between related species.
D) They can act as antisense RNAs.
E) They play a role in regulating genes involved in oxidative stress, acid resistance, and quorum sensing.

A) tRNA
B) mRNA
C) sRNA
D) rRNA
E) tsRNA

A) downregulation of rRNA synthesis.
B) downregulation of tRNA synthesis.
C) ATP.
D) GTP.
E) a lack of change in gene expression.

A) gene inversion.
B) chemotaxis.
C) outer membrane proteins.
D) sRNA.
E) slipped-strand mispairing.

A) sporulation.
B) attenuation.
C) regulation.
D) activation.
E) phase variation.

A) a type III secretion system in Pseudomonas; NitR
B) a type III secretion system in Pseudomonas; ExsA
C) a type III secretion system in Pseudomonas; YbtA
D) virulence genes and cholera toxin in Vibrio; TxtR
E) virulence genes and cholera toxin in Vibrio; ExsA

A) codes for a sigma factor.
B) prevents CRP interaction with RNA polymerase, thereby blocking its access to the promoter.
C) synthesizes ppGpp.
D) targets mRNAs for degradation.
E) creates an attenuator stem loop.

A) directly control transcription.
B) determine whether transcription can proceed through the genes in the operon.
C) determine whether RNA polymerase can bind.
D) terminate transcription.
E) direct the looping of the DNA that prevents transcription initiation.

A) short repeats allow for slippage of the RNA polymerase during transcription of the affected genes.
B) short repeats allow for slippage of DNA polymerase during replication, which leads to an out-of-frame reading sequence.
C) an invertible promoter slips into different reading frames.
D) the genes coding for lipopolysaccharide in Gram-negative bacteria can be slipped in and out of frame.
E) short repeats slip and turn genes off, but they can never be turned back on.

A) an sRNA is produced that can then be used to turn on genes.
B) an sRNA is produced that can then be used to turn off genes.
C) a sigma factor mRNA is transcribed and forms secondary structures at lower temperatures. When heated, the structures melt and the mRNA for the heat shock sigma factor, rpoH, can be translated.
D) The hairpins contain codons for a needed amino acid. When amino acid is lacking, the ribosome stalls and prevents its formation, thus allowing translation.
E) The hairpins contain codons for needed amino acids. When amino acid is present, the ribosome stalls and prevents the formation of hairpins, thus allowing translation.

A) 10
B) 20
C) 30
D) 40
E) 50

A) enhanced
B) activated
C) degraded
D) protected
E) folded

A) inserted in
B) deleted from
C) folded over
D) folded under
E) bound to

A) They are found mainly at the 3' end of a mRNA.
B) They are capable of binding to a ligand and activating transcription but do not repress transcription.
C) They can control transcription but no translation.
D) Ligands that can bind range from vitamins, amino acids, magnesium, and fluoride.
E) They have no secondary structures involved in their control.

A) ribosomal
B) transfer
C) messenger
D) antisense
E) small

A) phosphorylations
B) methylation
C) feedback inhibition
D) phosphorylation and methylation
E) feedback inhibition, phosphorylation, and methylation

A) knowing the DNA sequence to predict the amino acid sequence
B) predicting the protein sequence by using the mRNA sequence
C) two-dimensional protein gels followed by mass spec of the proteins
D) obtaining cDNA and then probing a DNA microarray
E) digesting a cell extract with trypsin

A) controlling chemotactic activities of a cell.
B) coupling the genetic and biochemical control of a metabolic pathway.
C) timing the events of a developmental cycle.
D) having an influence on nitrogen metabolism.
E) specifically inverting the flagellin genes.

A) Cells are lysed, two-dimensional gels are run, and then spots of protein are run through mass spec. Proteins' peaks are identified.
B) Cells are lysed, two-dimensional gels are run, isobaric tags are added to the proteins, and they are run through a mass spec. Proteins' peaks are identified.
C) Cells are lysed, two-dimensional gels are run, and proteins are digested with trypsin and run through a mass spec. Proteins' peaks are identified.
D) Cells are lysed, proteins are digested with trypsin, and column is used followed by mass spec. Proteins' peaks are identified.
E) Cells are lysed, RNA is purified, cDNA is made, and sequencing is carried out.

A) can be involved in cross-talk between species, including eukaryotes.
B) can be involved in some pathogenesis and biofilm formation.
C) has only one autoinduction system per species.
D) is carried out with an autoinducer such as homoserine lactone.
E) plays a role in some antibiotic production.

A) antibiotics
B) peptides
C) furanosyl borate diester
D) cyclic di-GMP
E) ppGpp

A) It activates the expression of flagellin genes and thus enhances motility.
B) It is found in all microbes: bacteria, archaea, and eukaryotic microbes.
C) The action of diguanylate cyclase produces it.
D) It decreases in level as biofilm is produced.
E) Phosphodiesterase can convert GMP to cyclic di-GMP.

A) RNA is much easier to work with than DNA.
B) using bacterial RNA eliminates the introns they all have.
C) one can get a snapshot of what genes are expressed under some conditions but not others.
D) a transcriptome is more related to the protein.
E) deep sequencing can only be performed on RNA.

A) accumulating inside the cell until enough is present to bind repressor proteins and stop transcription.
B) accumulating inside the cell until enough is present to bind activator proteins and initiate transcription.
C) interacting with small RNAs to either inhibit or enhance transcription.
D) diffusing out of the cell and when a critical cell density is reached, moving back in and binding to a regulatory protein to initiate transcription.
E) being synthesized after glucose is used up, thereby bypassing catabolite repression.

A) They control which form of flagellin is expressed.
B) They change the direction of the flagella from counterclockwise to clockwise and back.
C) They promote longer "tumbles" when a chemoattractant is present.
D) They increase the phosphorylation of CheY so that there are more counterclockwise flagella.
E) They respond to demethylation of methyl-accepting chemotaxis proteins to bring about longer runs.

A) autoinducer.
B) activator.
C) repressor.
D) inducer.
E) corepressor.

A) Proteins are isolated and mass spec is used. Once the proteins are known, the RNA that coded for them can be determined.
B) RNA from a particular growth condition is isolated and converted to cDNA; DNA adapters are added, allowing high-throughput sequencing to be carried out. The genome position of the sequence obtained is then determined using computer software.
C) A DNA microarray is used to find the RNA sequences expressed at that time.
D) One examines the tRNA and rRNA in a given culture in order to study various physiological conditions.
E) One determines the RNA sequence of every gene in the genome and then determines if it is present in a given culture.

A) DNA
B) RNA
C) mRNA
D) cDNA
E) qDNA

A) genome.
B) transcriptome.
C) proteome.
D) holoenzyme.
E) ORF.