Brock Biology of Microorganisms (15th Edition)
15th Edition
ISBN: 9780134261928
Author: Michael T. Madigan, Kelly S. Bender, Daniel H. Buckley, W. Matthew Sattley, David A. Stahl
Publisher: PEARSON
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Textbook Question
Chapter 10, Problem 1AQ
Not all proteins are made from the RNA genome of bacteriophage MS2 in the same amounts. Can you explain why? One of the proteins functions very much like a repressor, but it functions at the translational level. Which protein is it and how does it function?
Expert Solution & Answer
Summary Introduction
The RNA bacteriophage are very small, around 25 nm in diameter with icosahedral virion structure. For example, MS2 (having positive strand RNA) virus has a small genome, which encodes only four types of proteins. These are 1) Mutation proteins, which are present as a single copy in a mature virion, 2) coat protein, 3) lysis protein and 4) subunit of RNA replicase (it is the enzyme, which replicates the viral RNA). RNA replicase protein consists of one virus encoded polypeptide and many peptides of the host.
Explanation of Solution
The RNA of phage MS2 is folded in a complicated way, thereby, leading to formation of an extensive secondary structure. The translation at coat protein site on m-RNA starts very early upon viral infection, as it is most accessible to translation machinery among the four AUG translation sites. The m-RNA replicase enzyme also translate early. Since coat proteins translate early, they start increasing in number in number within the cell. Coat proteins start binding to RNA at AUG region, which is the initiation site for replicase protein and shit down the production of replicase. Therefore, coat protein also acts like a repressor protein. Also due to extensive folding of RNA limited copies maturation protein is produced even though it is present at 5’ end. Thus translation regulation occurs due to the folding of RNA, thereby, producing limited proteins for viral assemble. Coat protein, however is required in large quantity, therefore it is majorly produced.
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(c) By binding one L-tryptophan molecule/monomer, the trp repressor binds to DNA to suppress syn-
thesis of L-tryptophan in E. coli. Below is the amino acid sequence of the helix – (reverse) turn – helix
region of the trp repressor that binds to DNA compared to the sequence of the corresponding DNA
binding motif of the Prl protein, a different type of repressor protein. A diagram of the trp repressor
dimer is also shown.
reverse turn
trp helix 4
70
Trp
-Gly-Glu-Met-Ser-Gln-Arg-Glu-Leu-Lys-Asn-Glu-Leu-Gly-Ala-Gly-
Ile-
Prl
-Ser-Glu-Glu-Ala-Lys-Glu-Glu-Leu-Ala-Lys-Lys-Cys-Gly-Ile-Thr-
Val-
Pri heilix
trp helix 5
80
90
Trp
Ala-Thr-Ile-Thr-Arg-Gly-Ser sgn-Ser-Leu-Lys-Ala-Ala-
Prl
Ser-Gln-Val-Ser-Asn-Trp-Phe-Gly-Asn-Lys-Arg-Ile-Arg-
Prl helix
A mutation is found in a tRNA-encoding gene. The wild type (non-mutant) allele (version) produces a tRNA that recognizes the codon GAA, and is charged with the amino acid glutamic acid (Glu). The mutant tRNA is still charged with Glu, but it recognizes the codon UAA. What effect will this have on translation in these cells? How will the proteins produced be different?
Speculate: is this mutation more likely to be beneficial or harmful?
Knowing that the genetic code is almost universal, a scientist uses molecular biological methods to insert the human β-globin gene (Shown in Figure 17.11) into bacterial cells, hoping the cells will express it and synthesize functional β-globin protein. Instead, the protein produced is nonfunctional and is found to contain many fewer amino acids than does β-globin made by a eukaryotic cell. Explain why.
Chapter 10 Solutions
Brock Biology of Microorganisms (15th Edition)
Ch. 10.1 - Distinguish between a positive-strand RNA virus...Ch. 10.1 - Prob. 2MQCh. 10.1 - Prob. 3MQCh. 10.1 - Describe the classes of viruses based on their...Ch. 10.2 - Prob. 1MQCh. 10.2 - Prob. 2MQCh. 10.2 - Prob. 3MQCh. 10.2 - Prob. 1CRCh. 10.3 - Prob. 1MQCh. 10.3 - In the X174 genome, describe the difference...
Ch. 10.3 - Prob. 3MQCh. 10.3 - Describe how the genome of bacteriophage X174 is...Ch. 10.4 - In what major way does transcription of phage DNA...Ch. 10.4 - Prob. 2MQCh. 10.4 - Why can it be said that transcription of the...Ch. 10.5 - What type of genome is seen in most archaeal...Ch. 10.5 - Compared with other archaeal viruses, what are two...Ch. 10.5 - Prob. 1CRCh. 10.6 - Prob. 1MQCh. 10.6 - Prob. 2MQCh. 10.6 - Prob. 3MQCh. 10.6 - Prob. 1CRCh. 10.7 - Prob. 1MQCh. 10.7 - Prob. 2MQCh. 10.7 - Prob. 3MQCh. 10.7 - Prob. 1CRCh. 10.8 - Prob. 1MQCh. 10.8 - Prob. 2MQCh. 10.8 - How are protein synthesis and genomic replication...Ch. 10.8 - Prob. 1CRCh. 10.9 - Prob. 1MQCh. 10.9 - Prob. 2MQCh. 10.9 - Prob. 3MQCh. 10.9 - Rabies virus and poliovirus both have...Ch. 10.10 - Prob. 1MQCh. 10.10 - Prob. 2MQCh. 10.10 - Prob. 3MQCh. 10.10 - Prob. 1CRCh. 10.11 - Prob. 1MQCh. 10.11 - Prob. 2MQCh. 10.11 - How does the role of reverse transcriptase in the...Ch. 10.11 - Why do both hepadnaviruses and retroviruses...Ch. 10.12 - What type of bacteriophages are most common in the...Ch. 10.12 - Prob. 2MQCh. 10.12 - Prob. 3MQCh. 10.12 - Prob. 1CRCh. 10.13 - Prob. 1MQCh. 10.13 - Prob. 2MQCh. 10.13 - Prob. 3MQCh. 10.13 - Prob. 1CRCh. 10.14 - Prob. 1MQCh. 10.14 - Prob. 2MQCh. 10.14 - Prob. 3MQCh. 10.14 - How do bacterial viruses help prevent human...Ch. 10.15 - If viroids are circular molecules, why are they...Ch. 10.15 - Prob. 2MQCh. 10.15 - Prob. 1CRCh. 10.16 - Prob. 1MQCh. 10.16 - Prob. 2MQCh. 10.16 - Prob. 3MQCh. 10.16 - What are the similarities and differences between...Ch. 10 - Not all proteins are made from the RNA genome of...Ch. 10 - Replication of both strands of DNA in adenoviruses...Ch. 10 - Imagine that you are a researcher at a...Ch. 10 - Prob. 4AQ
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- The genetic code is thought to have evolved to maximize genetic stability by minimizing the effect on protein function of most substitution mutations (single-base changes). We will use the six arginine codons to test this idea. Consider all of the substitutions that could affect all of the six arginine codons.(a) How many total mutations are possible?(b) How many of these mutations are “silent,” in the sense that the mutantcodon is changed to another Arg codon?(c) How many of these mutations are conservative, in the sense that an Argcodon is changed to a functionally similar Lys codon?arrow_forwardYou’re going for a bike ride, and as your muscles work harder, your body needs to produce more of the enzyme. You now know genes are transcribed from DNA into RNA in the nucleus and translated from RNA into proteins by ribosomes. Explain the steps of its creation from DNA to protein. Aside for having a nasty inhibitor around like the one from that insecticide, how else might an enzyme end up being non-functioning? During transcription, a base substitution occurred. Explain two reasons why this change in nucleotide sequence could result in no change to the protein.arrow_forwardThe E. coli genome contains approximately 4639 kb. (a) How many copies of the 6-bp recognition sequence for the trp repressor would be expected to occur in the E. coli chromosome? (b) Explain why it is advantageous for the trp repressor to be a dimer that recognizes two adjacent 6-bp sequences.arrow_forward
- A mutation is found in a tRNA-encoding gene. The wild type allele produces a tRNA that recognizes the codon GAA, and is charged with the amino acid Glutamic acid. The mutant tRNA is still charged with Glu, but the anticodon is mutated such that it recognizes the stop codon TAA. What effect will this have on translation in these cells? Select all that apply In the mutant cells, the stop codon TAA will always be bound by the release factors In the mutant cells, some of the synthesized proteins will be longer. O In the mutant cells, the stop codon TAA will sometimes be bound by the mutant TRNA charged with Glutamic acid. O In the mutant cells, some of the synthesized proteins will be shorter.arrow_forwardin a clever experiment performed in 1962, a cysteine already attached to its tRNA was chemically converted to an alanine. these “hybrid” tRNA molecules were then added to a cell- free translation system from which the normal cysteine-tRNAs had been removed. When the resulting protein was analyzed, it was found that alanine had been inserted at every point in the polypeptide chain where cysteine was supposed to be. Discuss what this experiment tells you about the role of aminoacyl- tRNA synthetases during the normal translation of the genetic code.arrow_forwardThe following fictitious double-stranded bacterial DNA sequence codes for a fictitious protein. Both strands are shown; the top strand reads 5' to 3' left to right, while the bottom strand reads 5' to 3' right to left. Transcription begins with and includes the red underlined A/T (top strand/bottom strand) base pair. This is a bacterial sequence, so there are no introns. 5'GTGTCCGTATGATATTGTGAGATGTTATATCCCGCCGTCAACACCATAAAACAGGATAATCGCCTGCTGGGGCAAAGGCGGTGAAGGTAAAGGTGTTGCC 3′ 3' CACAGGCATACTATAACACTCTACAATATAGGGCGGCAGTTGTGGTATTTTGTCCTAT TAGCGGACGACCCCGTTTCCGCCACTTCCATTTCCACAACGG 5′ a) Which strand is used as a template for transcription, the top or the bottom? b) What are the first 15 nucleotides of the resulting mRNA? Indicate the 5' and 3' ends. c) What is the translation of the first 15 nucleotides of the mRNA? d) Do the underlined nucleotides TAA encode a stop codon for the protein? Explain. e) A mutation occurs which results in the insertion of an extra G/C (top strand/bottom…arrow_forward
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- Which statement is false: A) Each type of protein ( ex: hemoglobin vs trypsionngen) varies in the length and amino acid sequence of its peptide B) After the rpocess of transcription is complete, the mRNA that is produced will continue being tranlsated by ribosomes for the rest of the cells life. mRNA never breaks down C) A ribosome will bind to an mRNA and will translate the sequence by reading one codon at a time and adding one amino acid to the peptide chain. It will stop the translation once it encounters a stop codon D) The gene for a protein provides the information on the legth of the peptide, along w the amino acid sequence so the protein can be synthesized by a ribosome E) Once mRNA has left the nucleus, ribosomes will bind to it and will follow the instructions in its sequence to make the new protienarrow_forwardThis sequence given is of one strand of eukaryotic DNA containing a hypothetical gene. The base that is first (at the 5' end) in the sequence is at position -25. The translational start site is the first initiating codon encountered after the transcriptional start. This gene has three exons. The last base of the first exon is the A at position +30; the first base of the second exon is the C at position +62; the last base of the second exon is the A at position +82; the first base of the third exon is the G at position +118; and the last base of the third exon is for you to determine. Determine, and show, the sequence of the polypeptide produced by this gene in this format: Met-Thr-Trp-Tyr-Val etc. 5'-TATATACGTC CTATCGATGC ATCGTGTACG TAGCTAGGGG ATGCATGAAG TCACAGTAGC TAGCTATGGC TGATCGATCG TTGTGGCTTA AATATTGCGC TGGACTAGGA AAAGCTCGCA GGTACCCGAT CGATCCCGTG GAGTTCCAAG TTAGGATCTA CTTTAGCTAG TTTTAGCGGA ATAAAGATCG ATTATAGCTG AGAGATAAGC GTGGGTTGAT GATCGTAGCT AGCTAGCTAG CTAGCATCGA-3'arrow_forwardSome of the mutations of the type mentioned in Problem 28 have an interesting property: they prevent the formation of the antiterminator that normally takes place when the tryptophan level is low. In one of these mutations, the AUG start codon for translation of the 5′ UTR has been deleted. How might this mutation prevent antitermination from taking place?arrow_forward
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