(a)
To determine:
The effect on translation process if Initiation factor-3 was removed from the cell-free protein-synthesizing system
Introduction:
Protein synthesis involves translation of mRNA into a protein that requires three complex stages: initiation, elongation, and termination. For the translation process to be completed, it requires several elements, such as ribosomes, tRNA, initiation factor, elongation factor, start codon, stop codon, release factor and so on. The translation process is completed when the ribosome translocates to a stop codon. If any of thesecomponents of translational machinery were omitted then the process of protein synthesis will be affected.
(a)
Explanation of Solution
(a) Initiation factor-3
The process of translation begins with the initiation stage, which requires initiation factors. Initiation factor 3 (IF-3) first come into the role in the translational process, it binds to the small subunit of the ribosome and restricts the association of large ribosomal subunit during initiation. The 30S initiation complex is formed by the binding of mRNA to the 30S ribosomal subunit. Initiation factor 3 attaches to the 30S subunit before the synthesis of the 30S initiation complex. During the last stage of the initiation process, IF-3 detaches from the 30S ribosomal subunit and facilitates the binding of the large ribosomal subunit to form a 70S initiation complex.
Therefore, elimination of IF-3 from cell-free protein synthesizing system would result in the decreased amount of protein synthesis and it also lowers the pace of initiation because more of 30S ribosomal subunit remains bound to the 50S subunit.
(b)
To determine:
The effect on translation process if Initiation factor-2 was removed from the cell-free protein-synthesizing system.
Introduction:
Protein synthesis involves translation of mRNA into a protein that requires three complex stages: initiation, elongation, and termination. For the translation process to be completed, it requires several elements, such as ribosomes, tRNA, initiation factor, elongation factor, start codon, stop codon, release factor and so on. The translation process is completed when the ribosome translocates to a stop codon. If any of thesecomponents of translational machinery were omitted then the process of protein synthesis will be affected.
(b)
Explanation of Solution
(b) Initiation factor-2
The process of translation begins with the initiation stage which requires initiation factors. Initiation factor 2 (IF-2) is a very essential component of translation as the binding of fMet-tRNA with the initiation codon is done through IF-2. If initiation factor 2 is removed from the translational machinery then the process of protein synthesis would terminate. fMet-tRNA would not be transferred to the 30S ribosomal subunit, which prevents the synthesis of the 30S initiation complex, in the absence of IF-2. The translation process will be ceased due to the absence of IF-2.
(c)
To determine:
The effect on translation process if Elongation Factor-Tu was removed from the cell-free protein-synthesizing system.
Introduction:
Protein synthesis involves translation of mRNA into a protein that requires three complex stages: initiation, elongation, and termination. For the translation process to be completed, it requires several elements, such as ribosomes, tRNA, initiation factor, elongation factor, start codon, stop codon, release factor and so on. The translation process is completed when the ribosome translocates to a stop codon. If any of thesecomponents of translational machinery were omitted then the process of protein synthesis will be affected.
(c)
Explanation of Solution
(c) Elongation Factor Tu (EF-Tu)
Elongation is one of the major stages in the synthesis of proteins. Elongation involves the joining of amino acids to produce a polypeptide chain. Elongation process requires several elongation factors. Elongation factor Tu comes into role first, it allows the binding of tRNA to the A site of the ribosome. This elongation factor joins with GTP and further with a charged tRNA to produce a three-part complex.
EF-Tu helps in the elongation of the polypeptide by forming three-part complex, this complex enters into A site of the ribosome where it delivers the charged tRNA. If EF-Tu were omitted from translation machinery then the charged tRNA would not be transferred to the A site of the ribosome and thus the process of translation will stop.
(d)
To determine:
The effect on translation process if Elongation Factor-G was removed from the cell-free protein-synthesizing system.
Introduction:
Protein synthesis involves translation of mRNA into a protein that requires three complex stages: initiation, elongation, and termination. For the translation process to be completed, it requires several elements, such as ribosomes, tRNA, initiation factor, elongation factor, start codon, stop codon, release factor and so on. The translation process is completed when the ribosome translocates to a stop codon. If any of thesecomponents of translational machinery were omitted then the process of protein synthesis will be affected.
(d)
Explanation of Solution
(d) Elongation Factor G (EF-G)
Elongation is one of the major stages in the synthesis of proteins. Elongation involves the joining of amino acids to produce a polypeptide chain. Elongation process requires several elongation factors. Elongation factor-G is required during the translocation of ribosome down the mRNA in
If EF-G component were omitted from translation machinery then the movement of the ribosome along the mRNA will not occur and thus it will prevent the reading of new codons. The elongation of the polypeptide chain will stop and it will hamper the protein synthesis.
(e)
To determine:
The effect on translation process if Release factors was removed from the cell-free protein-synthesizing system.
Introduction:
Protein synthesis involves translation of mRNA into a protein that requires three complex stages: initiation, elongation, and termination. For the translation process to be completed, it requires several elements, such as ribosomes, tRNA, initiation factor, elongation factor, start codon, stop codon, release factor and so on. The translation process is completed when the ribosome translocates to a stop codon. If any of thesecomponents of translational machinery were omitted then the process of protein synthesis will be affected.
(e)
Explanation of Solution
(e) Release factors RF-1, RF-1, and RF-3
Release factors play important role in recognition of termination codon which aids in the ending of the translation process. RF-1 is used to recognize the termination codon UAA and UAG while RF-2 identifies UGA and UAA. RF-1 and RF-1 bind with each other at the A site of the ribosome and promotes the freeing of a polypeptide chain and the cleavage of tRNA at P site of the ribosome. RF-3 binds with GTP and forms RF-3-GTP complex, which binds to the ribosome and results in a conformational change in it. The complex releases the RF-1 or RF-2 from A site of the ribosome, and the tRNA moves to the E site from P site. Finally, the GTP complex is being hydrolyzed and the tRNA is released from the P site. The mRNA is cleaved fromthe ribosome and this marks the termination of the translation process.
(f)
To determine:
The effect on translation process if ATP was removed from the cell-free protein-synthesizing system.
Introduction:
Protein synthesis involves translation of mRNA into a protein that requires three complex stages: initiation, elongation, and termination. For the translation process to be completed, it requires several elements, such as ribosomes, tRNA, initiation factor, elongation factor, start codon, stop codon, release factor and so on. The translation process is completed when the ribosome translocates to a stop codon. If any of thesecomponents of translational machinery were omitted then the process of protein synthesis will be affected.
(f)
Explanation of Solution
(f) ATP
ATP is required for the charging of tRNA with aminoacyl-tRNA synthetase. The coupling of tRNA to its suitable amino acid is termed as tRNA charging which requires ATP. If ATP were omitted from translational machinery, the charging of tRNAs will not occur. If tRNA will not charge then no amino acids will be available for translation and thus protein synthesis will not occur.
(g)
To determine:
The effect on translation process if GTP was removed from the cell-free protein-synthesizing system.
Introduction:
Protein synthesis involves translation of mRNA into a protein that requires three complex stages: initiation, elongation, and termination. For the translation process to be completed, it requires several elements, such as ribosomes, tRNA, initiation factor, elongation factor, start codon, stop codon, release factor and so on. The translation process is completed when the ribosome translocates to a stop codon. If any of thesecomponents of translational machinery were omitted then the process of protein synthesis will be affected.
(g)
Explanation of Solution
(g) GTP
GTP plays a significant role in the process of initiation, elongation, and termination during protein synthesis. If GTP were omitted then the process of protein synthesis will not occur. GTP forms an importantcomplex with the components involves in translation and support the protein synthesis.
Want to see more full solutions like this?
Chapter 15 Solutions
Genetics: A Conceptual Approach 6E w/ SaplingPlus (Six-Month Access)
- Neurons and Reflexes 1. Describe the function of the: a) dendrite b) axon c) cell body d) myelin sheath e) nodes of Ranvier f) Schwann cells g) motor neuron, interneuron and sensory neuron 2. List some simple reflexes. Explain why babies are born with simple reflexes. What are they and why are they necessary. 3. Explain why you only feel pain after a few seconds when you touch something very hot but you have already pulled your hand away. 4. What part of the brain receives sensory information? What part of the brain directs you to move your hand away? 5. In your own words describe how the axon fires.arrow_forwardMutations Here is your template DNA strand: CTT TTA TAG TAG ATA CCA CAA AGG 1. Write out the complementary mRNA that matches the DNA above. 2. Write the anticodons and the amino acid sequence. 3. Change the nucleotide in position #15 to C. 4. What type of mutation is this? 5. Repeat steps 1 & 2. 6. How has this change affected the amino acid sequence? 7. Now remove nucleotides 13 through 15. 8. Repeat steps 1 & 2. 9. What type of mutation is this? 0. Do all mutations result in a change in the amino acid sequence? 1. Are all mutations considered bad? 2. The above sequence codes for a genetic disorder called cystic fibrosis (CF). 3. When A is changed to G in position #15, the person does not have CF. When T is changed to C in position #14, the person has the disorder. How could this have originated?arrow_forwardhoose a scientist(s) and research their contribution to our derstanding of DNA structure or replication. Write a one page port and include: their research where they studied and the time period in which they worked their experiments and results the contribution to our understanding of DNA cientists Watson & Crickarrow_forward
- hoose a scientist(s) and research their contribution to our derstanding of DNA structure or replication. Write a one page port and include: their research where they studied and the time period in which they worked their experiments and results the contribution to our understanding of DNA cientists Watson & Crickarrow_forward7. Aerobic respiration of a protein that breaks down into 12 molecules of malic acid. Assume there is no other carbon source and no acetyl-CoA. NADH FADH2 OP ATP SLP ATP Total ATP Show your work using dimensional analysis here: 3arrow_forwardFor each of the following problems calculate the following: (Week 6-3 Video with 6-1 and 6-2) Consult the total catabolic pathways on the last page as a reference for the following questions. A. How much NADH and FADH2 is produced and fed into the electron transport chain (If any)? B. How much ATP is made from oxidative phosphorylation (OP), if any? Feed the NADH and FADH2 into the electron transport chain: 3ATP/NADH, 2ATP/FADH2 C. How much ATP is made by substrate level phosphorylation (SLP)? D. How much total ATP is made? Add the SLP and OP together. 1. Aerobic respiration using 0.5 mole of glucose? NADH FADH2 OP ATP SLP ATP Total ATP Show your work using dimensional analysis here:arrow_forward
- Aerobic respiration of one lipid molecule. The lipid is composed of one glycerol molecule connected to two fatty acid tails. One fatty acid is 12 carbons long and the other fatty acid is 18 carbons long in the figure below. Use the information below to determine how much ATP will be produced from the glycerol part of the lipid. Then, in part B, determine how much ATP is produced from the 2 fatty acids of the lipid. Finally put the NADH and ATP yields together from the glycerol and fatty acids (part A and B) to determine your total number of ATP produced per lipid. Assume no other carbon source is available. 18 carbons fatty acids 12 carbons glycerol . Glycerol is broken down to glyceraldehyde 3-phosphate, a glycolysis intermediate via the following pathway shown in the figure below. Notice this process costs one ATP but generates one FADH2. Continue generating ATP with glyceraldehyde-3-phosphate using the standard pathway and aerobic respiration. glycerol glycerol-3- phosphate…arrow_forwardDon't copy the other answerarrow_forward4. Aerobic respiration of 5 mM acetate solution. Assume no other carbon source and that acetate is equivalent to acetyl-CoA. NADH FADH2 OP ATP SLP ATP Total ATP Show your work using dimensional analysis here: 5. Aerobic respiration of 2 mM alpha-ketoglutaric acid solution. Assume no other carbon source. NADH FADH2 OP ATP Show your work using dimensional analysis here: SLP ATP Total ATParrow_forward
- Biology You’re going to analyze 5 ul of your PCR product(out of 50 ul) on the gel. How much of 6X DNAloading buffer (dye) are you going to mix with yourPCR product to make final 1X concentration ofloading buffer in the PCR product-loading buffermixture?arrow_forwardWrite the assignment on the title "GYMNOSPERMS" focus on the explanation of its important families, characters and reproduction.arrow_forwardAwnser these Discussion Questions Answer these discussion questions and submit them as part of your lab report. Part A: The Effect of Temperature on Enzyme Activity Graph the volume of oxygen produced against the temperature of the solution. How is the oxygen production in 30 seconds related to the rate of the reaction? At what temperature is the rate of reaction the highest? Lowest? Explain. Why might the enzyme activity decrease at very high temperatures? Why might a high fever be dangerous to humans? What is the optimal temperature for enzymes in the human body? Part B: The Effect of pH on Enzyme Activity Graph the volume of oxygen produced against the pH of the solution. At what pH is the rate of reaction the highest? Lowest? Explain. Why does changing the pH affect the enzyme activity? Research the enzyme catalase. What is its function in the human body? What is the optimal pH for the following enzymes found in the human body? Explain. (catalase, lipase (in your stomach),…arrow_forward
Human Anatomy & Physiology (11th Edition)BiologyISBN:9780134580999Author:Elaine N. Marieb, Katja N. HoehnPublisher:PEARSON
Biology 2eBiologyISBN:9781947172517Author:Matthew Douglas, Jung Choi, Mary Ann ClarkPublisher:OpenStax
Anatomy & PhysiologyBiologyISBN:9781259398629Author:McKinley, Michael P., O'loughlin, Valerie Dean, Bidle, Theresa StouterPublisher:Mcgraw Hill Education,
Molecular Biology of the Cell (Sixth Edition)BiologyISBN:9780815344322Author:Bruce Alberts, Alexander D. Johnson, Julian Lewis, David Morgan, Martin Raff, Keith Roberts, Peter WalterPublisher:W. W. Norton & Company
Laboratory Manual For Human Anatomy & PhysiologyBiologyISBN:9781260159363Author:Martin, Terry R., Prentice-craver, CynthiaPublisher:McGraw-Hill Publishing Co.
Inquiry Into Life (16th Edition)BiologyISBN:9781260231700Author:Sylvia S. Mader, Michael WindelspechtPublisher:McGraw Hill Education