2. Assume you have identified a new operon in bacteria (which you call the suc operon) thatencodes enzymes required for catabolism of the sugar sucrose. The structural genes that arerequired to breakdown sucrose are transcribed from a promoter (Psuc). One of theseenzymes is encoded by the sucS gene. Expression of the operon is controlled by a regulator,called SucR, which binds to an operator (O). Using your knowledge of the lac operon,interpret the results of the following experiments (Table 1) to propose a model describinghow the sucrose operon might be regulated.Cell genotypeProduction of SucS enzymeWithout sucroseWith sucroseR* O* P* s*R O* p* s*++R* O P* S*--RO* p* s* / R* Oʻ p* 5R° O* p* S++--++++Table 1. Production of SucS enzyme in various strains. “-" in the cell genotype indicates a lossof function mutation, “+" indicates wild type function, two genotypes separated by a /indicate a merodiploid or partial diploid. R° is a mutant version of SucR that always binds toO. Production of SucS enzyme is indicated with “++", and no expression with “–". You mayinclude diagrams in your answer.

Gene expression in prokaryotes is under the control of an operon system in which the transcription…

Answered: 2. Assume you have identified a new…

Biochemistry

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ISBN:9781319114671

Author:Lubert Stryer, Jeremy M. Berg, John L. Tymoczko, Gregory J. Gatto Jr.

Publisher:Lubert Stryer, Jeremy M. Berg, John L. Tymoczko, Gregory J. Gatto Jr.

Chapter1: Biochemistry: An Evolving Science

Section: Chapter Questions

Problem 1P

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2. Assume you have identified a new operon in bacteria (which you call the suc operon) that encodes enzymes required for catabolism of the sugar sucrose. The structural genes that are required to breakdown sucrose are transcribed from a promoter (Psuc). One of these enzymes is encoded by the sucS gene. Expression of the operon is controlled by a regulator, called SucR, which binds to an operator (0). Using your knowledge of the lac operon, interpret the results of the following experiments (Table 1) to propose a model describing how the sucrose operon might be regulated. Cell genotype Production of SucS enzyme Without sucrose With sucrose R* o* p* s* R O* p* s* R* O P* s* ++ -- -- -- --- -- RO* p* s* / R* o* p* s R° O* p* s ++ -- ++ ++ Table 1. Production of SucS enzyme in various strains. "-" in the cell genotype indicates a loss of function mutation, "+" indicates wild type function, two genotypes separated by a/ indicate a merodiploid or partial diploid. R° is a mutant version of…
1. The lactose operon is controlled by both lactose and glucose. Fill in the following table to indicate what would be occurring under different cellular conditions Lactose absent present absent present Glucose Operon Activity (high/low) absent absent present present low high 10W high CAMP Repressor (bound/free) (high/low) bound free buind will high high low CAP (bound/free) bound free full
Like the lac operon, the hexose operon is controlled by a separate regulatory protein under the control of its own promoter (see the schematic of the operon below). The hexose regulatory protein is sensitive to fatty acyl CoA levels. When all hexose fuel sources are depleted, the bacteria switch to lipid metabolism and fatty acyl CoA levels increase. This turns expression of the hexose operon off. +1 +1 Regulatory Gene P regulator Hexose Operon Genes operon regulator promoter operon promoter e. The regulatory protein that controls expression of the hexose operons is a transcriptional ACTIVTOR or REPRESSOR (circle one).
1. Describe which enzymes are required for lactose and tryptophan metabolism in bacteria when lactose and tryptophan, respectively, are (a) present and (b) absent. 2. Contrast positive versus negative regulation of gene expression. Describe the role of the repressor in an inducible system and in a repressible system.
47.
1. (a) Lactose levels are high Lac Operon Genes are switched OFF Lac Operon Genes are switched ON Does NOT affect the gene expression (b) Enhancer and activator proteins are working together Gene is switched ON Gene is switched OFF Does NOT affect the gene expression
6. please match each of the item
1. Please tell me: What's a mutation in moleculer terms? 2. When a mutation deletes a base in genomic DNA, how does it affect the expression product production and reading frame? 3. How does induction control enzyme synthesis using lactose operon?
28. Which statement does NOT explain why the lac operon would not be effectively regulated by an attenuation mechanism like the trp operon? 1.Lactose is a substrate for the lac operon protein products. 2.Products of lac operon enzymes are not used in protein synthesis. 3.Transcription and translation do not happen simultaneously for the lac operon. 4.Attenuation is a suitable regulatory mechanism for anabolic amino acid pathways. 5.All of these statements explain why regulation by attenuation would not be effective for the lac operon.
Like the lac operon, the hexose operon is controlled by a separate regulatory protein under the control of its own promoter (see the schematic of the operon below). The hexose regulatory protein is sensitive to fatty acyl CoA levels. When all hexose fuel sources are depleted, the bacteria switch to lipid metabolism and fatty acyl CoA levels increase. This turns expression of the hexose operon off. +1 +1 Regulatory Gene Pregulator P operon Hexose Operon Genes regulator promoter operon promoter
Match each description with the appropriate label (allo)Lactose binds to the lac repressor, causing it to release from the promoter CAP binds CAMP to stimulate transcripti of the lac operon ✓ [Choose ] positive control of an inducible gene negative control of an inducible gene [Choose]

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