Presentation is loading. Please wait.

Presentation is loading. Please wait.

OPERONS – GENES THAT CODE FOR ENZYMES ON THE SAME PATHWAY ARE REGULATED AS A GROUP.

Published byLinette Clemence Carter Modified over 7 years ago

Similar presentations

Presentation on theme: "OPERONS – GENES THAT CODE FOR ENZYMES ON THE SAME PATHWAY ARE REGULATED AS A GROUP."— Presentation transcript:

1 OPERONS – GENES THAT CODE FOR ENZYMES ON THE SAME PATHWAY ARE REGULATED AS A GROUP

2 Operons  Operons – set of genes coding for enzymes on one metabolic pathway controlled by the same operator  Operator- “on-off” switch for operons that includes regulatory gene (repressor or activators) and promoter region  Bacteria need to be able to turn genes on or off in response to environmental conditions – don’t want to waste energy and material transcribing unnecessary products

3 Fig. 18-UN2 Promoter Genes Genes not expressed Inactive repressor: no corepressor present Corepressor Active repressor: corepressor bound Genes expressed Operator ON-OFF SWITCH IS A PROTEIN REPRESSOR THAT BINDS TO OR COMES OFF DNA IN RESPONSE TO THE BINDING OF A SMALL SIGNAL MOLECULE TO REPRESSOR; WHEN REPRESSOR IS BOUND, RNA POLYMERASE CANNOT TRANSCRIBE GENES.

4 Regulation of Operons  Regulation may be: A) Repressible –default is on, genes can be turned off (repressed) B) Inducible- default is off, genes can be turned on (induced)

5 Repressible vs. Inducible Repressible  Example: Trp operator  Default on – Trp is essential amino acid (ususally need to make)  Regulation controlled by amount of final product in pathway (synthesis or anabolic pathway)  Trp abundant – trp binds to repressor to turn operon off Inducible  Example: Lac operon  Default is off – glucose is preferred sugar source; only use lactose when no glucose is present (rare situation)  Regulation controlled by first reactant in pathway (catabolic or digestion pathway)  Glucose low, lactose high, remove repressor, activate operon

6 Link to Tryp operon animation

7 Fig. 18-3a Polypeptide subunits that make up enzymes for tryptophan synthesis (a) Tryptophan absent, repressor inactive, operon on DNA mRNA 5 ProteinInactive repressor RNA polymerase Regulatory gene Promoter trp operon Genes of operon Operator Stop codon Start codon mRNA trpA 5 3 trpRtrpE trpD trpCtrpB AB CD E

8 Fig. 18-3b-1 (b) Tryptophan present, repressor active, operon off Tryptophan (corepressor) No RNA made Active repressor mRNA Protein DNA

9 Fig. 18-3b-2 (b) Tryptophan present, repressor active, operon off Tryptophan (corepressor) No RNA made Active repressor mRNA Protein DNA

10 Link to Tryp operon video

11 Fig. 18-3 Polypeptide subunits that make up enzymes for tryptophan synthesis (b) Tryptophan present, repressor active, operon off Tryptophan (corepressor) (a) Tryptophan absent, repressor inactive, operon on No RNA made Active repressor mRNA Protein DNA mRNA 5 Protein Inactive repressor RNA polymerase Regulatory gene Promoter trp operon Genes of operon Operator Stop codon Start codon mRNA trpA 5 3 trpR trpE trpD trpC trpB ABC D E SUMMARY TRYP OPERON

12 Operon Review Questions  1) What is an operon?  ANS: Set of genes coding for enzymes on one metabolic pathway controlled by operator  2) What is an operator?  ANS: “on-off” switch for operons that includes regulatory gene (repressor or activators) and promoter region

13 Operon Review Questions  3) Why would a bacterial cell need to control the expression of a gene based on environmental conditions?  ANS: Making proteins costs energy and material resources. Cells only make proteins when the proteins will help the cells survival.  4) In a repressible operon system is the default condition on or off?  ANS: DEFAULT IS ON, SYSTEM CAN BE TURNED OFF  5) In an inducible operon system is the default condition on or off?  ANS: DEFAULT IS OFF, SYSTEM CAN BE TURNED ON

14 Operon Review Questions  In a repressible operon, is the gene expression regulated by the first reactant in the pathway or the final product?  ANS: Final product  In an inducible operon, is the gene expression regulated by the first reactant in the pathway or the final product?  ANS: First reactant

15 Tryp Operon Review Questions  Under what conditions of tryptophan concentration, high or low, do most repressor molecules have tryptophan molecules bound?  ANS: High [Tryp ]  When tryptophan is bound to the repressor is the repressor in an inactive (doesn’t bond to DNA) or active (will bond to DNA) configuration.  ANS: active

16 Tryp Operon Review Questions  What segment of the DNA does the repressor bind to?  ANS: Operator  What is the effect on gene expression when the repressor binds to the operator?  ANS: The binding of the repressor blocks RNA polymerase from transcribing the genes. Therefore no new mRNA transcript will be made and thus protein product will decrease and eventually stop once existing mRNA is degraded.

Download ppt "OPERONS – GENES THAT CODE FOR ENZYMES ON THE SAME PATHWAY ARE REGULATED AS A GROUP."

Similar presentations

AP Biology 2007-2008 Control of Prokaryotic (Bacterial) Genes.

AP Biology Control of Prokaryotic (Bacterial) Genes.
Ch 18 Gene Regulation. Consider: A multicellular organism (Pliny) Do each of his cells have the same genes? Yes, with an exception: germ cells are haploid.

Ch 18 Gene Regulation. Consider: A multicellular organism (Pliny) Do each of his cells have the same genes? Yes, with an exception: germ cells are haploid.
Gene Expression AP Biology.

Gene Expression AP Biology.
DNA, AND IN SOME CASES RNA, IS THE PRIMARY SOURCE OF HERITABLE INFORMATION Noneukaryotic Genetic Information.

DNA, AND IN SOME CASES RNA, IS THE PRIMARY SOURCE OF HERITABLE INFORMATION Noneukaryotic Genetic Information.
Copyright © 2005 Pearson Education, Inc. publishing as Benjamin Cummings Concept 18.4: Individual bacteria respond to environmental change by regulating.

Copyright © 2005 Pearson Education, Inc. publishing as Benjamin Cummings Concept 18.4: Individual bacteria respond to environmental change by regulating.
To understand the concept of the gene function control. To understand the concept of the gene function control. To describe the operon model of prokaryotic.

To understand the concept of the gene function control. To understand the concept of the gene function control. To describe the operon model of prokaryotic.
The Chapter 15 Homework is due on Wednesday, February 4 th at 11:59 pm.

The Chapter 15 Homework is due on Wednesday, February 4 th at 11:59 pm.
Operons. Big picture Prokaryotic control of genome expression Prokaryotic control of genome expression 2 levels of control 2 levels of control  Change.

Operons. Big picture Prokaryotic control of genome expression Prokaryotic control of genome expression 2 levels of control 2 levels of control  Change.
OPERONS: BACTERIAL GENE CONTROL. OPERONS Bacterial cells A group of genes that work together Illustrate how genes expression (“on”) and repression (“off”)

OPERONS: BACTERIAL GENE CONTROL. OPERONS Bacterial cells A group of genes that work together Illustrate how genes expression (“on”) and repression (“off”)
AP Biology 2007-2008 Control of Prokaryotic (Bacterial) Genes.

AP Biology Control of Prokaryotic (Bacterial) Genes.
Differential Expression of Genes  Prokaryotes and eukaryotes precisely regulate gene expression in response to environmental conditions  In multicellular.

Differential Expression of Genes  Prokaryotes and eukaryotes precisely regulate gene expression in response to environmental conditions  In multicellular.
Draw 8 boxes on your paper

Draw 8 boxes on your paper
AP Biology Horizontal gene transfer Transmission of DNA between species  Transformation  Transduction  Conjugation.

AP Biology Horizontal gene transfer Transmission of DNA between species  Transformation  Transduction  Conjugation.
(distal control elements)

(distal control elements)
AP Biology April 12, 2012 BellRinger Quiz  Identify and describe the 3 main parts of an operon Objective  Explain prokaryotic and eukaryotic gene regulation.

AP Biology April 12, 2012 BellRinger Quiz  Identify and describe the 3 main parts of an operon Objective  Explain prokaryotic and eukaryotic gene regulation.
CHAPTER 18  REGULATION OF GENE EXPRESSION 18.1  Bacterial regulation I. Intro A. Genes are controlled by an on/off “switch ” 1. If on, the genes can.

CHAPTER 18  REGULATION OF GENE EXPRESSION 18.1  Bacterial regulation I. Intro A. Genes are controlled by an on/off “switch ” 1. If on, the genes can.
GENE EXPRESSION and the LAC OPERON We have about 42 000 genes inside our DNA that code for proteins. Clearly not all the proteins are needed at the same.

GENE EXPRESSION and the LAC OPERON We have about genes inside our DNA that code for proteins. Clearly not all the proteins are needed at the same.
CAMPBELL BIOLOGY Reece Urry Cain Wasserman Minorsky Jackson © 2014 Pearson Education, Inc. TENTH EDITION CAMPBELL BIOLOGY Reece Urry Cain Wasserman Minorsky.

CAMPBELL BIOLOGY Reece Urry Cain Wasserman Minorsky Jackson © 2014 Pearson Education, Inc. TENTH EDITION CAMPBELL BIOLOGY Reece Urry Cain Wasserman Minorsky.
Gene Regulation.

Gene Regulation.
AP Biology Discussion Notes Monday 3/14/2016. Goals for Today Be able to describe regions of DNA and how they are important to gene expression in Bacteria.

AP Biology Discussion Notes Monday 3/14/2016. Goals for Today Be able to describe regions of DNA and how they are important to gene expression in Bacteria.

Similar presentations

Ads by Google