Gene Regulation in Eukaryotic Cells. Gene regulation is complex Regulation, and therefore, expression of a gene is complex. Regulation of these genes.

Slides:

Advertisements

Similar presentations

Control of Eukaryotic Genes

Advertisements

Control of Gene Expression

3B1 Gene regulation results in differential GENE EXPRESSION, LEADING TO CELL SPECIALIZATION.

Gene Regulation and Expression

Section 12 – 5 Gene Regulation

1. What is the Central Dogma? 2. How does prokaryotic DNA compare to eukaryotic DNA? 3. How is DNA organized in eukaryotic cells?

Chapter 19: Eukaryotic Genomes Most gene expression regulated through transcription/chromatin structure Most gene expression regulated through transcription/chromatin.

Control of Gene Expression Eukaryotes. Eukaryotic Gene Expression Some genes are expressed in all cells all the time. These so-called housekeeping genes.

Gene Control Chapter 11. Prokaryotic Gene Regulation Operons, specific sets of clustered genes, are the controlling unit Promoter: sequence where RNA.

Introns and Exons DNA is interrupted by short sequences that are not in the final mRNA Called introns Exons = RNA kept in the final sequence.

Regulation of Gene Expression

Regulation of Gene Expression Eukaryotes

Gene Regulation Gene regulation in bacteria Cells vary amount of specific enzymes by regulating gene transcription – turn genes on or turn genes off.

Chapter 11 Regulation of Gene Expression. Regulation of Gene Expression u Important for cellular control and differentiation. u Understanding “expression”

Genetics: Chapter 7. What is genetics? The science of heredity; includes the study of genes, how they carry information, how they are replicated, how.

Eukaryotic Gene Regulation

Eukaryotic Genome & Gene Regulation The entire genome of the eukaryotic organism is present in every cell of the organism. Although all genes are present,

AP Biology Control of Eukaryotic Genes.

Regulating Eukaryotic Gene Expression. Why change gene expression? Different cells need different components Responding to the environment Replacement.

Section 2 CHAPTER 10. PROTEIN SYNTHESIS IN PROKARYOTES Both prokaryotic and eukaryotic cells are able to regulate which genes are expressed and which.

AP Biology Control of Eukaryotic Genes.

Eukaryotic Genomes  The Organization and Control of Eukaryotic Genomes.

Control of Gene Expression Chapter Proteins interacting w/ DNA turn Prokaryotic genes on or off in response to environmental changes  Gene Regulation:

Regulation and Control of Gene Expression Gene Expression in Eukaryotic Cells  Gene controls govern the kinds and amounts of substances in a cell.

Gene Expression and Regulation

Prokaryotic cells turn genes on and off by controlling transcription.

Controlling Gene Expression

AP Biology Control of Eukaryotic Genes.

GENE REGULATION RESULTS IN DIFFERENTIAL GENE EXPRESSION, LEADING TO CELL SPECIALIZATION Eukaryotic DNA.

3B2: Gene Expression Draw 5 boxes on your paper.

Gene Regulation Bacterial metabolism Need to respond to changes – have enough of a product, stop production waste of energy stop production.

KEY CONCEPT Gene expression is carefully regulated in both prokaryotic and eukaryotic cells. Chapter 11 – Gene Expression.

Regulating Gene Expression To accompany “Regulating Gene Expression” Packet -review packet reading, pictures, and questions.

Control of Gene Expression in Bacteria

Gene Regulation, Part 2 Lecture 15 (cont.) Fall 2008.

Gene Expression: Prokaryotes and Eukaryotes AP Biology Ch 18.

Molecular Genetics: Part 2B Regulation of metabolic pathways:

Regulation of Gene Expression

Eukaryotic Genome Control Mechanisms for Gene Expression

Eukaryotic Genome & Gene Regulation

Regulation of Gene Expression

Regulation of Gene Expression

Chapter 15 Controls over Genes.

Regulation of Gene Expression by Eukaryotes

Control of Gene Expression

Gene Regulation Ability of an organisms to control which genes are present in response to the environment.

SGN22 Regulation of Eukaryotic Genomes (CH 15.2, 15.3)

Regulation of Gene Expression

Chapter 12.5 Gene Regulation.

Regulation of Gene Expression

Concept 18.2: Eukaryotic gene expression can be regulated at any stage

Gene Regulation.

Daily Warm-Up Thursday, January 9th

Chapter 18: Regulation of Gene Expression

Control of Eukaryotic Genes

Eukaryote Regulation and Gene Expression

Epigenetics Study of the modifications to genes which do not involve changing the underlying DNA

Agenda 3/16 Eukaryotic Control Introduction and Reading

Control of Eukaryotic Genes

Review Warm-Up What is the Central Dogma?

7.2 Transcription & Gene Expression

Genetics and Information

Unit III Information Essential to Life Processes

Chp.19: Eukaryotic Gene Regulation Notes Please Print!

Non coding DNA Coding Not all DNA codes for a polypeptide to be made May have another useful function Non-coding sequences of DNA e.g. STRs Another example:

Prokaryotic (Bacterial) Gene Regulation

13.4 Gene regulation 5/16/19 TB page

Eukaryotic Gene Regulation

Gene Regulation A gene (DNA) is expressed when it is made into a functional product (protein/enzyme)

Presentation transcript:

Gene Regulation in Eukaryotic Cells

Gene regulation is complex Regulation, and therefore, expression of a gene is complex. Regulation of these genes require all of these to interact together –Regulatory genes –Regulatory proteins –Transcription factors

Transcription Factors Transcription factors (proteins) bind to specific DNA sequences and/or other regulatory proteins Some of the these transcription factors are activators, some are repressors

Many things must occur for a gene to be expressed Combination of transcription factors binding to specific DNA sequences at any one time determines how much transcription occurs or doesn’t occur

Some genes are continuously expressed Some genes are always turned “on,” which means they are always expressed (transcription, translation…) –Ribosomal genes –Glycolysis genes

What if we share similar genes with other organisms? Gene regulation leads to some phenotypic differences between organisms with similar genes –Arm bones in humans and front leg bones of dogs –Since we have similar bone structure, this suggests Common ancestry Similar DNA sequences

Transcription factor binding in eukaryotes; influences The interactions of transcription factors with one another or with DNA can be influenced by signals –From within the cell –From outside the cell Signals are integrated at the promoter

DNA-level Regulation Enhancer regions and activator proteins Acetylation of histones Methylation of C’s on DNA

Stimulation of transcription by an enhancer

Transcription-level Regualation Alternative splicing –Varies in different tissues (skin vs. liver vs. lung) RNAi (2006 Nobel Prize in medicine) –siRNA and miRNA 20-ish nucleotides long –Then use of RISC and Dicer Dicer is the enzyme that breaks apart ds RNA

Alternative Splicing

RNAi

Post-Translational Regulation of Expression Modifications of protein –Phosphorylation Targeting specific proteins to be degraded at a certain time

Importance of gene regulation The amount and time of gene expression can be regulated at any one of several steps between the DNA and the final functional gene product

Importance of gene regulation Gene regulation results in differential gene expression. This leads to cell specialization.

Regulation of transcription in eukaryotes