Gene Expression PDF

Summary

This document explains gene expression, focusing on how genes are expressed differently (prokaryotes vs. eukaryotes) and factors influencing gene expression. Topics covered include transcription factors, environmental impacts, RNA splicing, translation, and the overall role of gene regulation, including consequences like cancer.

Full Transcript

# Gene Expression

Gene expression is the process of a gene making a protein to produce something functional.

- Not every gene is expressed
- Gene expression has to be regulated
- Certain body parts don't need certain genes codes present in that area, so the gene is not expressed

## Gene Expression in Prokaryotes vs. Eukaryotes

### Prokaryotic
- Only DNA inside, no nucleus
- Transcription and translation just happen
- Control of gene expression affects transcription/translation

### Eukaryotic
- No traveling of DNA outside of the nucleus
- More opportunities for gene regulation

## Gene Expression Involves Transcription

- When an RNA polymerase makes mRNA from DNA template

## Transcription Factors: Regulatory Proteins that affect transcription and translation

- Found in both eukaryotes and prokaryotic cells

### Areas where proteins attach

- **Promoter**: Helps the RNA start transcriptions. Other attach to stop it.
- **Enhancer**: Increases transcription

## Environmental Factors that Affect Gene Expression

- UV light
- Lack of nutrients
- Too much
- **Repressors**: Block the DNA polymerase from performing transcription

## Lac operon
- Attaches to the 'Operator' so RNA polymerase cannot work and protein won't be produced
- When the gene doesn't need to be expressed, it's okay

## Certain genes need to be expressed: Example of Gene Expression

- **Lactose**: Bacteria want to break down the sugar lactose by lactose enzyme

### Repressor

- The repressor has to be removed so the polymerase can undergo transcription.
- Then mRNA is used to produce protein.
- The gene is expressed that contains the enzyme able to break down lactose

### Diagram of Gene Expression

- No lactose: Repressors can block the enzyme from being created. No gene expression.
- Lactose: Repressors can't block the enzyme from being created. Gene expression.

## Gene Regulation in Eukaryotes

### Transcription

- Gene that is made of DNA is "rewritten" to mRNA.
- DNA polymerase makes a copy of the DNA sequence called mRNA.
- mRNA carries the genes' protein information encoded in DNA.

### Post Transcription

- mRNA is made in transcription before translation
- Examination of mRNA strand is done.
- Certain areas of RNA are removed.

### RNA Splicing

- The process of removing introns (gene is cut)
- **Introns**: removed RNA regions.
- **Exons**: regions of mRNA that remain.
- Exons are connected together through splicing
- RNA splicing can affect remaining exons

## Translation

- **eIF-2** helps translation happen
- Making a polypeptide chain of amino acids
- These are then made into protein

### Stages

- **Initiation**: mRNA + ribosomes come together to make the first tRNA
- **Elongation**: Amino acids are brought to ribosome by tRNA.
- **Termination**: Polypeptide chains are released.

### Post-Translation

- Chemicals can be added or removed to proteins.
- Change where/how they function, impacting expression

## Why Gene Expression is Important

- Impacts:
* Height
* Eye color
* Blood type
* Hair color

- Also important when cells in the body aren't functioning correctly.

### Example: Cancer

- Can have expression or none expression of certain genes
- Can hurt situations
- Mutation that increase translation of genes that speed up cell division increases production of cancer cells dividing.

## Genetic Code: the relationship between nucleic acid sequences and amino acid sequences

- **First Letter of Codon**: U, C, A, G
- **Second Letter of Codon**: U, C, A, G
- **Third Letter of Codon**: U, C, A, G

- Each row represents a different amino acid.
- **Stop** codons stop the process of translation.
- **Start** codon begins the process of translation.