Showing posts with label Protein. Show all posts
Showing posts with label Protein. Show all posts

Thursday, 19 September 2024

New Video: Tagging and Labelling Proteins for Purification and Tracking

In this video - Tagging and Labelling Proteins for Purification and Tracking - I look at why we tag proteins and the methods we use to add a tag to a protein.

The Basics of Protein Tagging and Purification: A Lab Guide

During my career, I have had to produce and purify proteins in the lab, which can be challenging.

In the lab, we tag and purify proteins to understand what a protein does in the cell: how it works, is transported and what it interacts with, and to produce proteins for medical treatments. However, working with proteins in the lab presents some challenges. One of the biggest obstacles is that the cells that produce the protein of interest, they also make their own proteins for survival. So, how do we isolate our desired protein from the rest? The answer lies in tagging and labelling techniques, allowing easier purification and tracking.

Why Tag or Label a Protein?

When we express a protein in cells, whether for research or therapeutic purposes, it’s mixed with the cell’s proteins. Hence, we need to purify our protein of interest from this mix, and that's where tagging comes into play. Adding a specific "tag" to the protein allows us to separate it from other cellular proteins using specialised methods. 

Challenges in Protein Production

Another hurdle is that producing a large amount of protein burdens the cell, slowing its growth and division. To counteract this, we use a controlled system to regulate protein production. A common approach in bacterial systems is to use an expression vector that includes regulatory elements, such as the lac operon. Therefore, by adding a chemical called IPTG, we can switch on protein production at the right time once the cells have grown to the desired number.

Methods for Protein Tagging

When it comes to purification, two main protein tags are commonly used:

  1. Histag: This tag consists of a sequence of six or more histidine residues that can be added to either the N- or C-terminal of the protein. After the cells producing the protein are lysed, the tagged proteins can be captured using nickel affinity chromatography. The histidine residues bind to the nickel, making purifying the protein from the cell mixture easy.
  2. GST Tag (Glutathione S-Transferase): GST is a small protein that can be fused to the target protein. The fusion protein is purified using glutathione beads. One advantage of this method is that an enzyme can later cleave the GST tag, leaving behind the pure target protein.

Alternative Tagging for Visualisation

While GFP (Green Fluorescent Protein) doesn’t assist in purification, it is often used to label proteins for visualisation. GFP is a fluorescent protein derived from jellyfish, and it allows the movement of proteins to be tracked inside living cells under a microscope. Like Histag and GST, GFP tagging involves cloning the gene for GFP alongside the gene for the protein of interest, so both are expressed as a single molecule.

Additional Resources

Monday, 29 April 2024

New video posted: Translation - making proteins from DNA - decoding mRNA to make the protein

This is the second of two videos on how cells make proteins using DNA. In the first video, I looked at the first step, which is making the messenger RNA (mRNA) a process called transcription - Transcription - making proteins from DNA - the mRNA.

In this video, I will guide you through the process of producing the protein from the mRNA, also known as translation. I will look at the coding problem (how many mRNA bases do you need to code from an amino acid), the number of reading frames in a DNA molecule, and how the cell produces protein from the mRNA.

  

If you would like to support my blogging efforts, then please feel free to buy me a coffee at https://www.buymeacoffee.com/drnickm

Blog Bonus: Free information sheet summarising the video and defining the key terms - download.
 

Additional Reading

The video was produced with help from the following resources:

Monday, 5 October 2009

Protein sequence to DNA - Degeneracy calculation

I have had some questions about the reverse translation of protein to DNA and degeneracy...

The protein sequence is THERIGHTREADINGFRAME

It is 20 amino acids, and therefore, you will need 60 bases to encode it. So....

Protein Seq:  T  H  E  R  I  G  H  T  R  E  A  D  I  N  G  F  R  A  M  E 
DNA Seq:     ACNCAYGARMGNATHGGNCAYACNMGNGARGCNGAYATHAAYGGNTTYMGNGCNATGGAR    
Full DNA:    ACACACGAACGAATAGGACACACACGAGAAGCAGACATAAACGGATTCCGAGCAATGGAA
               T  T  G  T  C  T  T  T  T  G  T  T  C  T  T  T  T  T     G
               G        G  T  C     G  G     C     T     C     G  C
               C        C     G     C  C     G           G     C  G
                      AGG            AGG                     AGG
                        A              A                       A
Number codons: 4  2  2  6  3  4  2  4  6  2  4  2  3  2  4  2  6  4  1  2
So, 4 x 2 x 2 x 6 x 3 x 4 x 2 x 4 x 6 x 2 x 4 x 2 x 3 x 2 x 4 x 2 x 6 x 4 x 1 x 2 = 2,038,431,744 or 2 x 109 possible DNA sequences would encode the protein sequence.

This is a big number; however, compared to the total number of possible DNA sequences you could have for a 60-base sequence, it is small.

The total number of DNA sequences you could have for a 60 base sequence is 4 x 4 x 4.... sixty times, or 460, which is equal to 1.3 x 1036 possible sequences. Of those 1.3 x 1036 sequences only 2,038,431,744 would encode THERIGHTREADINGFRAME. Or in percentage terms, (2,038,431,744 / 1.3 x 1036) x 100 = 0.0000000000000000000000002% (2 x 10-25%) of all the possible sequences would encode THERIGHTREADINGFRAME.

You may find the following video useful where I explain the above:


If you would like to support my blogging efforts, then please feel free to buy me a coffee at https://www.buymeacoffee.com/drnickm

Additional Resources