Molecular Genetics and Genetic Engineering GEN 301 Lecture 1 PDF
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Uploaded by SmoothestHyperbola
October University for Modern Sciences and Arts
2024
Dr. Mustafa Mahmoud
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Summary
This is a lecture on Molecular Genetics and Genetic Engineering, GEN 301, presented by Dr. Mustafa Mahmoud, Ph.D., occurring in the Fall of 2024, at October University for Modern Sciences and Arts in Egypt. The lecture covers topics such as molecular biology, genetic engineering, and DNA recombination, and details the various types of restriction enzymes. It includes examples of restriction mapping approaches and the use of ligases in molecular applications like cloning.
Full Transcript
# Molecular Genetics and Genetic Engineering GEN 301 Lecture 1 ### Presented and edited by Dr. Mustafa Mahmoud, Ph.D. Faculty of Biotechnology October University for Modern Sciences and Arts (Fall 2024) ## Introduction ### Molecular Biology: - Field of science concerned with studying the molec...
# Molecular Genetics and Genetic Engineering GEN 301 Lecture 1 ### Presented and edited by Dr. Mustafa Mahmoud, Ph.D. Faculty of Biotechnology October University for Modern Sciences and Arts (Fall 2024) ## Introduction ### Molecular Biology: - Field of science concerned with studying the molecular nature of the gene and its mechanisms of gene replication, transcription, translation, etc... ### Molecular Genetics: - Molecular genetics relies heavily on genetic engineering (recombinant DNA technology), which can be used to modify organisms by adding foreign DNA, thereby forming transgenic organisms. ### Chronology: - 1973: created first genetically modified (GM) bacteria - 1974: created GM mice - 1982: first commercial development of genetically modified organisms [GMOs] (insulin-producing bacteria) - 1994: began to sell genetically modified food ## DNA recombination ### Restriction enzymes (restriction endonucleases): - enzymes, which are naturally produced by bacteria - cut **DNA** at a particular sequence of bases (recognition site): - 4-8 bp - Palindromic sequence | Enzyme | Recognition sequence | Cutting sites | Ends | | :-------- | :-------------------- | :---------------- | :-------- | | BamHI | 5'- GGATCC-3' | GGATCC / CCTAGG | sticky | | EcoRI | 5'- GAATTC-3′ | G'AATT C / CTTAAG | sticky | | Haelll | 5'- GGCC-3′ | GGCC / CCGG | blunt | | Hpal | 5'- GTTAAC-3′ | GTTAAC / CAATTG | blunt | | Pstl | 5'- CTGCAG-3' | CTGCAG / GACGTC | sticky | | Sau3A | 5'- GATC-3′ | GATC / CTAG | sticky | | Smal | 5'- CCCGGG-3' | CCCGGG / GGGCCC | blunt | | Sstl | 5'- GAGCTC-3' | GAGCT C / CTCGAG | sticky | | Xmal | 5'- CCCGGG-3' | CCCGGG / GGGCCC | sticky | #### Types: - **Type I**: cuts **DNA** randomly (upstream or downstream) the recognition site by 1000-5000 - endonuclease and methylase activities - **Type II**: Cuts **DNA** within or near recognition sequence - endonuclease activity - **Type III**: Cuts **DNA** 20-30 bp downstream recognition site - endonuclease and methylase activities - **Type IV**: Recognizes modified (methylated) **DNA** - endonuclease activity - **Type V (Artificial restriction enzymes)** - Generated by fusing a **DNA** binding domain to a nuclease domain. - They can cut **DNA** of variable length, provided that a suitable guide **RNA** is provided. - ex. CRISPR-Cas system, TALENS, Zinc finger nucleases #### Type II Subgroups: | Subgroup | Mechanism of digestion | | :-------- | :------------------------------------------------------------------------------------ | | Type IIP | Cut at the recognition site | | Type IIS | Cut away from the site | | Type IIB | Require two recognition sites and cut on the outside | | Type IIE | Require two recognition sites, and one of the two sites acts as allosteric effector | | Type IIF | Require two sites and cut at both sites as a tetramer after bringing the two regions together by looping the **DNA** | | Type II | In contrast to most Type II REs that act as dimers Bcnl act as a monomer | #### Concepts: - **Neoschizomers**: Different REs recognizes the same sequence but cut it differently. - **Isoschizomers**: Different REs recognize the same sequence and cleave in the same location. - **Isocaudomer**: Different REs that recognize and cleave different sequences giving compatible or complementary sticky ends. - The ligation of these sticky ends produces new sequence that can’t be digested by any of them. ### Restriction Mapping - To construct a map showing the relative positions in the DNA molecule of the recognition sequences for a number of different enzymes. - Important to select the correct RE for the particular cutting. #### Example: *What would be the number and sizes of the fragments that you would expect to find if you cut the following **DNA** fragment with: i- Enzyme A, ii- Enzyme B, iii- Both enzymes together?* | | Enzyme A | Enzyme B | Both | | :-------- | :------- | :------- | :------ | | | 1000 bp | 1200 bp | 1000 | | | 2100 bp | 2500 bp | 200 | | | 1400 bp | 1300 bp | 1900 | | | 500 bp | | 600 | | | | | 800 | | | | | 500 | #### Example: *Linear **DNA** fragment was digested. The reaction along with the fragments obtained in single and double digest reactions, resulted in:* | | BamHI | EcoRI | BamHI + EcoRI | | :--------- | :------- | :------- | :------------- | | | 14 | 12 | 11 | | | 1 | 3 | 3 | | | | | 1 | *Using this information, construct a restriction map of the **DNA** fragment.* #### Example: *An isolated plasmid was digested using EcoRI and BamHl. The fragments obtained in single and double digest reactions were as following:* | | EcoRI | BamHI | EcoRI + BamHI | | :------ | :------ | :------ | :------------- | | | 20 kb | 6 kb | 6 kb | | | | 12 kb | 4 kb | | | | 2 kb | 8 kb | | | | | 2 kb | *Using this information, construct a restriction map of the plasmid.* ### Ligases: - Catalyzes the formation of phosphodiester bond - NB: - Cut both the insert and vector by Isoschizomer RE so they give sticky ends complementary to each other giving. - Blunt end ligation between insert and vector is an inefficient process. - Vector and the insert can ligate in only one orientation (i.e., directional) and the digested ends of the vector are incompatible for self-ligation. - Possible outcomes for ligation: - i- recombinant vector; ii- native vector; iii- insert / vector concatemers; iv- no ligation #### Types: - **Bacterial DNA ligase** - 1- E.Coli ligase - 2- Needs NAD+, NADP as energy source - 3- Efficiency of ligation is low so can’t join blunt end (except under conditions of macromolecular crowding) - **Bacteriophage Ligase** - 1- T4 DNA ligase (from T4) - 2- Needs **ATP** as source of energy - 3- Efficiency of ligation is high so can join both sticky and blunt ends ### Blunt end ligation with a DNA topoisomerase - efficient way for blunt end ligation - DNA topoisomerases have both nuclease and ligase activities. - topoisomerase cuts DNA at the sequence CCCTT, which is present just once in the plasmid - after cutting the plasmid, topoisomerase enzymes remain covalently bound to the resulting blunt ends - insert is produced by cutting with a restriction enzyme, and treated with alkaline phosphatase to remove terminal 5’ phosphates before mixing the insert with the vector - only one strand is ligated at each junction point and the nicks will be repaired by cellular enzymes after the recombinant molecules have been introduced into the host bacteria #### Example: - [Graphic depiction of Blunt TOPO Cloning] ### Cloning with Different End Types: - **Cloning with two sticky ends** - Sticky ends must be compatible - Cloning is directional - Insert-vector ligation is efficient - Vector self-ligation is low - Recognition sites of ligated restriction enzymes are intact - **Cloning with two different but compatible ends** - Sticky ends must be compatible - Cloning is directional - Insert-vector ligation is efficient - Vector self-ligation is low - Recognition sites of original restriction enzymes (e.g., Xhol and Sall) may be destroyed after ligation - **Cloning with one sticky end and one blunt end** - Directional cloning is maintained - Ligation of the blunt ends may be less efficient - **Cloning with blunt ends ** - Ends are compatible - End sequences are modified - Directional cloning is lost - Ligation may be less efficient - Vector self-ligation is high ### Conversion of blunt ends to sticky ends - Addition of linkers or adaptors or homopolymer tailing to blunt ends: #### Linkers: - Double-stranded-oligomers that contain a recognition sequence for a particular restriction enzyme is added to blunt ends followed by digestion with restriction endonucleases. #### Adaptors: - Short double-stranded sticky ended oligonucleotides added to blunt ends, and do not require further digestion with RE #### Homopolymer Tailing: - Enzyme terminal transferase (TdT) adds homopolymers of dA, dT, dG, or dC to 3' of **DNA** molecules (ex. dG tails on insert and dC tails on vector) #### NB. - TdT add from 2- to 15-mers - homopolymer tailing advantages over the other methods: - provide longer regions for annealing **DNAs** together: means that ligation need not be carried out in vitro, as the **DNA**-vector hybrid is stable enough to survive introduction into the host cell, where it is ligated in vivo - more specificity: as the vector and insert **DNAs** have different but complementary tails, there is little chance of self-annealing, and the generation of concatemers #### Restriction sites introduction into PCR products: - PCR primers are designed which recognize sequences flanking the target region - A short extra region of **DNA** encoding a restriction site is added to the 5' end of the primers - The 5' ends of the primers with the restriction site will be incorporated into the newly synthesized amplicons ## Thank you For ## Your attention