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Manifestation of Novel Social Challenges of the European Union in the Teaching Material of Medical Biotechnology Master’s Programmes at the University.

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Presentation on theme: "Manifestation of Novel Social Challenges of the European Union in the Teaching Material of Medical Biotechnology Master’s Programmes at the University."— Presentation transcript:

1 Manifestation of Novel Social Challenges of the European Union in the Teaching Material of Medical Biotechnology Master’s Programmes at the University of Pécs and at the University of Debrecen Identification number: TÁMOP /1/A

2 RECOMBINANT ANTIBODIES AND THE PHAGE DISPLAY TECHNOLOGY
Manifestation of Novel Social Challenges of the European Union in the Teaching Material of Medical Biotechnology Master’s Programmes at the University of Pécs and at the University of Debrecen Identification number: TÁMOP /1/A Éva Csősz Molecular Therapies - Lecture 7 RECOMBINANT ANTIBODIES AND THE PHAGE DISPLAY TECHNOLOGY

3 VI.I.1. The structure of antibodies and their production in the body
TÁMOP /1/A The aim of lecture 7 is to present the possibilities for therapeutic antibody production, to highlight the pros and cons of the different production methods. In this lecture the production of antibodies in the body and by different techniques like in hybridoma cells or the generation of high antibody diversity by phage display technology will be discussed. Chapters in lecture 7. 7.1. Introduction VI.I.1. The structure of antibodies and their production in the body VI.I.2. Antigen-antibody binding 7.2. The production of therapeutic antibodies VI.II.1. The production of antibodies in hybridoma cells. VI.II.2. Humanized antibodies VI.II.3. Production of human antibodies 7.3. Generation of antibodies by phage display VI.III.1. The phage display technology VI.III.2. Generation of phage libraries 7.4. Administration of therapeutic antibodies

4 The structure of antibodies
TÁMOP /1/A The structure of antibodies Supervariable region NH3+ NH3+ NH3+ NH3+ VH VH VL VL Fab region CH1 CH1 Light chain: constant region, variable region CL CL COO- COO- Figure 1. The structure of antibodies. Hinge region CH2 Heavy chain: constant region, variable region Disulfide bonds Fc region CH3 COO- COO- 4

5 The structure of antibody heavy chain
TÁMOP /1/A The structure of antibody heavy chain kb. 85 gene kb. 27 gene kb. 6 gene VH1 VH2 VH3 VH4 VHn DH1 DHn JH1 JH2 JH3 JHn C C C  C α Heavy chain VH4 DH1 JH2 C  IgG Figure 2. The structure of antibody heavy chain. Each heavy chain is a combination of V (variable), J ( junction), D (diversity) and C (constant) genes. 5

6 The structure of antibody light chain
TÁMOP /1/A The structure of antibody light chain approx. 35 kappa gene approx. 5 kappa gene VL1 VL2 VL3 VL4 VLn JL1 JL2 JL3 JLn C approx. 30 lambda gene approx. 4 lambda gene VL2 JL3 C kappa light chain Figure 3. The structure of antibody light chain. Each light chain is a combination of V (variable), J ( junction) and C (constant) genes. 6

7 Production of antibodies in B cells
TÁMOP /1/A Production of antibodies in B cells B cell Antibody Figure 4. Production of antibodies by B cells. 7

8 Somatic hipermutation
TÁMOP /1/A Clonal selection and clonal expansion Y Recombination Junctional diversity Somatic hipermutation B cell BCR Clonal selection Antigene/epitope Figure 5. The clonal selection and clonal expansion provides the appearance of a high number of specific antibody producing B cells and plasma cells in a very short period of time. B cell Clonal expansion Specific antibody Plazma cell 8

9 Y Y Y Y Polyclonal antibodies B cell B cell antibody antigene epitope
TÁMOP /1/A Polyclonal antibodies Y Y Y B cell Figure 6. Polyclonal antibodies – a combination of immunoglobulins originated from different B cells recognising different epitopes of the antigene. B cell antibody Y antigene epitope antibody B cell 9

10 Monoclonal antibodies
TÁMOP /1/A Monoclonal antibodies B cell Figure 7. Monoclonal antibodies – immunogloulins originated from one type of B cells recognizing one epitope. antibody antigene epitope 10

11 Production of antiodies in hybridoma cells
TÁMOP /1/A Production of antiodies in hybridoma cells Antigene Myeloma cells HGPRT  antibody production  Mouse immunization Fusion of spleen and myeloma cells, generation of hibridoma cells Spleen cell isolation HGPRT antibody production Culturing of the hibridoma cells Figure 8. Production of antiodies in hybridoma cells. Y Y Y Y antibody isolation Y Y Y 11

12 Humanized antibodies Human antibody Mouse antibody
TÁMOP /1/A Humanized antibodies Figure 9. Humanized antibodies. Human antibody Mouse antibody Humanized antibody / chimera antibody 12

13 Production of human antibodies in genetically modified mice
TÁMOP /1/A Production of human antibodies in genetically modified mice Mouse immunoglobulin gene Figure 10. Production of human antibodies in genetically modified mice. Human immunoglobulin gene Human or humanized antibody production 13

14 The structure of M13 phage
TÁMOP /1/A The structure of M13 phage M13 bacteriophage 5 db p6 5 db p9 DNS kb E. coli 5 db p3 5 db p7 2700 db p8 F-pilus 900 nm Figure 11. The structure of M13 phage. 14

15 Specific elution of immobilized phage particles
TÁMOP /1/A Specific elution of immobilized phage particles Specific elution Figure 12. Specific elution of immobilized phage particles. Immobilized protein / affinity matrix 15

16 Enzyme phage display matrix Figure 13. Enzyme phage display. 16
TÁMOP /1/A Enzyme phage display Figure 13. Enzyme phage display. matrix 16

17 Substrate phage display I.
TÁMOP /1/A Substrate phage display I. Figure 14. Substrate phage display I. matrix 17

18 Substrate phage display II.
TÁMOP /1/A Substrate phage display II. Figure 15. Substrate phage display II. matrix matrix 18

19 Enzyme-substrate phage display I.
TÁMOP /1/A Enzyme-substrate phage display I. matrix Figure 16. Enzyme-substrate phage display I. 19

20 Enzyme-substrate phage display II.
TÁMOP /1/A Enzyme-substrate phage display II. Figure 17. Enzyme-substrate phage display II. matrix matrix 20

21 Generation of phage libraries
TÁMOP /1/A Generation of phage libraries Various sequences Phagemid Figure 18. Generation of phage libraries. Recombinant phagemid 21

22 Generation of protease substrate phage library
TÁMOP /1/A Generation of protease substrate phage library Generation of various sequences Protease substrate sequence hGH gene Protease substrate M13 gIII gene hGH gene Protease substrate M13 gIII gene phagemid vector Figure 19. Generation of protease substrate phage library. phagemid vector Phage library 22

23 Substrate phage display –engineering of protease substrate sequences
TÁMOP /1/A Substrate phage display –engineering of protease substrate sequences Protease sensitive sequences Protease hGH receptor Figure 20. Substrate phage display –engineering of protease substrate sequences. Protease Sequencing matrix low pH Protease resistent sequences 23

24 In vivo phage display – mapping vascular endothelial cells
TÁMOP /1/A In vivo phage display – mapping vascular endothelial cells Phage particles bind to the vascular endothelial cell surface proteins Biopsy Intravenous injection of phage library Removal of bound phages Figure 21. In vivo phage display – mapping vascular endothelial cells. Identification of phage- bound proteins/peptides Propagation of bound phages 24

25 contain 108 differnt antibody genes
TÁMOP /1/A Generation of antibody libraries from whole blood Whole blood (immunized donor) antibody genes Limfocytes antibody specific primer phagemid Figure 22. Generation of antibody libraries from whole blood. mRNA E. coli cells cDNA contain 108 differnt antibody genes 25

26 The mechanism of antibody dependent cell mediated cytotoxicity (ADCC)
TÁMOP /1/A The mechanism of antibody dependent cell mediated cytotoxicity (ADCC) Y Y Y Antibody against tumor cells Y Y Y Fc receptor Y Figure 23. The mechanism of antibody dependent cell mediated cytotoxicity (ADCC). Tumor cell Killer cell (NK cell or monocyte) 26

27 TÁMOP /1/A Administration of therapeutic antibodies with immunosupressant activity Monoclonal antibody Adalimumab Infliximab Golimumab Cetrolizumab pegol Psoriasis Rheumatoid arthritis Crohn disease Spondilitis TNFalpha Figure 24. Administration of therapeutic antibodies with immunosupressant activity. Inhibition of organ rejection after transplantation, especially in case of kidney transplantations. IL2 receptor alpha chain Basiliximab Human-mouse chimera antibody 27

28 Forms of therapeutic antibodies
TÁMOP /1/A Forms of therapeutic antibodies Bispecific antibody (approx. 300 kDa) Figure 25. Forms of therapeutic antibodies. IgG - scFv (Fab – scFv)2 28

29 Forms of small-sized therapeutic antibodies
TÁMOP /1/A Forms of small-sized therapeutic antibodies Fab F(ab’)2 scFv Tandem scFv Diabody Triabody Bispecific antibody Figure 26. Forms of small-sized therapeutic antibodies. S-S Fv S-S dsFv scFv2 Nanobody 29

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