1 / 38

Plant Parts and their main functions

Plant Parts and their main functions. Leaf (Photosynthesis) Shoot (Mechanical support, Transport of food) Root ( Water and mineral supply). Plant Cell Technology. Plant Cell Technology. The Architecture of Plants. Structure of Plant Cell. Organelles Specific to Plant Cells.

amos
Download Presentation

Plant Parts and their main functions

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Plant Parts and their main functions Leaf (Photosynthesis) Shoot (Mechanical support, Transport of food) Root ( Water and mineral supply)

  2. Plant Cell Technology Plant Cell Technology

  3. The Architecture of Plants

  4. Structure of Plant Cell

  5. Organelles Specific to Plant Cells

  6. The characteristics of plant, animal and microbial cultures

  7. Plants are obvious source for food, fiber and fuel. Besides these plants are a source of diverse array of chemicals as flavors, fragrances, natural pigments, pesticides and pharmaceuticals ( Plants derived secondary metabolites) thus plants are invariably the integral part of human life.

  8. Plant Cell Culture Plant Part (Leaf, Shoot, Root, Embryo) Callus culture (Solid/Semi solid media) Suspension culture (Liquid media) Bioreactor

  9. Development of Callus Culture:- Any plant part which contain the highest amount of desired compound is taken and kept on a defined media which contains all the nutrients required for plant cell growth and particular growth hormones and incubated under certain physical conditions of temp, light/dark period etc. under these conditions the organized plant part is converted into an unorganized growth and forms callus. Thus callus isunorganized growth of plant cells in vitro on a culture medium. This callus produces the same chemical compounds which are produced by the mature intact plant.

  10. Development of Suspension Culture and Scale-up:- Callus is transferred in liquid media and various culture parameters are optimized to enhance the yield of desired compound. For scale-up suspension culture is grown in Bioreactor and large-scale production of plant derived secondary metabolite is facilitated.

  11. Advantages of producing compounds from Plant Cell Culture • Control of supply of product independent of availability of plant itself and climatic, geographical and governmental restrictions etc. • High growth and turnover rate as compared to natural plant. • Reduction in time and space requirement for the production of desired chemicals. • Strain improvement with programs analogous to those used for microbial system.

  12. Applications of Plant Cell Culture • Production of plant derived chemicals • Development of transgenic plants • Mass multiplication of desirable genotype of plants (Micropropagation) • Production of pathogen free plants

  13. Compounds which are commercialized from Plant Cell Culture Technology Compound Plant Use • Shikonin ` Lithospermum Pigment erythrorhizon • Ginseng Panax ginseng Health tonic • Taxol Taxus baccta Anti-Cancer Drug • Vincristine & C. roseus Anti-Cancer Vinblastin Drug • Berberin Coptis japonica Anti-malarial

  14. Callus culture of some commercially important plants Podophyllum hexandrum Azadirachta indica Linum album

  15. Protocol for establishment of plant cell suspension cultures

  16. Various steps involved in cell culture Setric impeller Batch cultivation Callus culture Germinated seedling Batch cultivation with fluorescence probe Suspension culture Continuous cultivation with cell retention Seeds of P. hexandrum

  17. What bioreactor is? • A vessel, made up of glass or steel, in which plant cells are cultivated under controlled environment to obtain a desired product

  18. Basic parts of bioreactor • A culture vessel • Associate supply and environmental systems • Measurement and control systems

  19. Bioreactors for cultivation of plant cells • Stirred tank bioreactor • Air-lift bioreactor • Rotating drum bioreactor • Spin filter bioreactor

  20. Stirred tank bioreactor

  21. Air-Lift Reactors

  22. Spin Filter Bioreactor

  23. Plant Tissue Culture- Different Approaches for Production of Secondary Metabolites Plant Cell Suspension Culture (Plant cell suspension cultures are generated by transferring the callus tissue in liquid media) Tissue Culture Hairy Root Culture (Hairy root cultures are obtained by infection of Agrobacterium rhizogenes, a gram negative soil bacterium)

  24. Induction of Hairy Roots by Agrobacterium rhizogenes Wounded plant cells Signal Molecules Recognition by Agrobacterium Attachemnt of Agrobacterium With plant cells Transfer of Ri plasmid to wounded plant cells Co-Cultivation Integration of Ri plasmid into plant genome Hairy Root Induction Transfer of Ti/Ri Plasmind in plant cell /rhizogenes

  25. Advantages of Hairy Root Culture Over Plant Cell Suspension Culture • Fast growth • Low doubling time • Genetic and biochemical stability • Growth in hormone free media. These fast growing hairy roots can be used as a continuous source for the production of valuable secondary metabolites.

  26. Induction of hairy roots • Hairy roots appear within one to four weeks of infection. • In some plant species hairy roots may appear directly at the site of inoculation. • While in others a callus will form initially and hairy roots appear subsequently from it.

  27. Hairy root culture

  28. Establishment of axenic hairy root lines • Excise the transformed roots from the explant after it grows more than 1 cm in its length. • Transfer these excised roots to the same solidified growth medium with antibiotic to kill the bacterium. • After appearance of lateral branching roots may be transferred to the liquid medium. • Established roots may be cleared of bacteria by several passages in the medium containing 250 mg/l Cefotaxime and 250 mg/l ampicillin. • Each root growth represents a single root line .

  29. Measurement of growth • By direct methods (Biomass- drain and weigh) • By indirect methods (Conductivity, nutrient consumption profile)

  30. Cultivation of hairy roots in bioreactors The ability to exploit hairy root culture as a source of bioactive chemicals depends on development of suitable bioreactor system.

  31. Challenges in bioreactor designing Hairy roots are complicated biocatalysts when it comes to scaling up. The main challenges for development of bioreactor for hairy roots are- • Shear sensitivity of hairy root system. • Requirement for a support matrix. • Restriction of nutrient/oxygen delivery to the central mass of tissue. • Resistance to flow due to interlocked matrix because of extensive branching of roots.

  32. Bioreactors for hairy root cultures • Stirred tank bioreactor • Air lift bioreactor • Bubble column bioreactor • Turbine blade bioreactor • Mist (Trickle bed) bioreactor • Rotating drum bioreactor • Spin filter bioreactor

  33. Bioreactor designs: A comparison

  34. Bioreactor designs: A comparison

  35. Bioreactors for cultivation of hairy roots

  36. Bioreactors for cultivation of hairy roots

  37. Bioreactors for cultivation of hairy roots

  38. Bioreactors for cultivation of hairy roots

More Related