Plant tissue culture explained

Plant tissue culture is a collection of techniques used to maintain or grow plant cells, tissues, or organs under sterile conditions on a nutrient culture medium of known composition. It is widely used to produce clones of a plant in a method known as micropropagation. Different techniques in plant tissue culture may offer certain advantages over traditional methods of propagation, including:

Plant tissue culture relies on the fact that many plant parts have the ability to regenerate into a whole plant (cells of those regenerative plant parts are called totipotent cells which can differentiate into various specialized cells). Single cells, plant cells without cell walls (protoplasts), pieces of leaves, stems or roots can often be used to generate a new plant on culture media given the required nutrients and plant hormones.

Techniques used for plant tissue culture in vitro

Preparation of plant tissue for tissue culture is performed under aseptic conditions under HEPA filtered air provided by a laminar flow cabinet. Thereafter, the tissue is grown in sterile containers, such as Petri dishes or flasks in a growth room with controlled temperature and light intensity. Living plant materials from the environment are naturally contaminated on their surfaces (and sometimes interiors) with microorganisms, so their surfaces are sterilized in chemical solutions (usually alcohol and sodium or calcium hypochlorite)[1] before suitable samples (known as explants) are taken. The sterile explants are then usually placed on the surface of a sterile solid culture medium but are sometimes placed directly into a sterile liquid medium, particularly when cell suspension cultures are desired. Solid and liquid media are generally composed of inorganic salts plus a few organic nutrients, vitamins, and plant hormones. Solid media are prepared from liquid media with the addition of a gelling agent, usually purified agar.

The composition of the medium, particularly the plant hormones and the nitrogen source (nitrate versus ammonium salts or amino acids) have profound effects on the morphology of the tissues that grow from the initial explant. For example, an excess of auxin will often result in a proliferation of roots, while an excess of cytokinin may yield shoots. A balance of both auxin and cytokinin will often produce an unorganised growth of cells, or callus, but the morphology of the outgrowth will depend on the plant species as well as the medium composition. As cultures grow, pieces are typically sliced off and subcultured onto new media to allow for growth or to alter the morphology of the culture. The skill and experience of the tissue culturist are important in judging which pieces to culture and which to discard.

As shoots emerge from a culture, they may be sliced off and rooted with auxin to produce plantlets which, when mature, can be transferred to potting soil for further growth in the greenhouse as normal plants.[2]

Regeneration pathways

The specific differences in the regeneration potential of different organs and explants have various explanations. The significant factors include differences in the stage of the cells in the cell cycle, the availability of or ability to transport endogenous growth regulators, and the metabolic capabilities of the cells. The most commonly used tissue explants are the meristematic ends of the plants like the stem tip, axillary bud tip, and root tip.[3] These tissues have high rates of cell division and either concentrate or produce required growth-regulating substances including auxins and cytokinins.

Shoot regeneration efficiency in tissue culture is usually a quantitative trait that often varies between plant species and within a plant species among subspecies, varieties, cultivars, or ecotypes. Therefore, tissue culture regeneration can become complicated especially when many regeneration procedures have to be developed for different genotypes within the same species.

The three common pathways of plant tissue culture regeneration are propagation from preexisting meristems (shoot culture or nodal culture), organogenesis, and non-zygotic embryogenesis.

The propagation of shoots or nodal segments is usually performed in four stages for mass production of plantlets through in vitro vegetative multiplication but organogenesis is a standard method of micropropagation that involves tissue regeneration of adventitious organs or axillary buds directly orindirectly from the explants. Non-zygotic embryogenesis is a noteworthy developmental pathway that is highly comparable to that of zygotic embryos and it is an important pathway for producing somaclonal variants, developing artificial seeds, and synthesizing metabolites. Due to the single-cell origin of non-zygotic embryos, they are preferred in several regeneration systems for micropropagation, ploidy manipulation, gene transfer, and synthetic seed production. Nonetheless, tissue regeneration via organogenesis has also proved to be advantageous for studying regulatory mechanisms of plant development.

Choice of explant

The tissue obtained from a plant to be cultured is called an explant.

Explants can be taken from many different parts of a plant, including portions of shoots, leaves, stems, flowers, roots, single undifferentiated cells, and from many types of mature cells provided they still contain living cytoplasm and nuclei and are able to de-differentiate and resume cell division. This has given rise to the concept of totipotency of plant cells.[4] [5] However, this is not true for all cells or for all plants.[6] In many species explants of various organs vary in their rates of growth and regeneration, while some do not grow at all. The choice of explant material also determines if the plantlets developed via tissue culture are haploid or diploid. Also, the risk of microbial contamination is increased with inappropriate explants.

The first method involving the meristems and induction of multiple shoots is the preferred method for the micropropagation industry since the risks of somaclonal variation (genetic variation induced in tissue culture) are minimal when compared to the other two methods. Somatic embryogenesis is a method that has the potential to be several times higher in multiplication rates and is amenable to handling in liquid culture systems like bioreactors.

Some explants, like the root tip, are hard to isolate and are contaminated with soil microflora that becomes problematic during the tissue culture process. Certain soil microflora can form tight associations with the root systems, or even grow within the root. Soil particles bound to roots are difficult to remove without injury to the roots that then allows a microbial attack. These associated microflora will generally overgrow the tissue culture medium before there is significant growth of plant tissue.

Some cultured tissues are slow in their growth. For them there would be two options: (i) Optimizing the culture medium; (ii) Culturing highly responsive tissues or varieties.[7] Necrosis can spoil cultured tissues. Generally, plant varieties differ in susceptibility to tissue culture necrosis. Thus, by culturing highly responsive varieties (or tissues) it can be managed.

Aerial (above soil) explants are also rich in undesirable microflora. However, they are more easily removed from the explant by gentle rinsing, and the remainder usually can be killed by surface sterilization. Most of the surface microflora do not form tight associations with the plant tissue. Such associations can usually be found by visual inspection as a mosaic, de-colorization, or localized necrosis on the surface of the explant.

An alternative for obtaining uncontaminated explants is to take explants from seedlings which are aseptically grown from surface-sterilized seeds. The hard surface of the seed is less permeable to the penetration of harsh surface sterilizing agents, such as hypochlorite, so the acceptable conditions of sterilization used for seeds can be much more stringent than for vegetative tissues.

Tissue-cultured plants are clones. If the original mother plant used to produce the first explants is susceptible to a pathogen or environmental condition, the entire crop would be susceptible to the same problem. Conversely, any positive traits would remain within the line also.

Applications of plant tissue culture

Plant tissue culture is used widely in the plant sciences, forestry, and horticulture. Applications include:

Examples

Developing Somaclonal variation

PlantSomaclonal variantTraits
Sugarcane'Ono'resistance to Fiji disease.
Citronella java'Bio-13' (by CIMAP, Lucknow)37% more oil
Climate resilience

- As in Kaveri Vaman (by NRCB, Tamil Nadu), a Tissue Culture Banana Mutant to withstand heavy rains.[18]

Secondary metabolites production

- Such as Caffeine from coffea arabica, Nicotine from Nicotiana rustica or phenolic acids from Echinacea purpurea.[19]

Induction of flowering

- In trees with delay in flowering or Bamboo - where some species flower once in their life but may live longer than 50 years.[20]

See also

References

NotesSources

Notes and References

  1. Book: Sathyanarayana, B.N. . Plant Tissue Culture: Practices and New Experimental Protocols . 2007. I. K. International . 978-81-89866-11-2 . 106–.
  2. Book: S. S. . Bhojwani. M. K.. Razdan. 1996. Plant tissue culture: theory and practice. Revised. Elsevier. 978-0-444-81623-8 .
  3. Sarkar . Snehasish . Roy . Souri . Ghosh . Sudip K. . Basu . Asitava . Application of lateral branching to overcome the recalcitrance of in vitro regeneration of Agrobacterium-infected pigeonpea (Cajanus cajan L.) . Plant Cell, Tissue and Organ Culture . 1 April 2019 . 137 . 1 . 23–32 . 10.1007/s11240-018-01547-6 . en . 1573-5044.
  4. I.K.. Vasil. V.. Vasil. 1972. In Vitro. 8. 3. 117–125. Totipotency and embryogenesis in plant cell and tissue cultures.. 10.1007/BF02619487. 4568172. 20181898.
  5. Book: Plants in Action: Adaptation in Nature, Performance in Cultivation. Brian James Atwell. Colin G. N. Turnbull. Paul E. Kriedemann. 1999. dead. https://web.archive.org/web/20180327150832/http://plantsinaction.science.uq.edu.au/edition1/?q=content%2F10-2-1-concept-totipotency. March 27, 2018. May 7, 2020. 1st.
  6. Book: Indra K. Vasil. Trevor A. Thorpe. Plant Cell and Tissue Culture. 1994 . Springer. 978-0-7923-2493-5. 4–.
  7. Pazuki . Arman . Sohani . Mehdi . amp . 2013 . Phenotypic evaluation of scutellum-derived calluses in 'Indica' rice cultivars . Acta Agriculturae Slovenica . 101 . 2 . 239–247 . 10.2478/acas-2013-0020 . free .
  8. Lema-Rumińska J., Kulus D., 2014. Micropropagation of cacti – a review. Haseltonia 19: 46-63
  9. Mukund R. Shukla . A. Maxwell P. Jones . J. Alan Sullivan . Chunzhao Liu . Susan Gosling . Praveen K. Saxena . In vitro conservation of American elm (Ulmus americana): potential role of auxin metabolism in sustained plant proliferation . Canadian Journal of Forest Research . 42 . 4 . 686–697 . April 2012 . 10.1139/x2012-022 .
  10. Kulus D., Abratowska A., 2017. CRYOconservation of Ajania pacifica (Nakai) Bremer et Humphries via encapsulation-dehydration technique. CryoLetters 38(5): 387-398(12)
  11. Miler N., Kulus D., Sliwinska E., 2020. Nuclear DNA content as an indicator of inflorescence colour stability of in vitro propagated solid and chimera mutants of chrysanthemum. Plant Cell Tissue and Organ Culture 143: 421-430. https://doi.org/10.1007/s11240-020-01929-9
  12. 10.1007/s00253-009-2049-x. Bioprocessing of plant cell cultures for mass production of targeted compounds. 2009. Georgiev. Milen I.. Weber. Jost. MacIuk. Alexandre. Applied Microbiology and Biotechnology. 83. 5. 809–23. 19488748. 30677496.
  13. Manoj K. Rai . Rajwant K. Kalia . Rohtas Singh . Manu P. Gangola . A.K. Dhawan . Developing stress tolerant plants through in vitro selection—An overview of the recent progress . Environmental and Experimental Botany . 71 . 1 . 89–98 . April 2011 . 10.1016/j.envexpbot.2010.10.021 .
  14. O . Aina . K. . Quesenberry . M . Gallo . In vitro induction of tetraploids in Arachis paraguariensis . Plant Cell, Tissue and Organ Culture . 111. 2. 231–238. 2012 . 10.1007/s11240-012-0191-0 . 9211804 .
  15. Pawar, K. R., Waghmare, S. G., Tabe, R., Patil, A. and Ambavane, A. R. 2017. In vitro regeneration of Saccharum officinarum var. Co 92005 using shoot tip explant. International Journal of Science and Nature 8(1): 154-157.
  16. Waghmare, S. G., Pawar, K. R., and Tabe, R. 2017. Somatic embryogenesis in Strawberry (Fragaria ananassa) var. Camarosa. Global Journal of Bioscience and Biotechnology 6(2): 309 - 313.
  17. Kulus D., 2019. Application of synthetic seeds in propagation, storage and cryopreservation of Asteraceae plant species, [w:] Synthetic Seeds Germplasm Regeneration, Preservation and Prospects, red. Faisal A., Alatar A., Springer Science & Business Media, The Netherlands, pp. 155-179. ISBN 978-3-030-24630-3, ISBN 978-3-030-24631-0 (eBook), https://doi.org/10.1007/978-3-030-24631-0_6
  18. News: Bureau . The Hindu . 2023-08-21 . Tiruchi . en-IN . The Hindu . 2023-08-31 . 0971-751X.
  19. Lema-Rumińska J., Kulus D., Tymoszuk A., Varejão J.M.T.B., Bahcevandziev K., 2019. Profile of secondary metabolites and genetic stability analysis in new lines of Echinacea purpurea (L.) Moench micropropagated via somatic embryogenesis. Industrial Crops and Products 142: 111851. https://doi.org/10.1016/j.indcrop.2019.111851
  20. Book: Srivastava, S. . Plant Biotechnology and Molecular Markers . Narula . A. . 2006-01-16 . Springer Science & Business Media . 978-1-4020-3213-4 . en.