Cell and Tissue Culture PDF

Summary

This document is lecture notes on cell and tissue culture. It covers topics such as the structure and function of cells and tissues, as well as different types of cells and tissues. This document is part of a 4th-grade clinical nutrition program at a home economics faculty.

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CELL AND TISSUE CULTURE
BY
Prof. Dr. Hany Mohamed Samy Hassan

Clinical Nutrition Program
Faculty of Home Economics
4th Grade
 A single cell is the
building block for life
 Cell
A cell is the smallest structural and functional unit of life.
Therefore it is referred to as a fundamental unit of life.
The term cell was first coined in the year 1665 by an English
scientist Robert Hooke. Among all the living organisms, some
organisms are unicellular, consisting of only one cell, which is
capable of performing all the life functions. These unicellular
organisms include amoeba, bacteria, Protista.
Multicellular organisms consist of different types of cells which
have specialized functions. Plants, animals, human, and birds
are examples of multicellular organisms.
There are two different types of cells, the prokaryotic cells and
the eukaryotic cells and these differences are mainly based on
the presence and absence of the nucleus in their cell.
 Tissue
Tissues are groups of similar cells, working together to perform a specific
function. The word tissue is mainly derived from “tissue” – a French word
which is the past participle of the tisser (verb), “to weave”.
In the plant kingdom, tissues are divided into two different types:
Meristematic tissue and Permanent tissue.
In the animal kingdom, tissues are divided into four different types:
Connective Tissue: Blood, bone, cartilage, adipose, and lymph are examples
of Connective Tissue.
Muscle Tissue: Skeletal muscle, Cardiac muscle, and Smooth muscle are
examples of Muscle Tissue.
Nervous Tissue: Nervous tissue is seen in the brain, spinal cord, and nerves
Epithelial Tissue: The surface of the skin, the reproductive tract, the airways,
and the inner lining of the digestive tract are examples of Epithelial Tissue.
 CELL TISSUE
Cells are the smallest structural and functional
units of an organism, which are characteristically Tissues are clusters of cells, specialized cells.
microscopic.
Found in both unicellular and multicellular
Found only in multicellular organisms.
organisms.
Comprise of different cellular organelles, including
Comprise of similar types of cells, specialized for
the nucleus, mitochondria, lysosomes, Golgi
a unique function.
apparatus, etc.
Four main types of tissue- Epithelial tissue,
Two types of cells – Eukaryotic cells and
Connective tissue, Muscular tissue, and Nervous
prokaryotic cells.
tissue.
Has its own unique function. A group of similar
cells combines together to perform a similar
Functions include Growth, metabolism, and
function. Example – Nerve cells of the nervous
reproduction.
system are involved in different functions of the
nervous system.
How do plant and animal cells differ?
Both plant and animal cells are eukaryotic, so they contain
membrane-bound organelles like the nucleus and mitochondria.
However, plant cells and animal cells do not look exactly the same or
have all of the same organelles, since they each have different needs.
For example, plant cells contain chloroplasts since they need to
perform photosynthesis, but animal cells do not.
Both animal and plant cells have mitochondria, but only plant cells have
chloroplasts. Plants don’t get their sugar from eating food, so they need to
make sugar from sunlight. This process (photosynthesis) takes place in the
chloroplast. Once the sugar is made, it is then broken down by the
mitochondria to make energy for the cell. Because animals get sugar from
the food they eat, they do not need chloroplasts: just mitochondria.

Both plant and animal cells have vacuoles. A plant cell contains a large,
singular vacuole that is used for storage and maintaining the shape of the
cell. In contrast, animal cells have many, smaller vacuoles.

Plant cells have a cell wall, as well as a cell membrane. In plants, the cell wall
surrounds the cell membrane. This gives the plant cell its unique rectangular
shape. Animal cells simply have a cell membrane, but no cell wall.
Tissiue culture
Tissue fragments from animals or plants are transplanted to an artificial
environment where they can continue to thrive and function as part of the
biological research technique known as tissue culture. One cell, a group of
cells, an entire organ, or a portion of an organ may make up the cultured
tissue. In culture, cells can divide, alter their shape, size, or function, engage
in specialised activity or collaborate with other cells
History Of Plant Tissue Culture
The concept of tissue culture originated from the idea of totipotent—the ability
of any plant cell to grow into a whole plant—a property of plant cells. Let’s have a
look at the successive timeline for the development of the tissue culture
technique:
1902: Gottlieb Haberlandt proposed the theoretical basis of plant tissue culture.
He is known as the father of plant tissue culture. He experimented with isolated
photosynthetic leaf cells but was unsuccessful in inducing any growth. However,
he predicted that one can obtain artificial embryos from vegetative cells using
this culturing technique and established the concept of totipotency.

1904: Henning isolated embryos of some crucifers and successfully grew on
mineral salts and sugar solutions
1922: WJ Robbins and W. Kotte independently cultured small root tips of peas
and maize. This led to the development of the concept of Organ culture.
1934: Gautheret cultured cambium cells of Salix caprea, and Populus nigra on
Knop’s solution containing glucose and cysteine hydrochloride. The cultures
survived a few months.
1939: Gautheret obtained the first established continuously growing tissue
cultures from carrot root cambium. At this same point, P. R. White Demonstrated
indefinite culture of tomato roots on subculturing in a liquid medium.
1941: J Van Overbeek demonstrated that coconut milk is essential for the growth
and development of very young Datura embryos.
1942: P.R. White and A.C Braun began studying crown galls and tumor formation
in plants.

1952: G. Morel and Martin C demonstrated that virus-free plants can be
recovered from infected plants using shoot meristem culture.
1957: F. Skoog, and C.O. Miller proposed that a particular auxin-cytokinin ratio
can regulate shoot and root initiation in cultured callus.
1959: G. Melchers and Bergmann L cultivated haploid tissues other than pollen
for the first time.
1960: E.C Cocking isolated and cultured protoplasts after digesting the cell walls
enzymatically and showed new cell wall regeneration on tomato fruit locule
protoplasts. This same year L. Bergmann first obtained callus by transferring cells
from suspension cultures on to solid medium and G. Morel developed a method of
producing virus-free Cymbidium progenies through meristem culture.
1966: S G Guha and S C Maheshwari cultured anthers and pollen and produce
haploid embryos.

1973: I. Potrykus attempted the first chloroplast and nucleus transfer from Petunia
hybrida into albino protoplasts of the same species.
1974: J P Nitsch cultured microspores of Datura and Nicotina, doubling their
chromosome number and harvesting seed from homozygous diploid plants within
five months. At the same time, Mursahige developed the concept of
developmental stages in cultures in vitro: Stage I: Establishment; Stage II:
Multiplication; and Stage III: Rooting and hardening.
1975: G. Morel established cold storage of regenerated plants for a year.
1978: A. Zelcer, D. Aviv, and E. Galun devised a method for transferring
organelles from one plant to another called Donor - Recipient protoplast fusion.

1981: P. J. Larkin and W. R. Scowcraft developed the concept of somaclonal
variation. At the same time D. Wilson, G. Patnaik, G., and E. C. Cocking
regenerated a whole plant from a single free cultured tobacco protoplast.

1986: J. D. Hamill, A. J. Parr, R. J. Robins, and M. J. C. Rhodes established hairy
root cultures of Beta vulgaris and Nicotiana rustica following infection with
Agrobacterium rhizogenes. Compared to in vitro roots of the same variety, the
transformed cultures synthesized their characteristic secondary products.
1991: C. Sautter, H. Waldner, and G. Neuhaus developed a novel method for
the acceleration of microprojectiles, called micro-targeting.
Historical background for animal tissue culture
Tissue culture involves the in vitro maintenance and propagation of cells in
optimal conditions. Culturing animal cells, tissue or organs in a controlled
artificial environment is called animal tissue culture. The importance of
animal tissue culture was initially realized during the development of the
polio vaccine using primary monkey kidney cells (the polio vaccine was the
first commercial product generated using mammalian cell cultures).

These primary monkey kidney cells were associated with many
disadvantages such as:
- Chances of contamination with adventitious agents (risk of contamination
by various monkey viruses is high).
- Most of the cells are anchorage-dependent and can be cultured efficiently
only when they are attached to a solid or semi-solid substrate (obligatorily
adherent cell growth).
T- he cells are not well characterized for virus production.
A scarcity of donor animals as they are on the verge of extinction.
The foundation of animal tissue culture can be considered to have occurred in
1880: Arnold showed that leukocytes can divide outside the body.
Then, in the beginning of the 19th century:Jolly investigated the behavior of animal
cells in serum lymph.

1907 : Harrison developedment animal tissue culture commenced after the
breakthrough frog tissue culture technique. Due to this effort Harrison is considered
as the father of tissue culture. In his experiment he introduced tissue from frog
embryos into frog lymph clots and showed that not only did the tissue survive, but
nerve fibers grew out from the cells.

During the mid-20th century, human diploid fibroblast cells were established by
Hayflick and Moorhead. They named this cell line MRC-5 (a cell line of fibroblasts
derived from lung tissue).

(1964): Wiktor et al explored the utilization of this cell line in the production of
rabies virus for vaccine production. After a couple of years they suggested a large-
scale production protocol along with a method for the assessment of purified rabies
vaccine immunogenicity.
Losee and Ebeling cultured the first cancer cells and after a few decades the first
continuous rodent cell line was established by Earle (1943).

In 1951, Gay established that human tumor cells can give rise to continuous cell
lines. The cell line considered as the first human continuous cell line was derived
from a cancer patient, Henrietta Lacks, as mentioned above, and HeLa cells are still
used very widely. Continuous cell lines derived from human cancers are the most
extensively used resource in the modern laboratory.
 Advantages of Plant Tissue Culture
There are several advantages to using the tissue culture process. We already
mentioned its effectiveness in helping developing countries to increase food
production, but what are some other advantages that may be relevant to you?

- The new plantlets can be grown in a short amount of time.
- Only a small amount of initial plant tissue is required.
- The new plantlets and plants are more likely to be free of viruses and diseases.
- The process is not dependent on the seasons and can be done throughout the
year.
- You need only a relatively small space to perform the process (ten times the plants
in one-tenth of the space).
- On a larger scale, the tissue culture process helps to supply the consumer market
with new subspecies and variety.
- People looking to cultivate challenging plants such as specific breeds of orchid find
more success with the tissue culture process than traditional soil.
Disadvantages of Plant Tissue Culture
- Tissue culture can require more labor and cost more money in building the
facility and equipping the lab with all the instruments and chemicals.
- There is a chance that the propagated plants will be less resilient to diseases when
grown in outside conditions due to the type of environment they are grown in.
- It is imperative that, before being cultured, the material is screened; failure to pick
up any abnormalities could lead to the new plants being infected.
- While the success rate is high if the correct procedures are followed, success
with the tissue culture is not a guarantee. That's why accurate protocols are
necessary to grow plants in tissue culture setting, which can be laborious when
you try to create one working protocol by yourself.
- Contamination is the major issue in tissue culture setting. Plants can get infected
by bacteria, fungi, and viruses. That's why all measures should be taken and PPE kit
should be used while performing tissue culture in your lab.
- Tissue culture is an advanced technique and require some advanced knowledge
and practice for anyone to get started in the field.
Advantages of using animal cell culture
- Homogeneity of cells can be maintained more easily by using selective media.
- Physiological conditions (nutrient and hormone levels) as well as physio-chemical
environment in the culture (temperature, pH, level of dissolved gases, and osmolarity)
can be precisely controlled.
- Cell-to-cell interactions, regulation of matrix, cell substrate attachment, and other
micro-environment components of the cell can be controlled.
- It is possible to store cell cultures in liquid nitrogen for a long period of time using an
appropriate cryopreservation medium.

- Various cell quantification techniques can be used to easily quantify cells in the
culture.
- Immune-staining or cytological techniques can be used to easily characterize cells in
the culture.
- Researchers can test the potential toxicity of drugs and other compounds using in vitro
cytotoxicity studies, which use the cell culture technique.
- Cell cultures can be used to study the effects of concentration and time on drugs,
toxins, and pharmacologically active molecules.
- Using cell culture techniques significantly reduces the use of animals in scientific
experiments.
- Monoclonal antibodies can be produced using cell culture with hydridoma
technology.
- Aids in the study of molecular pathways inside cells.
- Helps researchers visualize various molecular and physiological events in the cells.
Disadvantages of animal cell culture:
- It can be challenging to maintain sterile aseptic conditions in vitro.
- There are challenges involved in maintaining proper concentration of nutrients and
serum, and standardization of medium as they vary among different cell types and their
origin.
- There is a high possibility of microbial and chemical contamination as well as cross
contamination among different types of cells in culture.
- There is a high possibility of cells undergoing chemical, physical and physiological
changes, induced by the micro-environment inside the culture container.
- Chances of genetic variation within a single cell population are very high because of
the rapid growth rate of cells in artificial culture.
- It is often difficult to identify cell types as the expression of marker proteins are often
insufficient under in vitro conditions.
- Setting up a cell culture requires a very high capital investment.
- Proper maintenance of the cells requires considerable experience and expertise.
- There are a limited number of passages in most of the primary cells in culture.