- •2) Objects and methods of animal biotechnology
- •3) Totipotent, multipotent, pluripotent animal cells
- •4.Allophenic animals. Genetic chimers
- •5)The principles of genetic cloning
- •6.Allophenic animals. Genetic chimers
- •8) Methods for introducing foreign dna into animal cells
- •9)Cryopreservation of reproductive and germ cells of animals and humans
- •11)The principles and methods of plant cells cultivation in vitro
- •12. The types of medium. Physiological means of compounds medium (as an example you can use the composition of Murashige-Skug medium)
- •14)Differentiation and dedifferentiation in plant cell culture. The obtaining callus mass and cultivation of callus tissue .
- •15)The influence of phytohormons on morphogenesis and regeneration in plant cells culture
- •16.The main path of morphogenesis processes in plant cells culture
- •18.The growth stages in suspension culture
- •20) The factors influenced on microclonal propagation in plant cell culture.
- •21) What is Biotechnology? Various definitions of “Biotechnology”. History of Biotechnology
- •22.Microbial Biotechnology: fundamentals of applied microbiology
- •24.Sterilization in Biotechnology: Methods and principles
- •26) Somaclonal and gametoclonal variation in plant cells culture.
- •27) Artificial seeds". Embryo culture in vitro
- •28. Culture of apical meristem cells
- •29)Cell reconstruction. Theoretical means of cell reconstruction
- •30.Basics of phytopathology. The main diagnostics methods of plant diseases
- •32) Main objects of animal biotechnology:
- •33) Morphological and functional features of gametes - eggs and sperm
- •34Hormonal regulation of mammalian reproduction
- •35)The history of investigations of the genetic transformation of animal cells
- •36.The principles of genetic engineering in animal biotechnology
- •53)Genetic engineering. Methods of genetic transformation
- •54. Methods of receiving plant materials without viruses
- •56) The vector systems used in the genetic engineering
- •57) Methods of genetic engineering: agrobacterial genetic transformation
- •58)Methods of genetic engineering: bioballistics methods
- •60.Apply cell technology and cryopreservation technology for safe gene bank
- •62) Methods of producing chimeras
- •63) Collection and cultivation of oocytes in vivo and in vitro
- •64 Collection and cultivation of embryos in vivo and in vitro
- •66.Fertilization of oocytes in vitro, environment and conditions
- •68) Draw a diagram of the structure of plasmid pBr322
- •69) Draw a diagram of an experiment in genetic engineering (design recDna) and give a description of the main stages
- •70)Describe the calcium-phosphate method for introducing foreign dna into mammalian cells.
- •72 Methods of cryopreservation of sperm and oocytes of mammals
- •74) Modes of freezing and thawing of gametes and embryos
- •75) Methods of artificial fertilization: gamete insemination fallopian tube (gift), zygosity insemination fallopian tubes (zift).
- •76) Stem cells and prospects for their use in practice
- •78.Technical equipment of experiments on artificial insemination
- •80) Methods of animal cloning, reproductive and therapeutic cloning
- •81) Microorganisms in water and wastewater treatment
- •82 Microbial fermentations in food products
- •84.Bacterial examination of water and standard water analysis
- •86) Use of e.Coli for the biotechnological production
- •87) Microbes in milk and dairy products
- •88) What is the benefit of microorganisms in industry
- •90. Algae, their applications
15)The influence of phytohormons on morphogenesis and regeneration in plant cells culture
Phytohormones function to coordinate plant growth and development. The compounds that have been considered as plant hormones are:
indole-3-acetic acid (auxin)
cytokinin
gibberellin
ethylene
abscisic acid
In addition, the following substances have been shown to have important growth regulating activities and are considered to function as Phytohormones:
brassinosteroids
jasmonic acid
salicylic acid
Plants contain a wealth of compounds often referred to as secondary metabolites with unknown functions. Many of these have the potential to have growth regulatory roles that remain to be discovered. Among these types of compounds, some have been shown to affect growth. These include
flavonoids
carbohydrates
fatty acids
peptides
phenolic acids and alcohols
We have already seen a number of developmental and physiological process in which certain phytohormones play critical roles. In addition to the processes already discussed, phytohormones and other growth regulatory substances control a wide range of other processes and in many cases, the effects of a particular hormone depend on the action of another.
Auxin has already been discussed with respect to its role in controlling cell elongation during photo- and gravitropism. Control of cell elongation is just one of many auxin responses. Auxin is a term that refers to compounds that, when applied to plants of plant tissues, cause growth effects that are similar to those seen with indoleacetic acid. Auxins include compounds like 2,4-D and NAA (2,4-D is a common herbicide and NAA is often included in mixtures used to stimulate root formation in cutting).
Auxin-regulated responses include:
induction of lateral and adventitious roots
stimulation of fruit growth
apical dominance
leaf and flower abscission
DNA synthesis
Auxins have found several uses in agriculture and horticulture. The auxin 2,4-D is a commonly used herbicide against broadleaf plants. NAA and IBA are often the active ingredient in products that stimulate root formation on plant cuttings. Auxins may be used to enhance fruit production or harvesting but these effects are species specific. Auxin, along with cytokinin, is used in for culturing plant tissues for mass propagation.
We have discussed cytokinin with respect to their role in controlling dormancy of seeds and buds. Like auxin, cytokinin is a term that describes a class of compounds. Specifically, cytokinins are compounds that stimulate cell division or cytokinesis, although they may also do other things. Proper regulation of cell division also requires auxin, which is needed to cause DNA synthesis before a cell can divide.
Cytokinin responses include:
cell division (cytokinesis)
organ development (shoot formation)
delayed senescence and promotion of chloroplast development
affect nutrient sink strength of organs
promotion of lateral bud growth
promotion of cotyledon expansion (only in certain species)
inhibition of auxin-induced elongation
Cytokinins have found few uses in agriculture. They are used in plant tissue culture and they have been used to delay senescence. Possible future applications will depend on clever bio-engineering. For example, since cytokinins are important in regulating source-sink relationships, controlled production of cytokinins in fruit could potentially lead to increased nutrient mobilization into the fruit, thus, more nutritionally valuable food.