Course Content
Introduction
0/5
Definition of crop and Plant  physiology
Aspects of Crop physiology
Importance of studying Plant Physiology
Scope of plant physiology
Practical application of crop physiology
Introduction to cell physiology
0/12
Introduction
Anatomy of cell
Nucleus
Mitochondria
Golgi bodies ( Dictyosomes)
Endoplasmic reticulum
Lysosome
Glyoxysomes ( Only fat storing cells of plants)
Chloroplast
Vacuole
Perioxisomes
Plant cell wall
Biological phenomenon in plant cells
0/5
Principles of thermodynamics
Some terminologies
Application of 1st law of thermodynamics
Application of 2nd law of thermodynamics
Significance of entropy
Absorption and translocation of water and nutrients
0/14
Introduction
Osmosis
Permeability of a membrane
Absorption of water
Pathway of water in root
Factors affecting water absorption
Minerals absorption
Theories of mineral absorption
Ascent of sap
Path of Ascent of sap
Mechanism of ascent of sap
Vital theory
Root pressure theory
Physical force theory
Transpiration
0/5
Introduction
Structure of stomata
Opening and closing of stomata
Theories of opening and closing of stomata
Factors affecting transpiration
Photosynthesis
0/17
Structure of chloroplast
Photosynthesis
Light reaction (or hill reaction)
Difference between cyclic and non-cyclic reaction
Dark reaction or Calvin cycle or C3.
Factors affecting photosynthesis
Photorespiration
Main features of P.R.
Hatch and slack cycle or c4 – cycle
Mechanism of C4-cycle:
Pathways of Hatch and Slack Cycle
Characteristic Features of C4 plants :
Biological Significance of C4-cycle
Crassulacean acid metabolism or CAM cycle
Characteristic Features of CAM plants
Blackman’s law of limiting factors
External and Internal Factors for Blackman’s law
Respiration
0/6
Introduction
Difference between Aerobic and Anaerobic respiration
Mechanism of Respiration
Electron Transport System (ETC)
Components of electron transport system:
Factors affecting respiration
Translocation of photosynthetic products and production of secondary metabolites
0/10
Translocation
Principal pathways for translocation of materials after uptake by the roots of leaves of a plant
Anatomy of phloem
Mechanism of translocation
Protein – Lecithin Theory
Munch mass flow hypothesis
Transcellular streaming (Thaine, 1964)
Phloem loading and unloading
Phloem unloading and sink loading
Factors that control translocation
Physiology of growth and development in crops
0/27
Growth
Development
Types of Growth
Environmental factors influencing growth
Germination
Types of Germination
Environmental conditions affecting seed germination
Requirements for Germination
Seed dormancy
Secondary dormancy
Seed Scarification
Seed Stratification
Other method are
Photoperiodism
Types of Photoperiodic Plants.
Other classification
Importance of photoperiodism
Mechanism of photoperiodism
Florigen
Theory of endogenesus rhythm
Vernalization
Age and Site of Vernalization
Temperature Effect
Vernalin
Devernalization
Mechanism of floral induction in vernalized plants
Importance of vernalization
Plant growth regulators
0/8
Introduction
Classification of PGR
Auxin
Gibberellins
Cytokinin
Absicissic Acid (ABA)
Ethylene
Other hormones
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Auxin

  • Chemically, auxin is indoleacetic acid (IAA), which is synthesized from indole or tryptophan.

 

Role of Auxins

Ø Apical Dominance: Removal of apical bud stimulates lateral buds. Auxins inhibit lateral bud formation since they are synthesized in the apex. This phenomenon is called apical dominance. E.g.: Potato tubers for apical buds forming.

 

Ø Cell Division and Elongation: Shoot and Root Growth.

 

Ø Xylem Differentiation: Auxins help in establishing contact between vascular tissues of the callus and that of the bud and make it possible for the bud to grow properly in the callus. By adding Auxins and sugar continued growth of callus may be obtained and new shoots and even new plants can be produced.

 

Ø Nucleic Acid Activities of IAA increase total RNA – synthesizes specific enzymes leading to cell enlargement.

 

Ø Manifold Activities Play a specific role in seed germination, growth, rooting, flowering (Reproductive phase), abscission, parthenocarpy, and tissue culture.

 

Practical Applications of Auxins

Ø Germination: IAA, IBA, NBA, 2,4-D are mostly used in soaking seed for germination- at low concentrations promotes germination but these effects are subjected to variation depending on form and species of plants.

 

Ø Root: NAA, 10% induces 100% rooting in mango: Dashri, langra IBA+SUGAR application leads to greater number of roots-structure of roots also changed (Vascular bundles).

 

Ø Flowering: Play a floragenic role in day-neutral plants IAA promotes the formation of female flowers. Increased spikelet number, leaf number weight, and number of grains in wheat. NAA & IAA increases boll-set (G.hirsutum) induced more pineapple. Fruit weight increases.

 

Ø Parthenocarpy: IBA, NAA produces seed less/fruits – smaller sized fruits, but more in number, hence yield not affected.

 

Ø Fruit setting: By using 2,4,5 T fruit setting and yield of ber/fruit increased. IAA, IBA, and NAA induce high percentage fruit sets

 

Ø Prevention of pre-mature drop of fruits: 2,4, D, IAA, IBA, 2,4,5-T, are used to prevent preharvest drop of sweet oranges( 100 to 500 ppm)

 

Ø Tissue and OrgaCulturere: IAA & Kinetin

 

Ø Auxins as inhibitors: High concentrations of auxins inhibit growth and exert toxic effects on plants. In normacasesse, self-produced auxins inhibit the growth and development of lateral buds, and as a result, apical buds remain dormant.

 

 

Auxins are used inn Agriculture and Horticulture.

Ø Propagation of plants by hormone treatment of cuttings

Ø Prevention of pre-harvest drops of plants.

Ø Increasing parthenocarpy.

Ø Increasing fruit set.

Ø Prevention of sprouting by inhibiting buds.

Ø Inhibition of prolonged dormancy.

Ø Control of flowering.

Ø Defoliation of plants

Ø Prevention of leaf fall or abscission.

Ø Thinning of compact fruits.

Ø Selective weed killer.

 

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