Plant prop quiz 2
Leaf Cuttings —Adventitious Bud (and Shoot) and Root Formation
-- Leaf Cuttings with Preformed Primary Meristems -- Leaf Cuttings with Wound-Induced, Secondary Meristems
Bud effects on rooting
-In some cases buds may be essential or promotive. - Root promoting compounds are thought to be translocated from buds and/or shoot tips, particularly when cuttings are active and not at rest. -These may include auxin andother root promoting substances.
Stages of root formation (4)
1.Dedifferentiation of cells. 2.Formation of root initials - from cells near the vascular bundles or vascular tissue which have become meristematic by dedifferentiation. 3.Development into root primordia. 4.Emergence of roots through the epidermis and formation of vascular connections between the root primordia and the cutting
Stages 4: Root emergence
1.Developing adventitious roots will push their way through the cortex and epidermis and emerge to be functional roots. 2.Visible roots are evident 3. Cuttings do not need as frequent misting.
Cytokinins
Effective in initiating budsand shoots from leaf cuttings and in tissue culture systems.
Maintaining polarity is important in cuttings.
It still produces shoots at the proximal end,and roots at the distal end regardless of the orientation.
Rooting co-factors.
Non-auxin chemicals that promote rooting have been identified in some species. • These chemical act synergistically with auxin to promote rooting
Adventitious organs
Organs that arise from dedifferentiation of pyarenchyma cells
Auxins
Required for initiation of adventitious roots. Division of the first root initial cells are dependent on applied or endogenous auxin.
Callus Formation:
Rooting and Bud (and Shoot) Callus Formation: Organogenesis - Root Organogenesis - Shoot Organogenesis
IBA and NAA:
Synthetic auxins that have greater stability. Most widely used for rooting stem cuttings.
Polarity
The orientation inherent in a stem or root cutting stem or root cutting
Preformed (latent) root initials
develop naturally on the stem and lie dormant or active growth.
Wound-induced roots
develop only after the cutting is made in response to wounding. Formed "de novo" (= "anew") ex.Corn
Formation of adventitious roots and shoots requires plant cells to
differentiate and develop into a root or shoot system
An adventitious bud is an
embryonic shoot
The distal end
is nearest the stem or root tip
When a potential root initiation site is already present the initial cell divisions
lead to root production in situ
roots tend to grow in what type of rows
longitudal
indirect model (interim period of undifferentiated cell division—i.e., generally
more difficult to root
IAA: Synthetic auxins that have greater stability. Most widely used for rooting stem cuttings.
naturally occurring, very unstable, readily degraded auxin
Adventitious buds & shoots = those that arise from any plant part
other then terminal, lateral or latent buds and stems
Auxin moves in a
polar manner from distal to proximal ends.
Changes in endogenous levels may influence
propigation success
adventitious root formation through direct (cells in close proximity to vascular system—i.e., generally
root easier
Application of cytokinin inhibits
rooting in cuttings.
• Adventitious roots =
roots that arise on aerial plant parts, underground stems (tissues other than the seedling root and its branches).
Dedifferentiation
the ability of previously developed, differentiated cells to initiate cell divisions & form new meristems =adventitious roots and buds
Correlative effect
the control of one organ over the development of another - Bud effects on rooting - Leaf effects on rooting Plant growth regulators play a major role
Endogenous rooting inhibitors.
• Rooting inhibitors have been found in some difficult-to-root species • In some cases differences among cultivars and/or tissues of different ages correlate with the rooting ability of shoots.
Leaf effects on rooting
-The presence of leaves exerts stimulating influence - Carbohydrates are translocated from the leaves. -Auxins and other substances are transported polarly
Stages 2: Formation of root initials (3)
1. Dividing cells organize into a root initial. 2. An apical root tip forms. 3. No vascular connection has formed between the cutting and developing root yet
Stages 3: Root primordium formation (3)
1. Root primordia have a well defined root meristem and root cap 2. The vascular system is forming to connect with the xylem and phloem in the parent stem 3. Root primordia are breaking through the sclerenchyma ring and pushing aside the swollen cortex cells
Order of events to produce wound-induced roots
1. outer, injured cells die 2.a necrotic plate forms and seals the would (suberin) = cork and gum blocks xylem 3. parenchyma cells (callus) form behind plate 4.cells near the vascular cambium divide and produce adventitious roots
Stages 1: Dedifferentiation (2)
1.Cells in the cortex divide. 2. These divisions are polar and ordered and will develop into roots. * = dividing cells in the cortex are random and will not become roots. # = epidermal cells
Low auxin/high cytokinin favors
adventitious buds.
Generally, a high auxin low cytokinin ratio favors
adventitious root formation.
Stem and leaf-bud cuttings only need to produce
adventitious roots
The success of cutting propagation depends upon the development of
adventitious roots and/or shoots that develop from cells and tissues of the plant parts used as the cutting material
Root and leaf cuttings need to develop
both adventitious buds & adventitious roots
At high cytokinin concentration, only
buds and budlike tissue are visible with poor shoot development; roots
The proximal end is
closest to the root:shoot junction.
