Plant Structure and Function

The "Typical" Plant Body

The Root System

Underground (usually)
Anchor the plant in the soil
Absorb water and nutrients
Conduct water and nutrients
Food Storage

The Shoot System

Above ground (usually)
Elevates the plant above the soil
Many functions including:
- photosynthesis
- reproduction & dispersal
- food and water conduction
Note: the shoot system includes the leaves and the reproductive organs, although these will be covered in more detail separately

Before we look at plant anatomy in detail, I want to caution you that we will be looking almost exclusively at Angiosperms, also know as flowering plants. Angiosperms are by far the most diverse group of plants known (over 275,000 named species and thought to be at least that many more unknown to science).

Within the Angiosperms, there are two plant groups, the Monocots and the Dicots. The distinction between these two groups is not always clear, but some general trends are outlined below:

	Monocots	Dicots
Floral Arrangement	3's	4's and 5's
Leaf Venation	Parallel	Net
Vascular bundles	Scattered	Ring
Habit	Herbaceous	Herbaceous + Woody
Roots	Fibrous	Taproot
Growth	Primary only	Primary and Secondary
Examples:	Grass, Palm, Orchid	Oaks, Roses, Sunflowers

Cell Types in the Plant Body

Parenchyma Cells

Least specialized plant cells
Thin and somewhat flexible cell walls
Living at maturity
Carry on most of the plant's metabolic functions
Generally have a large central vacuole
Most parenchyma cells have the ability to differentiate into other cell types under special conditions
- During repair and replacement of organs after injury

Collenchyma Cells

Thicker primary cells walls (usually with uneven thickness)
Living at maturity
Role in support of herbaceous plants
- Example - the "strings" of celery

Schlerenchyma Cells

Thick secondary cell walls
Dead at functional maturity
Cannot increase in length - occur in parts of the plant which have quit growing in length
Two types - fibers and schlerids
- Fibers - long, slender cells with a more or less regular secondary cell wall
  - Example - hemp fibers for making rope
- Schlerids - shorter cells with an irregular shape
  - Example - stone cells in pears and hard nut and seed shells

Xylem

Thick secondary cell walls, often deposited unevenly in a coil-like pattern so that they may stretch
Dead at functionally maturity.
Involved in conduct of water and ions in the plant
Two types - tracheids and vessels
- Tracheids - long, slender cells connected to each other by pits. Found in all vascular plants
- Vessels - shorter, larger diameter cells with completely perforated cell wall ends. Found only in Angiosperms

Phloem

Involved in transport of sucrose, other organic compounds, and some ions
Living at functional maturity
- Protoplast may lack organelles and nucleus, though
Endwalls connect to each other via sieve-plates
Two types of cells in the phloem - sieve-tube members and companion cells
- Sieve-tube members - actual conduit for sucrose transport
- Companion cells - has a nucleus that may also control the sieve-tube element and may aid in sucrose loading

Tissue Organization in Angiosperms

Dermal Tissue

Generally a single layer of cells
The "skin" of the plant
Primarily parenchyma cells
Main role is protection of the plant

Ground Tissue

Makes up the bulk of the plant
Predominately parenchyma, but collenchyma and schlerenchyma cells are found
Diverse functions including photosynthesis, storage, and support

Vascular Tissue

Involved in the transport of water, ions, minerals, and food
Also has a secondary role in support
Composed of xylem, phloem, parenchyma, schlerenchyma

Plant Growth

Plant growth is a phenomenon different from animal growth.
Animas exhibit a growth pattern called determinate growth.

After fertilization, the zygote cells are rapidly dividing, undifferentiated cells
However, after a certain critical stage, the cells differentiate and form tissues.
- From this point onward, their developmental fate is sealed
- There are exceptions to this (i.e. stem cells in bone marrow)
Most animals have a pre-programmed body plan (i.e. barring mutation or accident, most humans have 10 fingers and toes, two eyes, a heart with four chambers, etc..)
Most animals quit growing after a certain age

Plants, however, exhibit a growth pattern called indeterminate growth

The plant retains areas where rapidly dividing, undifferentiated cells remain all through the life of the plant
These areas are called meristems
- Meristematic tissue continues to rapidly divide producing undifferentiated cells which may eventually differentiate to form the tissue and cell types discussed above
Plants do not have a pre-programmed body plan
- There are constants like leaf shape and branching patters (opposite, alternate, etc.) but you can never predict where a new branch will come about on a tree...
Plants continue to grow throughout their life

Meristems

The pattern of plant growth depends upon the location of meristems

Apical meristems

located at the tips of roots and shoots
supply cells for the plant to increase in length (grow up for shoots and down for roots)
- growth in this direction is known as primary growth
- primary growth found in herbaceous and woody plants
- primary growth found in monocots and dicots

Lateral meristems

located near the periphery of the plant, usually in a cylinder
supply cells for the plant to increase in girth
- growth in this direction is known as secondary growth
- found in all woody and some herbaceous plants
- lateral meristems and secondary growth found only in dicots

Primary Growth in the Root

Root Cap
- Thimble-like covering which protects the delicate apical meristem
- Produced from cells derived from the root apical meristem
- Secretes polysaccharide slime that lubricates the soil
- Constantly sloughed off and replaced
Apical Meristem
- Region of rapid cell division of undifferentiated cells
- Most cell division is directed away from the root cap
Quiescent Center
- Populations of cells in apical meristem which reproduce much more slowly than other meristematic cells
- Resistant to radiation and chemical damage
- Possibly a reserve which can be called into action if the apical meristem becomes damaged
The Zone of Cell Division - Primary Meristems
- Three areas just above the apical meristem that continue to divide for some time
- Protoderm - outermost primary meristem - produces cells which will become dermal tissue
- Ground meristem - central primary meristem - produces cells which will become ground tissue
- Procambium - innermost primary meristem - produces cells which will become vascular tissue
The Zone of Elongation
- Cells elongate up to ten times their original length
- This growth pushes the root further downward into the soil
The Zone of Maturation
- Region of the root where completely functional cells are found

Root Anatomy - Dicot Roots

Epidermis

Dermal tissue
Protection of the root

Cortex

Ground tissue
Storage of photosynthetic products
Active in the uptake of water and minerals

Endodermis

cylinder once cell thick that forms a boundary between the cortex and the stele
contains the casparian strip, which will be explained later when we discuss water uptake

Pericycle

found just inside of the endodermis
may become meristematic
responsible for the formation of lateral roots

Vascular Tissue

Xylem and Phloem
Forms an X-shaped pattern in very center of root

Root Anatomy - Monocot Roots

Epidermis

Dermal tissue
Protection of the root

Cortex

Ground tissue
Storage of photosynthetic products
Active in the uptake of water and minerals

Endodermis

cylinder once cell thick that forms a boundary between the cortex and the stele
even more distinct than dicot counterpart
contains the casparian strip, which will be explained later when we discuss water uptake

Vascular Tissue

Xylem and Phloem
Forms a ring near center of plant

Pith

Center most region of root

Primary Growth of Shoots

Apical Meristem

Dome-shaped mass of dividing cells at tip of terminal bud
Gives rise to three primary mersitems: protoderm, ground meristem, and procambium just as root apical meristem
Leaves arise as leaf primordia on the flanks of apical meristem

Axillary Meristems

Regions of meristematic tissue left behind from apical meristem
Dormant, but have the ability to become activated and form a branch (i.e. becomes the branch's apical meristem)
- Note difference between how shoots forms a branch versus how a root forms a branch
- This is do to the position of the vascular tissue in a root vs. the vascular tissue in a shoot
Subtended by a leaf

Secondary Growth

Lateral Meristems add girth by producing secondary vascular tissue and periderm

Secondary Plant Body - tissue produced mersitems involved in secondary growth
Vascular Cambium - secondary growth meristem which produces xylem and phloem
Cork Cambium - secondary growth meristem which produces cork, a tough substance that replaces the epidermis

Vascular Cambium

Secondary growth begins with the initiation of the vascular cambium, a cylinder of meristematic tissue that produces additional xylic and phloic tissues. The cells that eventually form the vascular cambium come from two sources, the procambium in the vascular bundles and the interfascicular parenchyma cells between vascular bundles. The diagram below shows the positions of these two populations of cells in a stem with only primary growth.

The two populations of dividing cells unite to form a continuous ring of dividing cells, the vascular cambium.

If we look closely at the cells of the vascular cambium we see two patterns of division. Initial cells can undergo multiplicative divisions (red line in the following diagram) or they can undergo additive divisions (blue line). Multiplicative divisions produce more initial cells and result in the increased circumference of the vascular cambium. Of the two cells produced from an additive division one is retained as an initial cell that will divide again, and the other will become a phloem mother cell or a xylem mother cell. These mother cells will differentiate into their respective cell types.

Secondary Growth in Dicots - Herbaceous and Woody

Both herbaceous and woody dicots exhibit secondary growth.
In herbaceous dicots, secondary xylem and phloem are in a single ring of discrete bundles which form
In woody dicots, the secondary xylem forms a continuous cylinder

The Cork Cambium and the Production of Periderm

During secondary growth, the epidermis produced by primary growth splits and falls off the stem
It is replaced by a new protective tissues produced by the cork cambium

A cylinder meristematic tissue that initially forms from the outer cortex of the stem
Cork cambium produces cork cells, which form exterior to the cork cambium
As cork cells mature, they secrete suberin (a waxy substance) in their cell walls and then die
Cork cells function as a barrier to protect the stem from physical damage and from pathogens

The cork cambium + the cork are known as the periderm
The "bark" of the tree consists of the periderm + the phloem

What would happen if you removed a large ring of bark from a tree?

Unlike the vascular cambium which can grow in diameter via multiplicative growth, the cork cambium is fixed in size.

After a few weeks, the cork cambium loses meristematic ability
Expansion splits the original periderm
New cork cambium then forms deeper in the cortex of the stem
Eventually no more cortex remains, so the cork cambium then forms from parenchyma cells of the secondary xylem

The Monocot Stem - A Stem Lacking Secondary Growth

Monocot stems differ from dicot stems in that they lack secondary growth

No vascular cambium nor cork cambium
Stems usually uniform in diameter
Scattered vascular bundles (not in a ring like dicot stems)