Perchè MERISTEMA: Wikipedia 2008


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A meristem is a tissue in all plants consisting of undifferentiated cells ( meristematic cells ) and found in zones of the plant where growth can take place.

The term “meristem” was first used by Karl Wilhelm von Nägeli (1817-1891) from his book “Beiträge zur Wissenschaftichen Botanik” in 1858. It is derived from the Greek word “merizein”, meaning to divide in recognition of its inherent function.

Differentiated plant cells generally cannot divide or produce cells of a different type. Therefore, cell division in the meristem is required to provide new cells for expansion and differentiation of tissues and initiation of new organs, providing the basic structure of the plant body.

Meristematic cells are analogous in function to stem cells in animals , are incompletely or not at all differentiated , and are capable of continued cellular division (youthful). Furthermore, the cells are small and protoplasm fills the cell completely. The vacuoles are extremely small. The cytoplasm does not contain differentiated plastids ( chloroplasts or chromoplasts ), although they are present in rudimentary form ( proplastids ). Meristematic cells are packed closely together without intercellular cavities. The cell wall is a very thin primary cell wall .

Maintenance of the cells requires a balance between two antagonistic processes: organ initiation and stem cell population renewal.

Meristematic zones

Apical meristems are the completely undifferentiated (indeterminate) meristems in a plant. These differentiate into three kinds of primary meristems. The primary meristems in turn produce the two secondary meristem types. These secondary meristems are also known as lateral meristems because they are involved in lateral growth.

At the meristem summit there is a small group of slowly dividing cells which is commonly called the central zone. Cells of this zone have a stem cell function and are essential for meristem maintenance. The proliferation and growth rates at the meristem summit usually differ considerably from those at the periphery.


[ edit ] Apical meristems

Organisation of an apical meristem (growing tip) 1 - Central zone 2 - Peripheral zone 3 - Médullaire meristem 4 - tissus médullairesOrganisation of an apical meristem (growing tip)
1 - Central zone
2 - Peripheral zone
3 - Médullaire meristem
4 - tissus médullaires

The apical meristem , or growing tip, is a completely undifferentiated meristematic tissue found in the buds and growing tips of roots in plants . Its main function is to begin growth of new cells in young seedlings at the tips of roots and shoots (forming buds, among other things). Specifically, an active apical meristem lays down a growing root or shoot behind itself, pushing itself forward. Apical meristems are very small, compared to the cylinder-shaped lateral meristems .

Apical meristems are composed of several layers. The number of layers varies according to plant type. In general the outermost layer is called the tunica while the innermost layers are the corpus . In monocots , the tunica determine the physical characteristics of the leaf edge and margin. In dicots , layer two of the corpus determine the characteristics of the edge of the leaf. The corpus and tunica play a critical part of the plant physical appearance as all plant cells are formed from the meristems. Apical meristems are found in two locations: the root and the stem.


[ edit ] Shoot apical meristems

The source of all above-ground organs. Cells at the SAM summit serve as stem cells to the surrounding peripheral region, where they proliferate rapidly and are incorporated into differentiating leaf or flower primordia.

The shoot apical meristem is the site of most of the embryogenesis in flowering plants. Primordia of leaves, sepals, petals, stamens and ovaries are initiated here at the rate of one every time interval, called a plastochron . It is where the first indications that flower development has been evoked are manifested. One of these indications might be the loss of apical dominance and the release of otherwise dormant cells to develop as axillary shoot meristems, in some species in axils of primordia as close as two or three away from the apical dome. The SAM consists of 4 distinct cell groups: -.

  • Stem Cells
  • The immediate daughter cells of the stem cells
  • A subjacent organising centre
  • Founder cells for organ initiation in surrounding regions

The four distinct zones mentioned above are maintained by a complex signalling pathway. In Arabidopsis thaliana , 3 interacting CLAVATA genes are required to regulate the size of the stem cell reservoir in the SAM by controlling the rate of cell division . [1] CLV1 and CLV2 are predicted to form a receptor complex (of the LRR receptor like kinase family) to which CLV3 is a ligand . CLV3 shares some homology with the ESR proteins of maize , with a short 14 amino acid region being conserved between the proteins. Proteins that contain these conserved regions have been grouped into the CLE family of proteins.

CLV1 has been shown to interact with several cytoplasmic proteins that are most likely involved in downstream signalling , for example the CLV complex has been found to be associated with Rho/Rac small GTPase related proteins . These proteins may act as an intermediate between the CLV complex and a mitogen-activated protein kinase (MAPK) which is often involved in signalling cascades. KAPP is a kinase-associated protein phosphatase that has been shown to interact with CLV1. KAPP is thought to act as a negative regulator of CLV1 by dephosphorylating it.

Another important gene in plant meristem maintenance is WUSCHEL (shorted to WUS ), which is a target of CLV signalling. WUS is expressed in the cells below the stem cells of the meristem and its presence prevents the differentiation of the stem cells.CLV1 acts to promote cellular differentiation by repressing WUS activity outside of the central zone containing the stem cells. STM also acts to prevent the differentiation of stem cells by repressing the expression of Myb genes that are involved in cellular differentiation.

Root apical meristems

10x microscope image of root tip with meristem (1)10x microscope image of root tip with meristem (1)

Unlike the SAM, the root apical meristem (RAM) produces cells in two directions. It is covered by the root cap, which protects the apical meristem from the rocks, dirt and pathogens. Cells are continuously sloughed off the outer surface of the root cap. The center of the RAM is occupied by a quiescent center which has low mitotic activity. Evidence suggests the quiescent center does function as the zone of initials. Infrequent division of initial cells in the quiescent center is the source of cells for the RAM. These initial cells and tissue patterns become established in the embryo in the case of the primary root and in the new lateral meristems in the case of secondary roots.


Intercalary meristem

The intercalary meristems occur only in monocot (particularly grass) stems at the base of nodes and leaf blades. Intercalary meristems are capable of cell division and allow for rapid growth and regrowth of many monocots. Intercalary meristems at the nodes of bamboo allow for rapid stem elongation, while those at the base of most grass leaf blades allow damaged leaves to rapidly regrow. This leaf regrowth in grasses evolved in response to damage by grazing herbivores, but is more familiar to us in response to lawnmowers.


Floral meristem

When plants begin the developmental process known as flowering, the shoot apical meristem is transformed into an inflorescence meristem which goes on to produce the floral meristem which produces the familiar sepals, petals, stamens, and carpels of the flower.


Apical dominance

Apical dominance is phenomenon where one meristem prevents or inhibits the growth of other meristems. As a result the plant will have one clearly defined main trunk. For example, in trees the tip of the main trunk bears the dominant meristem. Therefore the tip of the trunk grows fast and is not shadowed by branches. If the dominant meristem is cut off, one or more branch tips will assume dominance. The branch will start growing faster and the new growth will be vertical. Over the years the branch may begin to look more and more like an extension of the main trunk. Often several branches will exhibit this behaviour after the removal of apical meristem, leading to a bushy growth.

The mechanism of apical dominance is based on the plant hormone auxin . It is produced in the apical meristem and transported towards the roots in the cambium . If apical dominance is complete, it prevents any branches from forming as long as apical meristem is active. If the dominance is incomplete, side branches will develop.

Primary meristems

Apical meristems may differentiate into three kinds of primary meristem:

  • Protoderm - lies around the outside of the stem and develops into the epidermis .
  • Procambium - lies just inside of the protoderm and develops into primary xylem and primary phloem . It also produces the vascular cambium , a secondary meristem.
  • Ground meristem develops into the pith . It produces the cork cambium , another secondary meristem.

These meristems are responsible for primary growth, or an increase in length or height.

Secondary meristems

There are two types of secondary meristems, these are also called the lateral meristems because they surround the established stem of a plant and cause it to grow laterally (i.e. larger in diameter).

  • Vascular cambium - produces secondary xylem and secondary phloem, this is a process which may continue throughout the life of the plant. This is what gives rise to wood in plants. Such plants are called arborescent . This does not occur in plants which do not go through secondary growth (known as herbaceous plants).
  • Cork cambium - gives rise to the bark of a tree.

Indeterminate growth of meristems

Though each plant grows according to a certain set of rules, each new root and shoot meristem can go on growing for as long as it is alive; In many plants meristematic growth is potentially indeterminate , making the overall shape of the plant not determinate in advance. This is the primary growth .


Under appropriate conditions, each shoot meristem can develop into a complete new plant or clone . Such new plants can be grown from shoot cuttings that contain an apical meristem. Root apical meristems are not readily cloned, however. This cloning is called asexual reproduction or vegetative reproduction and is widely practiced in horticulture to mass-produce plants of a desirable genotype . This process is also known as mericloning.