Primary growth

Last updated January 01, 2024

Primary growth in plants is growth that takes place from the tips of roots or shoots. It leads to lengthening of roots and stems and sets the stage for organ formation. It is distinguished from secondary growth that leads to widening. Plant growth takes place in well defined plant locations. Specifically, the cell division and differentiation needed for growth occurs in specialized structures called meristems.^[1]^[2] These consist of undifferentiated cells (meristematic cells) capable of cell division. Cells in the meristem can develop into all the other tissues and organs that occur in plants. These cells continue to divide until they differentiate and then lose the ability to divide. Thus, the meristems produce all the cells used for plant growth and function.^[3]

At the tip of each stem and root, an apical meristem adds cells to their length, resulting in the elongation of both. Examples of primary growth are the rapid lengthening growth of seedlings after they emerge from the soil and the penetration of roots deep into the soil.^[4] Furthermore, all plant organs arise ultimately from cell divisions in the apical meristems, followed by cell expansion and differentiation.^[1]

In contrast, a growth process that involves thickening of stems takes place within lateral meristems that are located throughout the length of the stems. The lateral meristems of larger plants also extend into the roots. This thickening is secondary growth and is needed to give mechanical support and stability to the plant.^[4]

The functions of a plant's growing tips – its apical (or primary) meristems – include: lengthening through cell division and elongation; organising the development of leaves along the stem; creating platforms for the eventual development of branches along the stem;^[4] laying the groundwork for organ formation by providing a stock of undifferentiated or incompletely differentiated cells^[5] that later develop into fully differentiated cells, thereby ultimately allowing the "spatial deployment off both arial and underground organs."^[1]

Primary growth in stems

In stems, primary growth occurs in the apical bud (the one on the tips of stems) and not in axillary buds (primary buds at locations of side branching). This results from apical dominance, which prevents the growth of axillary buds that form along the sides of branches and stems. Auxin (a plant hormone) produced in the apical bud inhibits the growth of axillary buds. However, if the apical bud is removed or damaged, the axillary buds begin to grow.^[4]

These axillary buds have developed through evolution as a form of botanical risk management – they give the plant a means to continue to grow in the face of environmental hazards. When gardeners prune the tops of branches in order to obtain a bushier plant, they are using this feature of primary growth in plants. By eliminating the apical bud, they force the axillary buds to start growing, causing the plant to emit new stems.^[4]^[5]

Primary growth in roots

10x microscope image of a root tip with meristem: 1. quiescent center (consisting of rarely dividing stem cells); 2. calyptrogen (live root cap cells); 3. root cap; 4. sloughed off dead root cap cells; 5. meristem Root-tip-tag.png — 10x microscope image of a root tip with meristem: 1. quiescent center (consisting of rarely dividing stem cells); 2. calyptrogen (live root cap cells); 3. root cap; 4. sloughed off dead root cap cells; 5. meristem

Evolution has provided plants with a way of dealing with the injuries created as the root system burrows its way through soil that contain objects that injure the root buds. The tip of the root is protected by a root cap that is continuously sloughed off and replaced because it gets damaged as it pushes through the soil. Cellular division via mitosis takes place at the very tip of the root cap. The newly created cells then begin a stretching process of cellular elongation, thereby adding length to the root. Finally, the cells undergo a process of cellular differentiation that converts them into the components of dermal, vascular or ground tissues.^[5]^[6]

Plant morphology and function

By laying the groundwork for organ differentiation and because of its role in plant growth, primary growth – coordinated with the secondary growth process – largely determines the morphology and functioning of plants.

The question of how the biochemical pathways underpinning this process are regulated and coordinated is the subject of ongoing research. This research sheds light on the nature and timing of gene expression and of hormonal regulation in this process, though their roles are still not completely understood.^[1]^[2]

Related Research Articles

In vascular plants, the roots are the organs of a plant that are modified to provide anchorage for the plant and take in water and nutrients into the plant body, which allows plants to grow taller and faster. They are most often below the surface of the soil, but roots can also be aerial or aerating, that is, growing up above the ground or especially above water.

In botany, apical dominance is the phenomenon whereby the main, central stem of the plant is dominant over other side stems; on a branch the main stem of the branch is further dominant over its own side twigs.

The vascular cambium is the main growth tissue in the stems and roots of many plants, specifically in dicots such as buttercups and oak trees, gymnosperms such as pine trees, as well as in certain other vascular plants. It produces secondary xylem inwards, towards the pith, and secondary phloem outwards, towards the bark.

<span class="mw-page-title-main">Meristem</span> Type of plant tissue involved in cell proliferation

The meristem is a type of tissue found in plants. It consists of undifferentiated cells capable of cell division. Cells in the meristem can develop into all the other tissues and organs that occur in plants. These cells continue to divide until a time when they get differentiated and then lose the ability to divide.

<span class="mw-page-title-main">Plant hormone</span> Chemical compounds that regulate plant growth and development

Plant hormones are signal molecules, produced within plants, that occur in extremely low concentrations. Plant hormones control all aspects of plant growth and development, including embryogenesis, the regulation of organ size, pathogen defense, stress tolerance and reproductive development. Unlike in animals each plant cell is capable of producing hormones. Went and Thimann coined the term "phytohormone" and used it in the title of their 1937 book.

Auxins are a class of plant hormones with some morphogen-like characteristics. Auxins play a cardinal role in coordination of many growth and behavioral processes in plant life cycles and are essential for plant body development. The Dutch biologist Frits Warmolt Went first described auxins and their role in plant growth in the 1920s. Kenneth V. Thimann became the first to isolate one of these phytohormones and to determine its chemical structure as indole-3-acetic acid (IAA). Went and Thimann co-authored a book on plant hormones, Phytohormones, in 1937.

<span class="mw-page-title-main">Cytokinin</span> Class of plant hormones promoting cell division

Cytokinins (CK) are a class of plant hormones that promote cell division, or cytokinesis, in plant roots and shoots. They are involved primarily in cell growth and differentiation, but also affect apical dominance, axillary bud growth, and leaf senescence.

Organogenesis is the phase of embryonic development that starts at the end of gastrulation and continues until birth. During organogenesis, the three germ layers formed from gastrulation form the internal organs of the organism.

Plant embryonic development, also plant embryogenesis is a process that occurs after the fertilization of an ovule to produce a fully developed plant embryo. This is a pertinent stage in the plant life cycle that is followed by dormancy and germination. The zygote produced after fertilization must undergo various cellular divisions and differentiations to become a mature embryo. An end stage embryo has five major components including the shoot apical meristem, hypocotyl, root meristem, root cap, and cotyledons. Unlike the embryonic development in animals, and specifically in humans, plant embryonic development results in an immature form of the plant, lacking most structures like leaves, stems, and reproductive structures. However, both plants and animals including humans, pass through a phylotypic stage that evolved independently and that causes a developmental constraint limiting morphological diversification.

Gravitropism is a coordinated process of differential growth by a plant in response to gravity pulling on it. It also occurs in fungi. Gravity can be either "artificial gravity" or natural gravity. It is a general feature of all higher and many lower plants as well as other organisms. Charles Darwin was one of the first to scientifically document that roots show positive gravitropism and stems show negative gravitropism. That is, roots grow in the direction of gravitational pull and stems grow in the opposite direction. This behavior can be easily demonstrated with any potted plant. When laid onto its side, the growing parts of the stem begin to display negative gravitropism, growing upwards. Herbaceous (non-woody) stems are capable of a degree of actual bending, but most of the redirected movement occurs as a consequence of root or stem growth outside. The mechanism is based on the Cholodny–Went model which was proposed in 1927, and has since been modified. Although the model has been criticized and continues to be refined, it has largely stood the test of time.

Micropropagation or tissue culture is the practice of rapidly multiplying plant stock material to produce many progeny plants, using modern plant tissue culture methods.

The axillary bud is an embryonic or organogenic shoot located in the axil of a leaf. Each bud has the potential to form shoots, and may be specialized in producing either vegetative shoots or reproductive shoots (flowers). Once formed, a bud may remain dormant for some time, or it may form a shoot immediately.

In botany, secondary growth is the growth that results from cell division in the cambia or lateral meristems and that causes the stems and roots to thicken, while primary growth is growth that occurs as a result of cell division at the tips of stems and roots, causing them to elongate, and gives rise to primary tissue. Secondary growth occurs in most seed plants, but monocots usually lack secondary growth. If they do have secondary growth, it differs from the typical pattern of other seed plants.

A primordium in embryology, is an organ or tissue in its earliest recognizable stage of development. Cells of the primordium are called primordial cells. A primordium is the simplest set of cells capable of triggering growth of the would-be organ and the initial foundation from which an organ is able to grow. In flowering plants, a floral primordium gives rise to a flower.

Lateral roots, emerging from the pericycle, extend horizontally from the primary root (radicle) and over time makeup the iconic branching pattern of root systems. They contribute to anchoring the plant securely into the soil, increasing water uptake, and facilitate the extraction of nutrients required for the growth and development of the plant. Lateral roots increase the surface area of a plant's root system and can be found in great abundance in several plant species. In some cases, lateral roots have been found to form symbiotic relationships with rhizobia (bacteria) and mycorrhizae (fungi) found in the soil, to further increase surface area and increase nutrient uptake.

Polar auxin transport is the regulated transport of the plant hormone auxin in plants. It is an active process, the hormone is transported in cell-to-cell manner and one of the main features of the transport is its asymmetry and directionality (polarity). The polar auxin transport functions to coordinate plant development; the following spatial auxin distribution underpins most of plant growth responses to its environment and plant growth and developmental changes in general. In other words, the flow and relative concentrations of auxin informs each plant cell where it is located and therefore what it should do or become.

This page provides a glossary of plant morphology. Botanists and other biologists who study plant morphology use a number of different terms to classify and identify plant organs and parts that can be observed using no more than a handheld magnifying lens. This page provides help in understanding the numerous other pages describing plants by their various taxa. The accompanying page—Plant morphology—provides an overview of the science of the external form of plants. There is also an alphabetical list: Glossary of botanical terms. In contrast, this page deals with botanical terms in a systematic manner, with some illustrations, and organized by plant anatomy and function in plant physiology.

Important structures in plant development are buds, shoots, roots, leaves, and flowers; plants produce these tissues and structures throughout their life from meristems located at the tips of organs, or between mature tissues. Thus, a living plant always has embryonic tissues. By contrast, an animal embryo will very early produce all of the body parts that it will ever have in its life. When the animal is born, it has all its body parts and from that point will only grow larger and more mature. However, both plants and animals pass through a phylotypic stage that evolved independently and that causes a developmental constraint limiting morphological diversification.

<span class="mw-page-title-main">Plant tissue culture</span> Growing cells under lab conditions

Plant tissue culture is a collection of techniques used to maintain or grow plant cells, tissues, or organs under sterile conditions on a nutrient culture medium of known composition. It is widely used, to produce clones of a plant in a method known as micropropagation. Different techniques in plant tissue culture may offer certain advantages over traditional methods of propagation, including:

References

1 2 3 4 Baucher, Marie; AlmJaziri, Mondher; Vandeputte, Olivier. "From primary to secondary growth: origin and development of the vascular system". academic.oup.com. Retrieved 2023-03-18.
1 2 Tognetti, Vanesa B.; Bielach, Agnieszka; Hrtyan, Mónika (October 2017). "Redox regulation at the site of primary growth: auxin, cytokinin and ROS crosstalk: Apical meristems plasticity in response to stress". Plant, Cell & Environment. 40 (11): 2586–2605. doi: 10.1111/pce.13021 . PMID 28708264.
↑ Gross-Hardt R, Laux T. Stem cell regulation in the shoot meristem. J Cell Sci. 2003 May 1;116(Pt 9):1659-66. doi: 10.1242/jcs.00406. PMID: 12665547.
1 2 3 4 5 Capon, Brian (2015). Botany for Gardeners (7th printing ed.). Portland: Timber Press. pp. 23–26, 159–160. ISBN 978-1-60469-095-8.
1 2 3 "Plant Development II: Primary and Secondary Growth | Organismal Biology". organismalbio.biosci.gatech.edu. Retrieved 2023-03-18.
↑ Svolacchia, Noemi; Salvi, Elena; Sabatini, Sabrina (2020-10-01). "Arabidopsis primary root growth: let it grow, can't hold it back anymore!" . Current Opinion in Plant Biology. Cell signalling and gene regulation. 57: 133–141. doi:10.1016/j.pbi.2020.08.005. ISSN 1369-5266. PMID 33096518. S2CID 225058835.

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[:1-1] 1 2 3 4 Baucher, Marie; AlmJaziri, Mondher; Vandeputte, Olivier. "From primary to secondary growth: origin and development of the vascular system". academic.oup.com. Retrieved 2023-03-18.

[:2-2] 1 2 Tognetti, Vanesa B.; Bielach, Agnieszka; Hrtyan, Mónika (October 2017). "Redox regulation at the site of primary growth: auxin, cytokinin and ROS crosstalk: Apical meristems plasticity in response to stress". Plant, Cell & Environment. 40 (11): 2586–2605. doi: 10.1111/pce.13021 . PMID 28708264.

[3] Gross-Hardt R, Laux T. Stem cell regulation in the shoot meristem. J Cell Sci. 2003 May 1;116(Pt 9):1659-66. doi: 10.1242/jcs.00406. PMID: 12665547.

[:0-4] 1 2 3 4 5 Capon, Brian (2015). Botany for Gardeners (7th printing ed.). Portland: Timber Press. pp. 23–26, 159–160. ISBN 978-1-60469-095-8.

[:3-5] 1 2 3 "Plant Development II: Primary and Secondary Growth | Organismal Biology". organismalbio.biosci.gatech.edu. Retrieved 2023-03-18.

[6] Svolacchia, Noemi; Salvi, Elena; Sabatini, Sabrina (2020-10-01). "Arabidopsis primary root growth: let it grow, can't hold it back anymore!" . Current Opinion in Plant Biology. Cell signalling and gene regulation. 57: 133–141. doi:10.1016/j.pbi.2020.08.005. ISSN 1369-5266. PMID 33096518. S2CID 225058835.

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