amoeba with extending pseudopodia
Category: Science & Tech
- Also called:
- pseudopod movement
- Related Topics:
- protozoan
- slime mold
- amoeba
- pseudopodium
- amoeboid locomotion
pseudopodial locomotion, movement that results when a cell extends a temporary projection of membrane and then flows its cellular contents to fill the extension. Pseudopodial locomotion is a type of cellular movement used by certain eukaryotes, particularly slime molds and certain types of protozoans, such as amoebas. In multicellular organisms, some motile cell types, such as white blood cells and some kinds of tumour cells, also use a form of pseudopodial locomotion. In addition, some organisms utilize a modified form of pseudopodial locomotion to capture materials; phagocytosis pseudopodia, for example, help sense and engulf materials.
Process
Pseudopodial locomotion consists of several steps, including extension, attachment, contraction and cytoplasmic flow, gel-sol transformation, and detachment and pseudopod retraction. In extension, the cell generates a temporary projection of membrane and cytoplasm—called a pseudopodium—which extends outward in a specific direction; this process is controlled via the assembly and disassembly of cytoskeletal components, especially actin filaments. In attachment, the cell anchors itself to the substrate, facilitating the contraction phase of movement, in which cytoskeletal components rearrange and shorten themselves to pull the cell in the direction of the temporary membrane projection. Contraction of the cell causes cytoplasm to flow into the pseudopodium.
Most pseudopodial locomotion requires a substrate on which the cell can glide. This process is facilitated by gel-sol transformation, in which the cytoplasm of the moving cell changes from a liquid state to a more gel-like state. Gel-sol transformation is aided by a flexible network of actin filaments; as pseudopodial locomotion progresses, the assembly and disassembly of microfilament structures made of actin and myosin drive the cell’s movement. In detachment, the rear portion of the cell releases from the substrate and contracts, allowing the entire cell to move in the desired direction; the pseudopodium then retracts.
Among protists, pseudopodial locomotion is considered slow relative to other forms of locomotion, such as movement via cilia or flagella. Estimates of average velocity for pseudopodial locomotion range from 5 μm/sec to 20 μm/min. Phagocytes in the human body may move a few millimetres per day using this motion.
Mechanisms
Pseudopodial locomotion is a highly flexible and adaptable kind of movement, making it possible for cells to navigate across a variety of surfaces and through different mediums, such as water. Thus, the mechanisms by which pseudopodia drive movement can vary markedly. Foraminiferans, for example, use stiff pseudopodia that poke through holes in a shell to swim, while radiolarians use thin stiff pseudopodia to help them float through water. Members of the ocean protist genera Sticholonche move using axopodia, semipermanent pseudopodia that rotate like oars anchored in sockets. Heliozoans alternately extend and shorten their axopodia for movement.
Structures
Different types of organisms and cells form distinct types of pseudopodia, which are distinguished by their shape and structure. These include: lobopodia, filopodia, reticulopodia, and axopodia. Lobopodia are fingerlike, with rounded ends, and may be flattened or tubular. They are generally produced one or two at a time per cell. These lumpy pseudopodia can be used to creep across surfaces, such as the bottom of a pond. Filopodia are more slender with pointed ends that can branch. Multiple filopodia can be produced at one time. Reticulopodia are branching filaments that form in foraminiferans; these structures can connect with one another to make dense networks. Axopodia are long and sticky pseudopodia with an internal rod made of microtubules; these are especially prominent in radiolarians and heliozoans.
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The projections that drive movement in motile cells within multicellular organisms often have the same structure as amoeboid pseudopodia. However, in some instances, they are thinner. Such thin structures are known as lamellipodia; lamellipodia depend heavily on adhesion to a surface to propel cell movement. The term lamellipodia is sometimes also used to describe broad, flat pseudopodia in amoeba.
Pseudopodial locomotion is a fascinating aspect of cellular movement, notably observed in various eukaryotes such as amoebas, slime molds, and certain protozoans. This mechanism involves the extension of temporary projections of membrane and cytoplasm called pseudopodia, allowing cells to move and navigate across surfaces or through different mediums like water.
The process involves several key steps: extension, attachment, contraction and cytoplasmic flow, gel-sol transformation, and detachment and pseudopod retraction. These steps are orchestrated by the cell's cytoskeletal components, particularly actin filaments, which control the assembly and disassembly facilitating the movement.
During extension, the cell generates a pseudopodium, anchoring itself to the substrate in the attachment phase. Contraction then occurs as cytoskeletal components rearrange and shorten, pulling the cell in the direction of the projection while cytoplasm flows into the pseudopodium. Gel-sol transformation aids in the movement, altering the cell's cytoplasm from a liquid to a more gel-like state.
There are various structures of pseudopodia, each distinctive to different organisms. Lobopodia are fingerlike and rounded, used for creeping across surfaces, while filopodia are slender and branch out, facilitating movement through branching. Reticulopodia form dense networks and axopodia, prevalent in radiolarians and heliozoans, have an internal rod made of microtubules.
In multicellular organisms, motile cells, like white blood cells and some tumor cells, utilize a similar mechanism for movement. These structures, akin to amoeboid pseudopodia, are sometimes thinner and termed lamellipodia. Lamellipodia heavily rely on surface adhesion to propel cell movement.
The adaptability and flexibility of pseudopodial locomotion allow cells to navigate diverse surfaces and mediums. Various organisms employ different forms of pseudopodia suited to their locomotive needs, be it swimming, floating, or navigating through environments.
Understanding these mechanisms aids in comprehending cellular movement in both single-celled organisms and certain cell types within multicellular organisms, shedding light on how cells interact with their surroundings and move within them.
