User:BradyT123/Cellular differentiation

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Germ line cells are any line of cells that give rise to gametes—eggs and sperm—and thus are continuous through the generations. Stem cells, on the other hand, have the ability to divide for indefinite periods and to give rise to specialized cells. They are best described in the context of normal human development.^[1]

Pluripotent stem cells undergo further specialization into multipotent progenitor cells that then give rise to functional cells. Examples of stem and progenitor cells include:^[2]^[3]^[4]

Each specialized cell type in an organism expresses a subset of all the genes that constitute the genome of that species. Each cell type is defined by its particular pattern of regulated gene expression. Cell differentiation is thus a transition of a cell from one cell type to another and it involves a switch from one pattern of gene expression to another. Cellular differentiation during development can be understood as the result of a gene regulatory network. A regulatory gene and its cis-regulatory modules are nodes in a gene regulatory network; they receive input and create output elsewhere in the network. The systems biology approach to developmental biology emphasizes the importance of investigating how developmental mechanisms interact to produce predictable patterns (morphogenesis). However, recent research suggests there may be an alternative view. Based on stochastic gene expression, cellular differentiation is the result of a Darwinian selective process occurring among cells. In this frame, protein and gene networks are the result of cellular processes and not their cause.^[5]

In order to fulfill the purpose of regenerating a variety of tissues, adult stems are known to migrate from their niches, adhere to new extracellular matrices (ECM) and differentiate. The ductility of these microenvironments are unique to different tissue types. The ECM surrounding brain, muscle and bone tissues range from soft to stiff. The transduction of the stem cells into these cells types is not directed solely by chemokine cues and cell to cell signaling. The elasticity of the microenvironment can also affect the differentiation of mesenchymal stem cells (MSCs which originate in bone marrow.) When MSCs are placed on substrates of the same stiffness as brain, muscle and bone ECM, the MSCs take on properties of those respective cell types. Matrix sensing requires the cell to pull against the matrix at focal adhesions, which triggers a cellular mechano-transducer to generate a signal to be informed what force is needed to deform the matrix. To determine the key players in matrix-elasticity-driven lineage specification in MSCs, different matrix microenvironments were mimicked. From these experiments, it was concluded that focal adhesions of the MSCs were the cellular mechano-transducer sensing the differences of the matrix elasticity. The non-muscle myosin IIa-c isoforms generates the forces in the cell that lead to signaling of early commitment markers. Nonmuscle myosin IIa generates the least force increasing to non-muscle myosin IIc. There are also factors in the cell that inhibit non-muscle myosin II, such as blebbistatin. This makes the cell effectively blind to the surrounding matrix. Researchers have achieved some success in inducing stem cell-like properties in HEK 239 cells by providing a soft matrix without the use of diffusing factors. The stem-cell properties appear to be linked to tension in the cells' actin network. One identified mechanism for matrix-induced differentiation is tension-induced proteins, which remodel chromatin in response to mechanical stretch. The RhoA pathway is also implicated in this process.^[6]

Mechanisms

Gene regulatory networks

Each specialized cell type in an organism expresses a subset of all the genes that constitute the genome of that species. Each cell type is defined by its particular pattern of regulated gene expression. Cell differentiation is thus a transition of a cell from one cell type to another and it involves a switch from one pattern of gene expression to another. Cellular differentiation during development can be understood as the result of a gene regulatory network. A regulatory gene and its cis-regulatory modules are nodes in a gene regulatory network; they receive input and create output elsewhere in the network. The systems biology approach to developmental biology emphasizes the importance of investigating how developmental mechanisms interact to produce predictable patterns (morphogenesis). However, an alternative view has been proposed recently^{[when?][by whom?]}. Based on stochastic gene expression, cellular differentiation is the result of a Darwinian selective process occurring among cells. In this frame, protein and gene networks are the result of cellular processes and not their cause.^[5]

Signaling pathways

Cellular differentiation is often controlled by cell signaling. Many of the signal molecules that convey information from cell to cell during the control of cellular differentiation are called growth factors. Although the details of specific signal transduction pathways vary, these pathways often share the following general steps. A ligand produced by one cell binds to a receptor in the extracellular region of another cell, inducing a conformational change in the receptor. The shape of the cytoplasmic domain of the receptor changes, and the receptor acquires enzymatic activity. The receptor then catalyzes reactions that phosphorylate other proteins, activating them. A cascade of phosphorylation reactions eventually activates a dormant transcription factor or cytoskeletal protein, thus contributing to the differentiation process in the target cell. Cells and tissues can vary in competence, their ability to respond to external signals.

Inductive signaling

Signal induction refers to cascades of signaling events, during which a cell or tissue signals to another cell or tissue to influence its developmental fate. Yamamoto and Jeffery investigated the role of the lens in eye formation in cave- and surface-dwelling fish, a striking example of induction. Through reciprocal transplants, Yamamoto and Jeffery found that the lens vesicle of surface fish can induce other parts of the eye to develop in cave- and surface-dwelling fish, while the lens vesicle of the cave-dwelling fish cannot.

Asymmetric cell divison

Other important mechanisms fall under the category of asymmetric cell divisions, divisions that give rise to daughter cells with distinct developmental fates. Asymmetric cell divisions can occur because of asymmetrically expressed maternal cytoplasmic determinants or because of signaling. In the former mechanism, distinct daughter cells are created during cytokinesis because of an uneven distribution of regulatory molecules in the parent cell; the distinct cytoplasm that each daughter cell inherits results in a distinct pattern of differentiation for each daughter cell. A well-studied example of pattern formation by asymmetric divisions is body axis patterning in Drosophila. RNA molecules are an important type of intracellular differentiation control signal. The molecular and genetic basis of asymmetric cell divisions has also been studied in green algae of the genus Volvox, a model system for studying how unicellular organisms can evolve into multicellular organisms. In Volvox carteri, the 16 cells in the anterior hemisphere of a 32-cell embryo divide asymmetrically, each producing one large and one small daughter cell. The size of the cell at the end of all cell divisions determines whether it becomes a specialized germ or somatic cell.

Evolutionary perspectives on mechanisms

While evolutionarily conserved molecular processes are involved in the cellular mechanisms underlying these switches, in animal species these are very different from the well-characterized gene regulatory mechanisms of bacteria, and even from those of the animals' closest unicellular relatives. Specifically, cell differentiation in animals is highly dependent on biomolecular condensates of regulatory proteins and enhancer DNA sequences.

References

↑ Zakrzewski, Wojciech; Dobrzyński, Maciej; Szymonowicz, Maria; Rybak, Zbigniew (26 February 2019). "Stem cells: past, present, and future". Stem Cell Research & Therapy. 10 (1): 68. doi:10.1186/s13287-019-1165-5. ISSN 1757-6512.{{cite journal}}: CS1 maint: unflagged free DOI (link)
↑ Tesche, Leora; Gerber, David (October 2009). "Tissue-Derived Stem and Progenitor Cells". pmc.ncbi.nlm.nih.gov. Archived from the original on 1 June 2018. Retrieved 9 March 2025.
↑ Kriegstein, Arnold; Alvarez-Buylla, Arturo (21 July 2009). "The Glial Nature of Embryonic and Adult Neural Stem Cells". Annual Review of Neuroscience. 32: 149–184. doi:10.1146/annurev.neuro.051508.135600. ISSN 0147-006X. PMC 3086722. PMID 19555289 – via NIH.{{cite journal}}: CS1 maint: PMC format (link)
↑ Morgan, Jennifer E.; Partridge, Terence A. (August 2003). "Muscle satellite cells". The International Journal of Biochemistry & Cell Biology. 35 (8): 1151–1156. doi:10.1016/s1357-2725(03)00042-6. ISSN 1357-2725. PMID 12757751.
1 2 Capp, Jean-Pascal; Laforge, Bertrand (23 July 2020). "A Darwinian and Physical Look at Stem Cell Biology Helps Understanding the Role of Stochasticity in Development". Frontiers in Cell and Developmental Biology. 8. doi:10.3389/fcell.2020.00659. ISSN 2296-634X. PMC 7391792. PMID 32793600.{{cite journal}}: CS1 maint: PMC format (link) CS1 maint: unflagged free DOI (link)
↑ Vining, Kyle H.; Mooney, David J. (8 November 2017). "Mechanical forces direct stem cell behaviour in development and regeneration". Nature Reviews Molecular Cell Biology. 18 (12): 728–742. doi:10.1038/nrm.2017.108. ISSN 1471-0080. PMC 5803560. PMID 29115301.{{cite journal}}: CS1 maint: PMC format (link)

[1] Zakrzewski, Wojciech; Dobrzyński, Maciej; Szymonowicz, Maria; Rybak, Zbigniew (26 February 2019). "Stem cells: past, present, and future". Stem Cell Research & Therapy. 10 (1): 68. doi:10.1186/s13287-019-1165-5. ISSN 1757-6512.{{cite journal}}: CS1 maint: unflagged free DOI (link)

[2] Tesche, Leora; Gerber, David (October 2009). "Tissue-Derived Stem and Progenitor Cells". pmc.ncbi.nlm.nih.gov. Archived from the original on 1 June 2018. Retrieved 9 March 2025.

[3] Kriegstein, Arnold; Alvarez-Buylla, Arturo (21 July 2009). "The Glial Nature of Embryonic and Adult Neural Stem Cells". Annual Review of Neuroscience. 32: 149–184. doi:10.1146/annurev.neuro.051508.135600. ISSN 0147-006X. PMC 3086722. PMID 19555289 – via NIH.{{cite journal}}: CS1 maint: PMC format (link)

[4] Morgan, Jennifer E.; Partridge, Terence A. (August 2003). "Muscle satellite cells". The International Journal of Biochemistry & Cell Biology. 35 (8): 1151–1156. doi:10.1016/s1357-2725(03)00042-6. ISSN 1357-2725. PMID 12757751.

[:0-5] 1 2 Capp, Jean-Pascal; Laforge, Bertrand (23 July 2020). "A Darwinian and Physical Look at Stem Cell Biology Helps Understanding the Role of Stochasticity in Development". Frontiers in Cell and Developmental Biology. 8. doi:10.3389/fcell.2020.00659. ISSN 2296-634X. PMC 7391792. PMID 32793600.{{cite journal}}: CS1 maint: PMC format (link) CS1 maint: unflagged free DOI (link)

[6] Vining, Kyle H.; Mooney, David J. (8 November 2017). "Mechanical forces direct stem cell behaviour in development and regeneration". Nature Reviews Molecular Cell Biology. 18 (12): 728–742. doi:10.1038/nrm.2017.108. ISSN 1471-0080. PMC 5803560. PMID 29115301.{{cite journal}}: CS1 maint: PMC format (link)

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