differentiate

(verb)

to produce distinct cells, organs or to achieve specific functions by a process of development

Related Terms

Examples of differentiate in the following topics:

  • Cellular Differentiation

    • Cellular differentiation occurs so cells can specialize for different functions within an organism.
    • To develop a multicellular organisms, cells must differentiate to specialize for different functions.
    • The variation in proteomes between cell types is what drives differentiation and thus, specialization of cells.
    • Muscle satellite cells (progenitor cells) that contribute to differentiated muscle tissue
    • Mechanics of cellular differentiation can be controlled by growth factors which can induce cell division.

  • Mechanics of Cellular Differentation

    • Cellular differentiation, a necessary process in development and maintenance of multicellularity, is regulated by transcription factors.
    • Throughout development and adulthood, the process of cellular differentiation leads cells to assume their final morphology and physiology.
    • Differentiation is the process by which unspecialized cells become specialized to carry out distinct functions.
    • Stem cells are divided into several categories according to their potential to differentiate.
    • The process of hematopoiesis involves the differentiation of multipotent cells into blood and immune cells.

  • Gene Expression in Stem Cells

    • Symmetric division maintains stem cell lines and asymmetric division yields differentiated cells.
    • Progenitors can go through several rounds of cell division themselves before terminally differentiating into a mature cell. .
    • Stem cells differentiate when they leave that niche or no longer receive those signals.
    • This diagram illustrates stem cell division and differentiation, through the processes of (1) symmetric stem cell division, (2) asymmetric stem cell division, (3) progenitor division, and (4) terminal differentiation.
    • Stem cells are indicated by (A), progenitor cells by (B), and differentiated cells by (C).

  • Gene Expression for Spatial Positioning

    • Organs form from the germ layers through the process of differentiation.
    • During differentiation, the embryonic stem cells express specific sets of genes which will determine their ultimate cell type.
    • As a result, these cells will differentiate into epidermal cells.
    • The process of differentiation is regulated by cellular signaling cascades.
    • If the signaling by growth factors were disrupted, then the entire ectoderm would differentiate into neural tissue.

  • Organogenesis

    • During organogenesis, the three germ layers of the embryo differentiate and further specialize to form the various organs of the body.
    • During differentiation, the embryonic stem cells express specific sets of genes which will determine their ultimate cell type.
    • As a result, these cells will differentiate into epidermal cells.
    • Therefore, the process of differentiation is regulated by cellular signaling cascades.
    • If the signaling by growth factors were disrupted, then the entire ectoderm would differentiate into neural tissue.

  • Immunological Memory

    • During the adaptive immune response to a pathogen that has not been encountered before, known as the primary immune response, plasma cells secreting antibodies and differentiated T cells increase, then plateau over time.
    • As B cells and T cells mature into effector cells, a subset of the naïve populations differentiates into B and T memory cells with the same antigen specificities .
    • However, if the host is re-exposed to the same pathogen type, circulating memory cells will immediately differentiate into plasma cells and TC cells without input from APCs or TH cells.
    • Memory B cells that differentiate into plasma cells output ten to hundred-fold greater antibody amounts than were secreted during the primary response .
    • Upon re-exposure to the same pathogen, memory cells differentiate into antibody-secreting plasma cells that output a greater amount of antibody for a longer period of time.

  • Plant Responses to Light

    • Plants respond to light stimuli by growing, differentiating, tracking the time of day and seasons, and moving toward or away from the light.
    • Plants can differentiate and develop in response to light (known as photomorphogenesis), which allows plants to optimize their use of light and space.

  • Structure and Function of the Muscular System

    • The muscular system controls numerous very different functions, this is achieved by significant differentiation of muscle tissue morphology and function.
    • Cardiac muscle can be further differentiated from skeletal muscle by the presence of intercalated discs which control the synchronized contraction of cardiac tissues.
    • Visible striations in skeletal and cardiac muscle are visible, differentiating them from the more randomised appearance of smooth muscle.

  • Cleavage, the Blastula Stage, and Gastrulation

    • At this stage of development, the inner cell mass consists of embryonic stem cells that will differentiate into the different cell types needed by the organism.
    • Each of these layers is called a germ layer, which differentiate into different organ systems .

  • Signaling in Yeast

    • It is hypothesized that phosphorylation of tyrosine residues is needed to control the more sophisticated functions of development, differentiation, and cellular communication used in multicellular organisms.
    • In this micrograph, they are visualized using differential interference contrast microscopy, a light microscopy technique that enhances the contrast of the sample.