Interphase

Interphase is the portion of the cell cycle that is not accompanied by observable changes under the microscope, and includes the G1, S and G2 phases. During interphase, the cell grows (G1), replicates its DNA (S) and prepares for mitosis (G2). A cell in interphase should not be confused with a cell in quiescent state, which represents most of the cell’s lifetime. The term quiescent (i.e. state of dormancy) is misleading since a quiescent cell is very busy synthesizing proteins, copying DNA into RNA, engulfing extracellular material, processing signals, to name just a few activities. The cell is quiescent only in the sense of cell division (i.e. the cell is out of the cell cycle, G0).Interphase is the phase of the cell cycle in which a typical cell spends most of its life. During interphase, the cell copies its DNA in preparation for mitosis.[1] Interphase is the 'daily living' or metabolic phase of the cell, in which the cell obtains nutrients and metabolizes them, grows, reads its DNA, and conducts other "normal" cell functions.[1] This phase was formerly called the resting phase. However, interphase does not describe a cell that is merely resting; rather, the cell is living and preparing for later cell division, so the name was changed. A common misconception is that interphase is the first stage of mitosis, but since mitosis is the division of the nucleus, prophase is actually the first stage.[2]

An illustration of interphase. The chromatin has not yet condensed, and the cell is undergoing its normal functions.
An image of the nucleus of a cell (HT1080) currently in interphase (likely G1). Note: Cytoplasm of this cell or the neighboring cell is not visible (top-left), which is currently in the telophase of mitosis. Image taken using an optical microscope and DAPI staining of DNA.

In interphase, the cell gets itself ready for mitosis or meiosis. Somatic cells, or normal diploid cells of the body, go through mitosis in order to reproduce themselves through cell division, whereas diploid germ cells (i.e., primary spermatocytes and primary oocytes) go through meiosis in order to create haploid gametes (i.e., sperm and ova) for the purpose of sexual reproduction.

Stages of interphase

There are three stages of cellular interphase, with each phase ending when a cellular checkpoint checks the accuracy of the stage's completion before proceeding to the next. The stages of interphase are:

  • G1 (Gap 1), in which the cell grows and functions normally. During this time, a high amount of protein synthesis occurs and the cell grows (to about double its original size) – more organelles are produced and the volume of the cytoplasm increases. If the cell is not to divide again, it will enter G0.[3]
  • Synthesis (S), in which the cell synthesizes its DNA and the amount of DNA is doubled but the number of chromosomes remains constant (via semiconservative replication).
  • G2 (Gap 2), in which the cell resumes its growth in preparation for division. The mitochondria divide and the cell continues to grow until mitosis begins. In plants, chloroplasts also divide during G2.
  • In addition, some cells that do not divide often or ever, enter a stage called G0 (Gap zero), which is either a stage separate from interphase or an extended G1.

The duration of time spent in interphase and in each stage of interphase is variable and depends on both the type of cell and the species of organism it belongs to. Most cells of adult mammals spend about 24 hours in interphase; this accounts for about 90%-96% of the total time involved in cell division.[4] Interphase includes G1, S, and G2 phases. Mitosis and cytokinesis, however, are separate from interphase.

DNA double-strand breaks can be repaired during interphase by two principal processes.[5] The first process, non-homologous end joining (NHEJ), can join the two broken ends of DNA in the G1, S and G2 phases of interphase. The second process, homologous recombinational repair (HRR), is more accurate than NHEJ in repairing double-strand breaks. However HRR is only active during the S and G2 phases of interphase when DNA replication is either partially or fully accomplished, since HRR requires two adjacent homologous chromosomes.

Interphase within sequences of cellular processes

Interphase and the cell cycle

When G2 is completed, the cell enters a relatively brief period of nuclear and cellular division, composed of mitosis and cytokinesis, respectively. After the successful completion of mitosis and cytokinesis, both resulting daughter cells re-enter G1 of interphase.

In the cell cycle, interphase is preceded by telophase and cytokinesis of the M phase. In alternative fashion, interphase is sometimes interrupted by G0 phase, which, in some circumstances, may then end and be followed by the remaining stages of interphase. After the successful completion of the G2 checkpoint, the final checkpoint in interphase, the cell proceeds to prophase, or in plants to preprophase, which is the first stage of mitosis.

G0 phase is viewed as either an extended G1 phase where the cell is neither dividing nor preparing to divide, or as a distinct quiescent stage which occurs outside of the cell cycle.[6]

Interphase and other cellular processes

In gamete production, interphase is succeeded by meiosis. In programmed cell death, interphase is followed or preempted by apoptosis.

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See also

References

  1. Marieb E (2000). Essentials of human anatomy and physiology. San Francisco: Benjamin Cummings. ISBN 978-0805349405.
  2. "The Cell Cycle & Mitosis Tutorial". The Biology Project – Cell Biology. University of Arizona.
  3. Cummings MR (2014). Human Heredity: Principles and Issues (10th ed.). Belmont, CA: Brooks/Cole. pp. 28–29.
  4. Mader SS (2007). Biology (9th ed.). Boston, MA, USA: McGraw Hill Higher Education. ISBN 978-0-07-325839-3.
  5. Shibata A. Regulation of repair pathway choice at two-ended DNA double-strand breaks. Mutat Res. 2017 Oct;803-805:51-55. doi: 10.1016/j.mrfmmm.2017.07.011. Epub 2017 Jul 29. Review. PMID: 28781144
  6. Cram E. "Re: Are the cells in the G0 (g zero) phase of mitosis really suspended?". MadScience Network. Molecular and Cellular Biology, University of California, Berkeley. 1999.
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