Astrobiology. Charles S. Cockell
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Название: Astrobiology

Автор: Charles S. Cockell

Издательство: John Wiley & Sons Limited

Жанр: Физика

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isbn: 9781119550396

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СКАЧАТЬ estimate, the panel agreed that 250 ± 50 nm constitutes a reasonable lower size limit for life as we know it.” Discuss this statement and whether you agree with the assessment of the minimum number of proteins required for life. How would the minimum size of a cell be different if it required 10 times this number of proteins or 50 times this number?

      United States National Research Council (1999). Size Limits of Very Small Microorganisms: Proceedings of a Workshop, 1999. Washington, DC: National Academies Press (available online: http://www.nap.edu/books/0309066344/html).

      5.6.7 eDNA

      One of the more enigmatic occurrences of DNA is extracellular deoxyribonucleic acid (eDNA), which is found outside the cell. Once thought to be DNA that had simply been released from dead cells, it is now understood to be involved in a variety of processes, including the formation of biofilms in bacteria. It may also provide a rich source of genetic information that can be sequestered by other organisms in the process of transformation, whereby naked DNA in the environment is taken up and incorporated into the genome of organisms. This process is discussed in more detail in Chapter 8.

      Eukaryotic cells have a number of crucial differences from prokaryotic cells (Figure 5.16), the most notable is the presence of a cell nucleus. In the prokaryotic cell, the DNA is free floating in the fluid, or cytoplasm, of the cell and is sometimes referred to as the nucleoid. It is not surrounded by a nuclear membrane. In contrast, in eukaryotic cells, the DNA is found in the nucleus. Transcription occurs in the nucleus before the mRNA is moved into the cytoplasm for processing. The nucleus is constructed with a nuclear membrane containing pores allowing for the movement of material, such as the transcribed mRNA, in and out. Eukaryotic DNA also has important differences to prokaryotic DNA. The DNA contains sequences called introns. These are removed once the mRNA has been synthesized in the nucleus to leave only the exons (the parts of the mature mRNA that will be used to translate the genes). Eukaryotic cells contain histones. These are proteins around which the chromosomal DNA is packaged. Without them, the DNA would be long and unwieldy. For example, a typical diploid human cell contains about 1.8 m of DNA. Wound around the histones, the DNA can be effectively packaged in the nucleus.

Diagram of a typical plant eukaryotic cell with labels golgi body, cell wall, chloroplast, mitochondria, cytosol, endoplasmic reticulum, nucleus, chromosomes, membrane, and cytoskeleton.

       Figure 5.16 A typical plant eukaryotic cell with some of its components. The cell shown is about 10 microns across. A typical size of a prokaryotic cell is shown for comparison.

      A variety of other adaptations are found in specific eukaryotic cells (Figure 4.16). For example, a cell wall made of the polysaccharide, cellulose, which is constructed from repeating glucose molecules (Chapter 4), is found in plants. In fungi, the cell wall contains chitin, a polysaccharide made from N-acetylglucosamine, a derivative of glucose. Keratins are another type of tough filamentous protein. These are excreted in mammalian skin cells and account for the tough exterior of skin. When excreted outside the cell, keratins make hair and nails.

      Many eukaryotic cells have a cytoskeleton, made up of a variety of structures including tubes and filaments of the proteins tubulin (microtubules) and actin (microfilaments). These molecules provide a rigid structure to the cell and can allow it to change shape, such as when it is involved in tissue formation or movement toward nutrients and resources. The cytoskeleton plays a particularly important role in cell division, providing a scaffold during the separation of chromosomes. It is also used as a network for moving cell components around within the cell. Components travel along the microtubules like a railway track, attached to molecules such as kinesin. This is an adenosine triphosphate (ATP)-requiring process.

      The cytoskeleton may not be completely unique to eukaryotes. Prokaryotes have been shown to have simple cytoskeletal structures made up of proteins such as crescentin, which seems to form a ring structure, providing shape to some bacterial cells. These observations show that although in gross characteristics eukaryotic cells seem very different from prokaryotic cells, they share common characteristics that likely reflect their common origins.

      Animal cells have lysosomes, which are organelles containing enzymes that allow the cell to break down engulfed molecules as a source of food. Secretory vesicles are involved in the excretion of hormones and other chemical messengers.

      A particularly important organelle within the eukaryotes is the mitochondrion (plural mitochondria), found in most eukaryotic cells. They are ATP-producing organelles, the site of aerobic respiration, although they also have roles to play in cell signaling and differentiation. Although plants trap energy in chloroplasts, they still use mitochondria to break down the glucose they produce in photosynthesis as a source of energy for the cell. The mitochondria are important because they are the energy-yielding factories, if you like, of the eukaryotic cell and in many ways define the eukaryotic cell. By tapping into aerobic respiration, which is much more energy-yielding than oxygen-free modes of acquiring energy, and by having many mitochondria, the eukaryotic cell was able to harness much greater quantities of energy to allow for greater complexity and for the energy-intensive processes we associate with multicellular life. In that sense, the acquisition and taming of the mitochondrion by the earliest eukaryotic cell likely allowed for the revolution we associate with the emergence of complex multicellular life. You might like to consider this paragraph again when you have investigated energy acquisition in cells, discussed in the next chapter.

      5.7.1 Endosymbiosis

      Where did these organelles in eukaryotes come from? It was long suspected that maybe some of them had begun their origins as independent cells. For example in the mitochondria, the physically circular nature of their DNA and the content of the genetic code suggested that they were once bacteria that were acquired by eukaryotes, eventually becoming dependent on the host cell (Figure 5.17). The ancestral bacterium is thought to have been an alphaproteobacterium, a subphylum of bacteria. This process of endosymbiosis, championed by biologist Lynn Margulis (1938–2011), explains the origin of chloroplasts СКАЧАТЬ