In the Company of Microbes. Moselio Schaechter. Читать онлайн. Newlib. NEWLIB.NET

Автор: Moselio Schaechter
Издательство: John Wiley & Sons Limited
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Жанр произведения: Биология
Год издания: 0
isbn: 9781683673248
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a surprise. One would expect that such a complex structure be the product of an uncommon event in evolution, consequently, that it be alike in different bacterial species. Not so. A most exciting detailed analysis of eleven different species shows that although the basic plan is the same, these tiny machines vary considerably in detail. Their elements differ in curvature and in the positioning with regard to the axis. True, the bacteria species chosen included an assortment of flagellar arrangements, the flagella being polar in some, all over the surface (peritrichous) in others, and in yet others encased in the periplasm. One can well imagine that such different arrangements might require specially adapted machinery. But this finding does reveal a great degree of plasticity in the way flagellar motors are made. Isn’t this amazing?

      Self-assembly requires a high degree of “smartness” by the molecules involved—a higher degree than found in our “smartphones” that are all but self-assembled. Not only must the whole bunch of molecules carry out their intended function; they must be able to join with others into highly sophisticated ultra-tiny machines. Even more fascinating is that this self assembling ability is self-evolved! If I were starting over and wanted to dedicate myself to molecular mechanisms, I would be likely to turn to the study of such smart molecules.

      August 27, 2014

       bit.ly/1LHBIU5

      On the Definition of Prokaryotes

      by Nanne Nanninga

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      As will be argued below, the present definition of a prokaryote is highly unsatisfactory. To give an example: a prokaryote is “a cell or organism lacking a nucleus and other membrane-enclosed organelles, usually having its DNA in a single circular molecule” (Brock, Biology of Microorganisms, 10th ed.). This seems a summary of the original definition of Stanier & van Niel (1962), which I quote for the sake of completeness: “The principle distinguishing features of the procaryotic cell are: 1. absence of internal membranes which separate the resting nucleus from the cytoplasm, and isolate the enzymatic machinery of photosynthesis and of respiration in specific organelles; 2. nuclear division by fission, not by mitosis, a character possibly related to the presence of a single structure which carries all the genetic information of the cell; and 3. the presence of a cell wall which contains a specific mucopeptide as its strengthening element.” Today’s perception of these points amounts largely, as indicated above, to the absence of a nuclear envelope in prokaryotes. It should be mentioned that Stanier & van Niel in the above paper also wished to differentiate a bacterium from a virus and to incorporate blue-green algae within the prokaryotic domain.

      The paper of Stanier & van Niel appeared more than 50 years ago. In this contribution I will attempt to present a more modern definition of a prokaryote, keeping in mind that one should distinguish between two aspects: its definition and its distinction from a eukaryote. But, before doing so I will insert an historic intermezzo.

      An alternative characterization of prokaryotes already emerged, though not explicitly, in 1964 through the study by Byrne et al. of the formation of DNA-ribosome complexes as analyzed by sucrose-gradient centrifugation. In those times sucrose gradient data were graphically expressed with radioactive counts on the vertical axis and fraction number on the horizontal axis. In the paper of Byrne et al. the focus was on the cellular organization of transcription and on the stability of RNAs, in particular mRNA (then also named cRNA). Their labeling and fractionation experiments led to the following conclusion: “Our results suggest that some time after the onset of cRNA transcription on the surface of the gene, a ribosome will attach to the RNA molecule. This event may signal the beginning of polypeptide synthesis on the ribosome. The ribosome may then advance along the cRNA strand followed by other ribosomes, resulting in a continuous translation of the genetic message into polypeptide sequences.” And further on: “In a sense, ribosomes in bacterial systems may be a rudimentary form of the “carrier” ribonucleoprotein particles believed to transport cRNA from the nuclei of higher organisms.” An electron micrograph of one of the fractions shows clusters of particles with ribosomal dimensions and threads, presumed to be DNA and perhaps mRNA.

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      Dispersed strands of genomic DNA with polysomes attached of the hyper-thermophilic archaeon Thermococcus kodakaraensis visualized by the Miller technique (1970). Bar: 200 nm.

      Source: French SL, Santangelo TJ, Beyer AL, Reeve JN. 2007. Transcription and translation are coupled in Archaea. Molecular Biology and Evolution 24:893-895.

      Then, E. coli was still the model organism. Some years ago, coupled transcription and translation was visualized for the hyperthermophilic archaeon Thermococcus kodakaraensis using the Miller technique (French et al. 2007). Thus, one can conclude that in the bacterium E. coli and in the archaeon T. kodakaraensi coupled transcription and translation are facts. Whether this applies to all Archaea remains to be seen. Because eukaryotes lack coupled transcription and translation, prokaryotes, in this way, distinguish themselves positively (Martin & Koonin, 2006).

       The Distinction between Prokaryotes and Eukaryotes

      As mentioned above, one should differentiate between definition and distinction. The fact that eukaryotes do not possess coupled transcription and translation—a negative qualification for some, by the way—does not tell us much about eukaryotes. Also, the absence of a nuclear envelope in prokaryotes—a negative qualification, too—is not very informative. What is fundamental in cells relates to the structural organization of information processing, i.e., the flow of information from DNA through mRNA to protein. Conceptually, this bears on the central dogma of molecular biology. Thus, the main distinction between pro- and eukaryotes lies in the presence or absence of coupled transcription and translation, respectively. Does this suffice as a definition of a prokaryote? This question is easier posed than answered. I refer to another quotation from Stanier & van Niel in the same paper mentioned above: “The differences between eucaryotic and procaryotic cells are not expressed in any gross features of cellular function; they reside rather in differences with respect to the detailed organization of the cellular machinery” (italics by Stanier & van Niel). The absence of a cellular structure (a nuclear envelope) can hardly be considered an informative statement when it is known that transcription and translation are spatially coupled. The latter reflects the “detailed organization of the cellular machinery” and, I believe, this should be part of a definition, as should microscopic size and a cell wall. If one contrasts prokaryotic cytoplasm with that of a eukaryote, the presence of membrane-bounded organelles suspended in a dynamic cytoskeletal framework appears a dominant feature in the latter case. Such structural differentiation could hardly be accommodated for in a microscopic cell. Also remember that mitochondria and chloroplasts have prokaryotic dimensions. Following this reasoning, a prokaryote can be considered a walled cell of microscopic size possessing coupled transcription and translation and a not-well differentiated cytoplasm. According to our present knowledge, this applies to Bacteria and Archaea. Structurally, there is a “deep gulf” (Lane, 2011) between prokaryotes and eukaryotes. To what extent this bears on their phylogenetic relationships remains to be seen.

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      Structural organization of the flow of information in pro- and eukaryotes.

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