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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of the present. Compare the two figures; they represent two different worldviews. One highlights the deep clefts between the three domains, the other is integrative and does away with such barriers. (The ecology perspective also acknowledges the highly abundant viruses, indicated by the stippled background.) Maybe it is not phylogeny’s job to emphasize ecology, but neither should we be fixated on evolution alone. Obviously, no one is, so I apologize for erecting a straw man. Yet let me voice a wish: I would like to see a wider-ranging acknowledgement of each organism’s give-and-take with its environment. Famed evolutionary biologist and geneticist Dobzhansky once said: “Nothing in Biology makes sense except in the light of evolution.” Do I dare modify this well-known dictum to read: “Nothing in Biology makes sense except in the light of evolution and ecology.”

      October 25, 2012

       bit.ly/1XgDLTc

      Virus in the Room

      by Welkin Johnson

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       I am the Lorax, I speak for the trees. I speak for the trees, for the trees have no tongues, and I’m asking you, sir, at the top of my lungs.

       from The Lorax by Dr. Seuss

      As biologists, we divvy the biological realm up into domains using a formula that, frankly, smacks of nepotism, bestowing three glorious domains upon our closest relatives—the Eucaryota, the Archaea, and the Bacteria—while committing an injustice to the so-called viruses, lumping them together in a miscellaneous catch-all category (“viruses” from Latin for poison and other noxious substances) with contemptible disregard for phylogeny or any true measure of diversity.

      Let us thumb through the catalogue of viral genomes: here we find the familiar double-stranded DNA, including both linear and circular genomes, but also some with not-so-familiar twists—poxviruses, for example, covalently closing both ends of their linear double-stranded DNA genomes. We also find an abundance of themes not found anywhere among the domains of cellular life: thus, there are viruses with single-stranded DNA genomes and viruses with single-stranded RNA genomes, the latter including some that are negative-sense, some positive-sense, and some part positive and part negative (ambisense). Additionally, there are viruses with double-stranded RNA genomes, and if that isn’t bizarre enough, there are viruses with segmented RNA genomes (to which the influenza virus belongs), whose virions incorporate a precise complement of eight different RNA segments.

      Equally impressive are the reoviruses, with genomes composed of a dozen different segments of double-stranded RNA. Replicate that! And there are retroviruses, whose genomes are sometimes RNA (in the virion), and at other times double-stranded DNA (upon entering a host cell). Hepadnaviruses, possible cousins to the retroviruses, have gapped double-stranded DNA genomes with a bit of RNA thrown in, which they, too, convert to DNA by means of reverse transcriptase.

      The tables thus turned, the viruses demand a fair redistricting, with the viral realm to include no fewer than seven domains to our three. They also ask that we wear name tags, since they are having trouble remembering how to tell an elephant from a bacillus.

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       Welkin Johnson is Professor and Chair of Biology at Boston College.

      November 19, 2012

       bit.ly/1GfyjMb

      #17

      by Elio

      What if someone discovered a fourth (or fifth, sixth, etc.) domain of life?

      May 28, 2007

       bit.ly/1GQ7OHL

      Feynman Said “Just Look at the Thing!”

      by Jan Spitzer

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      On October 28, 2010, Elio posted this Talmudic Question: “Richard Feynman, the famous physicist, said: It is very easy to answer many of these fundamental biological questions; you just look at the thing! To take him up on it, imagine a microscope that lets you observe single molecules in a living cell at one Angström resolution. What’s the first thing you would do with it?” Thank you, Elio, for allowing me to provide some thoughts on the matter from the perspective of a physical chemist/chemical engineer.

      Such a microscope could indeed help address some of the fundamental issues in biology today. I must say up front that I am surprised that microbiologists would want to look at (small) molecules (“pure” chemistry), or at the chemical details of “bigger things,” as suggested by the very notion of using a “Schaechter-Feynman supermicroscope.” This hypothetical instrument would have a resolution of 0.1nm with exposure times in the picosecond range (making it a bit akin to an infrared spectrophotometer) and would operate in Feynman’s quantum mechanical world. It would look at the chemistry of biology, dissecting cells into their molecular components that are then chemically characterized individually. But let me explain this more…

       What Should We Look At?