Diatom Gliding Motility. Группа авторов

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Название Diatom Gliding Motility
Автор произведения Группа авторов
Жанр Биология
Серия
Издательство Биология
Год выпуска 0
isbn 9781119526575



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      The appearance of biofilms was observed in several batch cultures. In contrast to biofilms in nature, these biofilms are only colonized by one diatom species and bacteria (no axenic cultures). Such biofilms are not generally suitable for making statements about biocenosis. They allow, however, studying the possible movements of pennate diatoms in such a film. To accomplish this, observations were made on cultures in Petri dishes in which the focal plane was chosen between the plane of the substrate and the surface of the biofilm. With the focal plane fixed, time-lapse recordings were made and analyzed.

Schematic illustration of pinnularia viridiformis with a length of approx. 90 micrometers. Schematic illustration of places within and on a biofilm where Pinnularia viridiformis can be found.

      These observations do not provide any information about the structure of the biofilm. Lauterborn [1.21] already reported in 1896 that Pinnularia maior extrudes gelatinous filaments during movement. The elasticity of these structures, which often contract into lumps, can easily be seen in the ink coloring used by Lauterborn. Presumably these gelatinous formations stick together to form a biofilm that is smooth at the top.

Photo depicts superimposed frames of a video during the standstill of a diatom.

      The investigation of the elastic deformations of the biofilm by marking can therefore serve the qualitative study of the relationship between movement and activity of the raphes, since both can be observed simultaneously. The method provides the possibility of quantitatively determining the forces exerted on the substrate by the raphe. For this purpose the elasticity module and the displacement of the particles have to be determined. Furthermore, a model is to be developed which relates the deformations on the surface to the forces exerted. These forces correspond to the driving force of the diatom. If there is no biofilm, it can be replaced by a synthetic elastic layer. This method complements the measurement of the force between the diatom and the substrate by deflection of a glass fiber introduced by Harper and Harper [1.18].

      When examining drops hanging from a cover glass, the diatoms contained sink to the water-air interface. They can show movements there even without a solid substrate [1.26] [1.3]. Occasionally, living diatoms also float on the water surface of densely populated cultures. This was relatively common in Nitzschia sigmoidea and much rarer in Cymatopleura solea, as well as in certain species of the genera Cymbella, Rhopalodia and Pinnularia. Since only a small number of diatom species have been cultivated, it can be assumed that this phenomenon occurs in many other genera and species. These questions arise in particular:

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