Literature DB >> 8710872

Do cyanobacteria swim using traveling surface waves?

K M Ehlers1, A D Samuel, H C Berg, R Montgomery.   

Abstract

Bacteria that swim without the benefit of flagella might do so by generating longitudinal or transverse surface waves. For example, swimming speeds of order 25 microns/s are expected for a spherical cell propagating longitudinal waves of 0.2 micron length, 0.02 micron amplitude, and 160 microns/s speed. This problem was solved earlier by mathematicians who were interested in the locomotion of ciliates and who considered the undulations of the envelope swept out by ciliary tips. A new solution is given for spheres propagating sinusoidal waveforms rather than Legendre polynomials. The earlier work is reviewed and possible experimental tests are suggested.

Mesh:

Year:  1996        PMID: 8710872      PMCID: PMC38672          DOI: 10.1073/pnas.93.16.8340

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  3 in total

1.  A cyanobacterium capable of swimming motility.

Authors:  J B Waterbury; J M Willey; D G Franks; F W Valois; S W Watson
Journal:  Science       Date:  1985-10-04       Impact factor: 47.728

2.  Self-electrophoresis is not the mechanism for motility in swimming cyanobacteria.

Authors:  T P Pitta; H C Berg
Journal:  J Bacteriol       Date:  1995-10       Impact factor: 3.490

3.  Gliding motility of Cytophaga sp. strain U67.

Authors:  I R Lapidus; H C Berg
Journal:  J Bacteriol       Date:  1982-07       Impact factor: 3.490
  3 in total
  20 in total

Review 1.  Cyanobacterial cell walls: news from an unusual prokaryotic envelope.

Authors:  E Hoiczyk; A Hansel
Journal:  J Bacteriol       Date:  2000-03       Impact factor: 3.490

2.  A simple, rapid method for demonstrating bacterial flagella.

Authors:  H P Grossart; G F Steward; J Martinez; F Azam
Journal:  Appl Environ Microbiol       Date:  2000-08       Impact factor: 4.792

Review 3.  Type IV pilus-dependent motility and its possible role in bacterial pathogenesis.

Authors:  Wenyuan Shi; Hong Sun
Journal:  Infect Immun       Date:  2002-01       Impact factor: 3.441

4.  The motility of mollicutes.

Authors:  Charles W Wolgemuth; Oleg Igoshin; George Oster
Journal:  Biophys J       Date:  2003-08       Impact factor: 4.033

5.  Fluid flow due to collective non-reciprocal motion of symmetrically-beating artificial cilia.

Authors:  S N Khaderi; J M J den Toonder; P R Onck
Journal:  Biomicrofluidics       Date:  2012-01-20       Impact factor: 2.800

6.  Origin of the directed movement of protocells in the early stages of the evolution of life.

Authors:  Alexey V Melkikh; Oksana I Chesnokova
Journal:  Orig Life Evol Biosph       Date:  2012-07-08       Impact factor: 1.950

7.  Transposon mutagenesis in a marine synechococcus strain: isolation of swimming motility mutants.

Authors:  J McCarren; B Brahamsha
Journal:  J Bacteriol       Date:  2005-07       Impact factor: 3.490

8.  Swimming speeds of filaments in nonlinearly viscoelastic fluids.

Authors:  Henry C Fu; Charles W Wolgemuth; Thomas R Powers
Journal:  Phys Fluids (1994)       Date:  2009-03-11       Impact factor: 3.521

9.  Lattice Boltzmann study of chemically-driven self-propelled droplets.

Authors:  F Fadda; G Gonnella; A Lamura; A Tiribocchi
Journal:  Eur Phys J E Soft Matter       Date:  2017-12-19       Impact factor: 1.890

10.  The putative eukaryote-like O-GlcNAc transferase of the cyanobacterium Synechococcus elongatus PCC 7942 hydrolyzes UDP-GlcNAc and is involved in multiple cellular processes.

Authors:  Kerry A Sokol; Neil E Olszewski
Journal:  J Bacteriol       Date:  2014-11-10       Impact factor: 3.490
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