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David B. Dusenbery is a biophysicist with a central interest in how information influences the behavior of organisms. In later years, he also considered the physical constraints hydrodynamics imposes on microorganisms and gametes.
Most of Dusenbery's research deals with how information controls behavior. At Caltech and the early years at Georgia Tech, Dusenbery focused on experimental studies of the nematode Caenorhabditis elegans because of its small nervous system and favorable genetics.
These experimental studies inspired the development of several innovative techniques:
Initially, Dusenbery was attempting to understand the flow of information in the nervous system of this simple animal. Later, he turned to the flow of information outside the organism, and how physics constrains how organisms behave. [9] More recently, he has also considered hydrodynamic constraints on small organisms, which can only swim at low speeds, where viscosity is far more important than inertia (low Reynolds numbers). [10]
From physical analysis, Dusenbery predicted [11] that the long-held belief that bacteria were too small to employ spatial sensing mechanisms to follow chemical gradients [12] [13] [14] [15] [16] [17] [18] [19] was erroneous and predicted that bacteria following steep gradients of chemicals at high concentrations would benefit from using a spatial mechanism. In 2003, a new bacterial species was discovered that swim sideways and respond to differences in oxygen concentration at the two ends of the cell, allowing them to follow steep gradients of oxygen. [20]
Similar considerations have also been applied to the behaviors of gametes, leading to an explanation of why the sperm/egg ( ovum) and thus the male/ female distinctions exist. [21] [22] [23]
This article has multiple issues. Please help
improve it or discuss these issues on the
talk page. (
Learn how and when to remove these template messages)
|
David B. Dusenbery is a biophysicist with a central interest in how information influences the behavior of organisms. In later years, he also considered the physical constraints hydrodynamics imposes on microorganisms and gametes.
Most of Dusenbery's research deals with how information controls behavior. At Caltech and the early years at Georgia Tech, Dusenbery focused on experimental studies of the nematode Caenorhabditis elegans because of its small nervous system and favorable genetics.
These experimental studies inspired the development of several innovative techniques:
Initially, Dusenbery was attempting to understand the flow of information in the nervous system of this simple animal. Later, he turned to the flow of information outside the organism, and how physics constrains how organisms behave. [9] More recently, he has also considered hydrodynamic constraints on small organisms, which can only swim at low speeds, where viscosity is far more important than inertia (low Reynolds numbers). [10]
From physical analysis, Dusenbery predicted [11] that the long-held belief that bacteria were too small to employ spatial sensing mechanisms to follow chemical gradients [12] [13] [14] [15] [16] [17] [18] [19] was erroneous and predicted that bacteria following steep gradients of chemicals at high concentrations would benefit from using a spatial mechanism. In 2003, a new bacterial species was discovered that swim sideways and respond to differences in oxygen concentration at the two ends of the cell, allowing them to follow steep gradients of oxygen. [20]
Similar considerations have also been applied to the behaviors of gametes, leading to an explanation of why the sperm/egg ( ovum) and thus the male/ female distinctions exist. [21] [22] [23]