Mechanical work hydrophobic consilient

The term machine is a general designation for any device that converts energy from one form to another. The particular type of machine that performs mechanical work or produces motion is commonly called either a motor or an engine. Here, we summarize the capacity of protein-based machines to perform mechanical work (pump iron) by the consilient mechanism of hydrophobic association by utilizing a number of different energy inputs. 

Pwffomtance of Mechanical Work by the Consiliant Mechanism of Hydrophobic Folding and Assembly... 

This axiom is the fundamental energy coupling axiom it utilizes the hydrophobic association transition common to all energy conversions by the consilient mechanism. Importantly, in doing so, it involves the performance of kinds of work in addition to mechanical work. Examples include the following ... 

As shown in the hexagonal array in Figure 5.22, five different energy inputs can perform mechanical work by the consilient mechanism. The set of elastic-contractile model proteins capable of direct utilization of hydrophobic association for contraction are called protein-based molecular machines of the first kind. These are enumerated below with brief consideration of the reversibility of these machines. 

E.4.1.3.1 Perspective of the Hydrophobic Consilient Mechanism in the Performance of Mechanical Work... 

In general, then, the energy conversions of biology reduce to the production of ATP and the uses of ATP, that is, the production of ATP by the five protein-based machines of the inner mitochondrial membrane and the thousands of subsequent protein-based machines that do the necessary work of the cell. This constitutes yet an enormous task that will fill hundreds of volumes in the future of protein-based machines. The intention of this volume, however, is to add a simplifying feature of a common groundwork of explanation for each of the hydrophobic and elastic consilient mechanisms. For the function of protein-based machines of biology, this perspective recovers an attractive element of simplification. 

The operative component of the comprehensive hydrophobic effect arises from the competition between charged and oil-like groups. This was shown to result in a previously unknown repulsive force embodied within an interaction energy called an apolar-polar repulsive free energy of hydration, AG,p. During function, AG,p works in conjunction with elastic force development by the restriction of internal chain dynamics. These have been called the hydrophobic and elastic consilient mechanisms. In Chapters 6,7, and 8, these consilient mechanisms were demonstrated to be fundamental to understanding the functions of biology s proteins. 

The concept of two distinct but interlinked mechanical processes, expanded here as the coupling of hydrophobic and elastic consilient mechanisms, entered the public domain in the publication of Urry and Parker. Experimental results on elastic-contractile model proteins forged the concept, and the work of Urry and Parker extended the concept to contraction in biology. Unexpected in our examination of the relevance of this perspective to biology was to find the first clear demonstration of the concept in biology in a protein-based machine of the electron transport chain as a transmembrane protein of the inner mitochondrial membrane. Unimaginable was the occurrence of the coupled forces precisely at the nexus at which electron transfer couples to proton pumping. 

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