Molecular motors: how to make models that can be used to convey the concept of molecular ratchets and thermal capture.

A wide variety of cellular processes use molecular motors, including processive motors that move along some form of track (e.g., myosin with actin, kinesin or dynein with tubulin) and polymerases that move along a template (e.g., DNA and RNA polymerases, ribosomes). In trying to understand how these molecular motors actually move, many apply their understanding of how man-made motors work: the latter use some form of energy to exert a force or torque on its load. However, quite a different mechanism has been proposed to possibly account for the movement of molecular motors. Rather than hydrolyzing ATP to push or pull their load, they might use their own thermal vibrational energy as well as that of their load and their environment to move the load, capturing those movements that occur along a desired vector or axis and resisting others; ATP hydrolysis is required to make backward movements impossible. This intriguing thermal capture or Brownian ratchet model is relatively more difficult to convey to students. In this report, we describe several teaching aids that are very easily constructed using widely available household materials to convey the concept of a molecular ratchet.

Reduction of arterial graft smooth muscle mass by moderate heat therapy.

Radial artery (RA) graft spasm is a major cause of early graft failure in coronary artery bypass grafting surgeries. We explored the feasibility of thermal reduction of smooth muscle mass to attenuate vasoconstriction. Rat and rabbit femoral arteries were treated thermally in situ (45°C to 65°C; 0 s to 120 s) and then excised at various time points for histological and physiological study (pressure-diameter relationships). Human radial arteries were treated in vitro and studied in similar fashion. Weeks after thermal treatment, no overt indication was noted of vasospasm, thrombosis, or scarring in the arterial wall; however, this intervention led to a thermal dose-dependent reduction of vasoconstriction (to phenylephrine or potassium chloride) and to a conspicuous loss of smooth muscle. Pressure-diameter relationships showed no aneurismal dilation of these demuscularized arteries up to 200 mmHg. Qualitatively identical results were obtained in human radial arteries. Thermal ablation of RAs may provide a simple, safe, and effective solution to postsurgical vasospasm.

Acute response of airway muscle to extreme temperature includes disruption of actin-myosin interaction.

Despite the emerging use of bronchial thermoplasty in asthma therapy, the response of airway smooth muscle (ASM) to extreme temperatures is unknown. We investigated the immediate effects of exposing ASM to supraphysiologic temperatures. Isometric contractions were studied in bovine ASM before and after exposure to various thermal loads and/or pharmacologic interventions. Actin-myosin interactions were investigated using a standard in vitro motility assay. We found steep thermal sensitivity for isometric contractions evoked by acetylcholine, with threshold and complete inhibition at less than 50°C and greater than 55°C, respectively. Contractile responses to serotonin or KCl were similarly affected, whereas isometric relaxations evoked by the nitric oxide donor S-nitrosyl-N-acetylpenicillamine or the ß-agonist isoproterenol were unaffected. This thermal sensitivity developed within 15 minutes, but did not evolve further over the course of several days (such a rapid time-course rules out heat shock proteins, apoptosis, autophagy, and necrosis). Although heat-sensitive transient receptor potential (TRPV2) channels and the calmodulin-dependent (Cam) kinase-II-induced inactivation of myosin light chain kinase are both acutely thermally sensitive, with a temperature producing half-maximal effect (T(1/2)) of 52.5°C, the phenomenon we describe was not prevented by blockers of TRPV2 channels (e.g., ruthenium red, gadolinium, zero-Ca(2+) or zero-Na(+)/zero-Ca(2+) media, and cromakalim) or of Cam kinase-II (e.g., W7, trifluoperazine, and KN-93). However, direct measurements of actin-myosin interactions showed the same steep thermal profile. The functional changes preceded any histologic evidence of necrosis or apoptosis. We conclude that extreme temperatures (such as those used in bronchial thermoplasty) directly disrupt actin-myosin interactions, likely through a denaturation of the motor protein, leading to an immediate loss of ASM cell function.