ABSTRACT
Titin, with a massive single chain of 3--4MDa and multiple modular motifs, spans the half-sarcomere of skeletal and cardiac muscles and serves important, multifaceted functions. In recent years, titin has become a favored subject of single molecule observations by atomic force microscopy (AFM) and laser optical trap (LOT). Here we review these single titin molecule extension studies with an emphasis on understanding their relevance to titin elasticity in muscle function. Some fundamental aspects of the methods for single titin molecule investigations, including the application of dynamic force, the elasticity models for filamentous titin motifs, the technical foundations and calibrations of AFM and LOT, and titin sample preparations are provided. A chronological review of major publications on recent single titin extension observations is presented. This is followed by summary evaluations of titin domain folding/unfolding results and of elastic properties of filamentous titin motifs. Implications of these single titin measurements for muscle physiology/pathology are discussed and forthcoming advances in single titin studies are anticipated.
Subject(s)
Muscle Proteins/chemistry , Protein Kinases/chemistry , Amino Acid Motifs , Animals , Connectin , Elasticity , Forecasting , Lasers , Microchemistry , Micromanipulation/instrumentation , Micromanipulation/methods , Microscopy, Atomic Force , Models, Chemical , Muscle Proteins/isolation & purification , Protein Denaturation , Protein Folding , Protein Kinases/isolation & purification , Specimen Handling , Stress, Mechanical , Tenascin/chemistryABSTRACT
VDAC forms the major pathway for metabolites across the mitochondrial outer membrane. The regulation of the gating of VDAC channels is an effective way to control the flow of metabolites into and out of mitochondria. Here we present evidence that actin can modulate the gating process of Neurospora crassa VDAC reconstituted into membranes made with phosphatidylcholine. An actin concentration as low as 50 nM caused the VDAC-mediated membrane conductance to drop by as much as 85% at elevated membrane potentials. Actin's effect could be quickly reversed by adding pronase to digest the protein. alpha-Actin, from mammalian muscle, has a stronger effect than beta- and gamma-actin from human platelets. The monomeric form of actin, G-actin, is effective. Stabilization of the fibrous form, F-actin, with the mushroom toxin, phalloidin, blocks the effect of actin on VDAC, indicating that F-actin might be ineffective. Cytochalasin B did not interfere with the ability of actin to favor VDAC closure. DNase- did effectively block actin's effect on VDAC, and VDAC decreased actin's inhibitory effect on DNase-I activity, indicating that N. crassa VDAC competes with DNase-I for the same binding site on actin. The actin-VDAC interaction might be a mechanism by which actin regulates energy metabolism.
