Issue 91 / January - February 2013
Meet Molecular Motors: The Cargo Transporters in the Microcosm
Ali Fethi Toprak
They are tiny, and there are billions of them inside you. Tiny machines, one thousand times thinner than a hair strand but strong enough to carry all kinds of material within your cells. Yes, there is a complex army of tiny machines inside your body performing an amazing array of functions while you sit at home sipping your tea.
Your heart is beating. Its lifelong duty is to pump blood to tissues to deliver essential nutrients. Transportation of nutrients continues from blood vessels to cells and then into subcellular compartments. Inside of a cell, there is a need for sophisticated biomachines which are responsible for transport. Did you know that you were equipped with minuscule motors that transported cargos in your cells? Or about cellular highways where molecular cargos are transported?
There are various proteins called âmotorsâ in the cell. They can convert chemical energy to mechanical energy to produce force and motion in the cellular highways.1 Amazingly, molecular motors are much superior to man-made motors in terms of energetic efficiency by hydrolyzing ATP to fuel enzymatic reactions. These molecular motors include rotary motors, polymerization motors, nucleic acid motors and cytoskeletal motors.
Bacterial flagellum, used for swimming, acts as a propeller and uses a rotary motor. It has been suggested that this motor is similar to Fo motor found in FoF1-ATP synthase. FoF1-ATP synthase takes part in the conversion of chemical energy in ATP to proton gradient, or vice versa. This chemical reaction involves mechanical rotation of parts of the complex.
Polymerization and nucleic acid motors
Polymerization motors take role in polymerizations and these polymerizations generate forces for repulsion (Actin or microtubule polymerization), or separation of clathrin buds from plasma membrane (Dynamin).
DNA and RNA synthesis also involves the use of molecular motors such as RNA polymerase (RNA synthesis from DNA), DNA polymerase (DNA synthesis), Helicases (separation of double stranded DNA prior to DNA or RNA synthesis), Topoisomerases (removal of supercoiling of DNA), RSC, SWI/SNF, and SMC proteins (Chromatin remodeling and chromosome condensation). Moreover, there are specific viral DNA packaging motors that pack tightly viral DNA into capsids. separation of double stranded DNA prior to DNA or RNA synthesis), Topoisomerases (removal of supercoiling of DNA), RSC, SWI/SNF, and SMC proteins (Chromatin remodeling and chromosome condensation). Moreover, there are specific viral DNA packaging motors that pack tightly viral DNA into capsids.
Dyneins, kinesins and myosins denote the three major classes of molecular motor that moves along cytoskeletal structures. Myosin is among the most prominent of motor proteins that takes role in muscle contraction. Kinesin operates on microtubules (long tubes composed of dimers of the protein tubulin, arranged to form 13 parallel tracks) to move cargos inside the cells away from the nucleus (toward positive end of microtubules) and play essential roles in the formation of spindle apparatus and axonal transport. Dynein is also known to transport cargo but in the opposite direction to Kinesin, towards the cell nucleus (toward minus end of microtubules). In addition, dynein is required to beat cilia and flagella.
How molecular motors move
Myosin and kinesin are structurally similar in terms of being dimeric with two motor heads, two legs, and a common stalk. The head regions control the forward movement by binding itself to actin or microtubule filaments. Movement is facilitated by the consumption of ATP by ATPase sites. It is fascinating how these motors translate chemical energy into motion and still be different to the movement of cars. There are different proposals as to how molecular motors move, such as walking (hand-over-hand model), inchworm model, and biased diffusion model.
The-hand-over-hand model suggests that ATP binding induces a conformational change in the forward head movements and keeps fixed, thus leading to the movement of the rear head forward and vice versa. This model, which is also known as the walking model, is similar to upright walking where one foot moves forward while other stay fixed, and vice versa. On the other hand, the inchworm model suggests that only forward head movements use ATP and leads while the other head follows. Studies on the Myosin VI with shorter legs suggested a biased diffusion model. In the diffusion model, the motor moves randomly to the next binding site in a forward direction. In order to find out which mechanism used by molecular motors, scientists measured how much of the head moves following staining with a fluorescent dye. Since molecular motor movements are so small (5-10 nM), optical traps and cantilever probes (>100 Î¼m) were not useful to watch head movements. By increasing both photostability and brightness of organic dyes, Dr. Yildiz at UC Berkeley was able to measure head movements down to 1.5nM scale.
Kinesin: A molecular motor that walks
Kinesins are among microtubule-based motors recently shown to walk like a mountain climber by swapping its two motor units (analogous to feet) in a hand-over-hand mechanism rather than an inchworm mechanism. This recent discovery sheds light on how kinesin moves its cargos such as membrane components, messenger RNA, signaling moleculers, and others along microtubules. In addition, as suggested by findings of Dr. Yildiz, kinesin demonstrates an asymmetric walking where motor heads alternate with slow and fast steps. Further studies using advanced microscopy techniques (called FIONA) which allow nano scale detection of movement down to 2nM resolution demonstrated delicately that processive kinesin motor takes about 8 nM steps (eight-billionths of a meter) for each ATP molecule consumption with alternating 16-nm and 0-nm steps. Furthermore, kinesin is attached to the microtubule while it waits for ATP between steps. Since kinesin is used for long distance cargo transport on relatively big highways of a cell, it elegantly demonstrates a processive motor that reliably travels in a coordinated manner. Of course, not all motors will be moving like kinesin.
Dynein moves through uncoordinated stepping of ring domains
Another motor protein involved in long distance cargo transport is dynein. Dynein is a staggering giant which is much bigger and complex than kinesin and myosin motors. There are about 15 types of dyneins known to take role in cilia and flagella movement and 2 cytoplasmic forms. Cytoplasmic dynein is a homodimeric AAA+ (ATPases associated with cellular activities) motor that transports toward the microtubule minus end, acting opposite to kinesin. FIONA assay demonstrated that the heads moving processively but independently. This mechanism is quite different from the hand-over-hand stepping of kinesin and myosin, for dyneinâs steps are not strictly coordinated and highly variable. Most of the time, dynein heads move alternatively with variable head-to-head distance of about 5-50nM. Each head of dynein mostly does not pass each other.
Elegant design, efficiency in transportation and being part of the living system makes molecular motors in the cells superior to man-made motors. Molecular motors travel on cellular highways in the cellular microcosm in the manner of dutiful officials of a king traveling in his domain in security via the fastest modes of transportation and easily cross provincial boundaries, demonstrating more evidently that the Sovereignty of the Eternal King is limitless. Indeed, the signs of His Dominion are reflected by each and every entity from the microcosmic world to macrocosmic universe.
1 Cellular highways are composed of microtubules, microfilaments and actin filaments. Myosin moves along microfilaments through interaction with actin, but dynein and kinesin move along microtubules through interaction with tubulin
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