What process transports small ions and molecules through the nuclear pore?
Added by Alexandria B.
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The process we are discussing involves the transport of small ions and molecules through the nuclear pore complex (NPC), which is a structure that spans the nuclear envelope, allowing for the exchange of materials between the nucleus and the cytoplasm in Show more…
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Discuss how molecules are transported and excreted out of the cell. The import and export of molecules are mediated by various mechanisms, such as NPC (nuclear pore complex) and membrane transporters.
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What are the features of the transport of proteins across the nuclear envelope? What mechanism ensures that the cargo-protein complex does not exit the nuclear pore complex (NPC) once it has passed through the nuclear pore and into the nucleus?
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The nuclear pore complex (NPC) creates a barrier to the free exchange of molecules between the nucleus and cytosol, but in a way that remains mysterious. In yeast, for example, the central pore of the NPC has a diameter of 35 $\mathrm{nm}$ and is $30 \mathrm{nm}$ long, which is somewhat smaller than its vertebrate counterpart. Even so, it is large enough to accommodate virtually all components of the cytosol. Yet the pore allows passive diffusion of molecules only up to about 40 kd; entry of anything larger requires help from a nuclear import receptor. Selective permeability is controlled by protein components of the NPC that have unstructured, polar tails extending into the central pore. These tails are characterized by periodic repeats of the hydrophobic amino acids phenylalanine (F) and glycine (G). At high enough concentration $(\sim 50 \mathrm{mM})$, the FG-repeat domains of these proteins can form a gel, with a meshwork of interactions between the hydrophobic $\mathrm{FG}$ repeats (Figure $\mathrm{Q} 12-2 \mathrm{A}$ ). These gels allow passive diffusion of small molecules, but they prevent entry of larger proteins such as the fluorescent protein mCherry fused to maltose binding protein (MBP) (Figure Q12-2B). (The fusion to MBP makes mCherry too large to enter the nucleus by passive diffusion.) However, if the nuclear import receptor, importin, is fused to a similar protein, MBP-GFP, the importin-MBP-GFP fusion readily enters the gel (Figure $\mathrm{Q} 12-2 \mathrm{B}$ ). A. $\quad$ FG-repeats only form gels in vitro at relatively high concentration $(50 \mathrm{mM}) .$ Is this concentration reasonable for FG repeats in the NPC core? In yeast, there are about 5000 FG-repeats in each NPC. Given the dimensions of the yeast nuclear pore $(35 \mathrm{nm} \text { diameter and } 30 \mathrm{nm} \text { length })$ calculate the concentration of FG-repeats in the cylindrical volume of the pore. Is this concentration comparable to the one used in vitro? B. A second question is whether the diffusion of importin-MBP-GFP through the FG-repeat gel is fast enough to account for the efficient flow of materials between the nucleus and cytosol. From experiments of the type shown in Figure $\mathrm{Q} 12-2 \mathrm{B}$, the diffusion coefficient $(D)$ of importin-MBP-GFP through the FG-repeat gel was determined to be about $0.1 \mu \mathrm{m}^{2} / \mathrm{s}$. The equation for diffusion is $t=x^{2} / 2 D,$ where $t$ is time and $x$ is distance. Calculate the time it would take importin-MBP-GFP to diffuse through a yeast nuclear pore $(30 \mathrm{nm})$ if the pore consisted of a gel of FG-repeats. Does this time seem fast enough for the needs of a eukaryotic cell?
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