Increased accuracy of ligand sensing by receptor internalization

Many types of cells can sense external ligand concentrations with cell-surface receptors at extremely high accuracy. Interestingly, ligand-bound receptors are often internalized, a process also known as receptor-mediated endocytosis. While internalization is involved in a vast number of important functions for the life of a cell, it was recently also suggested to increase the accuracy of sensing ligand as the overcounting of the same ligand molecules is reduced. Here we show, by extending simple ligand-receptor models to out-of-equilibrium thermodynamics, that internalization increases the accuracy with which cells can measure ligand concentrations in the external environment. Comparison with experimental rates of real receptors demonstrates that our model has indeed biological significance.Comment: 9 pages, 4 figures, accepted for publication in Physical Review

Maximum likelihood and the single receptor

Biological cells are able to accurately sense chemicals with receptors at their surfaces, allowing cells to move towards sources of attractant and away from sources of repellent. The accuracy of sensing chemical concentration is ultimately limited by the random arrival of particles at the receptors by diffusion. This fundamental physical limit is generally considered to be the Berg & Purcell limit [H.C. Berg and E.M. Purcell, Biophys. J. {\bf 20}, 193 (1977)]. Here we derive a lower limit by applying maximum likelihood to the time series of receptor occupancy. The increased accuracy stems from solely considering the unoccupied time intervals - disregarding the occupied time intervals as these do not contain any information about the external particle concentration, and only decrease the accuracy of the concentration estimate. Receptors which minimize the bound time intervals achieve the highest possible accuracy. We discuss how a cell could implement such an optimal sensing strategy by absorbing or degrading bound particles.Comment: 5 pages, 1 figure; accepted for publication in Phys. Rev. Let

Interaction of the Deubiquitinating Enzyme Ubp2 and the E3 Ligase Rsp5 Is Required for Transporter/Receptor Sorting in the Multivesicular Body Pathway

Protein ubiquitination is essential for many events linked to intracellular protein trafficking. We sought to elucidate the possible involvement of the S. cerevisiae deubiquitinating enzyme Ubp2 in transporter and receptor trafficking after we (this study) and others established that affinity purified Ubp2 interacts stably with the E3 ubiquitin ligase Rsp5 and the (ubiquitin associated) UBA domain containing protein Rup1. UBP2 interacts genetically with RSP5, while Rup1 facilitates the tethering of Ubp2 to Rsp5 via a PPPSY motif. Using the uracil permease Fur4 as a model reporter system, we establish a role for Ubp2 in membrane protein turnover. Similar to hypomorphic rsp5 alleles, cells deleted for UBP2 exhibited a temporal stabilization of Fur4 at the plasma membrane, indicative of perturbed protein trafficking. This defect was ubiquitin dependent, as a Fur4 N-terminal ubiquitin fusion construct bypassed the block and restored sorting in the mutant. Moreover, the defect was absent in conditions where recycling was absent, implicating Ubp2 in sorting at the multivesicular body. Taken together, our data suggest a previously overlooked role for Ubp2 as a positive regulator of Rsp5-mediated membrane protein trafficking subsequent to endocytosis

Direct evidence for ligand-induced internalization of the yeast alpha-factor pheromone receptor.

When Saccharomyces cerevisiae a cells bind alpha-factor pheromone, the ligand is internalized and its binding sites are lost from the cell surface in a time-, energy-, and temperature-dependent manner. This report presents direct evidence for alpha-factor-induced internalization of cell surface receptors. First, membrane fractionation on Renografin density gradients indicated that the alpha-factor receptors were predominantly found in the plasma membrane peak before alpha-factor treatment and then appeared in membranes of lesser buoyant density after alpha-factor exposure. Second, receptors were susceptible to cleavage by extracellular proteases before alpha-factor treatment and then became resistant to proteolysis after exposure to pheromone, consistent with the transit of receptors from the cell surface to an internal compartment. The median transit time in both assays was approximately 8 min. The ultimate target of the internalized receptors was identified as the vacuole, since the membranes containing internalized receptors cofractionated with vacuolar membranes, since the turnover of receptors was stimulated by alpha-factor exposure, and since receptor degradation was blocked in a pep4 mutant that is deficient for vacuolar proteases. The carboxy-terminal domain of the receptor that is required for ligand internalization was also found to be essential for endocytosis of the receptor. A receptor mutant, ste2-L236H, which is defective for pheromone response but capable of ligand internalization, was found to be proficient for receptor endocytosis. Hence, separate structural features of the receptor appear to specify its signal transduction and internalization activities

Localization of TraC, a protein involved in assembly of the F conjugative pilus.

TraC is one of the proteins encoded by the F transfer region of the F conjugative plasmid which is required for the assembly of F pilin into the mature F pilus structure. Overproduction of this protein from the plasmid pKAS2, which carries only traC, resulted in the formation of inclusion bodies from which soluble TraC was purified. When small amounts of TraC were produced from pKAS2, the protein was localized to the cytoplasm by using anti-TraC antibodies. Similar analysis of a set of TraC-alkaline phosphatase fusion proteins localized all of these fusion proteins to the cytoplasm. However, when TraC was expressed from the F plasmid, much of it appeared associated with the bacterial membrane fraction. Under these conditions, TraC does not appear to be part of the tip of the F pilus, as neither anti-TraC antibodies nor purified TraC had any effect on the infection of F-containing bacteria by the filamentous bacteriophage f1. These data suggest that TraC is normally associated with the membrane through interactions with other proteins specified by the tra region. This interaction may be via the carboxyl-terminal region of the TraC protein, as a mutant TraC protein containing an Arg-Cys substitution at amino acid 811 exhibits an interaction with the membrane weaker than that of the wild-type protein in the presence of the other Tra proteins

A traC mutant that retains sensitivity to f1 bacteriophage but lacks F pili.

An F lac pro mutant which was temperature sensitive for infection by the filamentous bacteriophage f1 but resistant to the F-specific icosahedral RNA phage f2 was isolated. Cells carrying the F' mutation failed to elaborate F pili at all temperatures. Mutant cells were able to pair with recipient cells during bacterial conjugation, but transfer of conjugal DNA occurred at a greatly reduced frequency. Complementation analyses showed the F' mutation to be in the traC gene. When a plasmid carrying traC was introduced into hosts harboring the F' mutation, phage sensitivity, the ability to elaborate F pili, and conjugation efficiency were restored. The mutation was named traC1044. The F lac pro traC1044 mutant appears to be unique among traC mutants in retaining host sensitivity to the filamentous phage f1 in the absence of expression of extended F pili. Phage f1 attachment sites appeared to be present at the cell surface in traC1044 mutants. The reduced accessibility of these sites may account for the reduced efficiency of phage f1 infection of traC1044 hosts, although the possibility that a defect was present in the receptor site itself was not eliminated. Membranes of hosts carrying the F' mutation contained a full complement of mature F-pilin subunits, so the product of traC is presumably required for pilus assembly but not for pilin processing. This, together with the deficiency in conjugal DNA transfer, suggests that traC may be part of a membrane-spanning tra protein complex responsible for pilus assembly and disassembly and conjugal DNA transmission

Characterization of trbC, a new F plasmid tra operon gene that is essential to conjugative transfer

We have characterized a previously unidentified gene, trbC, which is contained in the transfer region of the Escherichia coli K-12 fertility factor, F. Our data show that the trbC gene is located between the F plasmid genes traU and traN. The product of trbC was identified as a polypeptide with an apparent molecular weight (Ma) of 23,500 that is processed to an Ma-21,500 mature protein. When ethanol was present, the Ma-23,500 polypeptide accumulated; the removal of ethanol resulted in the appearance of the processed mature protein. Subcellular fractionation experiments demonstrated that the processed, Ma-21,500 mature protein was located in the periplasm. DNA sequence analysis showed that trbC encodes a 212-amino-acid Mr-23,432 polypeptide that could be processed to a 191-amino-acid Mr-21,225 mature protein through the removal of a typical amino-terminal signal sequence. We also constructed two different Kmr gene insertion mutations in trbC and crossed these onto the transmissible F plasmid derivative pOX38. We found that cells carrying pOX38 trbC mutant plasmids were transfer deficient and resistant to infection by F-pilus-specific phages. Transfer proficiency and bacteriophage sensitivity were restored by complementation when a trbC+ plasmid clone was introduced into these cells. These results showed that trbC function is essential to the F plasmid conjugative transfer system and suggested that the TrbC protein participates in F-pilus assembly