Roles of charged residues in the conserved motif, G-X-X-X-D/E-R/K-X-G-[X]-R/K-R/K, of the lactose permease of Escherichia coli.

The lactose permease is a polytopic membrane protein that has a duplicated conserved motif, GXXX(D/E)(R/K)XG[X](R/K)(R/K), located in cytoplasmic loops 2/3 and 8/9. In the current study, the roles of the basic residues and the acidic residue were investigated in greater detail. Neutral substitutions of two positive charges in loop 2/3 were tolerated, while a triple mutant resulted in a complete loss of expression. Neutral substitutions of a basic residue in loop 8/9 (i.e., K289I) also diminished protein stability. By comparison, neutral substitutions affecting the negative charge in loop 2/3 had normal levels of expression, but were defective in transport. A double mutant (D68T/N284D), in which the aspartate of loop 2/3 was moved to loop 8/9, did not have appreciable activity, indicating that the negative charge in the conserved motif could not be placed in loop 8/9 to recover lactose transport activity. An analysis of site-directed mutants in loop 7/8 and loop 8/9 indicated that an alteration in the charge distribution across transmembrane segment 8 was not sufficient to alleviate a defect caused by the loss of a negative charge in loop 2/3. To further explore this phenomenon, the double mutant, D68T/N284D, was used as a parental strain to isolate suppressor mutations which restored function. One mutant was obtained in which an acidic residue in loop 11/12 was changed to a basic residue (i.e., Glu374 --> Lys). Overall, the results of this study suggest that the basic residues in the conserved motif play a role in protein insertion and/or stability, and that the negative charge plays a role in conformational changes.

Mouse receptor interacting protein 3 does not contain a caspase-recruiting or a death domain but induces apoptosis and activates NF-kappaB.

The death domain-containing receptor superfamily and their respective downstream mediators control whether or not cells initiate apoptosis or activate NF-kappaB, events critical for proper immune system function. A screen for upstream activators of NF-kappaB identified a novel serine-threonine kinase capable of activating NF-kappaB and inducing apoptosis. Based upon domain organization and sequence similarity, this novel kinase, named mRIP3 (mouse receptor interacting protein 3), appears to be a new RIP family member. RIP, RIP2, and mRIP3 contain an N-terminal kinase domain that share 30 to 40% homology. In contrast to the C-terminal death domain found in RIP or the C-terminal caspase-recruiting domain found in RIP2, the C-terminal tail of mRIP3 contains neither motif and is unique. Despite this feature, overexpression of the mRIP3 C terminus is sufficient to induce apoptosis, suggesting that mRIP3 uses a novel mechanism to induce death. mRIP3 also induced NF-kappaB activity which was inhibited by overexpression of either dominant-negative NIK or dominant-negative TRAF2. In vitro kinase assays demonstrate that mRIP3 is catalytically active and has autophosphorylation site(s) in the C-terminal domain, but the mRIP3 catalytic activity is not required for mRIP3 induced apoptosis and NF-kappaB activation. Unlike RIP and RIP2, mRIP3 mRNA is expressed in a subset of adult tissues and is thus likely to be a tissue-specific regulator of apoptosis and NF-kappaB activity. While the lack of a dominant-negative mutant precludes linking mRIP3 to a known upstream regulator, characterizing the expression pattern and the in vitro functions of mRIP3 provides insight into the mechanism(s) by which cells modulate the balance between survival and death in a cell-type-specific manner.

An analysis of suppressor mutations suggests that the two halves of the lactose permease function in a symmetrical manner.

A conserved motif, GXXX(D/E)(R/K)XG[X](R/K)(R/K), is located in loop 2/3 and loop 8/9 in the lactose permease, and also in hundreds of evolutionarily related transporters. The importance of conserved residues in loop 8/9 was previously investigated (Pazdernik, N. J., Jessen-Marshall, A. E., and Brooker, R. J. (1997) J. Bacteriol. 179, 735-741). Although this loop was tolerant of many substitutions, a few mutations in the first position of the motif were shown to dramatically decrease lactose transport. In the current study, a mutant at the first position in the motif having very low lactose transport, Leu280, was used as a parental strain to isolate second-site revertants that restore function. A total of 23 independent mutants were sequenced and found to have a second amino acid substitution at several locations (G46C, G46S, F49L, A50T, L212Q, L216Q, S233P, C333G, F354C, G370C, G370S, and G370V). A kinetic analysis revealed that the first-site mutation, Leu280, had a slightly better affinity for lactose compared with the wild-type strain, but its Vmax for lactose transport was over 30-fold lower. The primary effect of the second-site mutations was to increase the Vmax for lactose transport, in some cases, to levels that were near the wild-type value. When comparing this study to second-site mutations obtained from loop 2/3 defective strains, a striking observation was made. Mutations in three regions of the protein, codons 45-50, 234-241, and 366-370, were able to restore functionality to both loop 2/3 and loop 8/9 defects. These results are discussed within the context of a C1/C2 alternating conformation model in which lactose translocation occurs by a conformational change at the interface between the two halves of the protein.

Role of conserved residues in hydrophilic loop 8-9 of the lactose permease.

A peptide motif, GXXX(D/E)(R/K)XG(R/K)(R/K), has been conserved in a large group of evolutionarily related membrane proteins that transport small molecules across the membrane. Within the superfamily, this motif is located in two cytoplasmic loops that connect transmembrane segments 2 and 3 and transmembrane segments 8 and 9. In a previous study concerning the loop 2-3 motif of the lactose permease (A. E. Jessen-Marshall, N. J. Paul, and R. J. Brooker, J. Biol. Chem. 270:16251-16257, 1995), it was shown that the first-position glycine and the fifth-position aspartate are critical for transport activity since a variety of site-directed mutations greatly diminished the rate of transport. In the current study, a similar approach was used to investigate the functional significance of the conserved residues in the loop 8-9 motif. In the wild-type lactose permease, however, this motif has been evolutionarily modified so that the first-position glycine (an alpha-helix breaker) has been changed to proline (also a helix breaker); the fifth position has been changed to an asparagine; and one of the basic residues has been altered. In this investigation, we made a total of 28 single and 7 double mutants within the loop 8-9 motif to explore the functional importance of this loop. With regard to transport activity, amino acid substitutions within the loop 8-9 motif tend to be fairly well tolerated. Most substitutions produced permeases with normal or mildly defective transport activities. However, three substitutions at the first position (i.e., position 280) resulted in defective lactose transport. Kinetic analysis of position 280 mutants indicated that the defect decreased the Vmax for lactose uptake. Besides substitutions at position 280, a Gly-288-to-Thr mutant had the interesting property that the kinetic parameters for lactose uptake were normal yet the rates of lactose efflux and exchange were approximately 10-fold faster than wild-type rates. The results of this study suggest that loop 8-9 may facilitate conformational changes that translocate lactose.