Structure and function of the juxtamembrane GAF domain of potassium biosensor KdpD.

KdpD/KdpE two-component signaling system regulates expression of a high affinity potassium transporter responsible for potassium homeostasis. The C-terminal module of KdpD consists of a GAF domain linked to a histidine kinase domain. Whereas certain GAF domains act as regulators by binding cyclic nucleotides, the role of the juxtamembrane GAF domain in KdpD is unknown. We report the high-resolution crystal structure of KdpD GAF domain (KdpDG ) consisting of five α-helices, four ß-sheets and two large loops. KdpDG forms a symmetry-related dimer, wherein parallelly arranged monomers contribute to a four-helix bundle at the dimer-interface, SAXS analysis of KdpD C-terminal module reveals an elongated structure that is a dimer in solution. Substitution of conserved residues with various residues that disrupt the dimer interface produce a range of effects on gene expression demonstrating the importance of the interface in inactive to active transitions during signaling. Comparison of ligand binding site of the classic cyclic nucleotide-binding GAF domains to KdpDG reveals structural differences arising from naturally occurring substitutions in primary sequence of KdpDG that modifies the canonical NKFDE sequence motif required for cyclic nucleotide binding. Together these results suggest a structural role for KdpDG in dimerization and transmission of signal to the kinase domain.

An asymmetric heterodomain interface stabilizes a response regulator-DNA complex.

Two-component signal transduction systems consist of pairs of histidine kinases and response regulators, which mediate adaptive responses to environmental cues. Most activated response regulators regulate transcription by binding tightly to promoter DNA via a phosphorylation-triggered inactive-to-active transition. The molecular basis for formation of stable response regulator-DNA complexes that precede the assembly of RNA polymerases is unclear. Here, we present structures of DNA complexed with the response regulator KdpE, a member of the OmpR/PhoB family. The distinctively asymmetric complex in an active-like conformation reveals a unique intramolecular interface between the receiver domain (RD) and the DNA-binding domain (DBD) of only one of the two response regulators in the complex. Structure-function studies show that this RD-DBD interface is necessary to form stable complexes that support gene expression. The conservation of sequence and structure suggests that these findings extend to a large group of response regulators that act as transcription factors.

Identification of the dimer interface of a bacterial Ca(2+)/H(+) antiporter.

Members of the calcium/cation antiporter superfamily, including the cardiac sodium/calcium exchangers, are secondary active transporters that play an essential role in cellular Ca(2+) homeostasis. A notable feature of this group of transporters is the high levels of sequence similarity in relatively short sequences constituting the functionally important α-1 and α-2 regions in contrast to relatively lower degrees of similarity in the extended adjoining sequences. This suggests a similar structure and function of core transport machinery but possible differences in topology and/or oligomerization, a topic that has not been adequately addressed. Here we present the first example of purification of a bacterial member of this superfamily (CAX(CK31)) and analyze its quaternary structure. Purification of CAX(CK31) required the presence of a choline headgroup-containing detergent or lipid to yield stable preparations of the monomeric transporter. H(+)-driven Ca(2+) transport was demonstrated by reconstituting purified CAX(CK31) into liposomes. Dimeric CAX(CK31) could be isolated by manipulation of detergent micelles. Dimer formation was shown to be dependent on micelle composition as well as protein concentration. Furthermore, we establish that CAX(CK31) forms dimers in the membrane by analysis of cross-linked proteins. Using a dimeric homology model derived from the monomeric structure of the archaeal NCX homologue (Protein Data Bank entry 3V5U ), we introduced cysteine residues and through cross-linking experiments established the role of transmembrane helices 2 and 6 in the putative dimer interface.

Structure-function studies of DNA binding domain of response regulator KdpE reveals equal affinity interactions at DNA half-sites.

Expression of KdpFABC, a K(+) pump that restores osmotic balance, is controlled by binding of the response regulator KdpE to a specific DNA sequence (kdpFABC(BS)) via the winged helix-turn-helix type DNA binding domain (KdpE(DBD)). Exploration of E. coli KdpE(DBD) and kdpFABC(BS) interaction resulted in the identification of two conserved, AT-rich 6 bp direct repeats that form half-sites. Despite binding to these half-sites, KdpE(DBD) was incapable of promoting gene expression in vivo. Structure-function studies guided by our 2.5 Å X-ray structure of KdpE(DBD) revealed the importance of residues R193 and R200 in the α-8 DNA recognition helix and T215 in the wing region for DNA binding. Mutation of these residues renders KdpE incapable of inducing expression of the kdpFABC operon. Detailed biophysical analysis of interactions using analytical ultracentrifugation revealed a 2∶1 stoichiometry of protein to DNA with dissociation constants of 200±100 and 350±100 nM at half-sites. Inactivation of one half-site does not influence binding at the other, indicating that KdpE(DBD) binds independently to the half-sites with approximately equal affinity and no discernable cooperativity. To our knowledge, these data are the first to describe in quantitative terms the binding at half-sites under equilibrium conditions for a member of the ubiquitous OmpR/PhoB family of proteins.

Crystal structure and characterization of coiled-coil domain of the transient receptor potential channel PKD2L1.

The cation-permeable channel PKD2L1 forms a homomeric assembly as well as heteromeric associations with both PKD1 and PKD1L3, with the cytoplasmic regulatory domain (CRD) of PKD2L1 often playing a role in assembly and/or function. Our previous work indicated that the isolated PKD2L1 CRD assembles as a trimer in a manner dependent on the presence of a proposed oligomerization domain. Herein we describe the 2.7Å crystal structure of a segment containing the PKD2L1 oligomerization domain which indicates that trimerization is driven by the ß-branched residues at the first and fourth positions of a heptad repeat (commonly referred to as "a" and "d") and by a conserved R-h-x-x-h-E salt bridge motif that is largely unique to parallel trimeric coiled coils. Further analysis of the PKD2L1 CRD indicates that trimeric association is sufficiently strong that no other species are present in solution in an analytical ultracentrifugation experiment at the lowest measurable concentration of 750nM. Conversely, mutation of the "a" and "d" residues leads to formation of an exclusively monomeric species, independent of concentration. Although both monomeric and WT CRDs are stable in solution and bind calcium with 0.9µM affinity, circular dichroism studies reveal that the monomer loses 25% more α-helical content than WT when stripped of this ligand, suggesting that the CRD structure is stabilized by trimerization in the ligand-free state. This stability could play a role in the function of the full-length complex, indicating that trimerization may be important for both homo- and possibly heteromeric assemblies of PKD2L1.

Restrained expression, a method to overproduce toxic membrane proteins by exploiting operator-repressor interactions.

A major rate-limiting step in determining structures of membrane proteins is heterologous protein production. Toxicity often associated with rapid overexpression results in reduced biomass along with low yields of target protein. Mitigation of toxic effects was achieved using a method we call "restrained expression," a controlled reduction in the frequency of transcription initiation by exploiting the infrequent transitions of Lac repressor to a free state from its complex with the lac-operator site within a T7lac promoter that occur in the absence of the inducer isopropyl ß-D-1-thiogalactopyranoside. In addition, production of the T7 RNA polymerase that drives transcription of the target is limited using the tightly regulated arabinose promoter in Escherichia coli strain BL21-AI. Using this approach, we can achieve a 200-fold range of green fluorescent protein expression levels. Application to members of a family of ion pumps results in 5- to 25-fold increases in expression over the benchmark BL21(DE3) host strain. A viral ion channel highly toxic to E. coli can also be overexpressed. In comparative analyses, restrained expression outperforms commonly used E. coli expression strategies. The mechanism underlying improved target protein yield arises from minimization of protein aggregation and proteolysis that reduce membrane integrity and cell viability. This study establishes a method to overexpress toxic proteins.

Identification of the structural motif responsible for trimeric assembly of the C-terminal regulatory domains of polycystin channels PKD2L1 and PKD2.

Polycystin 2-type cation channels PKD2 and PKD2L1 interact with polycystin 1-type proteins PKD1 and PKD1L3 respectively, to form receptor-cation-channel complexes. The PKD2L1-PKD1L3 complex perceives sour taste, whereas disruption of the PKD2-PKD1 complex, responsible for mechanosensation, leads to development of ADPKD (autosomal-dominant polycystic kidney disease). Besides modulating channel activity and related signalling events, the CRDs (C-terminal regulatory domains) of PKD2 and PKD2L1 play a central role in channel oligomerization. The present study investigates the aggregation state of purified full-length PKD2L1-CRD as well as truncations of CRDs from PKD2 channels. Far- and near-UV CD spectroscopy show that the full-length PKD2L1 CRD (PKD2L1-198) and the truncated PKD2 CRD (PKD2-244) are alpha-helical with no beta-sheet, the alpha-helix content agrees with sequence-based predictions, and some of its aromatic residues are in an asymmetric environment created at least by partially structured regions. Additionally, the CRD truncations exhibit an expected biochemical function by binding Ca2+ in a physiologically relevant range with Kd values of 2.8 muM for PKD2-244 and 0.51 muM for PKD2L1-198. Complimentary biophysical and biochemical techniques establish that truncations of the PKD2 and PKD2L1 CRDs are elongated molecules that assemble as trimers, and the trimeric aggregation state is independent of Ca2+ binding. Finally, we show that a common coiled-coil motif is sufficient and necessary to drive oligomerization of the PKD2 and PKD2L1 CRD truncations under study. Despite the moderate sequence identity (39%) between CRDs of PKD2 and PKD2L1, they both form trimers, implying that trimeric organization of CRDs may be true of all polycystin channels.