Michael C. Wiener

Substrate-induced transmembrane signaling in the cobalamin transporter BtuB

The outer membranes of Gram-negative bacteria possess transport proteins essential for uptake of scarce nutrients. In TonB-dependent transporters, a conserved sequence of seven residues, the Ton box, faces the periplasm and interacts with the inner membrane TonB protein to energize an active transport cycle. A critical mechanistic step is the structural change in the Ton box of the transporter upon substrate binding; this essential transmembrane signaling event increases the affinity of the transporter for TonB and enables active transport to proceed. We have solved crystal structures of BtuB, the outer membrane cobalamin transporter from Escherichia coli, in the absence and presence of cyanocobalamin (vitamin B12). In these structures, the Ton box is ordered and undergoes a conformational change in the presence of bound substrate. Calcium has been implicated as a necessary factor for the high-affinity binding (Kd ∼0.3 nM) of cyanocobalamin to BtuB. We observe two bound calcium ions that order three extracellular loops of BtuB, thus providing a direct (and unusual) structural role for calcium.

Outer Membrane Active Transport: Structure of the BtuB:TonB Complex

In Gram-negative bacteria, the import of essential micronutrients across the outer membrane requires a transporter, an electrochemical gradient of protons across the inner membrane, and an inner membrane protein complex (ExbB, ExbD, TonB) that couples the proton-motive force to the outer membrane transporter. The inner membrane protein TonB binds directly to a conserved region, called the Ton-box, of the transporter. We solved the structure of the cobalamin transporter BtuB in complex with the C-terminal domain of TonB. In contrast to its conformations in the absence of TonB, the Ton-box forms a β strand that is recruited to the existing β sheet of TonB, which is consistent with a mechanical pulling model of transport.

The structure of BtuB with bound colicin E3 R-domain implies a translocon

Cellular import of colicin E3 is initiated by the Escherichia coli outer membrane cobalamin transporter, BtuB. The 135-residue 100-Å coiled-coil receptor-binding domain (R135) of colicin E3 forms a 1:1 complex with BtuB whose structure at a resolution of 2.75 Å is reported. Binding of R135 to the BtuB extracellular surface (ΔG° = −12 kcal mol−1) is mediated by 27 residues of R135 near the coiled-coil apex. Formation of the R135–BtuB complex results in unfolding of R135 N- and C-terminal ends, inferred to be important for unfolding of the colicin T-domain. Small conformational changes occur in the BtuB cork and barrel domains but are insufficient to form a translocation channel. The absence of a channel and the peripheral binding of R135 imply that BtuB serves to bind the colicin, and that the coiled-coil delivers the colicin to a neighboring outer membrane protein for translocation, thus forming a colicin translocon. The translocator was concluded to be OmpF from the occlusion of OmpF channels by colicin E3.

Identification of the Periplasmic Cobalamin-Binding Protein BtuF of Escherichia coli

Cells of Escherichia coli take up vitamin B(12) (cyano-cobalamin [CN-Cbl]) and iron chelates by use of sequential active transport processes. Transport of CN-Cbl across the outer membrane and its accumulation in the periplasm is mediated by the TonB-dependent transporter BtuB. Transport across the cytoplasmic membrane (CM) requires the BtuC and BtuD proteins, which are most related in sequence to the transmembrane and ATP-binding cassette proteins of periplasmic permeases for iron-siderophore transport. Unlike the genetic organization of most periplasmic permeases, a candidate gene for a periplasmic Cbl-binding protein is not linked to the btuCED operon. The open reading frame termed yadT in the E. coli genomic sequence is related in sequence to the periplasmic binding proteins for iron-siderophore complexes and was previously implicated in CN-Cbl uptake in Salmonella. The E. coli yadT product, renamed BtuF, is shown here to participate in CN-Cbl uptake. BtuF protein, expressed with a C-terminal His(6) tag, was shown to be translocated to the periplasm concomitant with removal of a signal sequence. CN-Cbl-binding assays using radiolabeled substrate or isothermal titration calorimetry showed that purified BtuF binds CN-Cbl with a binding constant of around 15 nM. A null mutation in btuF, but not in the flanking genes pfs and yadS, strongly decreased CN-Cbl utilization and transport into the cytoplasm. The growth response to CN-Cbl of the btuF mutant was much stronger than the slight impairment previously described for btuC, btuD, or btuF mutants. Hence, null mutations in btuC and btuD were constructed and revealed that the btuC mutant had a strong impairment similar to that of the btuF mutant, whereas the btuD defect was less pronounced. All mutants with defective transport across the CM gave rise to frequent suppressor variants which were able to respond at lower levels of CN-Cbl but were still defective in transport across the CM. These results finally establish the identity of the periplasmic binding protein for Cbl uptake, which is one of few cases where the components of a periplasmic permease are genetically separated.

Inhibition of tobacco etch virus protease activity by detergents

Affinity tags such as polyhistidine greatly facilitate recombinant protein production. The solubility of integral membrane proteins is maintained by the formation of protein-detergent complexes (PDCs), with detergent present at concentration above its critical micelle concentration (CMC). Removal of the affinity tag necessitates inclusion of an engineered protease cleavage site. A commonly utilized protease for tag removal is tobacco etch virus (TEV) protease. TEV is available in a recombinant form (rTEV) and frequently contains its own polyhistidine affinity tag for removal after use in enzymatic digestion. Proteolytic cleavage of the tagged domain is carried out by incubation of the protein with rTEV protease. We have observed that the efficiency of rTEV digestion decreases significantly in the presence of a variety of detergents utilized in purification, crystallization, and other biochemical studies of integral membrane proteins. This reduction in protease activity is suggestive of detergent-induced inhibition of rTEV. To test this hypothesis, we examined the effects of detergents upon the rTEV proteolytic digestion of a soluble fusion protein, alpha(1) platelet activating factor acetylhydrolase (PAFAHalpha(1)). Removal of a hexahistidine amino-terminal affinity tag has been characterized in the presence of 16 different detergents at concentrations above their respective CMCs. Our data indicate that half of the detergents tested reduce the activity of rTEV and that these detergents should be avoided or otherwise accounted for during rTEV digestion of recombinant integral membrane proteins.

The CHIP28 water channel visualized in ice by electron crystallography

Electron crystallography of frozen-hydrated two-dimensional crystals of deglycosylated human erythrocyte CHIP28 reveals an aqueous vestibule in each monomer leading to the water-selective channel that is enclosed by multiple transmembrane α-helices.

Comparative structural analysis of TonB-dependent outer membrane transporters: Implications for the transport cycle

TonB‐dependent outer membrane transporters (TBDTs) transport organometallic substrates across the outer membranes of Gram‐negative bacteria. Currently, structures of four different TBDTs have been determined by X‐ray crystallography. TBDT structures consist of a 22‐stranded β‐barrel enclosing a hatch domain. Structure‐based sequence alignment of these four TBDTs indicates the presence of highly conserved motifs in both the hatch and barrel domains. The conserved motifs of the two domains are always in close proximity to each other and interact. We analyzed the very large interfaces between the barrel and hatch domains of TBDTs and compared their properties to those of other protein–protein interfaces. These interfaces are extensively hydrated. Most of the interfacial waters form hydrogen bonds to either the barrel or the hatch domain, with the remainder functioning as bridging waters in the interface. The hatch/barrel interfacial properties most resemble those of obligate transient protein complexes, suggesting that the interface is conducive to conformational change and/or movement of the hatch within the barrel. These results indicate that TBDTs can readily accommodate substantial conformational change and movement of their hatch domains during the active transport cycle. Also, these structural changes may require only modest forces exerted by the energy‐coupling TonB protein upon the transporter. Proteins 2005.

Structure of the Integral Membrane Protein CAAX Protease Ste24p

Lamin Loppers The nuclear lamina provides mechanical stability to the nuclear envelope and is involved in regulation of cellular processes such as DNA replication. Defects in the nuclear lamina lead to diseases such as progeria and metabolic disorders. One of the components of the nuclear lamina, lamin A, undergoes a complex maturation process. A key player is an inner nuclear membrane zinc metalloprotease (ZMP) that is responsible for two proteolysis steps (see the Perspective by Michaelis and Hrycyna). Quigley et al. (p. 1604) report the crystal structure of human ZMPSTE24 and Pryor et al. (p. 1600) that of the yeast homolog Ste24p. The structures provide insight into the mechanism of catalysis and into why mutations in ZMPSTE24 lead to laminopathies. Structures of two transmembrane zinc proteases reveal a barrel of seven helices surrounding a large cavity. [Also see Perspective by Michaelis and Hrycyna] Posttranslational lipidation provides critical modulation of the functions of some proteins. Isoprenoids (i.e., farnesyl or geranylgeranyl groups) are attached to cysteine residues in proteins containing C-terminal CAAX sequence motifs (where A is an aliphatic residue and X is any residue). Isoprenylation is followed by cleavage of the AAX amino acid residues and, in some cases, by additional proteolytic cuts. We determined the crystal structure of the CAAX protease Ste24p, a zinc metalloprotease catalyzing two proteolytic steps in the maturation of yeast mating pheromone a-factor. The Ste24p core structure is a ring of seven transmembrane helices enclosing a voluminous cavity containing the active site and substrate-binding groove. The cavity is accessible to the external milieu by means of gaps between splayed transmembrane helices. We hypothesize that cleavage proceeds by means of a processive mechanism of substrate insertion, translocation, and ejection.

Coordinating the impact of structural genomics on the human α-helical transmembrane proteome

Given the recent successes in determining membrane-protein structures, we explore the tractability of determining representatives for the entire human membrane proteome. This proteome contains 2,925 unique integral α-helical transmembrane-domain sequences that cluster into 1,201 families sharing more than 25% sequence identity. Structures of 100 optimally selected targets would increase the fraction of modelable human α-helical transmembrane domains from 26% to 58%, providing structure and function information not otherwise available.

The variable detergent sensitivity of proteases that are utilized for recombinant protein affinity tag removal

Recombinant proteins typically include one or more affinity tags to facilitate purification and/or detection. Expression constructs with affinity tags often include an engineered protease site for tag removal. Like other enzymes, the activities of proteases can be affected by buffer conditions. The buffers used for integral membrane proteins contain detergents, which are required to maintain protein solubility. We examined the detergent sensitivity of six commonly-used proteases (enterokinase, factor Xa, human rhinovirus 3C protease, SUMOstar, tobacco etch virus protease, and thrombin) by use of a panel of 94 individual detergents. Thrombin activity was insensitive to the entire panel of detergents, thus suggesting it as the optimal choice for use with membrane proteins. Enterokinase and factor Xa were only affected by a small number of detergents, making them good choices as well.