Mikaela Rapp

Identification and evolution of dual-topology membrane proteins

Integral membrane proteins are generally believed to have unique membrane topologies. However, it has been suggested that dual-topology proteins that adopt a mixture of two opposite orientations in the membrane may exist. Here we show that the membrane orientations of five dual-topology candidates identified in Escherichia coli are highly sensitive to changes in the distribution of positively charged residues, that genes in families containing dual-topology candidates occur in genomes either as pairs or as singletons and that gene pairs encode two oppositely oriented proteins whereas singletons encode dual-topology candidates. Our results provide strong support for the existence of dual-topology proteins and shed new light on the evolution of membrane-protein topology and structure.

Control of Membrane Protein Topology by a Single C-Terminal Residue

In, Out, Positive Charge About The mechanism by which multispanning, helix-bundle membrane proteins are inserted into their target membrane is not completely understood. EmrE is an Escherichia coli inner-membrane protein with four transmembrane helices that can take up two distinct topologies—with its amino terminus toward the cytosol, or away from the cytosol. Seppälä et al. (p. 1698, published online 27 May; see the Perspective by Tate) exploited the dual-topology property of EmrE to study the mechanism of membrane protein assembly in Escherichia coli. Systematically exploring the effects of positively charged residues on the topology of EmrE revealed that the membrane orientation of EmrE constructs with four or five transmembrane helices could be controlled by a single positively charged residue placed in different locations throughout the protein, including the very carboxyl terminus. Such global control of membrane protein topology raises important questions concerning how multispanning membrane proteins are handled by the membrane protein insertion machinery. The orientation of a multispanning inner membrane protein can be engineered by a single positively charged residue. The mechanism by which multispanning helix-bundle membrane proteins are inserted into their target membrane remains unclear. In both prokaryotic and eukaryotic cells, membrane proteins are inserted cotranslationally into the lipid bilayer. Positively charged residues flanking the transmembrane helices are important topological determinants, but it is not known whether they act strictly locally, affecting only the nearest transmembrane helices, or can act globally, affecting the topology of the entire protein. Here we found that the topology of an Escherichia coli inner membrane protein with four or five transmembrane helices could be controlled by a single positively charged residue placed in different locations throughout the protein, including the very C terminus. This observation points to an unanticipated plasticity in membrane protein insertion mechanisms.

A scalable, GFP-based pipeline for membrane protein overexpression screening and purification

We describe a generic, GFP‐based pipeline for membrane protein overexpression and purification in Escherichia coli. We exemplify the use of the pipeline by the identification and characterization of E. coli YedZ, a new, membrane‐integral flavocytochrome. The approach is scalable and suitable for high‐throughput applications. The GFP‐based pipeline will facilitate the characterization of the E. coli membrane proteome and serves as an important reference for the characterization of other membrane proteomes.

Emulating Membrane Protein Evolution by Rational Design

How do integral membrane proteins evolve in size and complexity? Using the small multidrug-resistance protein EmrE from Escherichia coli as a model, we experimentally demonstrated that the evolution of membrane proteins composed of two homologous but oppositely oriented domains can occur in a small number of steps: An original dual-topology protein evolves, through a gene-duplication event, to a heterodimer formed by two oppositely oriented monomers. This simple evolutionary pathway can explain the frequent occurrence of membrane proteins with an internal pseudo–two-fold symmetry axis in the plane of the membrane.

Experimentally based topology models for E. coli inner membrane proteins

Membrane protein topology predictions can be markedly improved by the inclusion of even very limited experimental information. We have recently introduced an approach for the production of reliable topology models based on a combination of experimental determination of the location (cytoplasmic or periplasmic) of a proteins C terminus and topology prediction. Here, we show that determination of the location of a proteins C terminus, rather than some internal loop, is the best strategy for large‐scale topology mapping studies. We further report experimentally based topology models for 31 Escherichia coli inner membrane proteins, using methodology suitable for genome‐scale studies.

Membrane protein structural biology - How far can the bugs take us? (Review)

Membrane proteins are core components of many essential cellular processes, and high-resolution structural data is therefore highly sought after. However, owing to the many bottlenecks associated with membrane protein crystallization, progress has been slow. One major problem is our inability to obtain sufficient quantities of membrane proteins for crystallization trials. Traditionally, membrane proteins have been isolated from natural sources, or for prokaryotic proteins, expressed by recombinant techniques. We are however a long way away from a streamlined overproduction of eukaryotic proteins. With this technical limitation in mind, we have probed the question as to how far prokaryotic homologues can take us towards a structural understanding of the eukaryotic/human membrane proteome(s).

Structural basis of GDP release and gating in G protein coupled Fe2+ transport.

G proteins are key molecular switches in the regulation of membrane protein function and signal transduction. The prokaryotic membrane protein FeoB is involved in G protein coupled Fe2+ transport, and is unique in that the G protein is directly tethered to the membrane domain. Here, we report the structure of the soluble domain of FeoB, including the G protein domain, and its assembly into an unexpected trimer. Comparisons between nucleotide free and liganded structures reveal the closed and open state of a central cytoplasmic pore, respectively. In addition, these data provide the first observation of a conformational switch in the nucleotide‐binding G5 motif, defining the structural basis for GDP release. From these results, structural parallels are drawn to eukaryotic G protein coupled membrane processes.

Why is the GMN motif conserved in the CorA/Mrs2/Alr1 superfamily of magnesium transport proteins?

Members of the CorA/Mrs2/Alr1 superfamily of transport proteins mediate magnesium uptake in all kingdoms of life. Family members have a low degree of sequence conservation but are characterized by a conserved extracellular loop. While the degree of sequence conservation in the loop deviates to some extent between family members, the GMN family signature motif is always present. Structural and functional data imply that the loop plays a central role in magnesium selectivity, and recent biochemical data suggest it is crucial for stabilizing the pentamer in the magnesium-free (putative open) conformation. In this study, we present a detailed structure-function analysis of the extracellular loop of CorA from Thermotoga maritima, which provides molecular insight into how the loop mediates these two functions. The data show that loop residues outside of the GMN motif can be substituted if they support the pentameric state, but the residues of the GMN motif are intolerant to substitution. We conclude that G(312) is absolutely required for magnesium uptake, M(313) is absolutely required for pentamer integrity in the putative open conformation, and N(314) plays a role in both of these functions. These observations suggest a molecular reason why the GMN motif is conserved throughout the CorA/Mrs2/Alr1 superfamily.

The Periplasmic Loop Provides Stability to the Open State of the CorA Magnesium Channel

Background: Members of the CorA/Mrs2 family mediate Mg2+ uptake in prokaryotic cells and mitochondria. Results: Mutations in the periplasmic loop disrupt the integrity of the CorA pentamer in low [Mg2+] but not high [Mg2+]. Conclusion: The CorA pentamer is stabilized differently in the presence and absence of Mg2+. Significance: The periplasmic loop stabilizes the open state of the channel. Crystal structures of the CorA Mg2+ channel have suggested that metal binding in the cytoplasmic domain stabilizes the pentamer in a closed conformation. The open “metal free” state of the channel is, however, still structurally uncharacterized. Here, we have attempted to map conformational states of CorA from Thermotoga maritima by determining which residues support the pentameric structure in the presence or absence of Mg2+. We find that when Mg2+ is present, the pentamer is stabilized by the putative gating sites (M1/M2) in the cytoplasmic domain. Strikingly however, we find that the conserved and functionally important periplasmic loop is vital for the integrity of the pentamer when Mg2+ is absent from the M1/M2 sites. Thus, although the periplasmic loops were largely disordered in the x-ray structures of the closed channel, our data suggests a prominent role for the loops in stabilizing the open conformation of the CorA channels.

Why have small multidrug resistance proteins not evolved into fused, internally duplicated structures?

The increasing number of solved membrane protein structures has led to the recognition of a common feature in a large fraction of the small-molecule transporters: inverted repeat structures, formed by two fused homologous membrane domains with opposite orientation in the membrane. An evolutionary pathway in which the ancestral state is a single gene encoding a dual-topology membrane protein capable of forming antiparallel homodimers has been posited. A gene duplication event enables the evolution of two oppositely orientated proteins that form antiparallel heterodimers. Finally, fusion of the two genes generates an internally duplicated transporter with two oppositely orientated membrane domains. Strikingly, however, in the small multidrug resistance (SMR) family of transporters, no fused, internally duplicated proteins have been found to date. Here, we have analyzed fused versions of the dual-topology transporter EmrE, a member of the SMR family, by blue-native PAGE and in vivo activity measurements. We find that fused constructs give rise to both intramolecular inverted repeat structures and competing intermolecular dimers of varying activity. The formation of several intramolecularly and intermolecularly paired species indicates that a gene fusion event may lower the overall amount of active protein, possibly explaining the apparent absence of fused SMR proteins in nature.