Protein complex expression by using multigene baculoviral vectors

Elucidation of the molecular basis of protein-interaction networks, in particular in higher eukaryotes, is hampered by insufficient quantities of endogenous multiprotein complexes. Present recombinant expression methods often require considerable investment in both labor and materials before multiprotein expression, and after expression and biochemical analysis these methods do not provide flexibility for expressing an altered multiprotein complex. To meet these demands, we have recently introduced MultiBac, a modular baculovirus-based system specifically designed for eukaryotic multiprotein expression. Here we describe new transfer vectors and a combination of DNA recombination-based methods, which further facilitate the generation of multigene cassettes for protein coexpression (Fig. 1), thus providing a flexible platform for generation of protein expression vectors and their rapid regeneration for revised expression studies. Genes encoding components of a multiprotein complex are inserted into a suite of compatible transfer vectors by homologous recombination. These progenitor constructs are then rapidly joined in the desired combination by Cre-loxP-mediated in vitro plasmid fusion. Protocols for integration of the resulting multigene expression cassettes into the MultiBac baculoviral genome are provided that rely on Tn7 transposition and/or Cre-loxP reaction carried out in vivo in Escherichia coli cells tailored for this purpose. Detailed guidelines for multigene virus generation and amplification, cell culture maintenance and protein production are provided, together with data illustrating the simplicity and remarkable robustness of the present method for multiprotein expression using a composite MultiBac baculoviral vector.     

Robots, pipelines, polyproteins: enabling multiprotein expression in prokaryotic and eukaryotic cells

Multiprotein complexes catalyze vital biological functions in the cell. A paramount objective of the SPINE2 project was to address the structural molecular biology of these multiprotein complexes, by enlisting and developing enabling technologies for their study. An emerging key prerequisite for studying complex biological specimens is their recombinant overproduction. Novel reagents and streamlined protocols for rapidly assembling co-expression constructs for this purpose have been designed and validated. The high-throughput pipeline implemented at IGBMC Strasbourg and the ACEMBL platform at the EMBL Grenoble utilize recombinant overexpression systems for heterologous expression of proteins and their complexes. Extension of the ACEMBL platform technology to include eukaryotic hosts such as insect and mammalian cells has been achieved. Efficient production of large multicomponent protein complexes for structural studies using the baculovirus/insect cell system can be hampered by a stoichiometric imbalance of the subunits produced. A polyprotein strategy has been developed to overcome this bottleneck and has been successfully implemented in our MultiBac baculovirus expression system for producing multiprotein complexes.     

Baculovirus expression system for heterologous multiprotein complexes

The discovery of large multiprotein complexes in cells has increased the demand for improved heterologous protein production techniques to study their molecular structure and function. Here we describe MultiBac, a simple and versatile system for generating recombinant baculovirus DNA to express protein complexes comprising many subunits. Our method uses transfer vectors containing a multiplication module that can be nested to facilitate assembly of polycistronic expression cassettes, thereby minimizing requirements for unique restriction sites. The transfer vectors access a modified baculovirus DNA through Cre-loxP site-specific recombination or Tn7 transposition. This baculovirus has improved protein expression characteristics because specific viral genes have been eliminated. Gene insertion reactions are carried out in Escherichia coli either sequentially or concurrently in a rapid, one-step procedure. Our system is useful for both recombinant multiprotein production and multigene transfer applications.     

The MultiBac Protein Complex Production Platform at the EMBL

Proteomics research revealed the impressive complexity of eukaryotic proteomes in unprecedented detail. It is now a commonly accepted notion that proteins in cells mostly exist not as isolated entities but exert their biological activity in association with many other proteins, in humans ten or more, forming assembly lines in the cell for most if not all vital functions.^1,2 Knowledge of the function and architecture of these multiprotein assemblies requires their provision in superior quality and sufficient quantity for detailed analysis. The paucity of many protein complexes in cells, in particular in eukaryotes, prohibits their extraction from native sources, and necessitates recombinant production. The baculovirus expression vector system (BEVS) has proven to be particularly useful for producing eukaryotic proteins, the activity of which often relies on post-translational processing that other commonly used expression systems often cannot support.³ BEVS use a recombinant baculovirus into which the gene of interest was inserted to infect insect cell cultures which in turn produce the protein of choice. MultiBac is a BEVS that has been particularly tailored for the production of eukaryotic protein complexes that contain many subunits.⁴ A vital prerequisite for efficient production of proteins and their complexes are robust protocols for all steps involved in an expression experiment that ideally can be implemented as standard operating procedures (SOPs) and followed also by non-specialist users with comparative ease. The MultiBac platform at the European Molecular Biology Laboratory (EMBL) uses SOPs for all steps involved in a multiprotein complex expression experiment, starting from insertion of the genes into an engineered baculoviral genome optimized for heterologous protein production properties to small-scale analysis of the protein specimens produced.^5-8 The platform is installed in an open-access mode at EMBL Grenoble and has supported many scientists from academia and industry to accelerate protein complex research projects.     

Getting a Grip on Complexes

We are witnessing tremendous advances in our understanding of the organization of life. Complete genomes are being deciphered with ever increasing speed and accuracy, thereby setting the stage for addressing the entire gene product repertoire of cells, towards understanding whole biological systems. Advances in bioinformatics and mass spectrometric techniques have revealed the multitude of interactions present in the proteome. Multiprotein complexes are emerging as a paramount cornerstone of biological activity, as many proteins appear to participate, stably or transiently, in large multisubunit assemblies. Analysis of the architecture of these assemblies and their manifold interactions is imperative for understanding their function at the molecular level. Structural genomics efforts have fostered the development of many technologies towards achieving the throughput required for studying system-wide single proteins and small interaction motifs at high resolution. The present shift in focus towards large multiprotein complexes, in particular in eukaryotes, now calls for a likewise concerted effort to develop and provide new technologies that are urgently required to produce in quality and quantity the plethora of multiprotein assemblies that form the complexome, and to routinely study their structure and function at the molecular level. Current efforts towards this objective are summarized and reviewed in this contribution.Key Words: Proteome, interactome, multiprotein assemblies, structural genomics, robotics, multigene expression, multiBac, BEVS, ACEMBL, complexomics.     

Examining multiprotein signaling complexes from all angles

Dynamic protein-protein interactions are involved in most physiological processes and, in particular, for the formation of multiprotein signaling complexes at transmembrane receptors, adapter proteins and effector molecules. Because the unregulated induction of signaling complexes has substantial clinical relevance, the investigation of these complexes is an active area of research. These studies strive to answer questions about the composition and function of multiprotein signaling complexes, along with the molecular mechanisms of their formation. In this review, the adapter protein, linker for activation of T cells (LAT), will be employed as a model to exemplify how signaling complexes are characterized using a range of techniques. The intensive investigation of LAT highlights how the systematic use of complementary techniques leads to an integrated understanding of the formation, composition and function of multiprotein signaling complexes that occur at receptors, adapter proteins and effector molecules.     

Interactive proteomics research technologies: recent applications and advances

Proteins rarely exert their function alone. They normally function in multiprotein complexes that play central roles in all biological functions. Thus, it is not surprising that the investigation of protein-protein interactions on a global scale, of so-called interactomes, has become crucial to modern molecular biology. Dissecting partners in protein complexes gives insight into their molecular function and can help in understanding disease-related mechanisms, ultimately resulting in better drug target definition. A variety of methods exist to unravel protein interaction circuitries and recently, significant progress has been made in adapting these tools for the generation of large-scale interaction datasets. Here, we present an overview of the latest advances and applications of interactive proteomics research technologies.     

DNA replication: a complex matter

In eukaryotic cells, the essential function of DNA replication is carried out by a network of enzymes and proteins, which work together to rapidly and accurately duplicate the genetic information of the cell. Many of the components of this DNA replication apparatus associate with other cellular factors as components of multiprotein complexes, which act cooperatively in networks to regulate cell cycle progression and checkpoint control, but are distinct from the pre-replication complexes that associate with the origins and regulate their firing. In this review, we summarize current knowledge about the composition and dynamics of these large multiprotein complexes in mammalian cells and their relationships to the replication factories.     

Ultrastructural diversity of the cellulase complexes of Clostridium papyrosolvens C7.

Transmission electron microscopy was used to investigate the ultrastructural features of diverse cellulase and cellulase-xylanase multiprotein complexes that are components of the cellulase-xylanase system of Clostridium papyrosolvens C7. The multiprotein complexes were separated by anion-exchange chromatography into seven biochemically distinguishable fractions (F1 to F7). Most individual F fractions contained, in relatively large numbers, an ultrastructurally recognizable type of particle that occurred only in smaller numbers, or not at all, in the other F fractions. It is suggested that these ultrastructurally distinct particles represent the biochemically distinct multiprotein complexes that constitute the cellulase-xylanase system of C. papyrosolvens C7. Some of the particles consisted of tightly packed globular components that appeared to be arranged in the shape of a ring with conical structures pointing out along its axis. Other particles had triangular, polyhedral, or star shapes. The major protein fraction (F4) almost exclusively contained particles consisting of loosely aggregated components, many of which appeared to be arranged along filamentous structures. The ultrastructural observations reported here support our previous conclusion that the cellulase-xylanase system of C. papyrosolvens C7 comprises at least seven different high-molecular-weight multiprotein complexes. Furthermore, results of this and earlier studies indicate that the interactions between C. papyrosolvens C7 and cellulose are different from those that have been described for Clostridium thermocellum.     

Integrin-linked Kinase Interactions with ELMO2 Modulate Cell Polarity

Cell polarization is a key prerequisite for directed migration during development, tissue regeneration, and metastasis. Integrin-linked kinase (ILK) is a scaffold protein essential for cell polarization, but very little is known about the precise mechanisms whereby ILK modulates polarization in normal epithelia. Elucidating these mechanisms is essential to understand tissue morphogenesis, transformation, and repair. Here we identify a novel ILK protein complex that includes Engulfment and Cell Motility 2 (ELMO2). We also demonstrate the presence of RhoG in ILK–ELMO2 complexes, and the localization of this multiprotein species specifically to the leading lamellipodia of polarized cells. Significantly, the ability of RhoG to bind ELMO is crucial for ILK induction of cell polarization, and the joint expression of ILK and ELMO2 synergistically promotes the induction of front-rear polarity and haptotactic migration. This places RhoG–ELMO2–ILK complexes in a key position for the development of cell polarity and forward movement. Although ILK is a component of many diverse multiprotein species that may contribute to cell polarization, expression of dominant-negative ELMO2 mutants is sufficient to abolish the ability of ILK to promote cell polarization. Thus, its interaction with ELMO2 and RhoG is essential for the ability of ILK to induce front-rear cell polarity.     

Towards eukaryotic structural complexomics

Many eukaryotic proteins exist in large multisubunit assemblies and often show compromised folding or activity when their interaction partners are not present. Protein complexes in eukaryotes can contain ten or more subunits with individual polypeptides ranging in size up to several hundred kilodalton, severely restricting the application of conventional cloning strategies and imposing constraints on the choice of the expression host. Modern structural molecular biology often depends on introducing diversity into the specimens under investigation, including mutation, truncation and placement of purification aids. Current recombinant expression methods often require a disproportionate labor investment prior to multiprotein expression, and subsequent to expression and analysis do not provide for rapid revision of the experiment. We have developed reagents and protocols for rapid and flexible multiprotein complex expressions suitable for structural biology, focusing on multigene baculoviral vectors and their recombination mediated assembly. A top priority in protein science is automation. Our strategy can be readily adapted in a robotics setup, for baculovirus/insect cell expression of protein complexes, but likewise also for mammalian or prokaryotic hosts.     

Binding specificity of multiprotein signaling complexes is determined by both cooperative interactions and affinity preferences

The generation of multiprotein complexes at receptors and adapter proteins is crucial for the activation of intracellular signaling pathways. In this study, we used multiple biochemical and biophysical methods to examine the binding properties of several SH2 and SH3 domain-containing signaling proteins as they interact with the adapter protein linker for activation of T-cells (LAT) to form multiprotein complexes. We observed that the binding specificity of these proteins for various LAT tyrosines appears to be constrained both by the affinity of binding and by cooperative protein-protein interactions. These studies provide quantitative information on how different binding parameters can determine in vivo binding site specificity observed for multiprotein signaling complexes.     

An efficient protein complex purification method for functional proteomics in higher eukaryotes

The ensemble of expressed proteins in a given cell is organized in multiprotein complexes. The identification of the individual components of these complexes is essential for their functional characterization. The introduction of the 'tandem affinity purification' (TAP) methodology substantially improved the purification and systematic genome-wide characterization of protein complexes in yeast. The use of this approach in higher eukaryotic cells has lagged behind its use in yeast because the tagged proteins are normally expressed in the presence of the untagged endogenous version, which may compete for incorporation into multiprotein complexes. Here we describe a strategy in which the TAP approach is combined with double-stranded RNA interference (RNAi) to avoid competition from corresponding endogenous proteins while isolating and characterizing protein complexes from higher eukaryotic cells. This strategy allows the determination of the functionality of the tagged protein and increases the specificity and the efficiency of the purification.     

Synapse signalling complexes and networks: machines underlying cognition

All thoughts and actions are encoded in patterns of neuronal electrical activity. Circuits of nerve cells connected by synapses are dedicated to processing information in these patterns. Information is not only transmitted across the synapse but also monitored by postsynaptic molecular machines. These machines are macromolecular complexes of approximately 100 proteins organised into a network of protein interactions. The network can be mathematically described as a scale-free network. Components of the complexes are necessary for decoding the neural code and converting electrical information into biochemical changes. The network properties of these complexes may explain many of the features of neuronal plasticity and cognitive function in rodents. Importantly, these multiprotein complexes and their network properties shed new light on the basis of human cognitive diseases including schizophrenia, autism, Huntington's disease and mental retardation. Supplementary material for this article can be found on the BioEssays website http://www.interscience.wiley.com/jpages/0265-9247/suppmat/index.html.