Lactococcus lactis provides an efficient platform for production of disulfide-rich recombinant proteins from Plasmodium falciparum.

BACKGROUND: The production of recombinant proteins with proper conformation, appropriate post-translational modifications in an easily scalable and cost-effective system is challenging. Lactococcus lactis has recently been identified as an efficient Gram positive cell factory for the production of recombinant protein. We and others have used this expression host for the production of selected malaria vaccine candidates. The safety of this production system has been confirmed in multiple clinical trials. Here we have explored L. lactis cell factories for the production of 31 representative Plasmodium falciparum antigens with varying sizes (ranging from 9 to 90 kDa) and varying degree of predicted structural complexities including eleven antigens with multiple predicted structural disulfide bonds, those which are considered difficult-to-produce proteins. RESULTS: Of the 31 recombinant constructs attempted in the L. lactis expression system, the initial expression efficiency was 55% with 17 out of 31 recombinant gene constructs producing high levels of secreted recombinant protein. The majority of the constructs which failed to produce a recombinant protein were found to consist of multiple intra-molecular disulfide-bonds. We found that these disulfide-rich constructs could be produced in high yields when genetically fused to an intrinsically disorder protein domain (GLURP-R0). By exploiting the distinct biophysical and structural properties of the intrinsically disordered protein region we developed a simple heat-based strategy for fast purification of the disulfide-rich protein domains in yields ranging from 1 to 40 mg/l. CONCLUSIONS: A novel procedure for the production and purification of disulfide-rich recombinant proteins in L. lactis is described.

Method for Production of Cysteine-Rich Proteins in Lactococcus lactis Expression System.

The Gram-positive bacterium Lactococcus lactis is an ideal expression host for the overproduction of heterologous proteins in a functional form. L. lactis has recently been identified as an efficient Gram-positive cell factory for the production of recombinant proteins and the safety of this production system has been confirmed in multiple clinical trials. Key desirable features of L. lactis include its generally recognized as safe (GRAS) status, long history of safe use in food production, probiotic properties, absence of endotoxins, capacity to secrete stable recombinant protein to the growth medium, the presence of few proteases, and a diverse selection of cloning and inducible expression vectors. Growth of lactococci is rapid, proceeds to high cell densities, and does not require aeration, which facilitates large-scale fermentation. We have previously described the production of several Plasmodium falciparum antigens with varying degrees of predicted structural complexities, those which are considered difficult-to-produce proteins by using L. lactis pH-dependent inducible promoter (P170). The purpose of this chapter is to provide a detailed protocol for the expression of difficult-to-produce proteins, mainly high cysteine-rich proteins, in the soluble form in L. lactis from cloning of the target gene to the determination of expression levels and purification.

Production of Metridia Luciferase in Native Form by Oxidative Refolding from E. coli Inclusion Bodies.

The small coelenterazine-dependent luciferase from Metridia longa (MLuc), in view of its high activity, simplicity of bioluminescent (BL) reaction, and stability, has found successful analytical applications as a genetically encoded reporter for in vivo assessment of cellular processes. However, the study on the biochemical and BL properties and the development of in vitro analytical applications of MLuc are hampered by the difficulties of obtaining a sufficient amount of the highly active recombinant protein due to the presence of multiple (up to five) disulfide bonds per molecule. Here, we present a protocol to obtain the recombinant disulfide-rich MLuc using a cheap and simple Escherichia coli expression system without any affinity tags in its native form by refolding from inclusion bodies. The method includes (i) purification of MLuc inclusion bodies, solubilization of the aggregated form with full reduction of disulfide bonds, and refolding to the native state using a glutathione redox system in the presence of arginine and Cu2+ ions and (ii) chromatographic purification of MLuc and its functional assessment in terms of activity. We introduce the empirical, optimal conditions for oxidative refolding and subsequent purification of MLuc, with its basic properties taken into account. We believe that this protocol is adaptable for a large-scale harvest of other natively folded copepod luciferases as well as other disulfide-rich recombinant proteins from E. coli inclusion bodies.

Mapping the chemical and sequence space of the ShKT superfamily.

The ShKT superfamily is widely distributed throughout nature and encompasses a wide range of documented functions and processes, from modulation of potassium channels to involvement in morphogenesis pathways. Cysteine-rich secretory proteins (CRISPs) contain a cysteine-rich domain (CRD) at the C-terminus that is similar in structure to the ShK fold. Despite the structural similarity of the CRD and ShK-like domains, we know little of the sequence-function relationships in these families. Here, for the first time, we examine the evolution of the biophysical properties of sequences within the ShKT superfamily in relation to function, with a focus on the ShK-like superfamily. ShKT data were sourced from published sequences in the protein family database, in addition to new ShK-like sequences from the Australian speckled anemone (Oulactis sp.). Our analysis clearly delineates the ShK-like family from the CRDs of CRISP proteins. The four CRISP subclusters separate out into the main phyla of Mammalia, Insecta and Reptilia. The ShK-like family is in turn composed of seven subclusters, the largest of which contains members from across the eukaryotes, with a continuum of intermediate properties. Smaller sub-clusters contain specialised members such as nematode ShK-like sequences. Several of these ShKT sub-clusters contain no functionally characterised sequences. This chemical space analysis should be useful as a guide to select sequences for functional studies and to gain insight into the evolution of these highly divergent sequences with an ancient conserved fold.

A Strategy for Production of Correctly Folded Disulfide-Rich Peptides in the Periplasm of E. coli.

Recombinant expression of disulfide-reticulated peptides and proteins is often challenging. We describe a method that exploits the periplasmic disulfide-bond forming machinery of Escherichia coli and combines this with a cleavable, solubility-enhancing fusion tag to obtain higher yields of correctly folded target protein than is achievable via cytoplasmic expression. The protocols provided herein cover all aspects of this approach, from vector construction and transformation to purification of the cleaved target protein and subsequent quality control.