Crohn's Disease Variants of Nod2 Are Stabilized by the Critical Contact Region of Hsp70.

Nod2 is a cytosolic, innate immune receptor responsible for binding to bacterial cell wall fragments such as muramyl dipeptide (MDP). Upon binding, subsequent downstream activation of the NF-κB pathway leads to an immune response. Nod2 mutations are correlated with an increased susceptibility to Crohn's disease (CD) and ultimately result in a misregulated immune response. Previous work had demonstrated that Nod2 interacts with and is stabilized by the molecular chaperone Hsp70. In this work, it is shown using purified protein and in vitro biochemical assays that the critical Nod2 CD mutations (G908R, R702W, and 1007fs) preserve the ability to bind bacterial ligands. A limited proteolysis assay and luciferase reporter assay reveal regions of Hsp70 that are capable of stabilizing Nod2 and rescuing CD mutant activity. A minimal 71-amino acid subset of Hsp70 that stabilizes the CD-associated variants of Nod2 and restores a proper immune response upon activation with MDP was identified. This work suggests that CD-associated Nod2 variants could be stabilized in vivo with a molecular chaperone.

Membrane Association Dictates Ligand Specificity for the Innate Immune Receptor NOD2.

The human gut must regulate its immune response to resident and pathogenic bacteria, numbering in the trillions. The peptidoglycan component of the bacterial cell wall is a dense and rigid structure that consists of polymeric carbohydrates and highly cross-linked peptides which offers protection from the host and surrounding environment. Nucleotide-binding oligomerization domain-containing protein 2 (NOD2), a human membrane-associated innate immune receptor found in the gut epithelium and mutated in an estimated 30% of Crohn's disease patients, binds to peptidoglycan fragments and initiates an immune response. Using a combination of chemical synthesis, advanced analytical assays, and protein biochemistry, we tested the binding of a variety of synthetic peptidoglycan fragments to wild-type (WT)-NOD2. Only when the protein was presented in the native membrane did binding measurements correlate with a NOD2-dependent nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) response, supporting the hypothesis that the native-membrane environment confers ligand specificity to the NOD2 receptor for NF-κB signaling. While N-acetyl-muramyl dipeptide (MDP) has been thought to be the minimal peptidoglycan fragment necessary to activate a NOD2-dependent immune response, we found that fragments with and without the dipeptide moiety are capable of binding and activating a NOD2-dependent NF-κB response, suggesting that the carbohydrate moiety of the peptidoglycan fragments is the minimal functional epitope. This work highlights the necessity of studying NOD2-ligand binding in systems that resemble the receptor's natural environment, as the cellular membrane and/or NOD2 interacting partners appear to play a crucial role in ligand binding and in triggering an innate immune response.

Peptidoglycan Modifications Tune the Stability and Function of the Innate Immune Receptor Nod2.

Natural modifications of peptidoglycan modulate the innate immune response. Peptidoglycan derivatives activate this response via the intracellular innate immune receptor, Nod2. To probe how these modifications alter the response, a novel and efficient carbohydrate synthesis was developed to allow for late-stage modification of the amine at the 2-position. Modification of the carbohydrate was found to be important for stabilizing Nod2 and generating the proper response. The native Nod2 ligands demonstrate a significant increase in the cellular stability of Nod2. Moreover, changing the identity of the natural ligands at the carbohydrate 2-position allows for the Nod2-dependent immune response to be either up-regulated or down-regulated. The ligand structure can be adjusted to tune the Nod2 response, suggesting that other innate immune receptors and their ligands could use a similar strategy.

Recovery of Chinese hamster ovary host cell proteins for proteomic analysis.

Identification and characterization of Chinese hamster ovary (CHO) host cell protein (HCP) impurities by proteomic techniques can aid bioprocess design and lead to more efficient development and improved biopharmaceutical manufacturing operations. Recovery of extracellular CHO HCP for proteomic analysis is particularly challenging due to the relatively low protein concentration and complex composition of media. In this article, we report the development of optimized protocols that improve proteome capture for CHO HCP. Eleven precipitation protocols were screened for protein recovery and optimized for a subset of precipitants by a design of experiments (DOE) approach. Because total protein recovery does not fully replicate a proteomics experiment, or detect non-protein agents that may interfere with proteomic methods, a subset of precipitation conditions were compared by two-dimensional electrophoresis and liquid chromatography coupled with mass spectrometry, with optimized recovery shown to differ between the two proteomic methods. This work demonstrates broadly applicable methods that can be applied as initial steps to optimize sample preparation of any sample type for proteomic analysis, and presents optimized precipitation protocols for extracellular CHO HCP recovery, which can vary appreciably between gel-based and shotgun proteomic methods.