Prion replication environment defines the fate of prion strain adaptation.

The main risk of emergence of prion diseases in humans is associated with a cross-species transmission of prions of zoonotic origin. Prion transmission between species is regulated by a species barrier. Successful cross-species transmission is often accompanied by strain adaptation and result in stable changes of strain-specific disease phenotype. Amino acid sequences of host PrPC and donor PrPSc as well as strain-specific structure of PrPSc are believed to be the main factors that control species barrier and strain adaptation. Yet, despite our knowledge of the primary structures of mammalian prions, predicting the fate of prion strain adaptation is very difficult if possible at all. The current study asked the question whether changes in cofactor environment affect the fate of prions adaptation. To address this question, hamster strain 263K was propagated under normal or RNA-depleted conditions using serial Protein Misfolding Cyclic Amplification (PMCA) conducted first in mouse and then hamster substrates. We found that 263K propagated under normal conditions in mouse and then hamster substrates induced the disease phenotype similar to the original 263K. Surprisingly, 263K that propagated first in RNA-depleted mouse substrate and then normal hamster substrate produced a new disease phenotype upon serial transmission. Moreover, 263K that propagated in RNA-depleted mouse and then RNA-depleted hamster substrates failed to induce clinical diseases for three serial passages despite a gradual increase of PrPSc in animals. To summarize, depletion of RNA in prion replication reactions changed the rate of strain adaptation and the disease phenotype upon subsequent serial passaging of PMCA-derived materials in animals. The current studies suggest that replication environment plays an important role in determining the fate of prion strain adaptation.

Changes in prion replication environment cause prion strain mutation.

Interspecies prion transmission often leads to stable changes in physical and biological features of prion strains, a phenomenon referred to as a strain mutation. It remains unknown whether changes in the replication environment in the absence of changes in PrP primary structure can be a source of strain mutations. To approach this question, RNA content was altered in the course of amplification of hamster strains in serial protein misfolding cyclic amplification (sPMCAb). On adaptation to an RNA-depleted environment and then readaptation to an environment containing RNA, strain 263K gave rise to a novel PrP(Sc) conformation referred to as 263K(R+), which is characterized by very low conformational stability, high sensitivity to proteolytic digestion, and a replication rate of 10(6)-fold/PMCAb round, which exceeded that of 263K by almost 10(4)-fold. A series of PMCAb experiments revealed that 263K(R+) was lacking in brain-derived 263K material, but emerged de novo as a result of changes in RNA content. A similar transformation was also observed for strain Hyper, suggesting that this phenomenon was not limited to 263K. The current work demonstrates that dramatic PrP(Sc) transformations can be induced by changes in the prion replication environment and without changes in PrP primary structure.

Highly efficient protein misfolding cyclic amplification.

Protein misfolding cyclic amplification (PMCA) provides faithful replication of mammalian prions in vitro and has numerous applications in prion research. However, the low efficiency of conversion of PrP(C) into PrP(Sc) in PMCA limits the applicability of PMCA for many uses including structural studies of infectious prions. It also implies that only a small sub-fraction of PrP(C) may be available for conversion. Here we show that the yield, rate, and robustness of prion conversion and the sensitivity of prion detection are significantly improved by a simple modification of the PMCA format. Conducting PMCA reactions in the presence of Teflon beads (PMCAb) increased the conversion of PrP(C) into PrP(Sc) from ∼10% to up to 100%. In PMCAb, a single 24-hour round consistently amplified PrP(Sc) by 600-700-fold. Furthermore, the sensitivity of prion detection in one round (24 hours) increased by 2-3 orders of magnitude. Using serial PMCAb, a 10¹²-fold dilution of scrapie brain material could be amplified to the level detectible by Western blotting in 3 rounds (72 hours). The improvements in amplification efficiency were observed for the commonly used hamster 263K strain and for the synthetic strain SSLOW that otherwise amplifies poorly in PMCA. The increase in the amplification efficiency did not come at the expense of prion replication specificity. The current study demonstrates that poor conversion efficiencies observed previously have not been due to the scarcity of a sub-fraction of PrP(C) susceptible to conversion nor due to limited concentrations of essential cellular cofactors required for conversion. The new PMCAb format offers immediate practical benefits and opens new avenues for developing fast ultrasensitive assays and for producing abundant quantities of PrP(Sc)in vitro.

Manipulating Galectin Expression in Zebrafish (Danio rerio).

Techniques for disrupting gene expression are invaluable tools for the analysis of the biological role of a gene product. Because of its genetic tractability and multiple advantages over conventional mammalian models, the zebrafish (Danio rerio) is recognized as a powerful system for gaining new insight into diverse aspects of human health and disease. Among the multiple mammalian gene families for which the zebrafish has shown promise as an invaluable model for functional studies, the galectins have attracted great interest due to their participation in early development, regulation of immune homeostasis, and recognition of microbial pathogens. Galectins are ß-galactosyl-binding lectins with a characteristic sequence motif in their carbohydrate recognition domains (CRDs), that constitute an evolutionary conserved family ubiquitous in eukaryotic taxa. Galectins are emerging as key players in the modulation of many important pathological processes, which include acute and chronic inflammatory diseases, autoimmunity and cancer, thus making them potential molecular targets for innovative drug discovery. Here, we provide a review of the current methods available for the manipulation of gene expression in the zebrafish, with a focus on gene knockdown [morpholino (MO)-derived antisense oligonucleotides] and knockout (CRISPR-Cas) technologies.

Relationship between conformational stability and amplification efficiency of prions.

Recent studies demonstrated that the efficiency, rate, and yield of prion amplification in vitro could be substantially improved by supplementing protein misfolding cyclic amplification (PMCA) with Teflon beads [Gonzalez-Montalban et al. (2011) PLoS Pathog. 7, e1001277]. Here we employed the new PMCA format with beads (PMCAb) to gain insight into the mechanism of prion amplification. Using a panel of six hamster prion strains, the effect of beads on amplification was found to be strain-specific, with the largest improvements in efficiency observed for strains with the highest conformational stability. This result suggests a link between PrP(Sc) conformational stability and its fragmentation rate and that beads improved amplification by assisting fragmentation. Furthermore, while exploring the PrP(Sc)-independent bead effect mechanism, a synergy between the effects of RNA and beads on amplification was observed. Consistent with previous studies, amplification of all six hamster strains tested here was found to be RNA-dependent. Under sonication conditions used for PMCA, large RNA molecules were found to degrade into smaller fragments of a size that was previously shown to be the most effective in facilitating prion conversion. We speculate that sonication-induced changes in RNA size distribution could be one of the rate-limiting steps in prion amplification.

Learning about protein solubility from bacterial inclusion bodies.

The progressive solving of the conformation of aggregated proteins and the conceptual understanding of the biology of inclusion bodies in recombinant bacteria is providing exciting insights on protein folding and quality. Interestingly, newest data also show an unexpected functional and structural complexity of soluble recombinant protein species and picture the whole bacterial cell factory scenario as more intricate than formerly believed.

The Functional quality of soluble recombinant polypeptides produced in Escherichia coli is defined by a wide conformational spectrum.

We have observed that a soluble recombinant green fluorescent protein produced in Escherichia coli occurs in a wide conformational spectrum. This results in differently fluorescent protein fractions in which morphologically diverse soluble aggregates abound. Therefore, the functional quality of soluble versions of aggregation-prone recombinant proteins is defined statistically rather than by the prevalence of a canonical native structure.

In situ protein folding and activation in bacterial inclusion bodies.

Recent observations indicate that bacterial inclusion bodies formed in absence of the main chaperone DnaK result largely enriched in functional, properly folded recombinant proteins. Unfortunately, the molecular basis of this intriguing fact, with obvious biotechnological interest, remains unsolved. We have explored here two non-excluding physiological mechanisms that could account for this observation, namely selective removal of inactive polypeptides from inclusion bodies or in situ functional activation of the embedded proteins. By combining structural and functional analysis, we have not observed any preferential selection of inactive and misfolded protein species by the dissagregating machinery during inclusion body disintegration. Instead, our data strongly support that folding intermediates aggregated as inclusion bodies could complete their natural folding process once deposited in protein clusters, which conduces to significant functional activation. In addition, in situ folding and protein activation in inclusion bodies is negatively regulated by the chaperone DnaK.

Functions of galectins as 'self/non-self'-recognition and effector factors.

Carbohydrate structures on the cell surface encode complex information that through specific recognition by carbohydrate-binding proteins (lectins) modulates interactions between cells, cells and the extracellular matrix, or mediates recognition of potential microbial pathogens. Galectins are a family of ß-galactoside-binding lectins, which are evolutionary conserved and have been identified in most organisms, from fungi to invertebrates and vertebrates, including mammals. Since their discovery in the 1970s, their biological roles, initially understood as limited to recognition of endogenous carbohydrate ligands in embryogenesis and development, have expanded in recent years by the discovery of their roles in tissue repair and regulation of immune homeostasis. More recently, evidence has accumulated to support the notion that galectins can also bind glycans on the surface of potentially pathogenic microbes, and function as recognition and effector factors in innate immunity, thus establishing a new paradigm. Furthermore, some parasites 'subvert' the recognition roles of the vector/host galectins for successful attachment or invasion. These recent findings have revealed a striking functional diversification in this structurally conserved lectin family.

Amyloid-like properties of bacterial inclusion bodies.

Bacterial inclusion bodies are major bottlenecks in protein production, narrowing the spectrum of relevant polypeptides obtained by recombinant DNA. While regarded as amorphous deposits formed by passive and rather unspecific precipitation of unfolded chains, we prove here that they are instead organized aggregates sharing important structural and biological features with amyloids. By using an Escherichia coli beta-galactosidase variant, we show that aggregation does not necessarily require unfolded polypeptide chains but rather depends on specific interactions between solvent-exposed hydrophobic stretches in partially structured species. In addition, purified inclusion bodies are efficient and highly selective nucleation seeds, promoting deposition of soluble homologous but not heterologous polypeptides in a dose-dependent manner. Finally, inclusion bodies bind amyloid-diagnostic dyes, which, jointly with Fourier transform infra red spectroscopy data, indicates a high level of organized intermolecular beta-sheet structure. The evidences of amyloid-like structure of bacterial inclusion bodies, irrespective of potential applications in bioprocess engineering, prompts the use of bacterial models to explore the molecular determinants of protein aggregation by means of simple biological systems.

The chaperone DnaK controls the fractioning of functional protein between soluble and insoluble cell fractions in inclusion body-forming cells.

BACKGROUND: The molecular mechanics of inclusion body formation is still far from being completely understood, specially regarding the occurrence of properly folded, protein species that exhibit natural biological activities. We have here comparatively explored thermally promoted, in vivo protein aggregation and the formation of bacterial inclusion bodies, from both structural and functional sides. Also, the status of the soluble and insoluble protein versions in both aggregation systems have been examined as well as the role of the main molecular chaperones GroEL and DnaK in the conformational quality of the target polypeptide. RESULTS: While thermal denaturation results in the formation of heterogeneous aggregates that are rather stable in composition, protein deposition as inclusion bodies renders homogenous but strongly evolving structures, which are progressively enriched in the main protein species while gaining native-like structure. Although both type of aggregates display common features, inclusion body formation but not thermal-induced aggregation involves deposition of functional polypeptides that confer biological activity to such particles, at expenses of the average conformational quality of the protein population remaining in the soluble cell fraction. In absence of DnaK, however, the activity and conformational nativeness of inclusion body proteins are dramatically impaired while the soluble protein version gains specific activity. CONCLUSION: The chaperone DnaK controls the fractioning of active protein between soluble and insoluble cell fractions in inclusion body-forming cells but not during thermally-driven protein aggregation. This cell protein, probably through diverse activities, is responsible for the occurrence and enrichment in inclusion bodies of native-like, functional polypeptides, that are much less represented in other kind of protein aggregates.

Reversible off and on switching of prion infectivity via removing and reinstalling prion sialylation.

The innate immune system provides the first line of defense against pathogens. To recognize pathogens, this system detects a number of molecular features that discriminate pathogens from host cells, including terminal sialylation of cell surface glycans. Mammalian cell surfaces, but generally not microbial cell surfaces, have sialylated glycans. Prions or PrP(Sc) are proteinaceous pathogens that lack coding nucleic acids but do possess sialylated glycans. We proposed that sialylation of PrP(Sc) is essential for evading innate immunity and infecting a host. In this study, the sialylation status of PrP(Sc) was reduced by replicating PrP(Sc) in serial Protein Misfolding Cyclic Amplification using sialidase-treated PrP(C) substrate and then restored to original levels by replication using non-treated substrate. Upon intracerebral administration, all animals that received PrP(Sc) with original or restored sialylation levels were infected, whereas none of the animals that received PrP(Sc) with reduced sialylation were infected. Moreover, brains and spleens of animals from the latter group were completely cleared of prions. The current work established that the ability of prions to infect the host via intracerebral administration depends on PrP(Sc) sialylation status. Remarkably, PrP(Sc) infectivity could be switched off and on in a reversible manner by first removing and then restoring PrP(Sc) sialylation.

The zebrafish galectins Drgal1-L2 and Drgal3-L1 bind in vitro to the infectious hematopoietic necrosis virus (IHNV) glycoprotein and reduce viral adhesion to fish epithelial cells.

The infectious hematopoietic necrosis virus (IHNV; Rhabdoviridae, Novirhabdovirus) infects teleost fish, such as salmon and trout, and is responsible for significant losses in the aquaculture industry and in wild fish populations. Although IHNV enters the host through the skin at the base of the fins, the viral adhesion and entry mechanisms are not fully understood. In recent years, evidence has accumulated in support of the key roles played by protein-carbohydrate interactions between host lectins secreted to the extracellular space and virion envelope glycoproteins in modulating viral adhesion and infectivity. In this study, we assessed in vitro the potential role(s) of zebrafish (Danio rerio) proto type galectin-1 (Drgal1-L2) and a chimera galectin-3 (Drgal3-L1) in IHNV adhesion to epithelial cells. Our results suggest that the extracellular Drgal1-L2 and Drgal3-L1 interact directly and in a carbohydrate-dependent manner with the IHNV glycosylated envelope and glycans on the epithelial cell surface, significantly reducing viral adhesion.

Lon and ClpP proteases participate in the physiological disintegration of bacterial inclusion bodies.

Aggregated protein is solubilized by the combined activity of chaperones ClpB, DnaK and small heat-shock proteins, and this could account, at least partially, for the physiological disintegration of bacterial inclusion bodies. In vivo, the involvement of proteases in this process had been suspected but not investigated. By using an aggregation prone beta-galactosidase fusion protein produced in Escherichia coli, we show in this study that the main ATP-dependent proteases Lon and ClpP participate in the physiological disintegration of cytoplasmic inclusion bodies, their absence minimizing the protein removal up to 40%. However, the role of these proteases is clearly distinguishable especially regarding the fate of solubilized protein. While Lon appears as a minor contributor in the disintegration process, ClpP directs an important attack on the released or releasable protein even not being irreversibly misfolded. ClpP is then observed as a wide-spectrum, main processor of aggregation-prone proteins and also of polypeptides physiologically released from inclusion bodies, even when occurring as soluble versions with a conformation compatible with their enzymatic activity.

Bacterial inclusion bodies are cytotoxic in vivo in absence of functional chaperones DnaK or GroEL.

Cytotoxicity of cytoplasmic bacterial inclusion bodies has been explored in vivo in cells producing a model, misfolding-prone beta-galactosidase fusion protein. The formation of such aggregates does not result in detectable toxicity on Escherichia coli producing cells. However, a deficiency in the main chaperones DnaK or GroEL but not in other components of the heat shock system such as the chaperone ClpA or the protease Lon, promotes a dramatic inhibition of cell growth. The role of DnaK and GroEL in minimizing toxicity of in vivo protein aggregation is discussed in the context of the conformational stress and the protein quality control system.

Aggregation as bacterial inclusion bodies does not imply inactivation of enzymes and fluorescent proteins.

BACKGROUND: Many enzymes of industrial interest are not in the market since they are bio-produced as bacterial inclusion bodies, believed to be biologically inert aggregates of insoluble protein. RESULTS: By using two structurally and functionally different model enzymes and two fluorescent proteins we show that physiological aggregation in bacteria might only result in a moderate loss of biological activity and that inclusion bodies can be used in reaction mixtures for efficient catalysis. CONCLUSION: This observation offers promising possibilities for the exploration of inclusion bodies as catalysts for industrial purposes, without any previous protein-refolding step.

Manipulating galectin expression in zebrafish (Danio rerio).

Techniques for disrupting gene expression are invaluable tools for the analysis of the biological role(s) of a gene product. Because of its genetic tractability and multiple advantages over conventional mammalian models, the zebrafish (Danio rerio) is recognized as a powerful system for gaining new insight into diverse aspects of human health and disease. Among the multiple mammalian gene families for which the zebrafish has shown promise as an invaluable model for functional studies, the galectins have attracted great interest due to their participation in early development, regulation of immune homeostasis, and recognition of microbial pathogens. Galectins are ß-galactosyl-binding lectins with a characteristic sequence motif in their carbohydrate recognition domains (CRDs), which comprise an evolutionary conserved family ubiquitous in eukaryotic taxa. Galectins are emerging as key players in the modulation of many important pathological processes, which include acute and chronic inflammatory diseases, autoimmunity and cancer, thus making them potential molecular targets for innovative drug discovery. Here, we provide a review of the current methods available for the manipulation of gene expression in the zebrafish, with a focus on gene knockdown [morpholino (MO)-derived antisense oligonucleotides] and knockout (CRISPR-Cas) technologies.

Assessment of strain-specific PrP(Sc) elongation rates revealed a transformation of PrP(Sc) properties during protein misfolding cyclic amplification.

Prion replication is believed to consist of two components, a growth or elongation of infectious isoform of the prion protein (PrP(Sc)) particles and their fragmentation, a process that provides new replication centers. The current study introduced an experimental approach that employs Protein Misfolding Cyclic Amplification with beads (PMCAb) and relies on a series of kinetic experiments for assessing elongation rates of PrP(Sc) particles. Four prion strains including two strains with short incubation times to disease (263K and Hyper) and two strains with very long incubation times (SSLOW and LOTSS) were tested. The elongation rate of brain-derived PrP(Sc) was found to be strain-specific. Strains with short incubation times had higher rates than strains with long incubation times. Surprisingly, the strain-specific elongation rates increased substantially for all four strains after they were subjected to six rounds of serial PMCAb. In parallel to an increase in elongation rates, the percentages of diglycosylated PrP glycoforms increased in PMCAb-derived PrP(Sc) comparing to those of brain-derived PrP(Sc). These results suggest that PMCAb selects the same molecular features regardless of strain initial characteristics and that convergent evolution of PrP(Sc) properties occurred during in vitro amplification. These results are consistent with the hypothesis that each prion strain is comprised of a variety of conformers or 'quasi-species' and that change in the prion replication environment gives selective advantage to those conformers that replicate most effectively under specific environment.

Inclusion bodies of fuculose-1-phosphate aldolase as stable and reusable biocatalysts.

Fuculose-1-phosphate aldolase (FucA) has been produced in Escherichia coli as active inclusion bodies (IBs) in batch cultures. The activity of insoluble FucA has been modulated by a proper selection of producing strain, culture media, and process conditions. In some cases, when an optimized defined medium was used, FucA IBs were more active (in terms of specific activity) than the soluble protein version obtained in the same process with a conventional defined medium, supporting the concept that solubility and conformational quality are independent protein parameters. FucA IBs have been tested as biocatalysts, either directly or immobilized into Lentikat beads, in an aldolic reaction between DHAP and (S)-Cbz-alaninal, obtaining product yields ranging from 65 to 76%. The production of an active aldolase as IBs, the possibility of tailoring IBs properties by both genetic and process approaches, and the reusability of IBs by further entrapment in appropriate matrices fully support the principle of using self-assembled enzymatic clusters as tunable mechanically stable and functional biocatalysts.