Charles E. Mays

The inhibition of prions through blocking prion conversion by permanently charged branched polyamines of low cytotoxicity.

Branched polyamines are effective in inhibiting prions in a cationic surface charge density dependent manner. However, toxicity associated with branched polyamines, in general, often hampers the successful application of the compounds to treat prion diseases. Here, we report that constitutively maintained cationic properties in branched polyamines reduced the intrinsic toxicity of the compounds while retaining the anti-prion activities. In prion-infected neuroblastoma cells, quaternization of amines in polyethyleneimine (PEI) and polyamidoamine (PAMAM) dendrimers markedly increased the nontoxic concentration ranges of the compounds and still supported, albeit reduced, an appreciable level of anti-prion activity in clearing prions from the infected cells. Furthermore, quaternized PEI was able to degrade prions at acidic pH conditions and inhibit the in vitro prion propagation facilitated by conversion of the normal prion protein isoform to its misfolded counterpart, although such activities were decreased by quaternization. Quaternized PAMAM was least effective in degrading prions but efficiently inhibited prion conversion with the same efficacy as unmodified PAMAM. Our results suggest that quaternization represents an effective strategy for developing nontoxic branched polyamines with potent anti-prion activity. This study highlights the importance of polyamine structural control for developing polyamine-based anti-prion agents and understanding of an action mechanism of quaternized branched polyamines.

Plasminogen stimulates propagation of protease-resistant prion protein in vitro

To clarify the role of plasminogen as a cofactor for prion propagation, we conducted functional assays using a cell-free prion protein (PrP) conversion assay termed protein misfolding cyclic amplification (PMCA) and prion-infected cell lines. Here, we report that plasminogen stimulates propagation of the protease-resistant scrapie PrP (PrP(Sc)). Compared to control PMCA conducted without plasminogen, addition of plasminogen in PMCA using wild-type brain material significantly increased PrP conversion, with an EC(50) = ∼56 nM. PrP conversion in PMCA was substantially less efficient with plasminogen-deficient brain material than with wild-type material. The activity stimulating PrP conversion was specific for plasminogen and conserved in its kringle domains. Such activity was abrogated by modification of plasminogen structure and interference of PrP-plasminogen interaction. Kinetic analysis of PrP(Sc) generation demonstrated that the presence of plasminogen in PMCA enhanced the PrP(Sc) production rate to ∼0.97 U/μl/h and reduced turnover time to ∼1 h compared to those (∼0.4 U/μl/h and ∼2.5 h) obtained without supplementation. Furthermore, as observed in PMCA, plasminogen and kringles promoted PrP(Sc) propagation in ScN2a and Elk 21(+) cells. Our results demonstrate that plasminogen functions in stimulating conversion processes and represents the first cellular protein cofactor that enhances the hypothetical mechanism of prion propagation.

Enhancement of protein misfolding cyclic amplification by using concentrated cellular prion protein source

Protein misfolding cyclic amplification (PMCA) is a cell-free assay mimicking the prion replication process. However, constraints affecting PMCA have not been well-defined. Although cellular prion protein (PrP(C)) is required for prion replication, the influence of PrP(C) abundance on PMCA has not been assessed. Here, we show that PMCA was enhanced by using mouse brain material in which PrP(C) was overexpressed. Tg(MoPrP)4112 mice overexpressing PrP(C) supported more sensitive and efficient PMCA than wild type mice. As brain homogenate of Tg(MoPrP)4112 mice was diluted with PrP(C)-deficient brain material, PMCA became less robust. Our studies suggest that abundance of PrP(C) is a determinant that directs enhancement of PMCA. PMCA established here will contribute to optimizing conditions to enhance PrP(Sc) amplification by using concentrated PrP(C) source and expands the use of this methodology.

In Vitro Amplification of Misfolded Prion Protein Using Lysate of Cultured Cells

Protein misfolding cyclic amplification (PMCA) recapitulates the prion protein (PrP) conversion process under cell-free conditions. PMCA was initially established with brain material and then with further simplified constituents such as partially purified and recombinant PrP. However, availability of brain material from some species or brain material from animals with certain mutations or polymorphisms within the PrP gene is often limited. Moreover, preparation of native PrP from mammalian cells and tissues, as well as recombinant PrP from bacterial cells, involves time-consuming purification steps. To establish a convenient and versatile PMCA procedure unrestricted to the availability of substrate sources, we attempted to conduct PMCA with the lysate of cells that express cellular PrP (PrPC). PrPSc was efficiently amplified with lysate of rabbit kidney epithelial RK13 cells stably transfected with the mouse or Syrian hamster PrP gene. Furthermore, PMCA was also successful with lysate of other established cell lines of neuronal or non-neuronal origins. Together with the data showing that the abundance of PrPC in cell lysate was a critical factor to drive efficient PrPSc amplification, our results demonstrate that cell lysate in which PrPC is present abundantly serves as an excellent substrate source for PMCA.

The suppression of prion propagation using poly-l-lysine by targeting plasminogen that stimulates prion protein conversion

Poly-l-lysine (PLL), a homopolymer of amino acid l-lysine (LL), has been frequently used for drug delivery. Here, we report that PLL is an effective agent to inhibit propagation of prions that cause fatal and incurable neurologic disorders in humans and animals, termed prion diseases. In our recent investigation on prion propagation facilitated by conversion of the cellular prion protein (PrP) to the misfolded, disease-associated PrP (PrP(Sc)), we demonstrated that plasminogen stimulates PrP conversion as a cellular cofactor. In the current study, we targeted plasminogen using PLL and assessed its anti-prion efficacy. The results showed that PLL strongly inhibited PrP(Sc) propagation in the cell-free, cell culture, and mouse models of prion disease. These results confirm the role of plasminogen in PrP(Sc) propagation, validates plasminogen as a therapeutic target to combat prion disease, and suggests PLL as a potential anti-prion agent. Therefore, our study represents a proof-of-concept that targeting plasminogen, a cofactor for PrP conversion, using PLL results in suppression of prion propagation, which represents a successful translation of our understanding on details of prion propagation into a potential therapeutic strategy for prion diseases.

CRBL cells: establishment, characterization and susceptibility to prion infection.

The cerebellum is involved in complex physiological functions including motor control, sensory perception, cognition, language, and emotion. Humans and animals with prion diseases are characterized clinically by ataxia, postural abnormalities and cognitive decline. Pathology in the cerebellum affected by prions includes spongiform degeneration, neuronal loss, and gliosis. To develop an in vitro model system for studying prion biology in cerebellar cells, we established and characterized an immortal cell line (CRBL) isolated from the cerebellum of mice lacking expression of a protein involved in cell cycle arrest. The characteristics of the cells include morphological heterogeneity, rapid proliferation, serum responsiveness during growth, and a change in the number of chromosomes. CRBL cells expressed both neuronal and glial cell markers as well as a considerable level of cellular prion protein, PrP(C). Upon in vitro infection, CRBL cells exhibited selective susceptibility to prions isolated from different sources. These cells chronically propagated prions from SMB cells. Strain-specific prion infection in CRBL cells was not due to instability of the cell line, allelic variance, or mutations in the PrP gene. Molecular properties of prions derived from SMB cells were maintained in the infected CRBL cells. Our results suggest that the specific interaction between a prion strain and hosts determined the selective susceptibility of CRBL cells, which reflects the conditions in vivo. In addition to the future studies revealing cellular and molecular mechanism involved in prion pathogenesis, CRBL cells will contribute to the studies dealing with prion strain properties and host susceptibilities.

Plasminogen: A cellular protein cofactor for PrPSc propagation.

The biochemical essence of prion replication is the molecular multiplication of the disease-associated misfolded isoform of prion protein (PrP), termed PrPSc, in a nucleic acid-free manner. PrPSc is generated by the protein misfolding process facilitated by conformational conversion of the host-encoded cellular PrP to PrPSc. Evidence suggests that an auxiliary factor may play a role in PrPSc propagation. We and others previously discovered that plasminogen interacts with PrP, while its functional role for PrPSc propagation remained undetermined. In our recent in vitro PrP conversion study, we showed that plasminogen substantially stimulates PrPSc propagation in a concentration-dependent manner by accelerating the rate of PrPSc generation, while depletion of plasminogen, destabilization of its structure, and interference with the PrP-plasminogen interaction hinder PrPSc propagation. Further investigation in cell culture models confirmed an increase of PrPSc formation by plasminogen. Although molecular basis of the observed activity for plasminogen remain to be addressed, our results demonstrate that plasminogen is the first cellular protein auxiliary factor proven to stimulate PrPSc propagation.

Utility of RNAi-mediated prnp gene silencing in neuroblastoma cells permanently infected by prions: Potentials and limitations

Prion diseases are incurable, transmissible neurodegenerative disorders in humans and animals. Because the disease-associated isoform of prion protein, PrP(Sc), is conformationally converted from cellular prion protein, PrP(C), knockdown of PrP(C) expression by RNA interference (RNAi) implicates therapy for prion diseases. In this study, introduction of small interfering (si) and small hairpin (sh) RNAs targeting the prion protein gene (prnp) transcripts triggered specific gene silencing and reduced the PrP(C) level in both prion-free and -infected neuroblastoma cell lines. Furthermore, this approach suppressed PrP(Sc) formation and ultimately eliminated PrP(Sc) from prion-infected cell lines. However, prolonged culture of cured cells resulted in reappearance of PrP(Sc) in the cell population, presumably by de novo PrP(Sc) formation from residual PrP(C) uncontrolled by RNAi and PrP(Sc) remained under the detection limit. Protein misfolding cyclic amplification assays further confirmed that lysate of cured cells was sufficient to support PrP(Sc) propagation. Our data not only suggest a potential treatment option but also implicate a caveat for using an RNAi approach for prion diseases. These findings provide critical information required to advance RNAi-based prevention and therapy for prion diseases of humans and animals.

Changes in gene expression of kringle domain-containing proteins in murine brains and neuroblastoma cells infected by prions

Prion protein (PrP) interacts with some kringle domain-containing proteins. Kringle domains serve as binding domains in the interaction with PrP. The structural conservation among kringle domains leads to the hypothesis that any protein containing these domains can interact with PrP and be involved in prion pathogenesis. Because prion pathogenesis occurs in the brain, kringle domain-containing proteins should be available in the same tissue if they are relevant to prion pathogenesis. However, gene expression of these proteins in brains infected by prions has not been examined. Here, we showed that plasminogen (plg), urokinase type plasminogen activator (upa), tissue type plasminogen activator (tpa), prothrombin (prothr), and hepatocyte growth factor (hgf) genes were expressed in murine brains and neuroblastoma cells. The changes in upa, prothr, and hgf gene expression correlated with prion disease, but those in plg and tpa gene expression did not. Our data suggest association of gene expression of kringle domain-containing proteins in brains with prion disease.