Autochthonous transmission of the Indomalayan parasite, Transversotrema patialense, in the Caribbean: Molecular, morphological, and experimental evidence.

The Asian freshwater snail Melanoides tuberculata has been established since the 1960s in the Americas, where it transmits cercariae of a small number of digenetic trematode species from its native range. In 2021-2022, 24 M. tuberculata were discovered shedding transversotrematid cercariae in Puerto Rico, where parasites of this snail have not been previously studied. Adult transversotrematids (in some cases, gravid) were found on field-caught fish and on fish exposed to shedding snails, including on fish species native to Puerto Rico. Adults and cercariae were identified as Transversotrema patialense (Soparkar, 1924), a species native to the Indomalayan region. Morphological identification was supported with 28S rDNA sequences closely matching that from unidentified transversotrematid cercariae in Thailand. The absence of T. patialense in snails collected prior to 2021, increasing prevalence of infection in snails collected thereafter, and lack of variation in parasite DNA sequences (28S, internal transcribed spacer 2, cytochrome c oxidase I) from three isolates are consistent with a recently introduced and possibly expanding parasite population. Transversotrema patialense has been recorded outside its native range before, but most studies (including a prior record in the Americas) reported the parasite from captive hosts from commercial sources such as pet shops. The present results thus provide the first demonstration of natural transmission of T. patialense in the Americas. Phylogenetic analysis of 28S but not of ITS2 show the transversotrematid genus Transversotrema Witenberg, 1944 is paraphyletic, with Crusziella Cribb, Bray and Barker 1992 nested within it.

shRNA-Based Screen Identifies Endocytic Recycling Pathway Components That Act as Genetic Modifiers of Alpha-Synuclein Aggregation, Secretion and Toxicity.

Alpha-Synuclein (aSyn) misfolding and aggregation is common in several neurodegenerative diseases, including Parkinson's disease and dementia with Lewy bodies, which are known as synucleinopathies. Accumulating evidence suggests that secretion and cell-to-cell trafficking of pathological forms of aSyn may explain the typical patterns of disease progression. However, the molecular mechanisms controlling aSyn aggregation and spreading of pathology are still elusive. In order to obtain unbiased information about the molecular regulators of aSyn oligomerization, we performed a microscopy-based large-scale RNAi screen in living cells. Interestingly, we identified nine Rab GTPase and kinase genes that modulated aSyn aggregation, toxicity and levels. From those, Rab8b, Rab11a, Rab13 and Slp5 were able to promote the clearance of aSyn inclusions and rescue aSyn induced toxicity. Furthermore, we found that endocytic recycling and secretion of aSyn was enhanced upon Rab11a and Rab13 expression in cells accumulating aSyn inclusions. Overall, our study resulted in the identification of new molecular players involved in the aggregation, toxicity, and secretion of aSyn, opening novel avenues for our understanding of the molecular basis of synucleinopathies.

(Poly)phenols protect from α-synuclein toxicity by reducing oxidative stress and promoting autophagy.

Parkinson's disease (PD) is the most common movement neurodegenerative disorder and is associated with the aggregation of α-synuclein (αSyn) and oxidative stress, hallmarks of the disease. Although the precise molecular events underlying αSyn aggregation are still unclear, oxidative stress is known to contribute to this process. Therefore, agents that either prevent oxidative stress or inhibit αSyn toxicity are expected to constitute potential drug leads for PD. Both pre-clinical and clinical studies provided evidence that (poly)phenols, pure or in extracts, might protect against neurodegenerative disorders associated with oxidative stress in the brain. In this study, we analyzed, for the first time, a (poly)phenol-enriched fraction (PEF) from leaves of Corema album, and used in vitro and cellular models to evaluate its effects on αSyn toxicity and aggregation. Interestingly, the PEF promoted the formation of non-toxic αSyn species in vitro, and inhibited its toxicity and aggregation in cells, by promoting the autophagic flux and reducing oxidative stress. Thus, C. album (poly)phenols appear as promising cytoprotective compounds, modulating central events in the pathogenesis of PD, such as αSyn aggregation and the impairment of autophagy. Ultimately, the understanding of the molecular effects of (poly)phenols will open novel opportunities for the exploitation of their beneficial effects and for drug development.

Phosphorylation modulates clearance of alpha-synuclein inclusions in a yeast model of Parkinson's disease.

Alpha-synuclein (aSyn) is the main component of proteinaceous inclusions known as Lewy bodies (LBs), the typical pathological hallmark of Parkinson's disease (PD) and other synucleinopathies. Although aSyn is phosphorylated at low levels under physiological conditions, it is estimated that ∼ 90% of aSyn in LBs is phosphorylated at S129 (pS129). Nevertheless, the significance of pS129 in the biology of aSyn and in PD pathogenesis is still controversial. Here, we harnessed the power of budding yeast in order to assess the implications of phosphorylation on aSyn cytotoxicity, aggregation and sub-cellular distribution. We found that aSyn is phosphorylated on S129 by endogenous kinases. Interestingly, phosphorylation reduced aSyn toxicity and the percentage of cells with cytosolic inclusions, in comparison to cells expressing mutant forms of aSyn (S129A or S129G) that mimic the unphosphorylated form of aSyn. Using high-resolution 4D imaging and fluorescence recovery after photobleaching (FRAP) in live cells, we compared the dynamics of WT and S129A mutant aSyn. While WT aSyn inclusions were very homogeneous, inclusions formed by S129A aSyn were larger and showed FRAP heterogeneity. Upon blockade of aSyn expression, cells were able to clear the inclusions formed by WT aSyn. However, this process was much slower for the inclusions formed by S129A aSyn. Interestingly, whereas the accumulation of WT aSyn led to a marked induction of autophagy, cells expressing the S129A mutant failed to activate this protein quality control pathway. The finding that the phosphorylation state of aSyn on S129 can alter the ability of cells to clear aSyn inclusions provides important insight into the role that this posttranslational modification may have in the pathogenesis of PD and other synucleinopathies, opening novel avenues for investigating the molecular basis of these disorders and for the development of therapeutic strategies.

Digital full arch implant supported Poly (methyl Methacrylate) interim prosthesis: a practice-based cohort study on survival and quality of life.

PURPOSE: Digitally planned and manufactured PMMA for full arch implant supported immediate loading interim prosthesis are becoming popular comparing with conventional acrylic prosthesis. Studies on prosthodontic performance and patient related outcomes are scarce but needed. The purpose of this study was to evaluate the clinical survival and impact on oral health related quality of life of immediate loading implant supported full arch CAD-CAM milled PMMA interim rehabilitations. METHODS: This was a practice based prospective cohort study performed in a Portuguese dental clinic. Eleven patients received a total of seventeen CAD CAM full implant-supported, screw-retained, full arch rehabilitation with milled PMMA and were followed up for 1 year. Primary outcome was Prosthesis survival determined with a modification of the California Dental Association score and a Kaplan Meyer survival function analysis. Secondary outcome was patient's quality of life as defined by application of the OHIP 14 PT questionnaire and standardized effect size variation between two visits. Significance was set at 5%. RESULTS: Survival probability at 12 months was 76%, complete fracture of the prosthesis occurred in 17,6 % of the cases and small fractures without lab involvement in 5,9%. There was a significant improvement in oral health related quality of life between visit 1 and 4. Mean difference and effect size for total OHIP-14 PT score were -32.91 (± 3.68 SD) and 3.66 (95% CI -1.83 to -5.80) P < 0.001* Wilcoxon matched paired rank test. CONCLUSIONS: Full arch implant supported CAD-CAM milled PMMA interim prosthesis seems a viable approach with good survival rate and great impact on patient's oral health related quality of life.

(Poly)phenol-digested metabolites modulate alpha-synuclein toxicity by regulating proteostasis.

Parkinson's disease (PD) is an age-related neurodegenerative disease associated with the misfolding and aggregation of alpha-synuclein (aSyn). The molecular underpinnings of PD are still obscure, but nutrition may play an important role in the prevention, onset, and disease progression. Dietary (poly)phenols revert and prevent age-related cognitive decline and neurodegeneration in model systems. However, only limited attempts were made to evaluate the impact of digestion on the bioactivities of (poly)phenols and determine their mechanisms of action. This constitutes a challenge for the development of (poly)phenol-based nutritional therapies. Here, we subjected (poly)phenols from Arbutus unedo to in vitro digestion and tested the products in cell models of PD based on the cytotoxicity of aSyn. The (poly)phenol-digested metabolites from A. unedo leaves (LPDMs) effectively counteracted aSyn and H2O2 toxicity in yeast and human cells, improving viability by reducing aSyn aggregation and inducing its clearance. In addition, LPDMs modulated pathways associated with aSyn toxicity, such as oxidative stress, endoplasmic reticulum (ER) stress, mitochondrial impairment, and SIR2 expression. Overall, LPDMs reduced aSyn toxicity, enhanced the efficiency of ER-associated protein degradation by the proteasome and autophagy, and reduced oxidative stress. In total, our study opens novel avenues for the exploitation of (poly)phenols in nutrition and health.

Polyphenols Beyond Barriers: A Glimpse into the Brain.

BACKGROUND: Ageing can be simply defined as the process of becoming older, which is genetically determined but also environmentally modulated. With the continuous increase of life expectancy, quality of life during ageing has become one of the biggest challenges of developed countries. The quest for a healthy ageing has led to the extensive study of plant polyphenols with the aim to prevent age-associated deterioration and diseases, including neurodegenerative diseases. The world of polyphenols has fascinated researchers over the past decades, and in vitro, cell-based, animal and human studies have attempted to unravel the mechanisms behind dietary polyphenols neuroprotection. METHODS: In this review, we compiled some of the extensive and ever-growing research in the field, highlighting some of the most recent trends in the area. RESULTS: The main findings regarding polypolyphenols neuroprotective potential performed using in vitro, cellular and animal studies, as well as human trials are covered in this review. Concepts like bioavailability, polyphenols biotransformation, transport of dietary polyphenols across barriers, including the blood-brain barrier, are here explored. CONCLUSION: The diversity and holistic properties of polypolyphenol present them as an attractive alternative for the treatment of multifactorial diseases, where a multitude of cellular pathways are disrupted. The underlying mechanisms of polypolyphenols for nutrition or therapeutic applications must be further consolidated, however there is strong evidence of their beneficial impact on brain function during ageing. Nevertheless, only the tip of the iceberg of nutritional and pharmacological potential of dietary polyphenols is hitherto understood and further research needs to be done to fill the gaps in pursuing a healthy ageing.

Analysis of Protein Oligomeric Species by Sucrose Gradients.

Protein misfolding, aggregation, and accumulation are a common hallmark in various neurodegenerative diseases. Invariably, the process of protein aggregation is associated with both a loss of the normal biological function of the protein and a gain of toxic function that ultimately leads to cell death. The precise origin of protein cytotoxicity is presently unclear but the predominant theory posits that smaller oligomeric species are more toxic than larger aggregated forms. While there is still no consensus on this subject, this is a central question that needs to be addressed in order to enable the design of novel and more effective therapeutic strategies. Accordingly, the development and utilization of approaches that allow the biochemical characterization of the formed oligomeric species in a given cellular or animal model will enable the correlation with cytotoxicity and other parameters of interest.Here, we provide a detailed description of a low-cost protocol for the analysis of protein oligomeric species from both yeast and mammalian cell lines models, based on their separation according to sedimentation velocity using high-speed centrifugation in sucrose gradients. This approach is an adaptation of existing protocols that enabled us to overcome existing technical issues and obtain reliable results that are instrumental for the characterization of the types of protein aggregates formed by different proteins of interest in the context of neurodegenerative disorders.

From the baker to the bedside: yeast models of Parkinson's disease.

The baker's yeast Saccharomyces cerevisiae has been extensively explored for our understanding of fundamental cell biology processes highly conserved in the eukaryotic kingdom. In this context, they have proven invaluable in the study of complex mechanisms such as those involved in a variety of human disorders. Here, we first provide a brief historical perspective on the emergence of yeast as an experimental model and on how the field evolved to exploit the potential of the model for tackling the intricacies of various human diseases. In particular, we focus on existing yeast models of the molecular underpinnings of Parkinson's disease (PD), focusing primarily on the central role of protein quality control systems. Finally, we compile and discuss the major discoveries derived from these studies, highlighting their far-reaching impact on the elucidation of PD-associated mechanisms as well as in the identification of candidate therapeutic targets and compounds with therapeutic potential.