Modern pollen dispersal in relation to present vegetation distribution and land use in the Baspa valley, Kinnaur, western Himalayas.

Interpretation of a fossil pollen data for the vegetation and climate reconstruction of any region needs a modern pollen-vegetation analogue for its calibration. We analyzed the surface sediments and moss polsters for the pollen and microcharcoal records to understand the modern pollen-vegetation relationship and human activities in the Baspa Valley, Kinnaur, Himachal Pradesh. Presently, valley is occupied by the arboreal and non-arboreal vegetation of temperate to subalpine habitats and land use activities. The recovered pollen assemblages showed variability in the dispersal behavior of pollen of taxa growing along the valley transect and also captured the signals of human activities over land use. The overall dominance of arboreal pollen in the recovered pollen assemblage corresponds with the dominant growth of conifers and broadleaf tree taxa and represents the valley vegetation at a regional scale. However, the profuse pollen production of a few arboreal taxa and long distance pollen transport from one vegetation zone to other by the strong upthermic valley winds could bias the pollen representation of in-situ vegetation. The high pollen frequency of non-arboreal taxa in the open meadows represents the near vicinity to their plant source. Human activities like fire burning and cultivation by the local population are evident by the recovery of microcharcoal particles and pollen of plants belonging to Cerealia Poaceae, Asteraceae, Amaranthaceae, Polygonaceae, Rosaceae, Juglandaceae, etc. The dataset taken as modern pollen-vegetation analogue is useful to assess past changes in the vegetation and land cover in relation to climate and human factors for future sustenance.

Bacterial Cellulose-Based Blends and Composites: Versatile Biomaterials for Tissue Engineering Applications.

Cellulose of bacterial origin, known as bacterial cellulose (BC), is one of the most versatile biomaterials that has a huge potential in tissue engineering due to its favourable mechanical properties, high hydrophilicity, crystallinity, and purity. Additional properties such as porous nano-fibrillar 3D structure and a high degree of polymerisation of BC mimic the properties of the native extracellular matrix (ECM), making it an excellent material for the fabrication of composite scaffolds suitable for cell growth and tissue development. Recently, the fabrication of BC-based scaffolds, including composites and blends with nanomaterials, and other biocompatible polymers has received particular attention owing to their desirable properties for tissue engineering. These have proven to be promising advanced materials in hard and soft tissue engineering. This review presents the latest state-of-the-art modified/functionalised BC-based composites and blends as advanced materials in tissue engineering. Their applicability as an ideal biomaterial in targeted tissue repair including bone, cartilage, vascular, skin, nerve, and cardiac tissue has been discussed. Additionally, this review briefly summarises the latest updates on the production strategies and characterisation of BC and its composites and blends. Finally, the challenges in the future development and the direction of future research are also discussed.

The role of the glycerol transporter channel Fps1p in cellular proteostasis during enhanced proteotoxic stress.

In response to osmotic shock, the components of high-osmolarity glycerol (HOG) pathway regulate the level of intracellular glycerol in yeast and ensure cell survival. Glycerol is a compatible solute and a stabiliser of proteins. Its role in maintaining proteostasis is less explored. We show that mild stress in the form of dietary restriction leads to increased glycerol level which increases cell viability. However, dietary restriction coupled with protein aggregation decreases intracellular glycerol level and attenuates cell viability. The transcript level of FPS1, the glycerol transporter channel, remains unchanged. However, its activity is altered under enhanced proteotoxic stress. Our results provide evidence for a probable role of the Fps1p channel in the cellular proteostasis network. KEY POINTS: • Dietary restriction led to increased accumulation of glycerol in Fps1-deleted yeast cells. • This led to lower protein aggregation in these cells. • Increased production of glycerol under dietary restriction was not linked to increased level of Fps1.

Lysine245 plays a crucial role in stability and function of glycerol 3-phosphate dehydrogenase (Gpd1) in Saccharomyces cerevisiae.

Glycerol 3-phosphate dehydrogenase (Gpd1 isoform) catalyzes the rate limiting step of glycerol synthesis and is a critical component of the osmo-responsive machinery in yeast. The three-dimensional structure of the enzyme is similar to the enzyme from many other organisms, including humans. A recent study with the human enzyme has proposed K120 (K152 in yeast) to be in the correct orientation for catalysis; K204 (K245 in yeast) is out of plane and is not a participant in the catalytic cycle. The current work was carried out to establish the role of K245 in the catalytic cycle of yeast Gpd1. K245A mutant was found to possess lower catalytic activity. Osmotically stressed cells expressing Gpd1 (K245A) showed no change in intracellular glycerol as compared with wild-type cells which showed ~60% increase. Fluorescence microscopy, native polyacrylamide gel electrophoresis (PAGE) analysis, fluorescence spectroscopy, and Thioflavin T spectrofluorimetry showed a relatively unstable, aggregation- and degradation-prone conformation for the mutant. In silico studies showed an aggregation "hotspot" around K245. This study establishes the requirement of K245 for conformational stability and functional adaptation of Gpd1 in Saccharomyces cerevisiae.

Molecular crowding accelerates aggregation of α-synuclein by altering its folding pathway.

Intracellular macromolecular crowding can lead to increased aggregation of proteins, especially those that lack a natively folded conformation. Crowding may also be mimicked by the addition of polymers like polyethylene glycol (PEG) in vitro. α-Synuclein is an intrinsically disordered protein that exhibits increased aggregation and amyloid fibril formation in a crowded environment. Two hypotheses have been proposed to explain this observation. One is the excluded volume effect positing that reduced water activity in a crowded environment leads to increased effective protein concentration, promoting aggregation. An alternate explanation is that increased crowding facilitates conversion to a non-native form increasing the rate of aggregation. In this work, we have segregated these two hypotheses to investigate which one is operating. We show that mere increase in concentration of α-synuclein is not enough to induce aggregation and consequent fibrillation. In vitro, we find a complex relationship between PEG concentrations and aggregation, in which smaller PEGs delay fibrillation; while, larger ones promote fibril nucleation. In turn, while PEG600 did not increase the rate of aggregation, PEG1000 did and PEG4000 and PEG12000 slowed it but led to a higher overall fibril burden in the latter to cases. In cells, PEG4000 reduces the aggregation of α-synuclein but in a way specific to the cellular environment/due to cellular factors. The aggregation of the similarly sized, globular lysozyme does not increase in vitro when at the same concentrations with either PEG8000 or PEG12000. Thus, natively disordered α-synuclein undergoes a conformational transition in specific types of crowded environment, forming an aggregation-prone conformer.

Towards More Predictive, Physiological and Animal-free In Vitro Models: Advances in Cell and Tissue Culture 2020 Conference Proceedings.

Experimental systems that faithfully replicate human physiology at cellular, tissue and organ level are crucial to the development of efficacious and safe therapies with high success rates and low cost. The development of such systems is challenging and requires skills, expertise and inputs from a diverse range of experts, such as biologists, physicists, engineers, clinicians and regulatory bodies. Kirkstall Limited, a biotechnology company based in York, UK, organised the annual conference, Advances in Cell and Tissue Culture (ACTC), which brought together people having a variety of expertise and interests, to present and discuss the latest developments in the field of cell and tissue culture and in vitro modelling. The conference has also been influential in engaging animal welfare organisations in the promotion of research, collaborative projects and funding opportunities. This report describes the proceedings of the latest ACTC conference, which was held virtually on 30th September and 1st October 2020, and included sessions on in vitro models in the following areas: advanced skin and respiratory models, neurological disease, cancer research, advanced models including 3-D, fluid flow and co-cultures, diabetes and other age-related disorders, and animal-free research. The roundtable session on the second day was very interactive and drew huge interest, with intriguing discussion taking place among all participants on the theme of replacement of animal models of disease.

Controlled Delivery of Pan-PAD-Inhibitor Cl-Amidine Using Poly(3-Hydroxybutyrate) Microspheres.

This study deals with the process of optimization and synthesis of Poly(3-hydroxybutyrate) microspheres with encapsulated Cl-amidine. Cl-amidine is an inhibitor of peptidylarginine deiminases (PADs), a group of calcium-dependent enzymes, which play critical roles in a number of pathologies, including autoimmune and neurodegenerative diseases, as well as cancer. While Cl-amidine application has been assessed in a number of in vitro and in vivo models; methods of controlled release delivery remain to be investigated. P(3HB) microspheres have proven to be an effective delivery system for several compounds applied in antimicrobial, wound healing, cancer, and cardiovascular and regenerative disease models. In the current study, P(3HB) microspheres with encapsulated Cl-amidine were produced in a size ranging from ~4-5 µm and characterized for surface morphology, porosity, hydrophobicity and protein adsorption, in comparison with empty P(3HB) microspheres. Cl-amidine encapsulation in P(3HB) microspheres was optimized, and these were found to be less hydrophobic, compared with the empty microspheres, and subsequently adsorbed a lower amount of protein on their surface. The release kinetics of Cl-amidine from the microspheres were assessed in vitro and expressed as a function of encapsulation efficiency. There was a burst release of ~50% Cl-amidine in the first 24 h and a zero order release from that point up to 16 days, at which time point ~93% of the drug had been released. As Cl-amidine has been associated with anti-cancer effects, the Cl-amidine encapsulated microspheres were assessed for the inhibition of vascular endothelial growth factor (VEGF) expression in the mammalian breast cancer cell line SK-BR-3, including in the presence of the anti-proliferative drug rapamycin. The cytotoxicity of the combinatorial effect of rapamycin with Cl-amidine encapsulated P(3HB) microspheres was found to be 3.5% more effective within a 24 h period. The cells treated with Cl-amidine encapsulated microspheres alone, were found to have 36.5% reduction in VEGF expression when compared with untreated SK-BR-3 cells. This indicates that controlled release of Cl-amidine from P(3HB) microspheres may be effective in anti-cancer treatment, including in synergy with chemotherapeutic agents. Using controlled drug-delivery of Cl-amidine encapsulated in Poly(3-hydroxybutyrate) microspheres may be a promising novel strategy for application in PAD-associated pathologies.

Stabilization of elongated polyglutamine tracts by a helical peptide derived from N-terminal huntingtin.

In Huntington's disease, the length of the polyglutamine tract in the mutant protein correlates positively with the formation of aggregates and disease symptoms and severity of the disease. Some disease-modifying factors exist. However, no organized study has been carried out to investigate the effect of polyglutamine length in the mutant protein on the efficacy of a therapeutic strategy. We had shown earlier that the helical peptide arising out of the N-terminal stretch of normal huntingtin is able to inhibit aggregation of a number of proteins, including luciferase, α-synuclein, p53, and Rnq1. In this work, we show that polyglutamine stretches of differing lengths, namely 51Q, 72Q, and 103Q, form a mixture of aggregates at different rates, with the rate increasing in a polyQ length-dependent manner. The helical peptide is able to inhibit the rate of aggregation. The extent of inhibition was different when measuring either total aggregation or only fibrillar aggregates, suggesting that the helical peptide with benign polyQ stretch alters the aggregation landscape of different elongated polyQ lengths differently. Our results suggest that designing a therapeutic approach to inhibit protein aggregation must take note of polyQ length of the protein.

How Corona Formation Impacts Nanomaterials as Drug Carriers.

As drugs/drug carriers, upon encountering physiological fluids, nanoparticles adsorb biological molecules almost immediately to form a biocorona, which is often simply called a corona. Once the corona is formed, it dictates the subsequent fate of the drug nanoparticle as a therapeutic agent. Protein adsorption on micron-size or even bigger particles was originally described by the Vroman effect. It has served as a useful framework to understand the corona formation. Proteins that are irreversibly adsorbed on nanoparticles form what is called a hard corona. Beyond that is the exchangeable population of proteins, which constitute the dynamic structure called a soft corona. More than the abundance, the affinity of the proteins toward the nanoparticles decides which ones end up in the corona. For example, the more common serum albumin, which is deposited initially, is displaced by fibrinogen, which has a higher affinity for gold nanoparticles. The curvature of the particle is a crucial parameter with bigger particles generally able to bind a more diverse population of proteins from the physiological milieu. The earlier perception of the corona formation being a challenge for drug targeting, etc. has been turned into an opportunity by engineering corona to manipulate properties like circulating half-lives, capacity to evade the immune system, and targeting or even overcoming the blood-brain barrier. The most commonly used techniques for particle characterization, including dynamic light scattering (DLS), differential sedimentation centrifugation, transmission electron microscopy (TEM), and SDS-PAGE, have been adopted to study corona formation in the past. Many newer tools, for example, a combination of capillary electrophoresis with mass spectrometry, are being used to study the corona composition. The comparison of interlaboratory results is a problem because of the lack of standard protocols. This has hindered the ability to obtain more precise information about the corona composition. That, in turn, affects our prospects to use nanoparticles as drugs/drug carriers. This overview is an attempt to assess our understanding of corona formation critically and to outline the complexities involved in gaining precise information. The discussion is largely focused on findings of the last year or so.

Physicochemical and Biological Characterisation of Diclofenac Oligomeric Poly(3-hydroxyoctanoate) Hybrids as ß-TCP Ceramics Modifiers for Bone Tissue Regeneration.

Nowadays, regenerative medicine faces a major challenge in providing new, functional materials that will meet the characteristics desired to replenish and grow new tissue. Therefore, this study presents new ceramic-polymer composites in which the matrix consists of tricalcium phosphates covered with blends containing a chemically bounded diclofenac with the biocompatible polymer-poly(3-hydroxyoctanoate), P(3HO). Modification of P(3HO) oligomers was confirmed by NMR, IR and XPS. Moreover, obtained oligomers and their blends were subjected to an in-depth characterisation using GPC, TGA, DSC and AFM. Furthermore, we demonstrate that the hydrophobicity and surface free energy values of blends decreased with the amount of diclofenac modified oligomers. Subsequently, the designed composites were used as a substrate for growth of the pre-osteoblast cell line (MC3T3-E1). An in vitro biocompatibility study showed that the composite with the lowest concentration of the proposed drug is within the range assumed to be non-toxic (viability above 70%). Cell proliferation was visualised using the SEM method, whereas the observation of cell penetration into the scaffold was carried out by confocal microscopy. Thus, it can be an ideal new functional bone tissue substitute, allowing not only the regeneration and restoration of the defect but also inhibiting the development of chronic inflammation.

Discrete roles of trehalose and Hsp104 in inhibition of protein aggregation in yeast cells.

Heat shock response (HSR) is an important element of cellular homeostasis. In yeast, HSR comprises of the heat shock proteins (Hsps) and the osmolytes trehalose and glycerol. The respective roles of trehalose and Hsp104 in regulating protein aggregation remain ambiguous. We report that trehalose and Hsp104 are important during the early stages of protein aggregation, i.e. when the process is still reversible. This corroborates the earlier reported role of trehalose being an inhibitor of protein folding. Under in vitro conditions, trehalose is able to restore the GdHCl-induced loss of ATPase activity of recombinant Hsp104 to almost its original level. As the saturation phase of aggregation approaches, neither of the two components is able to exert any effect. Inactivation of Hsp104 at the stage when oligomers have already been formed increases the rate of formation of aggregates by inhibiting disaggregation of oligomers. In the absence of an active disaggregase, the oligomers are converted to mature irreversible aggregates, accelerating their formation. Our results suggest that the disaccharide may have a marginally stronger influence than Hsp104 in inhibiting protein aggregation in yeast cells.

Biosynthesis and characterization of a novel, biocompatible medium chain length polyhydroxyalkanoate by Pseudomonas mendocina CH50 using coconut oil as the carbon source.

This study validated the utilization of triacylglycerides (TAGs) by Pseudomonas mendocina CH50, a wild type strain, resulting in the production of novel mcl-PHAs with unique physical properties. A PHA yield of 58% dcw was obtained using 20 g/L of coconut oil. Chemical and structural characterisation confirmed that the mcl-PHA produced was a terpolymer comprising of three different repeating monomer units, 3-hydroxyoctanoate, 3-hydroxydecanoate and 3-hydroxydodecanoate or P(3HO-3HD-3HDD). Bearing in mind the potential of P(3HO-3HD-3HDD) in biomedical research, especially in neural tissue engineering, in vitro biocompatibility studies were carried out using NG108-15 (neuronal) cells. Cell viability data confirmed that P(3HO-3HD-3HDD) supported the attachment and proliferation of NG108-15 and was therefore confirmed to be biocompatible in nature and suitable for neural regeneration.

Aligned nanofibres made of poly(3-hydroxybutyrate) grafted to hyaluronan for potential healthcare applications.

In this work, a hybrid copolymer consisting of poly(3-hydroxybutyrate) grafted to hyaluronic acid (HA) was synthesised and characterised. Once formed, the P(3HB)-g-HA copolymer was soluble in water allowing a green electrospinning process. The diameters of nanofibres can be tailored by simply varying the Mw of polymer. The optimization of the process allowed to produce fibres of average diameter in the range of 100-150 nm and low polydispersity. The hydrophobic modification has not only increased the fibre diameter, but also the obtained layers were homogenous. At the nanoscale, the hybrid copolymer exhibited an unusual hairy topography. Moreover, the hardness and tensile properties of the hybrid were found to be superior compared to fibres made of unmodified HA. Particularly, this reinforcement was achieved at the longitudinal direction. Additionally, this work reports the use in the composition of a water-soluble copolymer containing photo cross-linkable moieties to produce insoluble materials post-electrospinning. The derivatives as well as their nanofibrous mats retain the biocompatibility of the natural polymers used for the fabrication.

Nicotine slows down oligomerisation of α-synuclein and ameliorates cytotoxicity in a yeast model of Parkinson's disease.

Several retrospective epidemiological reports have indicated an inverse correlation between smoking and development of Parkinson's disease (PD). This has mostly been attributed to the neuroprotective role of nicotine in stimulating nicotinic acetylcholine receptors and dopaminergic neurons which are damaged in PD. One of the characteristic features of PD is the intraneuronal deposition of globular inclusions of the intrinsically disordered protein α-synuclein as Lewy bodies. Using in vitro and the well-validated yeast cell models, we show that nicotine also exerts a beneficial effect on aggregation of α-synuclein. The alkaloid increases the lag time of the nucleation step and reduces the build-up of the more toxic oligomeric species in a concentration-dependent manner. This results in lower oxidative stress in the cell, reduced cytotoxicity and increased cell survival. Structural studies using CD spectroscopy and fluorescence quenching showed that α-synuclein forms a transient complex with nicotine, distorting its native structure and altering its aggregation landscape such that the formation of oligomers is inhibited. As soluble oligomers are believed to modulate the mechanism of PD pathogenesis mainly by formation of pores in neuronal membranes, resulting in leaching of vital components of the cytoplasm with deleterious effects for the cell, our results provide a mechanistic rationale for the observed beneficial role of nicotine on the progression of the disease.

Obtaining a high activity subtilisin preparation by controlled thermal stress in n-octane.

The use of enzymes in organic solvents has considerably widened their repertoire of applications. Such low water containing media also offer the possibility of carrying out enzymatic reactions at higher temperatures and enhancing reaction yields. The utility of such preparations is limited by the damage caused to the protein structure during freeze-drying. This work investigates the result of exposing the proteolytic enzyme subtilisin to high temperature in low water containing n-octane on its activity in aqueous and non-aqueous media. Exposing subtilisin at 90 °C for 5 h led to 18-fold improvement in its transesterification activity even at the normal assay temperature (37 °C) when compared with the untreated enzyme. The use of n-octane as the reaction medium was important as it helped to retain the three-dimensional architecture of the enzyme and should be considered while designing strategies for obtaining high activity preparations of other enzymes. Structural analysis using differential scanning fluorimetry showed that the enzyme lost its structure after heating in aqueous medium but retained it when heated in organic solvent. The simplicity and general applicability of the strategy should make it useful for obtaining highly active preparations of other enzymes as well.

Cellular toxicity of yeast prion protein Rnq1 can be modulated by N-terminal wild type huntingtin.

Aggregation of the N-terminal human mutant huntingtin and the consequent toxicity in the yeast model of Huntington's disease (HD) requires the presence of Rnq1 protein (Rnq1p) in its prion conformation [RNQ1(+)]. The understanding of interaction of wild-type huntingtin (wt-Htt) with the amyloidogenic prion has some gaps. In this work, we show that N-terminal fragment of wt-Htt (N-wt-Htt) ameliorated the toxic effect of [RNQ1(+)] depending on expression levels of both proteins. When the expression of N-wt-Htt was high, it increased the expression and delayed the aggregation of [RNQ1(+)]. As the expression of N-wt-Htt was reduced, it formed high molecular weight aggregates along with the prion. Even when sequestered by [RNQ1(+)], the beneficial effect of N-wt-Htt on expression of Rnq1p and on cell survival was evident. Huntingtin protein ameliorated toxicity due to the prion protein [RNQ1(+)] in yeast cells in a dose-dependent manner, resulting in increase in cell survival, hinting at its probable role as a component of the proteostasis network of the cell. Taking into account the earlier reports of the beneficial effect of expression of N-wt-Htt on the aggregation of mutant huntingtin, the function of wild-type huntingtin as an inhibitor of protein aggregation in the cell needs to be explored.

Inhibition of Aggregation of Mutant Huntingtin by Nucleic Acid Aptamers In Vitro and in a Yeast Model of Huntington's Disease.

Elongated polyglutamine stretch in mutant huntingtin (mhtt) correlates well with the pathology of Huntington's disease (HD). Inhibition of aggregation of mhtt is a promising strategy to arrest disease progression. In this work, specific, high-affinity RNA aptamers were selected against monomeric mhtt (51Q-htt). Some of them inhibited its aggregation in vitro by stabilizing the monomer. They also recognized 103Q-htt but not 20Q-htt (nonpathogenic length). Inhibition of aggregation corresponded with reduced leakage of a fluorescent probe from liposomes and diminished oxidative stress in RBCs. The presence of aptamers was able to rescue the sequestration of the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH) by aggregated mhtt. Some of the aptamers were able to enhance the partitioning of mhtt in the soluble fraction in a yeast model of HD. They were also able to rescue endocytotic defect due to aggregation of mhtt. The beneficial effect of a combination of aptamers was enhanced with improvement in cell survival. Since HD is a monogenic autosomal dominant disorder, aptamers may be developed as a viable strategy to slow down the progress of the disease. Since they are nonimmunogenic and nontoxic, aptamers may emerge as strong candidates to reduce protein-protein interaction and hence protein aggregation in protein misfolding disorders in general.

Roles of Hsp104 and trehalose in solubilisation of mutant huntingtin in heat shocked Saccharomyces cerevisiae cells.

Inhibition of huntingtin aggregation, either in the nucleus and/or in the cytosol, has been identified as a major strategy to ameliorate the symptoms of Huntington's disease. Chaperones and other protein stabilisers would thus be key players in ensuring the correct folding of the amyloidogenic protein and its expression in the soluble form. By transient activation of the global heat stress response in Saccharomyces cerevisiaeBY4742, we show that heterologous expression of mutant huntingtin (103Q-htt) could be modulated so that the protein was partitioned off in the soluble fraction of the cytosol. This led to lower levels of reactive oxygen species and improved cell viability. Previous reports had speculated on the relationship between trehalose and the heat shock response in ensuring enhanced cell survival but no direct evidence of such an interaction was available. Using mutants of an isogenic strain which do not express the major trehalose synthetic or metabolising enzymes or the chaperone, heat shock protein 104 (Hsp104), we were able to identify the functions of Hsp104 and the osmoprotectant trehalose in solubilising mutant huntingtin. We propose that the beneficial effect of the protein refolding machinery in solubilising the aggregation-prone protein is exerted by maintaining a tight balance between the trehalose synthetic enzyme, trehalose-6-phosphate synthase 1 and Hsp104. This ensures that the level of the osmoprotectant, trehalose, does not exceed the limit beyond which it is reported to inhibit protein refolding.

Hsp104 as a key modulator of prion-mediated oxidative stress in Saccharomyces cerevisiae.

Maintenance of cellular redox homoeostasis forms an important part of the cellular defence mechanism and continued cell viability. Despite extensive studies, the role of the chaperone Hsp104 (heat-shock protein of 102 kDa) in propagation of misfolded protein aggregates in the cell and generation of oxidative stress remains poorly understood. Expression of RNQ1-RFP in Saccharomyces cerevisiae cells led to the generation of the prion form of the protein and increased oxidative stress. In the present study, we show that disruption of Hsp104 in an isogenic yeast strain led to solubilization of RNQ1-RFP. This reduced the oxidative stress generated in the cell. The higher level of oxidative stress in the Hsp104-containing (parental) strain correlated with lower activity of almost all of the intracellular antioxidant enzymes assayed. Surprisingly, this did not correspond with the gene expression analysis data. To compensate for the decrease in protein translation induced by a high level of reactive oxygen species, transcriptional up-regulation takes place. This explains the discrepancy observed between the transcription level and functional enzymatic product. Our results show that in a ΔHsp104 strain, due to lower oxidative stress, no such mismatch is observed, corresponding with higher cell viability. Thus Hsp104 is indirectly responsible for enhancing the oxidative stress in a prion-rich environment.

Immunotherapy: An emerging treatment option for neurodegenerative diseases.

Accumulation of misfolded proteins and protein aggregates leading to degeneration of neurons is a hallmark of several neurodegenerative diseases. Therapy mostly relies on symptomatic relief. Immunotherapy offers a promising approach for the development of disease-modifying routes. Such strategies have shown remarkable results in oncology, and this promise is increasingly being realized for neurodegenerative diseases in advanced preclinical and clinical studies. This review highlights cases of passive and active immunotherapies in Parkinson's and Alzheimer's diseases. The reasons for success and failure, wherever available, and strategies to cross the blood-brain barrier, are discussed. The need for conditional modulation of the immune response is also reflected on.