Protein reservoirs of seeds are amyloid composites employed differentially for germination and seedling emergence.

Seed protein localization in seed storage protein bodies (SSPB) and their significance in germination are well recognized. SSPB are spherical and contain an assembly of water-soluble and salt-soluble proteins. Although the native structures of some SSPB proteins are explored, their structural arrangement to the functional correlation in SSPB remains unknown. SSPB are morphologically analogous to electron-dense amyloid-containing structures reported in other organisms. Here, we show that wheat, mungbean, barley, and chickpea SSPB exhibit a speckled pattern of amyloids interspersed in an amyloid-like matrix along with native structures, suggesting the composite nature of SSPB. This is confirmed by multispectral imaging methods, electron microscopy, infrared, and X-ray diffraction analysis, using in situ tissue sections, ex vivo protoplasts, and in vitro SSPB. Laser capture microdissection coupled with peptide fingerprinting has shown that globulin 1 and 3 in wheat, and 8S globulin and conglycinin in mungbean are the major amyloidogenic proteins. The amyloid composites undergo a sustained degradation during germination and seedling growth, facilitated by an intricate interplay of plant hormones and proteases. These results would lay down the foundation for understanding the amyloid composite structure during SSPB biogenesis and its evolution across the plant kingdom and have implications in both basic and applied plant biology.

Evaluation of Pharmacokinetic and Pharmacodynamic (PK/PD) of Novel Fluorenylmethoxycarbonyl- Phenylalanine Antimicrobial Agent.

OBJECTIVE: To assess the pharmacokinetic profile, in-vivo toxicity, and efficacy of 9-Fluorenylmethoxycarbonyl-L-phenylalanine (Fmoc-F) as a potential antibacterial agent, with a focus on its suitability for clinical translation. METHODS: An RP-HPLC-based bio-analytical method was developed and qualified to quantify Fmoc-F levels in mouse plasma for pharmacokinetic analysis. Oral bioavailability was determined, and in-vivo toxicity was evaluated following intra-peritoneal administration. Efficacy was assessed by measuring the reduction in Staphylococcus aureus burden and survival rates in BALB/c mice. RESULTS: The RP-HPLC method is highly sensitive, detecting as low as 0.8 µg mL-1 (~ 2 µM) of Fmoc-F in blood plasma. This study revealed that Fmoc-F has an oral bioavailability of 65 ± 18% and suitable pharmacokinetic profile. Further, we showed that intra-peritoneal administration of Fmoc-F is well tolerated by BALB/c mice and Fmoc-F treatment (100 mg/kg, i.p.) significantly reduces Staphylococcus aureus burden from visceral organs in BALB/c mice but falls short in enhancing survival rates at higher bacterial loads. CONCLUSIONS: The study provides crucial insights into the pharmacokinetic and pharmacodynamic properties of Fmoc-F. The compound displayed favourable oral bioavailability and in-vivo tolerance. Its significant reduction of bacterial burden underscores its potential as a treatment for systemic infections. However, limited effectiveness for severe infections, short half-life, and inflammatory response at higher doses need to be addressed for its clinical application.

Mechanism of human γD-crystallin protein aggregation in UV-C light.

Purpose: To characterize intermediate aggregate species on the aggregation pathway of γD-crystallin protein in ultraviolet (UV)-C light. Methods: The kinetics of γD-crystallin protein aggregation was studied with reversed-phase high-performance liquid chromatography (RP-HPLC) sedimentation assay, ThT binding assay, and light scattering. We used analytical ultracentrifugation to recognize intermediate aggregate species and characterized them with Fourier transform infrared spectroscopy (FTIR). Quantification of free sulfhydryl groups in an ongoing aggregation reaction was achieved by using Ellman's assay. Results: Negligible lag phase was found in the aggregation kinetic experiments of the γD-crystallin protein. Dimer, tetramer, octamer, and higher oligomer intermediates were formed on the aggregation pathway. The protein changes its conformation to form intermediate aggregate species. FTIR and trypsin digestion indicated structural differences between the protein monomer, intermediate aggregate species, and fibrils. Ellman's assay revealed that disulfide bonds were formed in the protein monomers and aggregates during the aggregation process. Conclusions: This study showed that various intermediate and structurally different aggregate species are formed on the aggregation pathway of γD-crystallin protein in UV-C light.

Calmidazolium Chloride and Its Complex with Serum Albumin Prevent Huntingtin Exon1 Aggregation.

Huntington's disease (HD) is a genetic disorder caused by a CAG expansion mutation in Huntingtin gene leading to polyglutamine (polyQ) expansion in the N-terminus side of Huntingtin (Httex1) protein. Neurodegeneration in HD is linked to aggregates formed by Httex1 bearing an expanded polyQ. Initiation and elongation steps of Httex1 aggregation are potential target steps for the discovery of therapeutic molecules for HD, which is currently untreatable. Here we report Httex1 aggregation inhibition by calmidazolium chloride (CLC) by acting on the initial aggregation event. Because it is hydrophobic, CLC was adsorbed to the vial surface and could not sustain an inhibition effect for a longer duration. The use of bovine serum albumin (BSA) prevented CLC adsorption by forming a BSA-CLC complex. This complex showed improved Httex1 aggregation inhibition by interacting with the aggregation initiator, the NT17 part of Httex1. Furthermore, biocompatible CLC-loaded BSA nanoparticles were made which reduced the polyQ aggregates in HD-150Q cells.

Fmoc-phenylalanine displays antibacterial activity against Gram-positive bacteria in gel and solution phases.

In the quest for new antimicrobial materials, hydrogels of Fmoc-protected peptides and amino acids have gained momentum due to their ease of synthesis and cost effectiveness; however, their repertoire is currently limited, and the mechanistic details of their function are not well understood. Herein, we report the antibacterial activity of the hydrogel and solution phases of Fmoc-phenylalanine (Fmoc-F) against a variety of Gram-positive bacteria including methicillin-resistant Staphylococcus aureus (MRSA). Fmoc-F, a small molecule hydrogelator, reduces the bacterial load both in vitro and in the skin wound infections of mice. The antibacterial activity of Fmoc-F is predominantly due to its release from the hydrogel. Fmoc-F shows surfactant-like properties with critical micelle concentration nearly equivalent to its minimum bactericidal concentration. Similar to Fmoc-F, some Fmoc-conjugated amino acids (Fmoc-AA) have also shown antibacterial effects that are linearly correlated with their surfactant properties. At low concentrations, where Fmoc-F does not form micelles, it inhibits bacterial growth by entering the cell and reducing the glutathione levels. However, at higher concentrations, Fmoc-F triggers oxidative and osmotic stress and, alters the membrane permeabilization and integrity, which kills Gram-positive bacteria. Herein, we proposed the use of the Fmoc-F hydrogel and its solution for several biomedical applications. This study will open up new avenues to enhance the repertoire of Fmoc-AA to act as antimicrobial agents and improve their structure-activity relationship.

Osmolytes modulate polyglutamine aggregation in a sequence dependent manner.

Osmolytes stabilize protein structure and suppress protein aggregation. The mechanism of how osmolytes impact polyglutamine (polyQ) aggregation implicated in Huntington's disease was studied. By using a reverse-phase chromatography assay, we show that methylamines-trimethylamine N-oxide and betaine are generic in enhancing polyQ aggregation, while a disaccharide trehalose and an amino acid citrulline moderately retard polyQ aggregation in a sequence specific manner. Despite the altered kinetics, the fundamental nucleation mechanism of polyQ aggregation and the nature of end stage aggregates remains unaffected. These results highlight the importance of using osmolytes as modulatory agents of polyQ aggregation.

NMR Spectroscopy-based Metabolomics of Drosophila Model of Huntington's Disease Suggests Altered Cell Energetics.

Huntington's disease (HD) is a neurodegenerative disorder induced by aggregation of the pathological form of Huntingtin protein that has expanded polyglutamine (polyQ) repeats. In the Drosophila model, for instance, expression of transgenes with polyQ repeats induces HD-like pathologies, progressively correlating with the increasing lengths of these repeats. Previous studies on both animal models and clinical samples have revealed metabolite imbalances during HD progression. To further explore the physiological processes linked to metabolite imbalances during HD, we have investigated the 1D 1H NMR spectroscopy-based metabolomics profile of Drosophila HD model. Using multivariate analysis (PCA and PLS-DA) of metabolites obtained from methanolic extracts of fly heads displaying retinal deformations due to polyQ overexpression, we show that the metabolite imbalance during HD is likely to affect cell energetics. Six out of the 35 metabolites analyzed, namely, nicotinamide adenine dinucleotide (NAD), lactate, pyruvate, succinate, sarcosine, and acetoin, displayed segregation with progressive severity of HD. Specifically, HD progression was seen to be associated with reduction in NAD and increase in lactate-to-pyruvate ratio. Furthermore, comparative analysis of fly HD metabolome with those of mouse HD model and HD human patients revealed comparable metabolite imbalances, suggesting altered cellular energy homeostasis. These findings thus raise the possibility of therapeutic interventions for HD via modulation of cellular energetics.

Inhibition of polyglutamine aggregation by SIMILAR huntingtin N-terminal sequences: Prospective molecules for preclinical evaluation in Huntington's disease.

The mutant huntingtin protein (mHtt) fragments with expanded polyglutamine sequence forms microscopically visible aggregates in neurons, a hallmark of Huntington's disease (HD). The aggregation process and aggregates are possible targets of therapeutic intervention in HD. Owing to the lack of treatment and cure, the patients die within 15-20 years after the disease onset. Therefore, discovering therapeutic molecules that may either inhibit the aggregation mechanism or downregulate the toxic effects of mHtt are highly needed. This study demonstrates the design and use of peptide inhibitors based on the role played by the N-terminal seventeen amino acid sequence (NT17 ) of huntingtin fragment in its aggregation. Fug-NT17 (Fugu), Xen-NT17 (Xenopus), Dro-NT17 (Drosophila), Aib-NT17 , and Pro-NT17 sequences were tested for their ability to inhibit aggregation. Among them, the first three are the sequence variants of human NT17 from evolutionarily distant organisms and the latter two are the analogs of human NT17 -containing aminoisobutyric acid (Aib) and proline (Pro). Four out of five inhibited the aggregation of huntingtin fragment, NT17 Q35 P10 K2 polypeptide. Data indicate that the physicochemical properties of the inhibitors play a crucial role in exhibiting the inhibitory effect. These inhibitors can be tested in cell and animal models for the preclinical evaluation in the treating of HD.

Unaided trifluoroacetic acid pretreatment solubilizes polyglutamine peptides and retains their biophysical properties of aggregation.

Understanding the biophysical mechanism of polyglutamine (polyGln) aggregation is important to unravel the role of aggregates in the pathology of polyGln repeat disorders. To achieve this, synthetic polyGln peptides are widely used. Their disaggregation and solubilization is essential because it plays a crucial role in reproducing biophysical experimental data under in vitro conditions. Pretreatment with trifluoroacetic acid (TFA) and hexafluoroisopropanol (HFIP) at a 1:1 ratio is currently the method of choice to achieve solubility of polyGln peptides. Here we report that the disaggregation and solubilization of polyGln peptides can be achieved by TFA alone. We tested TFA due to the close similarity of it with HFIP in the nature of H-bond breakage and formation, higher cost, and the problems faced by us in the availability of HFIP. Our results demonstrate that the TFA disaggregated polyGln sequences give similar solubilization yield, aggregation kinetics, thioflavin T (ThT) binding, and structural features in comparison with the TFA/HFIP method. Furthermore, we show by limited validation studies that the proposed TFA method can replace the existing TFA/HFIP disaggregation method of polyGln sequences.

Understanding the self-assembly of Fmoc-phenylalanine to hydrogel formation.

Hydrogels of low molecular weight molecules are important in biomedical applications. Multiple factors are responsible for hydrogel formation, but their role in governing self-assembly to hydrogel formation is poorly understood. Herein, we report the hydrogel formation of fluorenylmethyloxycarbonyl phenylalanine (FmocF) molecule. We used physical and thermal stimuli for solubilizing FmocF above the critical concentration to induce gel formation. The key role of Fmoc, Fmoc and phenylalanine covalent linkage, flexibility of phe side chain, pH, and buffer ions in self-assembly of FmocF to gel formation is described. We found that the collective action of different non-covalent interactions play a role in making FmocF hydrogel. Using powder diffraction and infrared spectroscopy, we also report a new polymorphic form of FmocF after transitioning to hydrogel. In addition, we are proposing a model for drug release from FmocF hydrogel.

Amyloid nanospheres from polyglutamine rich peptides: assemblage through an intermolecular salt bridge interaction.

We have shown the conversion of an amyloid fiber forming nucleation pathway of polyglutamine (polyGln) to a non-nucleated pathway, generating nanospherical amyloid particles. This is achieved by engineering an intermolecular salt bridge interaction between the positively charged lysine and the negatively charged glutamate residues, in two polyGln rich peptides. The mechanism of their formation is characterized by chromatography, infrared, fluorescence and imaging methods.

Biodegradable delivery system containing a peptide inhibitor of polyglutamine aggregation: a step toward therapeutic development in Huntington's disease.

Huntington's and eight other neurodegenerative diseases occur because of CAG repeat expansion mutation culminating into an expanded polyglutamine tract in respective protein. In Huntington's disease (HD), a number of CAG repeats beyond normal repeat length (>36) lead to the formation of mutant protein, the proteolytic cleavage of which induces aggregation in polyglutamine length-dependent manner. The neurodegeneration in this disease is linked to aggregation, and its inhibition is a potential approach for therapeutic development. Although peptides and other molecules have been developed for inhibiting aggregation, peptides in general are susceptible to degradation in vivo conditions. To understand their clinical significance, they also need to be delivered through blood-brain barrier. Here, for the first time, we have synthesized poly-d,l-lactide-co-glycolide nanoparticles containing a polyglutamine aggregation inhibitor peptide PGQ9 [P(2) ], by nanoprecipitation method. This process yielded less than 200 nm spherical nanoparticles with uniform distribution. Characterization studies by infrared spectroscopy-based and HPLC-based assays show the presence of PGQ9 [P(2) ] in nanoparticles. In vitro release kinetics demonstrates that nanoparticles release PGQ9 [P(2) ] by erosion and diffusion processes. When the PGQ9 [P(2) ]-loaded nanoparticles are incubated with aggregation-prone Q35 P10 peptide, representing N-terminal part of Huntingtin protein, it arrests the elongation phase of Q35 P10 aggregation. These findings propose the first step toward delivery of a peptide inhibitor against polyglutamine aggregation in HD.

The worldwide need for amyloid diagnosis in animals.

Deposition of amyloid in tissues and organs leads to amyloidosis, impacting the function of vital organs and often resulting in mortality. About 42 proteins in humans and 10 in animals are known to form amyloid deposits. Amyloid research in humans has gained considerable pace in recent years but not in the case of animals. Being an essential part of the ecosystem, animals contribute significantly to the world economy. Many retrospective studies have shown amyloidosis as a possible cause of animal death. Underdiagnosis of amyloidosis in animals may also increase the chance of zoonotic transmission. Hence, assessment of the prevalence of amyloidosis necessitates significant attention. An early diagnosis will improve the overall prognosis and decrease in the fatality of animals. This article strives to bring this issue to the attention of scientists, veterinarians, and primary caretakers of animals. This will help in the diagnosis and treatment of amyloidosis in animals.

Addressing Challenges in Insulin Storage: An Ethical Dilemma among Physicians.

Background and Aims: Insulin is a temperature-sensitive protein; hence, its potency is highly dependent on appropriate storage. Ideally, insulin should be stored in the refrigerator, but when in use it can be stored at room temperature for up to four weeks. However, room temperatures vary widely across regions and countries, and all rural areas of developing countries like India are not electrified. This study explored physicians' perception of alternative methods for appropriate storage of insulin, such as indigenous storage methods like clay pots. Methods: A Study was conducted among 188 Indian physicians attending a diabetes conference in December 2018 to evaluate the feasibility of indigenous storage methods. Results: It was observed that although the use of alternate indigenous methods like clay pots was recommended by them, the proportion was low. The awareness of literature on these methods for insulin storage validation was also less than 50%. Owing to the lack of validation studies on indigenous methods, nearly 80% of the physicians felt that they were not confident to recommend them. Besides, the study results highlighted the necessity of conducting an adequate number of validation studies on indigenous methods in the Indian setting, considering their scarcity. Conclusion: This is the first time we highlight ethical dilemmas through a study among physicians when they advise non-refrigerator methods for insulin storage, in the event of a lack of electricity supply. It is hoped that results from these studies would highlight ethical dilemmas among physicians and would motivate researchers in this field to conduct studies to validate alternative methods of insulin storage.

Kinetically competing huntingtin aggregation pathways control amyloid polymorphism and properties.

In polyglutamine (polyQ) containing fragments of the Huntington's disease protein huntingtin (htt), the N-terminal 17 amino acid htt(NT) segment serves as the core of α-helical oligomers whose reversible assembly locally concentrates the polyQ segments, thereby facilitating polyQ amyloid nucleation. A variety of aggregation inhibitors have been described that achieve their effects by neutralizing this concentrating function of the htt(NT) segment. In this paper we characterize the nature and limits of this inhibition for three means of suppressing htt(NT)-mediated aggregation. We show that the previously described action of htt(NT) peptide-based inhibitors is solely due to their ability to suppress the htt(NT)-mediated aggregation pathway. That is, under htt(NT) inhibition, nucleation of polyQ amyloid formation by a previously described alternative nucleation mechanism proceeds unabated and transiently dominates the aggregation process. Removal of the bulk of the htt(NT) segment by proteolysis or mutagenesis also blocks the htt(NT)-mediated pathway, allowing the alternative nucleation pathway to dominate. In contrast, the previously described immunoglobulin-based inhibitor, the antihtt(NT) V(L) 12.3 protein, effectively blocks both amyloid pathways, leading to stable accumulation of nonamyloid oligomers. These data show that the htt(NT)-dependent and -independent pathways of amyloid nucleation in polyQ-containing htt fragments are in direct kinetic competition. The results illustrate how amyloid polymorphism depends on assembly mechanism and kinetics and have implications for how the intracellular environment can influence aggregation pathways.

Assays for studying nucleated aggregation of polyglutamine proteins.

The aggregation of polyglutamine containing protein sequences is implicated in a family of familial neurodegenerative diseases, the expanded CAG repeat diseases. While the cellular aggregation process undoubtedly depends on the flux and local environment of these proteins, their intrinsic physical properties and folding/aggregation propensities must also contribute to their cellular behavior. Here we describe a series of methods for determining mechanistic details of the spontaneous aggregation of polyQ-containing sequences, including the identification and structural examination of aggregation intermediates.

Amyloid deposition in granuloma of tuberculosis patients: A single-center pilot study.

The formation of granuloma is one of the characteristic features of tuberculosis. Besides, elevated serum amyloid A (SAA) protein level is the indicator for chronic inflammation associated with tuberculosis. The linkage between tuberculosis and SAA-driven secondary amyloidosis is well documented. However, SAA-derived amyloid onset and deposition start sites are not well understood in tuberculosis. We hypothesized that granuloma could be a potential site for amyloid deposition because of the presence of SAA protein and proteases, cleaving SAA into aggregation-prone fragments. 150 tuberculosis patients were identified and biopsies were collected from the affected organs. Patients showing eosinophilic hyaline-rich deposits within granuloma and its periphery were further screened for the presence of amyloid deposits. Upon Congo red staining, these hyaline deposits exhibited characteristic apple-green birefringence under polarized light, confirming their amyloid nature in 20 patients. Further upon Immuno-histochemical staining with anti-SAA antibody, the amyloid enriched areas showed positive immunoreactivity. In this pilot study, we have shown granuloma as a potential site for serum amyloid A derived amyloid deposition in tuberculosis patients. This study would expand the clinical and fundamental research for understanding the mechanism of amyloid formation in granuloma underlying tuberculosis and other chronic inflammatory conditions.

Likelihood of amyloid formation in COVID-19-induced ARDS.

Severe coronavirus disease 2019 (COVID-19) infection leads to multifactorial acute respiratory distress syndrome (ARDS), with little therapeutic success. The pathophysiology associated with ARDS or post-ARDS is not yet well understood. We hypothesize that amyloid formation occurring due to protein homeostasis disruption can be one of the complications associated with COVID-19-induced-ARDS.

Necessity of regulatory guidelines for the development of amyloid based biomaterials.

Amyloid diseases are caused due to protein homeostasis failure where incorrectly folded proteins/peptides form cross-ß-sheet rich amyloid fibrillar structures. Besides proteins/peptides, small metabolite assemblies also exhibit amyloid-like features. These structures are linked to several human and animal diseases. In addition, non-toxic amyloids with diverse physiological roles are characterized as a new functional class. This finding, along with the unique properties of amyloid like stability and mechanical strength, led to a surge in the development of amyloid-based biomaterials. However, the usage of these materials by humans and animals may pose a health risk such as the development of amyloid diseases and toxicity. This is possible because amyloid-based biomaterials and their fragments may assist seeding and cross-seeding mechanisms of amyloid formation in the body. This review summarizes the potential uses of amyloids as biomaterials, the concerns regarding their usage, and a prescribed workflow to initiate a regulatory approach.

Embryonic cuticle from artemia cyst shell displays amyloid-like characteristics and nontoxicity after oral consumption.

Artemia cysts are the essential food product for industrial larviculture of fishes. The cyst shell protects the artemia embryo from mechanical damage, ultraviolet light, excessive water loss, thermal variation and anoxia condition. However, the underlying mechanism of such environmental protection is largely unclear. The embryonic cuticle of cyst shell mainly constitutes chitin and proteins. Absence of cyst shell proteins compromises embryo survival. In literature, there are few examples of functional amyloids where proteins adapt amyloid-like structures and act as protective covering. We hypothesized that the proteins from the embryonic cuticle of artemia cyst shell may have amyloid-like properties. Using FTIR and CD analysis, we found that proteins in embryonic cuticle have high ß-sheet secondary structures. Embryonic cuticles displayed high Congo red binding affinity and stained samples showed apple-green birefringence under polarized light, confirming the presence of amyloid-like structures. Amyloid structures have a tendency to propagate and cause amyloidosis. However, feeding of amyloid rich embryonic cuticles to zebrafish did not show any signs of discomfort or morbidity and amyloid deposition. Taken together, the study reveals that amyloid-like structures are present in embryonic cuticle of artemia cyst and their consumption does not induce amyloidosis in zebrafish.