Quantitative Characterization of the Amount and Length of (1,3)-ß-d-glucan for Functional and Mechanistic Analysis of Fungal (1,3)-ß-d-glucan Synthase.

(1,3)-ß-d-Glucan synthase (GS) is an essential enzyme for fungal cell wall biosynthesis that catalyzes the synthesis of (1,3)-ß-d-glucan, a major and vital component of the cell wall. GS is a proven target of antifungal antibiotics including FDA-approved echinocandin derivatives; however, the function and mechanism of GS remain largely uncharacterized due to the absence of informative activity assays. Previously, a radioactive assay and reducing end modification have been used to characterize GS activity. The radioactive assay determines only the total amount of glucan formed through glucose incorporation and does not report the length of the polymers produced. The glucan length has been characterized by reducing end modification, but this method is unsuitable for mechanistic studies due to the very high detection limit of millimolar amounts and the labor intensiveness of the technique. Consequently, fundamental aspects of GS catalysis, such as the polymer length specificity, remain ambiguous. We have developed a size exclusion chromatography (SEC)-based method that allows detailed functional and mechanistic characterization of GS. The approach harnesses the pH-dependent solubility of (1,3)-ß-d-glucan, where (1,3)-ß-d-glucan forms water-soluble random coils under basic pH conditions, and can be analyzed by SEC using pulsed amperometric detection (PAD) and radioactivity counting (RC). This approach allows quantitative characterization of the total amount and length of glucan produced by GS with minimal workup and a d-glucose (Glc) detection limit of ~100 pmol. Consequently, this approach was successfully used for the kinetic characterization of GS, providing the first detailed mechanistic insight into GS catalysis. Due to its sensitivity, the assay is applicable to the characterization of GS from any fungi and can be adapted to study other polysaccharide synthases.

Immunological Aspects of Age-Related Macular Degeneration.

Increasing evidence over the past two decades points to a pivotal role for immune mechanisms in age-related macular degeneration (AMD) pathobiology. In this chapter, we will explore immunological aspects of AMD, with a specific focus on how immune mechanisms modulate clinical phenotypes of disease and severity and how components of the immune system may serve as triggers for disease progression in both dry and neovascular AMD. We will briefly review the biology of the immune system, defining the role of immune mechanisms in chronic degenerative disease and differentiating from immune responses to acute injury or infection. We will explore current understanding of the roles of innate immunity (especially macrophages), antigen-specific immunity (T cells, B cells, and autoimmunity), immune amplifications systems, especially complement activity and the NLRP3 inflammasome, in the pathogenesis of both dry and neovascular AMD, reviewing data from pathology, experimental animal models, and clinical studies of AMD patients. We will also assess how interactions between the immune system and infectious pathogens could potentially modulate AMD pathobiology via alterations in in immune effector mechanisms. We will conclude by reviewing the paradigm of "response to injury," which provides a means to integrate various immunologic mechanisms along with nonimmune mechanisms of tissue injury and repair as a model to understand the pathobiology of AMD.

Automated Recognition of Retinal Pigment Epithelium Cells on Limited Training Samples Using Neural Networks.

Purpose: To develop a neural network (NN)-based approach, with limited training resources, that identifies and counts the number of retinal pigment epithelium (RPE) cells in confocal microscopy images obtained from cell culture or mice RPE/choroid flat-mounts. Methods: Training and testing dataset contained two image types: wild-type mice RPE/choroid flat-mounts and ARPE 19 cells, stained for Rhodamine-phalloidin, and imaged with confocal microscopy. After image preprocessing for denoising and contrast adjustment, scale-invariant feature transform descriptors were used for feature extraction. Training labels were derived from cells in the original training images, annotated and converted to Gaussian density maps. NNs were trained using the set of training input features, such that the obtained NN models accurately predicted corresponding Gaussian density maps and thus accurately identifies/counts the cells in any such image. Results: Training and testing datasets contained 229 images from ARPE19 and 85 images from RPE/choroid flat-mounts. Within two data sets, 30% and 10% of the images, were selected for validation. We achieved 96.48% ± 6.56% and 96.88% ± 3.68% accuracy (95% CI), on ARPE19 and RPE/choroid flat-mounts. Conclusions: We developed an NN-based approach that can accurately estimate the number of RPE cells contained in confocal images. Our method achieved high accuracy with limited training images, proved that it can be effectively used on images with unclear and curvy boundaries, and outperformed existing relevant methods by decreasing prediction error and variance. Translational Relevance: This approach allows efficient and effective characterization of RPE pathology and furthermore allows the assessment of novel therapeutics.

Length Specificity and Polymerization Mechanism of (1,3)-ß-d-Glucan Synthase in Fungal Cell Wall Biosynthesis.

(1,3)-ß-d-Glucan synthase (GS) catalyzes formation of the linear (1,3)-ß-d-glucan in the fungal cell wall and is a target of clinically approved antifungal antibiotics. The catalytic subunit of GS, FKS protein, does not exhibit significant sequence homology to other glycosyltransferases, and thus, significant ambiguity about its catalytic mechanism remains. One of the major technical barriers in studying GS is the absence of activity assay methods that allow characterization of the lengths and amounts of (1,3)-ß-d-glucan due to its poor solubility in water and organic solvents. Here, we report a successful development of a novel GS activity assay based on size-exclusion chromatography coupled with pulsed amperometric detection and radiation counting (SEC-PAD-RC), which allows for the simultaneous characterization of the amount and length of the polymer product. The assay revealed that the purified yeast GS produces glucan with a length of 6550 ± 760 mer, consistent with the reported degree of polymerization of (1,3)-ß-d-glucan isolated from intact cells. Pre-steady state kinetic analysis revealed a highly efficient but rate-determining chain elongation rate of 51.5 ± 9.8 s-1, which represents the first observation of chain elongation by a nucleotide-sugar-dependent polysaccharide synthase. Coupling the SEC-PAD-RC method with substrate analogue mechanistic probes provided the first unambiguous evidence that GS catalyzes non-reducing end polymerization. On the basis of these observations, we propose a detailed model for the catalytic mechanism of GS. The approaches described here can be used to determine the mechanism of catalysis of other polysaccharide synthases.

Engineering of New Pneumocandin Side-Chain Analogues from Glarea lozoyensis by Mutasynthesis and Evaluation of Their Antifungal Activity.

Pneumocandins are lipohexapeptides of the echinocandin family that inhibit fungal 1,3-ß-glucan synthase. Most of the pathway steps have been identified previously. However, the lipoinitiation reaction has not yet been experimentally verified. Herein, we investigate the lipoinitiation step of pneumocandin biosynthesis in Glarea lozoyensis and demonstrate that the gene product, GLligase, catalyzes this step. Disruption of GLHYD, a gene encoding a putative type II thioesterase and sitting upstream of the pneumocandin acyl side chain synthase gene, GLPKS4, revealed that GLHYD was necessary for optimal function of GLPKS4 and to attain normal levels of pneumocandin production. Double disruption of GLHYD and GLPKS4 did not affect residual function of the GLligase or GLNRPS4. Mutasynthesis experiments with a gene disruption mutant of GLPKS4 afforded us an opportunity to test the substrate specificity of GLligase in the absence of its native polyketide side chain to diversify pneumocandins with substituted side chains. Feeding alternative side chain precursors yielded acrophiarin and four new pneumocandin congeners with straight C14, C15, and C16 side chains. A comprehensive biological evaluation showed that one compound, pneumocandin I (5), has elevated antifungal activity and similar hemolytic activity compared to pneumocandin B0, the starting molecule for caspofungin. This study demonstrates that the lipoinitiation mechanism in pneumocandin biosynthesis involves interaction among a highly reducing PKS, a putative type II thioesterase, and an acyl AMP-ligase. A comparison of the SAR among pneumocandins with different-length acyl side chains demonstrated the potential for using GLligase for future engineering of new echinocandin analogues.

Identification of a cyclic nucleotide as a cryptic intermediate in molybdenum cofactor biosynthesis.

The molybdenum cofactor (Moco) is a redox cofactor found in all kingdoms of life, and its biosynthesis is essential for survival of many organisms, including humans. The first step of Moco biosynthesis is a unique transformation of guanosine 5'-triphosphate (GTP) into cyclic pyranopterin monophosphate (cPMP). In bacteria, MoaA and MoaC catalyze this transformation, although the specific functions of these enzymes were not fully understood. Here, we report the first isolation and structural characterization of a product of MoaA. This molecule was isolated under anaerobic conditions from a solution of MoaA incubated with GTP, S-adenosyl-L-methionine, and sodium dithionite in the absence of MoaC. Structural characterization by chemical derivatization, MS, and NMR spectroscopy suggested the structure of this molecule to be (8S)-3',8-cyclo-7,8-dihydroguanosine 5'-triphosphate (3',8-cH2GTP). The isolated 3',8-cH2GTP was converted to cPMP by MoaC or its human homologue, MOCS1B, with high specificities (Km < 0.060 µM and 0.79 ± 0.24 µM for MoaC and MOCS1B, respectively), suggesting the physiological relevance of 3',8-cH2GTP. These observations, in combination with some mechanistic studies of MoaA, unambiguously demonstrate that MoaA catalyzes a unique radical C-C bond formation reaction and that, in contrast to previous proposals, MoaC plays a major role in the complex rearrangement to generate the pyranopterin ring.

Atomic force microscopy captures folded ribosome bound nascent chains.

Direct visualization of co-translational folding of nascent polypeptide chains is challenging. Here we present, for the first time, AFM images of large protein constructs based on the membrane binding domain of ankyrin-R, complexed with the ribosome. The characteristic "horse-shoe" shape of ankyrin-R emerging from the ribosome was captured.

Vortex-induced formation of insulin amyloid superstructures probed by time-lapse atomic force microscopy and circular dichroism spectroscopy.

Misfolding and aggregation of proteins are multipathway processes that result in polymorphism of amyloid fibrils. While agitation is one of the most common means of inducing structural variants of fibrils (the so-called 'amyloid strains'), there is as yet no mechanistic explanation for this effect. In this study, time-lapse atomic force microscopy has been employed to probe insulin fibrillation upon intensive agitation. At 60 degrees C, the initial stages of aggregation in agitated samples are similar to those in quiescent solutions; however, in vortexed samples, an abrupt and highly cooperative collapse of early filaments occurs, yielding twisted and laterally aligned aggregates with defined chiroptical properties. In the absence of any detectable birefringence and linear dichroism, the observed strong Cotton effect is attributed to twisted chiral amyloid superstructures. Early fibrils formed in agitated samples, but transferred to quiescent conditions before the collapse event, do not form the superstructures. On the other hand, mature insulin fibrils grown in quiescent samples and later subjected to rapid vortexing transform into clumps of finely broken fibers lacking the superstructural chirality and chiroptical properties of the continuously agitated samples. A generalized mechanism of inducing structural variants of amyloid fibrils by hydrodynamic forces favoring secondary nucleation events over elongation of fibrils is put forward. We propose that competition between low-aspect-ratio and high-aspect-ratio amyloidogenic pathways driven by fluid dynamics may play an important role in promoting distinct amyloid strains.

Detecting solvent-driven transitions of poly(A) to double-stranded conformations by atomic force microscopy.

We report the results of direct measurements by atomic force microscopy of solvent-driven structural transitions within polyadenylic acid (poly(A)). Both atomic force microscopy imaging and pulling measurements reveal complex strand arrangements within poly(A) induced by acidic pH conditions, with a clear fraction of double-stranded molecules that increases as pH decreases. Among these complex structures, force spectroscopy identified molecules that, upon stretching, displayed two distinct plateau features in the force-extension curves. These plateaus exhibit transition forces similar to those previously observed in native double-stranded DNA (dsDNA). However, the width of the first plateau in the force-extension curves of poly(A) varies significantly, and on average is shorter than the canonical 70% of initial length corresponding to the B-S transition of dsDNA. Also, similar to findings in dsDNA, stretching and relaxing elasticity profiles of dspoly(A) at forces below the mechanical melting transition overlap but reveal hysteresis when the molecules are stretched above the mechanical melting transition. These results strongly suggest that under acidic pH conditions, poly(A) can form duplexes that are mechanically stable. We hypothesize that under acidic conditions, similar structures may be formed by the cellular poly(A) tails on mRNA.

Noncooperative dimethyl sulfoxide-induced dissection of insulin fibrils: toward soluble building blocks of amyloid.

The enormous molecular weight complicates detailed structural studies of amyloid fibrils and obscures identification of biologically active forms of protein aggregates in amyloid-related diseases. Here we show that aqueous solutions of dimethyl sulfoxide (DMSO) solubilize insulin fibrils while maintaining their beta-pleated structure. This is accompanied by a marked decrease in the fluorescence of thioflavin T. According to atomic force microscopy images and dynamic light scattering measurements, the partial DMSO-induced dissection of insulin fibrils favors formation of smaller soluble oligomers, which retain a limited capacity to induce daughter generation of fibrils through seeding to the native insulin, as well as the ability to reassemble into fibrils upon removal of DMSO through dialysis against water. These findings suggest that the DMSO-induced ensembles of insulin molecules are closely related to elementary building blocks of amyloid fibrils.

De novo refolding and aggregation of insulin in a nonaqueous environment: an inside out protein remake.

While thermodynamic penalties associated with protein-water interactions are the key driving force of folding, perturbed hydration of destabilized protein molecules may trigger aggregation, which in vivo often causes cellular and histological damage. Here we show, that the denatured state of an alpha-helical protein, insulin, converts to a non-native beta-sheet-rich structure upon de novo "refolding" in an anhydrous environment. The beta-pleated conformer precipitates from solutions of DMSO-denatured insulin upon dilution with chloroform. DMSO destroys hydrogen bond network of the native protein acting as a strong acceptor of main chain hydrogen bonds. Upon the addition of chloroform, which is a weak hydrogen bond donor per se, competitive hydrogen bonds between DMSO and chloroform are formed. This leads to the release of unfolded insulin molecules. In the absence of water, the imminent saturation of polypeptide's dandling hydrogen bonds does not produce the native and predominantly alpha-helical state but a beta-sheet-rich structure, which is morphologically and spectrally distinct from insulin amyloid fibrils. Unlike insulin fibrils, the beta-sheet conformer is metastable and refolds spontaneously to the native form in an aqueous environment. This implies that "folding" in the absence of water results in inefficient burial of hydrophobic side-chains, and thermodynamic frustration at the water-protein interface.

Chiral bifurcation in aggregating insulin: an induced circular dichroism study.

The structural unambiguity of folding is lost when disordered protein molecules convert into beta-sheet-rich fibrils. The resulting polymorphism of protein aggregates has been studied in the context of its biomedical consequences. Events underlying the conformational variance of amyloid fibrils, as well as physicochemical boundaries between folding and misfolding pathways, remain obscure. Bifurcation and chiral mesoscopic-scale organization of amyloid fibrils are new aspects of protein misfolding. Here we characterize bifurcation events accompanying insulin fibrillation upon intensive vortexing. Upon agitation, two types of insulin fibrils with opposite chiral senses are formed; however, predominance of either species is only stochastically determined. The uncertainty of fibrils' chiral sense holds only for fibrils grown within the physiological temperature range, while above 50 degrees C, the bifurcation is no longer observed--fibrils' chiral moieties become uniformly biased towards ligand probes, as revealed by the extrinsic Cotton effect of thioflavin T, Congo red, and molecular iodine. According to transmission electron microscopy and scanning electron microscopy data, chiral variants of insulin fibrils consist of fibrous superstructures, distinct from spherulites, formed by the protein in nonagitated solutions. Gradual dissociation of the fibrils in the presence of dimethyl sulfoxide is noncooperative and can be resolved into three distinct phases: decay of the higher-order chiral structures, breakdown of fibrils, and unfolding of intermolecular beta-sheet. The chiral aggregates are also destabilized by elution of NaCl implying that Debye screening of charged beta-sheets provided by chloride counterions is needed for sustaining their kinetic stability. At elevated temperatures, cross-seeding of agitated insulin samples with preformed fibrils revealed a chiral conflict that prevented the passing of structural features of mother seeds to daughter fibrils in a manner typical of amyloid "strains."

Tyrosine side chains as an electrochemical probe of stacked beta-sheet protein conformations.

The in vivo formation of beta-pleated protein aggregates underlies a number of fatal neurodegenerative disorders, such as Alzheimer disease. Since molecular mechanisms of protein misfolding and aggregation remain poorly understood, this has been calling for many diverse biophysical tools capable of addressing different dynamic and conformational aspects of the phenomenon. The two model polypeptides used in this study are poly(l-tyrosine) and insulin. According to FT-IR spectra, poly(l-tyrosine) produced two distinct types of films with dominant either disordered or antiparallel beta-sheet conformations depending on carrier solvent used for film's deposition. Electrochemical analysis of both the types of polypeptide films by the means of cyclic voltammetry and differential pulse voltammetry proved that different electrochemical behaviour of the tyrosine residues is determined by the conformation of polypeptide chains. We have rationalized this difference in terms of varying electrochemical accessibility of Tyr residues in each structure. We have also carried out spectral and electrochemical characterization of insulin beta-sheet-rich amyloid fibrils. It appears that the detectable electrochemical response of the protein stems from the presence of four tyrosine residues per insulin monomer. Since hydrophobic residues, among them tyrosines play an important role in the formation of protein amyloid fibrils, but, on a molecular level, may be also critical in explaining neurotoxic properties of aggregates, their electrochemical properties may become a very valuable complementary tool in biophysical studies on protein misfolding.

Conformational indeterminism in protein misfolding: chiral amplification on amyloidogenic pathway of insulin.

Unlike folding, protein aggregation is a multipathway, kinetically controlled process yielding different conformations of fibrils. The dynamics and determinism/indeterminism boundaries of misfolded conformations remain obscure. Here we show that, upon vortexing, insulin forms two distinct types of fibrils with opposite local chiral preferences, which manifest in the opposite twists of bound dye, thioflavin T. Occurrence of either type of fibrils in a test tube is only stochastically determined. By acting through an autocatalytic, "chiral amplification"-like mechanism, a random conformational fluctuation triggers conversion of the macroscopic amount of insulin into aggregates with uniformly biased chiral moieties, which bind and twist likewise the achiral dye. Although a convection-driven chiral amplification in achiral systems, which results in randomly distributed excesses of optically active forms, is known, observation of such a phenomenon in misfolded protein built of l-amino acids is unprecedented. The two optical variants of insulin fibrils show distinct morphologies and can propagate their chiral biases upon seeding to nonagitated insulin solutions. Our findings point to a new aspect of topological complexity of protein fibrils: a chiral feature of hierarchically assembled polypeptides, which is partly emancipated from the innate left-handedness of amino acids. Because altering chirality of a molecule changes dramatically its biological activity, the finding may have important ramifications in the context of the structural basis of "amyloid strains".

New insights into the self-assembly of insulin amyloid fibrils: an H-D exchange FT-IR study.

The solvent protection of the amide backbone in bovine insulin fibrils was studied by FT-IR spectroscopy. In the mature fibrils, approximately 85 +/- 2% of amide protons are protected. Of those "trapped" protons, a further 25 +/- 2 or 35 +/- 2% is H-D exchanged after incubation for 1 h at 1 GPa and 25 degrees C or 0.1 MPa and 100 degrees C, respectively. In contrast to the native or unfolded protein, fibrils do not H-D exchange upon incubation at 65 degrees C. A complete deuteration of H(2)O-grown fibrils occurs when the beta-sheet structure is reassembled in a 75 wt % DMSO/D(2)O solution. Our findings suggest a densely packed environment around the amide protons involved in the intermolecular beta-sheet motive. In disagreement with the concept of "amyloid fibers as water-filled nanotubes" [Perutz, M. F., et al. (2002) Proc. Natl. Acad. Sci. U.S.A. 99, 5591-5595], elution of D(2)O-grown fibrils with H(2)O is complete, which is reflected by the vanishing of D(2)O bending vibrations at 1214 cm(-)(1). This implies the absence of "trapped water" within insulin fibrils. The rigid conformations of the native and fibrillar insulin contrast with transient intermediate states docking at the fibrils' ends. Room-temperature seeding is accompanied by an accelerated H-D exchange in insulin molecules in the act of docking and integrating with the seeds, proving that the profound structural disruption is the sine qua non of forming an aggregation-competent conformation.

Ethanol-perturbed amyloidogenic self-assembly of insulin: looking for origins of amyloid strains.

A model cosolvent, ethanol, has profound and diversified effects on the amyloidogenic self-assembly of insulin, yielding spectroscopically and morphologically distinguishable forms of beta-aggregates. The alcohol reduces hydrodynamic radii of insulin molecules, decreases enthalpic costs associated with aggregation-prone intermediate states, and accelerates the aggregation itself. Increasing the concentration of the cosolvent promotes curved, amorphous, and finally donut-shaped forms. According to FT-IR data, inter-beta-strand hydrogen bonding is stronger in fibrils formed in the presence of ethanol. Mechanisms underlying the polymorphism of insulin aggregates were investigated by spectroscopic (CD, FT-IR, and fluorescence anisotropy) and calorimetric (DSC and PPC) methods. The nonmonotonic character of the influence of ethanol on insulin aggregation suggests that both preferential exclusion (predominant at the low concentrations) and direct alcohol-protein interactions are involved. The perturbed hydration of aggregation nuclei appears to be a decisive factor in selection of a dominant mode of beta-strand alignment. It may override unfavorable structural consequences of an alternative strand-to-strand stacking, such as strained hydrogen bonding. A hypothetical mechanism of inducing different amyloid "strains" has been put forward. The cooperative character of fibril assembly creates enormous energy barriers for any interstrain transition, which renders the energy landscape comblike-shaped.

Template-controlled conformational patterns of insulin fibrillar self-assembly reflect history of solvation of the amyloid nuclei.

In the presence of ethanol, insulin forms amyloid morphologically distinct from the ambient specimen. Due to stability of fibrils and the autocatalytic character of the process, the two amyloid templates, when seeded, replicate the initial morphologies (and inter-beta-strand hydrogen bonding patterns) regardless of the environmental biases, such as the cosolvent presence. Such "templated memory" effect is advantageous in synthesizing structurally uniform protein nanofibrils under conditions favoring alternative "wild" forms. This also appears to parallel "prion strains" phenomenon, suggesting that "strains" may reflect a generic trait in all amyloids including those not associated with disease.