Sulfated glycosaminoglycans in protein aggregation diseases

Protein aggregation diseases are characterized by intracellular or extracellular deposition of misfolded and aggregated proteins. These aggregated deposits contain multiple proteinaceous and non-protein components that are thought to play critical roles in the etiology and pathogenesis of protein aggregation diseases in vivo. One of these components, the sulfated glycosaminoglycans (GAGs), includes heparan sulfate, chondroitin sulfate, and keratan sulfate. The sulfated GAGs are negatively charged heteropolysaccharides expressed in all mammalian tissues. Enzymatically generated structural patterns and the degree of sulfation in GAGs determine GAGs’ specific interactions with their protein ligands. Here, we review the potential roles of the sulfated GAGs in the pathogenesis and progression of protein aggregation diseases from a perspective of their sulfation modification. We also discuss the possibility of sulfated GAGs as therapeutic targets for protein aggregation diseases.     

Substrate specificity of 6-O-endosulfatase (Sulf-2) and its implications in synthesizing anticoagulant heparan sulfate

Heparan sulfate (HS) 6-O-endosulfatase (Sulf) catalyzes the hydrolysis of 6-O-sulfo groups from HS polysaccharides. The resultant HS has reduced sulfation levels and displays altered biological activities. The Sulfs have been associated with several cancers and developmental problems and could function as a tool for editing specific HS structures. Here, we characterize the substrate specificity of human Sulf-2 using site-specifically radiolabeled synthetic polysaccharides. The enzyme was expressed and harvested from the conditioned medium of Chinese hamster ovary cells transfected with Sulf-2 expression plasmids. The uniquely [(35)S]sulfated polysaccharides were prepared using purified recombinant HS biosynthetic enzymes. We found that Sulf-2 is particularly effective in removing the 6-O-sulfo group residing in the trisulfated disaccharide repeating unit comprising 2-O-sulfated uronic acid and N-sulfated 6-O-sulfo glucosamine, but can also hydrolyze sulfo groups from N- and 6-O-sulfated disaccharides. In addition, we found that Sulf-2 treatment significantly decreases HS's ability to bind to platelet factor 4 (PF4), a chemokine, while binding to antithrombin is maintained. Because HS-PF4 complexes are the initiating cause of heparin-induced thrombocytopenia, this finding provides a promising strategy for developing heparin therapies with reduced side effects. Further understanding of Sulf-2 activity will help elucidate HS structure-function relationships and provide a valuable tool in tailoring HS-based anticoagulant drugs.     

Highly sensitive sequencing of the sulfated domains of heparan sulfate.

The heparan sulfates (HS) are hypervariable linear polysaccharides that act as membrane co-receptors for growth factors, chemokines, and extracellular matrix proteins. In most instances, the molecular basis of protein recognition by HS is poorly understood. We have sequenced 75% of the sulfated domains (S-domains) of fibroblast HS, including all of the major ones. This analysis revealed tight coupling of N- and 2-O-sulfation and a low frequency but precise positioning of 6-O-sulfates, which are required functional groups for HS-mediated activation of the fibroblast growth factors. S-domain sequencing was conducted using a novel and highly sensitive method based on a new way of reading the sequence from high performance liquid chromatography separation profiles of metabolically labeled HS-saccharides following specific chemical and enzymatic scission. The implications of the patterns seen in the sulfated domains for better understanding of the synthesis and function of HS are discussed.     

Tumour-necrosis factor-α induces heparan sulfate 6-O-endosulfatase 1 (Sulf-1) expression in fibroblasts

Heparan sulfate (HS) 6-O-endosulfatases (Sulfs) have emerged recently as critical regulators of many physiological and pathological processes. By removing 6-O-sulfates from specific HS sequences, they modulate the activities of a variety of growth factors and morphogens, including fibroblast growth factor (FGF)-1. However, little is known about the functions of Sulfs in inflammation. Tumour-necrosis factor (TNF)-α plays an important role in regulating the behaviour of fibroblasts. In this study, we examined the effect of this inflammatory cytokine on the expression of Sulfs in human MRC-5 fibroblasts. Compositional analysis of HS from TNF-α-treated cells showed a strong reduction in the amount of the trisulfated UA2S-GlcNS6S disaccharide, which suggested a selective reaction of 6-O-desulfation. Real-time PCR analysis revealed that TNF-α increased Sulf-1 expression in a dose- and time-dependent manner, via a mechanism involving NF-ĸB, ERK1/2 and p38 MAPK. In addition, we confirmed that cell stimulation with TNF-α was accompanied by the secretion of an active form of Sulf-1. To study the function of Sulf- 1, we examined the responses induced by FGF-1. We showed that ERK1/2 activation and cell proliferation were markedly reduced in TNF-α-treated MRC-5 cells compared with untreated cells. Silencing the expression of Sulf-1 by RNA interference restored the responses induced by FGF-1, which indicated that TNF-α-mediated induction of the sulfatase indeed resulted in alterations of HS biological properties. Taken together, our results indicate that Sulf-1 is responsive to TNF-α stimulation and may function as an autocrine regulator of fibroblast expansion in the course of an inflammatory response.     

The spacing of S-domains on HS glycosaminoglycans determines whether the chain is a substrate for intracellular heparanases

Heparanases are mammalian endoglucuronidases that degrade heparan sulfate (HS) glycosaminoglycans to short 5-6 kDa pieces. In the Golgi, HS glycosaminoglycans are modified by a series of interdependent reactions which result in chains that have regions rich in N- and O-sulfate groups and iduronate residues (S-domains), separated by regions that are nearly devoid of sulfate. Structural analysis of the short HS chains produced by Chinese hamster ovary (CHO) cell heparanases indicate that the enzymes recognize differences in sulfate content between S-domains and unmodified sequences, and cleave the chain at junctions between these regions. To look more closely at whether the spacing of S-domains on the gly- cosaminoglycan influences its ability to be cleaved by heparanases, we examined the susceptibility of the HS chains synthesized by the proteoglycan synthesis mutant, pgsE-606. PGS:E-606 cells are deficient in the modification enzyme N-deacetylase/N-sulfotransferase I, and synthesize HS chains that have fewer N- and O-sulfate groups and iduronate residues compared to wild-type (Bame et al., (1991), J. Biol. Chem., 266, 10287). HS glycosaminoglycans were isolated from wild-type and pgsE-606 cells and separated into populations based on sulfate content. Compared to wild-type HS, which has 14 S-domains, pgsE-606 cells synthesize three HS species, 606-1, 606-2, and 606-3, with 1, 4, and 8 S-domains, respectively. The spacing of the S-domains on the pgsE-606 HS chains is similar to the spacing the modified sequences on wild-type HS, indicating that each mutant glycosaminoglycan is composed of wild-type-like sequences and sequences devoid of S-domains. When incubated with partially purified CHO heparanases, only the portion of the mutant HS chains that had S-domains were degraded. Structural analysis of the heparanase-products confirmed that both the number and the arrangement of S-domains on the HS glycosaminoglycan are important for heparanase susceptibility. The structure of the different pgsE-606 HS chains also suggests mechanisms for the placement of S-domains when the gly- cosaminoglycan is synthesized.     

The structural plasticity of heparan sulfate NA-domains and hence their role in mediating multivalent interactions is confirmed by high-accuracy <Superscript>15</Superscript>N-NMR relaxation studies

Considering the biological importance of heparan sulfate (HS) and the significant activity of its highly-sulfated regions (S-domains), the paucity of known functions for the non-sulfated NA-domains is somewhat puzzling. It has been suggested that chain dynamics within the NA-domains are the key to their functional role in HS. In this study, we investigate this hypothesis using state-of-the-art nuclear magnetic resonance (NMR) experiments at multiple frequencies. To resolve the problem of severe overlap in (1)H-NMR spectra of repetitive polysaccharides from proteoglycans, we have prepared oligosaccharides with the chemical structure of HS NA-domains containing the (15)N nucleus, which has enough chemical shift dispersion to probe the central residues of octasaccharides at atomic resolution using 600 MHz NMR. By performing NMR relaxation experiments at three magnetic-field strengths, high quality data on internal dynamics and rotational diffusion was obtained. Furthermore, translational diffusion could also be measured by NMR using pulse field gradients. These experimental data were used, in concert with molecular dynamics simulations, to provide information on local molecular shape, greatly aiding our relaxation analyses. Our results, which are more accurate than those presented previously, confirm the higher flexibility of the NA-domains as compared with reported data on S-domains. It is proposed that this flexibility has two functional roles. First, it confers a greater area of interaction from the anchoring point on the core protein for the bioactive S-domains. Secondly, it allows multiple interactions along the same HS chain that are dynamically independent of each other.     

Membranes as modulators of amyloid protein misfolding and target of toxicity

Abnormal protein aggregation is a hallmark of various human diseases. α-Synuclein, a protein implicated in Parkinson's disease, is found in aggregated form within Lewy bodies that are characteristically observed in the brains of PD patients. Similarly, deposits of aggregated human islet amyloid polypeptide (IAPP) are found in the pancreatic islets in individuals with type 2 diabetes mellitus. Significant number of studies have focused on how monomeric, disaggregated proteins transition into various amyloid structures leading to identification of a vast number of aggregation promoting molecules and processes over the years. Inasmuch as these factors likely enhance the formation of toxic, misfolded species, they might act as risk factors in disease. Cellular membranes, and particularly certain lipids, are considered to be among the major players for aggregation of α-synuclein and IAPP, and membranes might also be the target of toxicity. Past studies have utilized an array of biophysical tools, both in vitro and in vivo, to expound the membrane-mediated aggregation. Here, we focus on membrane interaction of α-synuclein and IAPP, and how various kinds of membranes catalyze or modulate the aggregation of these proteins and how, in turn, these proteins disrupt membrane integrity, both in vitro and in vivo. The membrane interaction and subsequent aggregation has been briefly contrasted to aggregation of α-synuclein and IAPP in solution. This article is part of a Special Issue entitled: Protein Aggregation and Misfolding at the Cell Membrane Interface edited by Ayyalusamy Ramamoorthy.     

Kinetic Analysis of Amyloid Formation in the Presence of Heparan Sulfate: FASTER UNFOLDING AND CHANGE OF PATHWAY*

A number of human diseases are associated with the conversion of proteins from their native state into well defined fibrillar aggregates, depositing in the extracellular space and generally termed amyloid fibrils. Heparan sulfate (HS), a glycosaminoglycan normally present in the extracellular matrix, has been found to be universally associated with amyloid deposits and to promote amyloid fibril formation by all studied protein systems. We have studied the impact of HS on the amyloidogenesis of human muscle acylphosphatase, monitoring the process with an array of techniques, such as normal and stopped-flow far-UV circular dichroism, thioflavin T fluorescence, static and dynamic light scattering, and atomic force microscopy. The results show that HS accelerates the conversion of the studied protein from the native state into the amyloidogenic, yet monomeric, partially folded state. They also indicate that HS does not simply accelerate the conversion of the resulting partially folded state into amyloid species but splits the process into two distinct pathways occurring in parallel: a very fast phase in which HS interacts with a fraction of protein molecules, causing their rapid aggregation into ThT-positive and β-sheet containing oligomers, and a slow phase resulting from the normal aggregation of partially folded molecules that cannot interact with HS. The HS-mediated aggregation pathway is severalfold faster than that observed in the absence of HS. Two aggregation phases are generally observed when proteins aggregate in the presence of HS, underlying the importance of a detailed kinetic analysis to fully understand the effect of this glycosaminoglycan on amyloidogenesis.Deposition of proteins in the form of extracellular amyloid fibrils is a consistent mechanism underlying a group of diverse human diseases, including neurodegenerative disorders and non-neuropathic conditions (1). From a pathogenetic standpoint, these disorders differ by type of aggregated protein and by type of organs involved in amyloid deposition. Among the most prominent neurodegenerative conditions are Alzheimer and Creuzfeldt Jakob diseases, which affect the central nervous system via extracellular deposits. Examples of non-neuropathic systemic amyloidosis are light chain amyloidosis and type II diabetes, where deposits are found in joints, skeletal tissue, and several organs (e.g. heart and kidney). Each of these disorders can be traced back to the aberrant conversion of one specific protein or peptide from its soluble, native state into amyloid structures (1). Numerous biochemical and genetic studies have established a widely accepted causative link between pathological symptoms and amyloid structure formation and deposition (2).Amyloid fibrils are often localized in close proximity to basement membranes, a specialized component of the extracellular matrix that is mainly built of collagens and glycosaminoglycans (GAGs),³ often attached to a protein core to form the proteoglycans (3–5). GAGs are long unbranched polysaccharides that often occur, with the exception of hyaluronic acid existing in a free form, as O- or N-linked side chains of proteoglycans, where they regulate the activity of several proteins. Since they have been found physically associated with all types of amyloid deposits in vivo so far analyzed, they have been attributed fundamental relevance in amyloidogenesis (3, 4). Of the different types of natural GAGs, heparan sulfate (HS) is among the most important cofactors in amyloid deposits. First, it has been established as a universal component of amyloid, since it has been found to be associated with amyloid deposits of different proteins, including the serum amyloid A protein (6), the immunoglobin light chain (7), transthyretin (8), cystatin C (9), the amyloid β peptide (10), the islet amyloid polypeptide (11), and the prion protein (PrP) (12). More importantly, it has been attributed an active role in amyloidogenesis. Its ability to promote fibrillogenesis has been reported for both the 42- and 40-residue forms of the amyloid β peptide (13, 14), mature islet amyloid polypeptide and proislet amyloid polypeptide 1–48 (15), α-synuclein (16), the 173–243 fragment of D187N gelsolin (17), β2-microgloblulin (18), and the tau protein (19). HS has also been found to shift the secondary structure of a subtype of serum amyloid A protein from a random coil to a β-sheet, presumably aggregated, structure (20, 21) and to convert the prion protein from the PrP^C to the PrP^SC form (22).Despite the large body of data supporting the importance of HS in amyloidogenesis, little is known about the precise mechanism by which HS promotes amyloid formation and the effect that this GAG has on the various phases of the aggregation process and on the overall aggregation pathway. In the current work, human muscle acylphosphatase (mAcP) is utilized to study the impact of HS on amyloid aggregation, with particular attention to the various kinetic phases observed in the presence of this GAG. mAcP represents an enzyme unrelated to any human disease but a particularly suitable model for amyloid aggregation studies for a number of reasons. First, it is small in size (98 residues) and lacks disulfide bridges, trans-peptidyl-prolyl bonds, non-proteinaceous cofactors, and other complexities (23, 24). Second, it can form in the presence of 25% (v/v) trifluoroethanol (TFE) amyloid-like fibrils with extensive β-sheet structure and Congo Red birefringence (25). Third, its aggregation process has been studied using a variety of experimental approaches (25–33) and has been shown to be dramatically influenced by heparin, the highly sulfated form of HS (34).In the presence of 25% (v/v) TFE, mAcP has been shown to unfold rapidly into a denatured state enriched with α-helical structure (25). This partially unfolded state assembles to form, on a time scale of 1–2 h, amyloid-like protofibrils that develop very slowly to form, after a period of several days, long amyloid protofilaments that then associate further to form higher order structures (35). Even the early, protofibrillar aggregates that form within 1–2 h have the ability to bind Congo Red and thioflavin T (ThT) and have an extensive β-sheet structure, as detected with far-UV CD and Fourier transform infrared spectroscopy (25). This indicates that these protofibrillar structures have the essential structural characteristics of amyloid. The unfolding of the native state into a partially unfolded state is required to initiate aggregation, as shown by the need to use denaturing conditions to start aggregation (27, 35), by the finding that mutations destabilizing the native state promote aggregation (26), and by the observation that ligands binding to and stabilizing the native state have the opposite effect (29). Importantly, the TFE-denatured state of mAcP, which is the most commonly used to trigger aggregation of this protein and will also be used here, is not the only aggregation-competent state of mAcP, since other denatured states of mAcP have been shown to be capable of amyloid fibril formation (27).The present study aims at investigating the mechanism through which HS influences mAcP aggregation into amyloid-like aggregates. We will investigate both the unfolding and aggregation phases of mAcP in the presence of HS and will monitor them using a variety of biophysical methods. We will show that HS accelerates unfolding in addition to promoting aggregation of the resulting TFE-denatured state, thus playing a double-faced role in the context of its proaggregating effect. We will also show that HS is responsible for the appearance of parallel phases in the aggregation process of this protein and that its effect is not limited to a simple acceleration of the overall process. Following these findings, we will emphasize that a full understanding of the newly generated kinetics is essential for a correct interpretation of the effects of HS on amyloid formation.     

Heparin-derived heparan sulfate mimics to modulate heparan sulfate-protein interaction in inflammation and cancer

The heparan sulfate (HS) chains of heparan sulfate proteoglycans (HSPG) are “ubiquitous” components of the cell surface and the extracellular matrix (EC) and play important roles in the physiopathology of developmental and homeostatic processes. Most biological properties of HS are mediated by interactions with “heparin-binding proteins” and can be modulated by exogenous heparin species (unmodified heparin, low molecular weight heparins, shorter heparin oligosaccharides and various non-anticoagulant derivatives of different sizes). Heparin species can promote or inhibit HS activities to different extents depending, among other factors, on how closely their structure mimics the biologically active HS sequences. Heparin shares structural similarities with HS, but is richer in “fully sulfated” sequences (S domains) that are usually the strongest binders to heparin/HS-binding proteins. On the other hand, HS is usually richer in less sulfated, N-acetylated sequences (NA domains). Some of the functions of HS chains, such as that of activating proteins by favoring their dimerization, often require short S sequences separated by rather long NA sequences. The biological activities of these species cannot be simulated by heparin, unless this polysaccharide is appropriately chemically/enzymatically modified or biotechnologically engineered. This mini review covers some information and concepts concerning the interactions of HS chains with heparin-binding proteins and some of the approaches for modulating HS interactions relevant to inflammation and cancer. This is approached through a few illustrative examples, including the interaction of HS and heparin-derived species with the chemokine IL-8, the growth factors FGF1 and FGF2, and the modulation of the activity of the enzyme heparanase by these species. Progresses in sequencing HS chains and reproducing them either by chemical synthesis or semi-synthesis, and in the elucidation of the 3D structure of oligosaccharide–protein complexes, are paving the way for rational approaches to the development of HS-inspired drugs in the field of inflammation and cancer, as well in other therapeutic fields.     

Opinion: What is the role of protein aggregation in neurodegeneration?

Neurodegenerative diseases typically involve deposits of inclusion bodies that contain abnormal aggregated proteins. Therefore, it has been suggested that protein aggregation is pathogenic. However, several lines of evidence indicate that inclusion bodies are not the main cause of toxicity, and probably represent a cellular protective response. Aggregation is a complex multi-step process of protein conformational change and accretion. The early species in this process might be most toxic, perhaps through the exposure of buried moieties such as main chain NH and CO groups that could serve as hydrogen bond donors or acceptors in abnormal interactions with other cellular proteins. This model implies that the pathogenesis of diverse neurodegenerative diseases arises by common mechanisms, and might yield common therapeutic targets.     

Sodium channel beta subunits mediate homophilic cell adhesion and recruit ankyrin to points of cell-cell contact

Sodium channels isolated from mammalian brain are composed of alpha, beta1, and beta2 subunits. The auxiliary beta subunits do not form the ion conducting pore, yet play important roles in channel modulation and plasma membrane expression. beta1 and beta2 are transmembrane proteins with one extracellular V-set immunoglobulin (Ig) protein domain. It has been shown recently that beta1 and beta2 interact with the extracellular matrix proteins tenascin-C and tenascin-R. In the present study we show that rat brain beta1 and beta2, but not alphaIIA, subunits interact in a trans-homophilic fashion, resulting in recruitment of the cytoskeletal protein ankyrin to sites of cell-cell contact in transfected Drosophila S2 cells. Whereas alphaIIA subunits expressed alone do not cause cellular aggregation, beta subunits co-expressed with alphaIIA retain the ability to adhere and recruit ankyrin. Truncated beta subunits lacking cytoplasmic domains interact homophilically to produce cell aggregation but do not recruit ankyrin. Thus, the cytoplasmic domains of beta1 and beta2 are required for cytoskeletal interactions. It is hypothesized that sodium channel beta subunits serve as a critical communication link between the extracellular and intracellular environments of the neuron and may play a role in sodium channel placement at nodes of Ranvier.     

Widespread Protein Aggregation as an Inherent Part of Aging in C. elegans

Aberrant protein aggregation is a hallmark of many age-related diseases, yet little is known about whether proteins aggregate with age in a non-disease setting. Using a systematic proteomics approach, we identified several hundred proteins that become more insoluble with age in the multicellular organism Caenorhabditis elegans. These proteins are predicted to be significantly enriched in β-sheets, which promote disease protein aggregation. Strikingly, these insoluble proteins are highly over-represented in aggregates found in human neurodegeneration. We examined several of these proteins in vivo and confirmed their propensity to aggregate with age. Different proteins aggregated in different tissues and cellular compartments. Protein insolubility and aggregation were significantly delayed or even halted by reduced insulin/IGF-1-signaling, which also slows aging. We found a significant overlap between proteins that become insoluble and proteins that influence lifespan and/or polyglutamine-repeat aggregation. Moreover, overexpressing one aggregating protein enhanced polyglutamine-repeat pathology. Together our findings indicate that widespread protein insolubility and aggregation is an inherent part of aging and that it may influence both lifespan and neurodegenerative disease.     

Fibroblast Growth Factor-based Signaling through Synthetic Heparan Sulfate Blocks Copolymers Studied Using High Cell Density Three-dimensional Cell Printing

Four well-defined heparan sulfate (HS) block copolymers containing S-domains (high sulfo group content) placed adjacent to N-domains (low sulfo group content) were chemoenzymatically synthesized and characterized. The domain lengths in these HS block co-polymers were ∼40 saccharide units. Microtiter 96-well and three-dimensional cell-based microarray assays utilizing murine immortalized bone marrow (BaF3) cells were developed to evaluate the activity of these HS block co-polymers. Each recombinant BaF3 cell line expresses only a single type of fibroblast growth factor receptor (FGFR) but produces neither HS nor fibroblast growth factors (FGFs). In the presence of different FGFs, BaF3 cell proliferation showed clear differences for the four HS block co-polymers examined. These data were used to examine the two proposed signaling models, the symmetric FGF₂-HS₂-FGFR₂ ternary complex model and the asymmetric FGF₂-HS₁-FGFR₂ ternary complex model. In the symmetric FGF₂-HS₂-FGFR₂ model, two acidic HS chains bind in a basic canyon located on the top face of the FGF₂-FGFR₂ protein complex. In this model the S-domains at the non-reducing ends of the two HS proteoglycan chains are proposed to interact with the FGF₂-FGFR₂ protein complex. In contrast, in the asymmetric FGF₂-HS₁-FGFR₂ model, a single HS chain interacts with the FGF₂-FGFR₂ protein complex through a single S-domain that can be located at any position within an HS chain. Our data comparing a series of synthetically prepared HS block copolymers support a preference for the symmetric FGF₂-HS₂-FGFR₂ ternary complex model.     

Interactions between M proteins of Streptococcus pyogenes and glycosaminoglycans promote bacterial adhesion to host cells.

Several microbial pathogens have been reported to interact with glycosaminoglycans (GAGs) on cell surfaces and in the extracellular matrix. Here we demonstrate that M protein, a major surface-expressed virulence factor of the human bacterial pathogen, Streptococcus pyogenes, mediates binding to various forms of GAGs. Hence, S. pyogenes strains expressing a large number of different types of M proteins bound to dermatan sulfate (DS), highly sulfated fractions of heparan sulfate (HS) and heparin, whereas strains deficient in M protein surface expression failed to interact with these GAGs. Soluble M protein bound DS directly and could also inhibit the interaction between DS and S. pyogenes. Experiments with M protein fragments and with streptococci expressing deletion constructs of M protein, showed that determinants located in the NH2-terminal part as well as in the C-repeat region of the streptococcal proteins are required for full binding to GAGs. Treatment with ABC-chondroitinase and HS lyase that specifically remove DS and HS chains from cell surfaces, resulted in significantly reduced adhesion of S. pyogenes bacteria to human epithelial cells and skin fibroblasts. Together with the finding that exogenous DS and HS could inhibit streptococcal adhesion, these data suggest that GAGs function as receptors in M protein-mediated adhesion of S. pyogenes.     

Emerging roles of O-glycosylation in regulating protein aggregation,phase separation,and functions

Protein O-glycosylation is widely identified in various proteins involved in diverse biological processes. Recent studies have demonstrated that O-glycosylation plays crucial and multifaceted roles in modulating protein amyloid aggregation and liquid–liquid phase separation (LLPS) under physiological conditions. Dysregulation of these processes is closely associated with human diseases such as neurodegenerative diseases (NDs) and cancers. In this review, we first summarize the distinct roles of O-glycosylation in regulating pathological aggregation of different amyloid proteins related to NDs and elaborate the underlying mechanisms of how O-glycosylation modulates protein aggregation kinetics, induces new aggregated structures, and mediates the pathogenesis of amyloid aggregates under diseased conditions. Furthermore, we introduce recent discoveries on O-GlcNAc-mediated regulation of synaptic LLPS and phase separation potency of low-complexity domain-enriched proteins. Finally, we identify challenges in future research and highlight the potential for developing new therapeutic strategies of NDs by targeting protein O-glycosylation.     

Functional analysis of chick heparan sulfate 6‐O‐sulfotransferases in limb bud development

Heparan sulfate (HS) interacts with numerous growth factors, morphogens, receptors, and extracellular matrix proteins. Disruption of HS synthetic enzymes causes perturbation of growth factor signaling and malformation in vertebrate and invertebrate development. Our previous studies show that the O‐sulfation patterns of HS are essential for the specific binding of growth factors to HS chains, and that depletion of O‐sulfotransferases results in remarkable developmental defects in Drosophila, zebrafish, chick, and mouse. Here, we show that inhibition of chick HS‐6‐O‐sulfotransferases (HS6ST‐1 and HS6ST‐2) in the prospective limb region by RNA interference (RNAi) resulted in the truncation of limb buds and reduced Fgf‐8 and Fgf‐10 expressions in the apical ectodermal ridge and in the underlying mesenchyme, respectively. HS6ST‐2 RNAi resulted in a higher frequency of limb truncation and a more marked change in both Fgf‐8 and Fgf‐10 expressions than that achieved with HS6ST‐1 RNAi. HS6ST‐1 RNAi and HS6ST‐2 RNAi caused a significant but distinct reduction in the levels of different 6‐O‐sulfation in HS, possibly as a result of their different substrate specificities. Our data support a model where proper levels and patterns of 6‐O‐sulfation of HS play essential roles in chick limb bud development.     

Expression of novel extracellular sulfatases Sulf-1 and Sulf-2 in normal and osteoarthritic articular cartilage

Introduction  

Changes in sulfation of cartilage glycosaminoglycans as mediated by sulfatases can regulate growth factor signaling. The aim of this study was to analyze expression patterns of recently identified extracellular sulfatases Sulf-1 and Sulf-2 in articular cartilage and chondrocytes.     

ATP‐independent molecular chaperone activity generated under reducing conditions

Molecular chaperones are essential to maintain proteostasis. While the functions of intracellular molecular chaperones that oversee protein synthesis, folding and aggregation, are established, those specialized to work in the extracellular environment are less understood. Extracellular proteins reside in a considerably more oxidizing milieu than cytoplasmic proteins and are stabilized by abundant disulfide bonds. Hence, extracellular proteins are potentially destabilized and sensitive to aggregation under reducing conditions. We combine biochemical and mass spectrometry experiments and elucidate that the molecular chaperone functions of the extracellular protein domain Bri2 BRICHOS only appear under reducing conditions, through the assembly of monomers into large polydisperse oligomers by an intra‐ to intermolecular disulfide bond relay mechanism. Chaperone‐active assemblies of the Bri2 BRICHOS domain are efficiently generated by physiological thiol‐containing compounds and proteins, and appear in parallel with reduction‐induced aggregation of extracellular proteins. Our results give insights into how potent chaperone activity can be generated from inactive precursors under conditions that are destabilizing to most extracellular proteins and thereby support protein stability/folding in the extracellular space.SignificanceChaperones are essential to cells as they counteract toxic consequences of protein misfolding particularly under stress conditions. Our work describes a novel activation mechanism of an extracellular molecular chaperone domain, called Bri2 BRICHOS. This mechanism is based on reducing conditions that initiate small subunits to assemble into large oligomers via a disulfide relay mechanism. Activated Bri2 BRICHOS inhibits reduction‐induced aggregation of extracellular proteins and could be a means to boost proteostasis in the extracellular environment upon reductive stress.     

Heparan sulfate proteoglycans and their binding proteins in embryo implantation and placentation

Complex interactions occur among embryonic, placental and maternal tissues during embryo implantation. Many of these interactions are controlled by growth factors, extracellular matrix and cell surface components that share the ability to bind heparan sulfate (HS) polysaccharides. HS is carried by several classes of cell surface and secreted proteins called HS proteoglycan that are expressed in restricted patterns during implantation and placentation. This review will discuss the expression of HS proteoglycans and various HS binding growth factors as well as extracellular matrix components and HS-modifying enzymes that can release HS-bound proteins in the context of implantation and placentation.