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The amyloid interactome: Exploring protein aggregation

  • Konstantina V. Biza ,

    Contributed equally to this work with: Konstantina V. Biza, Katerina C. Nastou, Paraskevi L. Tsiolaki

    Affiliation Section of Cell Biology and Biophysics, Department of Biology, School of Sciences, National and Kapodistrian University of Athens, Panepistimiopolis, Athens, Greece

  • Katerina C. Nastou ,

    Contributed equally to this work with: Konstantina V. Biza, Katerina C. Nastou, Paraskevi L. Tsiolaki

    Affiliation Section of Cell Biology and Biophysics, Department of Biology, School of Sciences, National and Kapodistrian University of Athens, Panepistimiopolis, Athens, Greece

  • Paraskevi L. Tsiolaki ,

    Contributed equally to this work with: Konstantina V. Biza, Katerina C. Nastou, Paraskevi L. Tsiolaki

    Affiliation Section of Cell Biology and Biophysics, Department of Biology, School of Sciences, National and Kapodistrian University of Athens, Panepistimiopolis, Athens, Greece

  • Chara V. Mastrokalou,

    Affiliation Section of Cell Biology and Biophysics, Department of Biology, School of Sciences, National and Kapodistrian University of Athens, Panepistimiopolis, Athens, Greece

  • Stavros J. Hamodrakas,

    Affiliation Section of Cell Biology and Biophysics, Department of Biology, School of Sciences, National and Kapodistrian University of Athens, Panepistimiopolis, Athens, Greece

  • Vassiliki A. Iconomidou

    veconom@biol.uoa.gr

    Affiliation Section of Cell Biology and Biophysics, Department of Biology, School of Sciences, National and Kapodistrian University of Athens, Panepistimiopolis, Athens, Greece

Abstract

Protein-protein interactions are the quintessence of physiological activities, but also participate in pathological conditions. Amyloid formation, an abnormal protein-protein interaction process, is a widespread phenomenon in divergent proteins and peptides, resulting in a variety of aggregation disorders. The complexity of the mechanisms underlying amyloid formation/amyloidogenicity is a matter of great scientific interest, since their revelation will provide important insight on principles governing protein misfolding, self-assembly and aggregation. The implication of more than one protein in the progression of different aggregation disorders, together with the cited synergistic occurrence between amyloidogenic proteins, highlights the necessity for a more universal approach, during the study of these proteins. In an attempt to address this pivotal need we constructed and analyzed the human amyloid interactome, a protein-protein interaction network of amyloidogenic proteins and their experimentally verified interactors. This network assembled known interconnections between well-characterized amyloidogenic proteins and proteins related to amyloid fibril formation. The consecutive extended computational analysis revealed significant topological characteristics and unraveled the functional roles of all constituent elements. This study introduces a detailed protein map of amyloidogenicity that will aid immensely towards separate intervention strategies, specifically targeting sub-networks of significant nodes, in an attempt to design possible novel therapeutics for aggregation disorders.

Introduction

The cellular and molecular mechanisms that underlie protein misfolding are a matter of major concern for studies conducted in several scientific centers all over the world. Under denaturing conditions, a growing number of proteins and peptides that fail to fold properly into their native structure, are led to the formation of highly ordered, insoluble aggregates, the so-called amyloid fibrils [1]. Amyloidogenicity, the ability of proteins to self-assemble into these well-defined fibrillar structures, was initially associated with a group of functionally unrelated proteins [2]. Meanwhile, targeted in vitro experiments revealed that amyloid formation is a universal phenomenon for polypeptide chains [3] and thus, this concept was the onset of a new era in protein misfolding, since a great number of novel amyloidogenic proteins and peptides were uncovered [4]. Noteworthy, proteins, ranging from bacteria to humans, have been also found to adopt the same amyloid architecture, as part of their nature [5, 6]. A vast amount of data, regarding amyloid fibril formation, present both in pathological and physiological conditions, is currently organized into freely available databases [711].

Amyloid fibril formation is widely observed and directly linked to the pathology of a range of widespread human diseases, known as amyloidoses [2]. Amyloidoses are a group of aggregation-disorders, where full-length amyloidogenic proteins or fragments of larger amyloidogenic protein precursors, precipitate and deposit, forming amyloid plaques and resulting in organ or tissue dysfunction [12, 13]. Literature data indicate the implication of more than one amyloidogenic proteins in the evolution of different amyloidoses. In the case of Senile Systemic Amyloidosis, co-operation of several Apolipoproteins and ATTR is recorded [14, 15], whereas in Alzheimer’s disease, apart from Aβ, proteinaceous components such as ACys, ATTR and AGel were found [16]. To date, the extent to which co-deposition in amyloid plaques has impacted the development of amyloidoses between putative unrelated amyloidogenic proteins, remains unclear.

Experimental work over the past ten years has revealed an intriguing, synergistic phenomenon between amyloidogenic proteins [17]. In vitro experiments highlighted the capacity of Aβ peptide under specific conditions to seed the polymerization process for α-synuclein [18], Tau [19] or APrp protein [20]. Similar experiments were performed on several well-characterized amyloidogenic proteins [2123]. Further to in vitro assays, animal models demonstrated the co-deposition of Aβ and Tau proteins [24] or APrp protein [20] in transgenic models. However, a hidden perspective emerges from this molecular association; amyloid “cross-seeding” could explain mechanistically the way by which misfolded proteins co-deposite, and propose possible, attractive candidates for the development of novel therapeutic strategies of aggregation-related diseases. An apt example towards this direction is the protective role of the amyloidogenic ACys in neurodegenerative diseases [25].

The interactomes [26, 27], a systems biology approach, were viable complements to proteomics, in an attempt to look at “the big picture” of protein-protein interactions (PPIs). Gaining a proper understanding of PPIs contributed to several problems in the field of biological and medical research [2830] and served as a reference for further targeted experimentation [31]. Systematic PPI studies are essential, in order to fully comprehend the molecular mechanisms that trigger human diseases [32, 33]. However, a subject poorly explored so far is deviating PPIs associated with amyloidogenic/amyloid forming proteins. To date, only a few studies utilized a protein interaction network framework, to obtain information regarding the Alzheimer’s [3436] or Huntington’s disease [37] and to construct the Amyloid precursor protein interactome [3840].

Incomplete knowledge on direct and/or indirect interactions of proteins “prone-to-misfold”, emphasizes the need to focus on the amyloid protein-protein interaction network. Here we introduce the amyloid interactome, a systematic approach to study “macroscopically” interactions between previously unrelated human amyloidogenic proteins, associated with distinct pathologies. Our ultimate goal was to find a common denominator for amyloid formation, unveil the relationships that govern amyloidogenicity and, subsequently, guide further experimental studies on protein misfolding.

Materials and methods

Amyloid classification

In order to classify amyloidogenic proteins, all protein-precursors were sorted into three categories:

  • in vivo amyloid forming protein: the precursor protein, or a peptide segment–derived from the precursor protein–, self assembles into typical amyloid fibrils, affecting one or more tissues or organs in human. These proteins, from a clinical perspective, give rise to distinct amyloidoses or play a pathological role in neurodegenerative or endocrine diseases [2].
  • in vitro amyloid forming protein: the precursor protein, or commonly a peptide segment–derived from the precursor protein–, that was reported to self assemble into amyloid-like fibrils, at experimental level. The amyloidogenicity of proteins comprising this list may be speculative. Only human precursor proteins are mentioned in this category.
  • protein related to amyloid fibril formation: the protein is associated with other in vivo amyloid forming proteins, but has no amyloid properties recorded.

Amyloid interactome datasets

Amyloidogenic proteins were firstly obtained from a literature-curated dataset, peer-reviewed in 2014, by the International Society of Amyloidosis (http://www.amyloidosis.nl/). This list included human proteins known to self-assemble into typical amyloid fibrils in vivo, along with intracellular inclusions with known biochemical composition [2]. In addition to this, the set was enriched with proteins that form amyloid fibrils in vitro [41]. To expand this dataset, AmyLoad [7] was used as a source of supplementary proteins, characterized to form amyloid-like fibrils in vitro at experimental level. A final addition included several UniProtKB [42] entries, gathered elaborately to incorporate reviewed proteins related to amyloid fibrils. Overall, the dataset contained 145 non-redundant amyloidogenic protein precursors. S1 Table provides a detailed catalogue of the aforementioned proteins, mapped to a UniProtKB Accession Number (AC).

The subsequent construction of the network incorporated only well-characterized in vivo amyloidogenic proteins, published by Sipe et al. [2], excluding Enfurvitide an anti-retroviral peptide drug [43], as well as Immunoglobulin Light and Heavy Chains. In the case of Immunoglobulin chains (e.g. Bence Jones proteins [44]), their variety in human population did not allow the identification of a unique protein precursor, related to amyloid fibril formation. The final seed-dataset included 28 proteins, related to in vivo amyloid fibril formation (Table 1), which were subsequently used for the collection of protein-protein interactions. Protein nomenclature follows abbreviations established by Sipe et al. [2].

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Table 1. The dataset of 28 proteins related to in vivo amyloid fibril formation.

https://doi.org/10.1371/journal.pone.0173163.t001

Assembling the protein-protein interaction dataset

UniProtKB ACs were used to query IntAct [45], BioGRID [46] and STRING [47] databases, in order to extract experimentally verified PPIs for the 28 proteins related to in vivo amyloid fibril formation (Table 1). This process resulted in three independent PPI datasets, derived from each database (data not shown). In general protein-protein interaction data contain experimentally verified interactions, along with data derived from prediction methods. These last data do not have the high reliability often attributed to them and thus, in order to avoid extracting automatic text-mining results from the plethora of scientific articles related to amyloid fibril formation, BioGRID and STRING datasets were excluded from any further analysis. IntAct PPIs, gather highly curated experimental data, which ensured the quality and consistency of information of our dataset [48].

The interaction data from IntAct (05–2016) were retrieved in a MITAB 2.5 format file [49], which is appropriate for Perl parsing, without the loss of information regarding PPIs. An editing process of the file allowed the removal of all the non-human interactions, and additional screening was performed to dismiss interactions with chemical compounds. The resulting set included 355 protein nodes with 762 edges.

In order to create a more robust network, the interactions deposited in IntAct between all 355 proteins were retrieved, whilst an extra processing allowed for the removal of self-loops and duplicated edges. Thus, a final dataset of 1178 PPIs between 353 human proteins was obtained, after the exclusion of two protein nodes that had only self interactions (See Results and discussion).

Visualization and analysis of the network

For the visualization and the analysis of the network we followed the protocol introduced by Nastou et al. [50]. Cytoscape 3.2.1 [51] was used to manipulate, analyze and visualize our data, since it ideally provides all the necessary and improved applications for the analysis of biological networks [52]. The analysis of simple and complex network topology parameters, was performed by NetworkAnalyzer [53]. The Cytoscape.js JavaScript library [54] was used to create interactive networks, is available at this link: http://83.212.109.111/amyloid_interactome.

Clustering analysis was performed with clusterMaker [55], utilizing the Markov Clustering algorithm (MCL), an optimal choice for biological interaction networks assembled from high-throughput experiments. Different inflation values, between 1.8 and 3.0, were used during the clustering process (data not shown). The inflation value was finally set to 1.8, as it has been proved to be the most suitable for biological networks [50, 56], in consistency with the observation that values above 1.8, result in extreme network fragmentation and the creation of clusters with minor biological significance (See Results and discussion).

BiNGO [57], an application for Cytoscape and WebGestalt [58], an online server, were both used to perform a functional enrichment analysis of the network. BiNGO determines Gene Ontology (GO) [59] categories that are statistically overrepresented in a set of proteins in a biological network (e.g. a cluster), and thus, aids in the detection of functional modules. WebGestalt was used to further supplement this analysis, since, besides GO term it can perform Disease Association and KEGG pathway analysis. The hypergeometric method was used, and significance was set at an adjusted P-value of <0.05 for BiNGO and <0.01 for WebGestalt (Benjamini and Hochberg method). Significant categories, driven by only two or less proteins, were discarded due to the high potential for false signals in such cases. S1 Fig outlines the overall study design of the amyloid interactome (S1 Fig).

Results and discussion

The study of the dynamics, structure and function of protein-protein interaction networks (PPINs) has proven crucial for the understanding of many biological phenomena [6063]. Hence, network theory is a sophisticated approach to study the puzzling phenomenon of amyloidogenicity. The amyloid interactome displays the interacting partners of in vivo amyloid forming proteins in a flat and detailed protein map (Fig 1). The results presented in this work, combine interactions from specialized networks of protein aggregation [34, 35, 3740, 64] and eventually, assemble a new set of functionally unconnected proteins into a network that would possibly fill the missing pieces of protein aggregation and shed light towards the exploitation of novel disease protein-targets.

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Fig 1. The amyloid interactome.

Interaction data for the creation of this network were gathered from the publicly available database IntAct [45] and Cytoscape [51] was used as a visualization tool (Interactive network available at http://83.212.109.111/amyloid_interactome). The network consists of 353 nodes and 1178 edges. Proteins are depicted as nodes and interactions as edges. Red-coloured nodes represent known in vivo amyloidogenic proteins, whereas yellow-coloured nodes represent in vitro amyloid-forming proteins or proteins related to amyloid fibril formation (see also Tables 1 and 2). Green-coloured nodes are proteins, listed as other interaction partners. Hubs and bottlenecks are depicted as triangles (▲) and squares (■), respectively. Protein-nodes, which are both hubs and bottlenecks are shown as diamonds (◆). Important molecular chaperones are highlighted with a blue outline.

https://doi.org/10.1371/journal.pone.0173163.g001

Construction of the amyloid interactome

In an effort to build the human amyloid interactome, in vivo amyloid-forming proteins were obtained from a peer-review library, published by Sipe et al. [2] (Table 1). Overall the protein-protein interaction network contains 353 protein nodes and 1178 protein-protein interaction edges, between them (Fig 1). Surprisingly, among the proteins listed in the network, 23 amyloidogenic proteins construct a giant connected component (Fig 1, red nodes), whereas 13 proteins (Fig 1, yellow nodes), recorded as in vitro amyloid-forming proteins and proteins related to amyloid fibril formation (S1 Table), are also identified. A list of these significant proteins is available in Table 2. Among them, proteins forming intracellular inclusions bodies were reported (Tau, Actin, NACP, HD) [2], while proteins, found as co-deposits in the Alzheimer’s disease, emerged (Apo-E, PS-1, PS-2, Tau) [65].

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Table 2. The dataset of 13 proteins related to amyloid fibril formation.

https://doi.org/10.1371/journal.pone.0173163.t002

Notably, APro, an anterior pituitary hormone known to self-assemble into amyloid fibrils [66], did not manage to join the giant connected component created by the other 23 amyloidogenic proteins in the network, whilst the only interactor identified was the prolactin receptor (Fig 1, right). This “detachment” of an important hormone together with the absence of AIAPP should receive a renewed emphasis [67]. Namely, for AIAPP no experimental verified partners were recorded, since only speculative approaches attempted to describe possible interaction partners [68]. AA1 and AA2 proteins, which can form amyloid fibrils after partial proteolysis [69], are important components of the High Density Lipoprotein (HDL) complex [70]. However, direct interactions of AA1 and AA2 are not recorded in IntAct. Therefore, at first glance, the network which has emerged designates a correlation among the majority of otherwise unrelated in vivo and also in vitro amyloidogenic proteins, along with proteins related to amyloid fibril formation.

Network analysis based on graph theory

One of the most fruitful approaches to extract relative biological conclusions from the structure of the amyloid interactome is to computationally calculate its topological parameters.

Simple topology parameters.

An assessment of simple topology parameters revealed intriguing information. A random graph with the same number of nodes and edges has been used as a “null model” to draw conclusions regarding certain topological traits of our network. In general, small-world graphs describe networks, where nodes can be reached from each other by traversing a small number of edges, and, thus their average path length is small and their clustering coefficient (transitivity) is high, compared to a random graph [71]. For the amyloid interactome, both the clustering coefficient (CC = 0.187) and the characteristic path length (CPL = 3.083) are higher and lower, respectively, than those of the corresponding random graph (CC = 0.003, CPL = 3.290), signifying that a small number of steps is needed, for one amyloidogenic protein to reach another. For example, Aβ can “reach” ATTR, by crossing AApoAI in only two (2) steps, verifying experimental data which pinpoint ATTR as a promising biomarker of the Alzheimer’s disease [72] (Fig 1, top). Furthermore, measuring the density of our network (0.019), a value lower than 0.1 was recorded, a result in accordance with other sparsely connected biological networks [73]. Since our network complies with all these criteria, we can safely conclude that it has small-world properties [74].

Complex topology parameters.

In addition to having small-world features, biological networks are commonly scale-free [75]. The most important parameter to gain an insight on the scale-free nature of a biological network is the node degree distribution [76]. In our case, the distribution is of the following form: (1) decaying as a power law (P(k) ~k). According to this finding, the network has scale-free properties [76] and specifically it consists of a few hubs (Fig 1, triangles and diamonds) connected with multiple nodes (S2A Fig). More importantly, hubs (S2 Table) seem to play a crucial role in our network, since the degree exponent (γ) is lower than 2 [77]. Generally, networks enriched with hubs, are robust against random node deletions [78, 79] as these disturbances do not affect the average path length severely (S2D Fig). Nevertheless, the removal of particular hubs, such as the Aβ or APrP (Fig 1), can drastically alter the average path length and so, our network can be generally addressed as ‘robust yet fragile’ [80].

As shown in Fig 1, several proteins act as “bridges”, immediately connecting many, otherwise distantly or unconnected proteins in the network, thus, increasing the network’s interconnectivity (Fig 1, squares and diamonds). The influence of these “bridging” proteins is expressed with high betweeness centrality values, indicating their role as bottlenecks, key connectors for the communication of other important proteins in the interactome, like hubs [81, 82] (S2B Fig). S3 Table introduces the top 20 bottlenecks of the interactome.

Among the topological parameters mentioned above, node degree, and betweenness centrality distributions were carefully studied. Fifteen protein-nodes were identified as both hubs and bottlenecks, whereas 5 proteins have high degree (hubs) and 5 proteins have high betweenness centrality (bottlenecks). Impressively, 6 out of the 23 in vivo amyloidogenic proteins have a major contribution on the interactome, demonstrating their crucial role in the network (S2 and S3 Tables). Additionally, the amyloid interactome has an average clustering coefficient distribution, that follows approximately the scaling law C(k) ~ k-1 (S2C Fig), indicating the ability of this network to form functional modules (clusters) with biological significance (See Clustering Analysis) [83]. Overall, the network analysis based on graph theory revealed that the amyloid interactome appears to be enriched with interactions between amyloidogenic proteins.

Finally, in order to further examine the role of selected and random perturbations in the stability of the amyloid interactome, we performed a “lethality” test [78]. A multistep procedure included the gradual removal of proteins, randomly (“failure”) and in descending order of node degree and betweeness centrality (“attacks”). The rapid increase in the network’s characteristic path length (CPL) during the targeted “attacks”, in contrast to the slow increase during its “failure”, puts emphasis on the significance of the removed proteins (S2D Fig).

The above analysis gave us valuable information regarding central components of the network (hubs and bottlenecks), ranging from single proteins to entire modules (S2 and S3 Tables). However, due to inevitable technical biases present in interaction data [84], all results produced from such analyses should be carefully examined. Aβ publication biases, for example, may lead to the overestimation of the role of certain constituents of the network, in expense of others. Graph theory based analysis combined with other validation approaches were utilized, in our case, to further address the aforementioned issues.

The amyloid interactome unravels interconnections between amyloidogenic proteins

In general, it is believed that disease-related proteins in a protein-protein interaction network are more interconnected than non-disease proteins [85], a claim in accordance with our findings. Fig 1 deciphers the complex interactions governing amyloidogenicity, by interconnecting well-characterized amyloidogenic proteins (red nodes) with a heterogeneous collection of proteins related to protein aggregation (yellow nodes). Nevertheless, it is possible to understand that not all proteins on the interactome were directly related, meaning that indirect links may occur. Consequently, amyloid forming proteins, such us Tau, NACP and HD, which were excluded from our initial seed-dataset (See Materials and methods), were ultimately retrieved during the interactome construction process (S3C Fig).

Impressively, the interaction network consolidates a number of human proteins, which have been shown to form amyloids in vitro. Frequently, in vitro aggregation assays are oriented towards protein segments, responsible to drive proteins from their native structure to the amyloid state, in place of full-length proteins [86]. Evidence at experimental level prove that “aggregation-prone” segments are indeed sufficient to lure a protein precursor into forming typical amyloid fibrils, and thus, these full-length protein precursors are characterized as “amyloidogenic” [87]. Interconnections between in vivo (red nodes) and in vitro amyloid forming proteins or protein segments (HspB5, Apo-CII, PS-1, PS-2, Spectrin, See Table 2) may extend biological expectations, related to protein-aggregation (S3A Fig).

Looking deeper into the crowded topography of the amyloid interactome, a great variety of “amyloid-binding proteins” is included. These amyloid specific molecules are basically a list of divergent proteins, capable of interacting with assemblies, derived from amyloidogenic proteins [8890]. A broad range of Aβ contributors, for example, includes molecular chaperones or co-chaperones, apolipoproteins and other amyloid-forming proteins, enhanced with various functional characteristics. Since cells have adapted a mechanism to avoid the accumulation of incorrectly folded proteins, the Gene Ontology (GO) term [59] enrichment analysis in the entire interactome revealed the overrepresentation of GO terms regarding regulatory mechanisms (positive or negative regulation), while the most important GO term recorded is “response to stress” (GO ID: 6950) (S4 Table and S4A Fig). In particular, knowledge of the biological role of non-amyloidogenic hubs and bottlenecks in our interactome (S3B Fig), is gathered and shown in S5 Table. As expected, proteins highly interconnected are involved in signal transduction and in several metabolic processes. Impressively, though, a vast amount of topologically important proteins is related with stress pathways, highlighting possible novel disease protein targets, mediating amyloidogenicity (See Rational Design of Protein Inhibitors).

The most abundant interaction detected is the one between amyloidogenic proteins and well-known regulatory proteins, the so-called chaperones (Fig 1). As Fig 1 illustrates, chaperones together with co-chaperones dynamically participate in the interactome (nodes with blue border). This finding was, more or less, an expected phenomenon, since molecular chaperones are molecules dedicated to suppress amyloid formation [91, 92] and usually have many interactors [93]. The expert review, by Yerbury & Kumita, presents an extended group of amyloid-specific chaperones and discusses their implications [94]. Our interaction network, apart from validating existing data, demonstrates that chaperones exhibit high connectivity and at the same time high betweeness centrality, meaning that a sudden removal of such a node would result to the elimination of many important interactions in the network (Fig 1 and S2D Fig). These findings are in accordance with previously published interaction networks, associated with aging [95] or stress [96], where chaperones participate as special constituents.

Clustering and functional enrichment analysis

Clustering analysis.

The core of our study is the Amyloid Interactome, an interaction network represented as a large interconnected network with embedded functional sub-networks. Consequently, in order to further evaluate functional modules, a network clustering analysis was performed, utilizing the MCL algorithm [97]. The network was divided in 20 clusters, 11 of which composed of three or more nodes (Fig 2), while 9 contained only two proteins and were not further analyzed. The inflation value of 1.8 allowed the creation of compact clusters, preventing the network’s fragmentation.

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Fig 2. Clustering analysis of the amyloid interactome.

The 11 clusters with 3 or more nodes of the amyloid interaction network, derived utilizing the MCL algorithm [97]. Cytoscape [51] was used as a visualization tool. The visual legend summarizes the shortcuts of node colour and node shape (See also Fig 1). The highly connected subnetwork of the first cluster within the amyloid interactome reveals the strong affinity between 7 amyloidogenic proteins (cluster 1—red nodes) and the integral representation of the proteins presented in Table 2 (cluster 1—yellow nodes) (Interactive cluster subnetworks available at http://83.212.109.111/amyloid_interactome).

https://doi.org/10.1371/journal.pone.0173163.g002

The most important cluster, retrieved after the MCL implementation, consists of 186 protein-nodes (Fig 2, cluster 1). The results revealed the strong association between 7 in vivo amyloidogenic proteins (Fig 2, cluster 1—red nodes) and 13 proteins related to amyloid fibril formation (Fig 2, cluster 1—yellow nodes). Impressively, the full list of proteins included in the amyloid interactome and recorded as in vitro amyloid forming proteins or proteins related to amyloid fibril formation (Table 2), is solidly represented in this first cluster. This finding further validates the strong interconnection observed in our initial interaction network (Fig 1), implying that all these 13 proteins are likely important determinants of protein aggregation.

Notably, the most important subgroup of our interaction network (Fig 2, cluster 1) includes direct or indirect well-known amyloidogenic interaction partners of Aβ. Namely, amyloid forming Apolipoproteins (AApoAI, AApoAII) are catalytic binding partners [98], whereas ACys [16, 99] and AGel [100, 101] prevent Aβ from accumulation. Moreover, Aβ cooperated with 9 (HspB5, Spectrin, Actin, PS-1, PS-2, ApoE, CASP-3, Tau, NACP) out of the 13 proteins of Table 2, both in the entire network and the fragmented network, a finding that might stimulate new ideas about the nature of Aβ interactions.

The amyloidogenic proteins, APrP and AKer are located in the second cluster, together with Clusterin (Fig 2, cluster 2—node with blue border), an extracellular chaperone, present in disease-associated extracellular amyloid deposits [102] and a proteasome functional subunit (Proteasome subunit alpha type-3). The absence of Clusterin from cluster 1, though, has prompted increasing interest, since the well-studied molecular chaperone is an existing protein target for the Alzheimer’s disease and so, we would expect a strong correlation with Aβ [103]. Nevertheless, MCL algorithm results point toward a possible relationship between Clusterin and Aker or APrp, a finding that remains to be elucidated. Additional proteins of this cluster are associated with transcriptional regulation and pre-mRNA splicing, since the over-expression of prions influences normal cellular proteins, participating in apoptosis or cell signaling [104]. Transthyretin, a potent inhibitor of Aβ [72], created a separate cluster together with Small ubiquitin-related modifier 3. The remaining complexes, consist of less than 7 nodes, where, with the exception of cluster 4, each one contains only one amyloidogenic protein (Fig 2, clusters 4–11).

Functional enrichment analysis.

Functional interpretation of the data, derived from each cluster, was performed using BiNGO [57] and thus, statistically significant GO terms [59] were obtained for three functional categories (biological process, molecular function and cellular component). Due to the excess of information derived from this analysis, terms with great statistical and biological significance were manually selected to functionally characterize each cluster. Importantly, as mentioned before, similar subcategories with the entire network analysis resulted from the cluster functional analysis, and “response to stress” was the most significant function in the majority of the clusters (details of cluster 1 GO enrichment are shown in S6 Table). Therefore, it is apparent from all the above results that the amyloid interaction map locates in “spatial proximity” proteins related to stress (chaperones, co-chaperones and amyloidogenic proteins), which arise as a response to pathological conditions [88] (S4B Fig). Nevertheless, biological systems are dynamic, meaning that a complex succession of events may occur over the course of time, in contrast with a protein-protein interaction network. Therefore, certain events described on the amyloid interactome are based on a static system and thus, this analysis could produce certain artificial results that should be addressed carefully to draw biologically significant conclusions.

Pathway analysis and disease association.

KEGG pathway analysis was performed, in an attempt to detect common metabolic pathways, in which the network’s proteins participate. A complex series of signaling pathways including the MAPK signaling pathway, B-cell and T-cell signaling pathways and the insulin signaling pathway are associated with the network’s proteins. Additional disease association analysis, conducted with WebGestalt [105], revealed significant associated disorders for every cluster. In the first cluster (Fig 2), for example, Tauopathies, Dementia and Alzheimer’s disease constitute the most significant group of pathologies. Pinpointing the components of such disease pathways is a promising perspective and thus, a detailed analysis and a novel joined network of diseases related to amyloidoses is currently being under construction (research article in preparation).

It is important to note that a delicate feature of our interactome, and its subsequent fragmentation, is the vast amount of experimental data on Aβ peptide polymerization, owing to the worldwide prevalence of the Alzheimer’s disease and the shortage of data on other less studied amyloidogenic proteins.

Rational design of protein inhibitors

Moving a step forward it seems interesting to investigate the correlation between biological factors, participating in the amyloid interactome that could influence amyloidogenicity. To determine whether significant elements of the amyloid interactome might indicate common properties of good candidates to be targeted by therapy, hubs and bottlenecks were thoroughly examined (Fig 3).

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Fig 3. Subnetworks of molecular chaperones participating in the amyloid interactome.

3 important subnetworks were isolated from the entire amyloid interactome: (A) Subnetwork of Hsp90 co-chaperone Cdc37, Hsc70-interacting protein, Hsp 90-alpha, Hsc71 and their first neighbors, (B) Subnetwork of Serum albumin and Hsc70-interacting protein and their first neighbors and (C) Subnetwork of Clusterin, Large proline-rich protein BAG6 and their first neighbors. The aforementioned proteins, having chaperone or co-chaperone activity, were found to play a pivotal role in the integrity of the interactome (See section Network Analysis Based on Graph Theory). A highly selective and direct correlation of Serum albumin and 6 amyloidogenic proteins was observed (B), whereas indirect interactions between Serum albumin and 2 amyloidogenic proteins were recorded (A). Hsc70-interacting protein is a significant element of the interactome, since it conciliates interactions between Apolipoproteins and ACys or ATTR (A,B). Clusterin synergistically with Large proline-rich protein BAG6 interferes with APrp and Aβ2M (C). The finding that more than one chaperones mediate the interconnection between different amyloidogenic proteins deserves further investigation.

https://doi.org/10.1371/journal.pone.0173163.g003

An important group of proteins, dynamically participating in the interactome, is the group of molecular chaperones (S3D Fig). Their active role in controlling protein aggregation and their close relation to amyloidogenic proteins is the “hidden weapon" of the protein machinery and the reason why 4 out of 9 chaperones were recorded as hubs and bottlenecks in the amyloid interactome (Fig 1). The transient nature of real-time interactions between chaperones and their partners, though, results in unrealistic low connectivity, in signaling and mitochondrial protein–protein interaction networks [106].

Contradictory theories on whether chaperones are “guilty or innocent” during the protein aggregation process provoke an intense debate. In particular, several experimental studies revealed the co-localization of chaperones with various amyloidogenic proteins [107, 108], whereas other experimental work reported on the inhibitory properties of chaperones, when added during fibrillation [102, 109, 110]. Impressively, molecular chaperones have been shown to inhibit the formation of amyloid fibrils even when present at extremely sub-stoichiometric ratios, comparing to amyloid forming protein [111]. Fig 3 illustrates the interaction partners of selected molecular chaperones, prospect for the rational design of aggregation inhibitors. All characteristic path lengths for the subnetworks shown in Fig 3 are reduced approximately by one degree, in comparison with those of the entire amyloid interactome (CPL ~ 2.4). This result quantifies the great importance of chaperones as mediators of communication between amyloidogenic proteins.

Plasma proteins, on the other hand, is another promising group of protein-targets, considering that it includes proteins with many interaction partners, which have a wide range of physiological functions. Noteworthy, this group of proteins contains significant amyloidogenic components of the amyloid interactome, such as ATTR and Aβ2M. Among them, Serum albumin is a co-chaperone with significant topological features in the amyloid interactome, since it acts both as a hub and a bottleneck (Fig 3A and 3B). As Fig 3 illustrates, Serum albumin interacts directly or indirectly with in vivo amyloidogenic proteins and proteins related to amyloid fibril formation (See Fig 3 legend for details).

Normally, Albumin is a prevalent transporter of human plasma, known to carry a wide range of molecules, but under in vitro conditions was found to self-assemble into typical amyloid fibrils [112]. Nevertheless, it is worth mentioning that Serum Albumin was absent from our initial non-redundant list of amyloidogenic proteins (S1 Table), since such an entry was not found recorded neither in our literature sources nor deposited in AmyLoad or UniProtKB. Despite the “aggregation-prone” nature of Albumin, the presence of this plasma protein promotes neuronal survival [113] or inhibits amyloid fibrillation in in vitro designed experiments [114], while according to the proteomic analysis, conducted by Hye et al., is an eligible biomarker for the Alzheimer’s Disease [115]. Therefore, because of its central role in the interactome (Fig 3A and 3B) and the previously recorded features as a potent inhibitor of fibrillation, it seems that human plasma Albumin is a challenging molecule, which might stimulate new ideas about the design of anti-amyloid drugs.

From the above discussion, we pinpointed hubs as the most competent candidates regarding the therapeutic intervention of amyloidogenicity. Opposing studies, though, suggest that proteins with low connectivity would be more efficient therapeutic targets for neurodegenerative diseases, since hubs are generally considered as “elegant features” for the robustness of an interactome [35]. Therefore, our computational approach should be followed by a variety of in vitro, cellular and in vivo experiments, in order to verify our speculations.

Conclusions

Given the complexity of the molecular mechanisms driving amyloid fibrillation, a frequently used strategy is directed towards studying amyloidogenicity at molecular level, although, this approach is not always feasible, due to the dynamics of protein misfolding. In this study, we attempted to answer the crucial question of amyloidogenicity, following the principles of systems biology, by assembling a group of “miscellaneous” proteins into a common biological interaction network. The amyloid interactome illustrates a united interaction network of critical hypotheses, regarding the irregular protein aggregation, since it represents an integrated protein map of in vivo amyloidogenic proteins, together with in vitro amyloid forming proteins or proteins related to amyloid fibril formation. The amyloidogenic and non-amyloidogenic elements of the amyloid interactome eventually come together to form a complex “tapestry” of protein-protein interactions. Based on the complex network theory analysis, this network exhibits topological properties that are similar to other significant interaction networks. Surprisingly, our approach, apart from validating all previously experimentally verified direct or indirect protein interactions, allowed us to stress the importance of novel protein targets. Our integrated project has raised plentiful questions and could serve as the driving force to guide the experimental process in the challenging field of protein aggregation, even at the molecular level. Nevertheless, it should be addressed that the amyloid interactome was built based on the current knowledge of protein-protein interactions, meaning that there is a “publication bias” between over and understudied amyloidogenic proteins. Individual proteins should be carefully validated, utilizing the appropriate methodology, in order to enhance the significance of our observations. Therefore, the strength of the amyloid interactome lies in the perspective to identify key mediators of amyloidogenicity that could be targeted therapeutically.

Supporting information

S1 Fig. Study design workflow of the amyloid interactome.

An overview of the basic protocol, used to create and analyze the amyloid interactome.

https://doi.org/10.1371/journal.pone.0173163.s001

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S2 Fig. Distributions for three complex topological parameters of the amyloid interactome and results from “Lethality Testing”.

(A) Node degree distribution in log-log plot. The red line shows that the distribution decays as a power law (P(k) = 117.86k-1.236). Nodes on the upper left corner of the chart (high node degree) are hubs in the amyloid interactome. (B) Betweenness centrality distribution with the horizontal axis in a logarithmic scale. Nodes on the right quarter of the chart (high betweeness centrality) are bottlenecks in the network. (C) Average clustering coefficient distribution. The red line shows that it follows approximately the scaling law (C(k) = 0.816k-0.647), designating the network’s ability to form clusters. (D) Lethality testing. This chart shows the effect of the gradual removal of random nodes (blue circles) and the gradual removal of hubs (black triangles) and bottlenecks (grey squares), on the Characteristic Path Length (CPL) of the network (For detailed discussion please refer to Results and discussion section).

https://doi.org/10.1371/journal.pone.0173163.s002

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S3 Fig. Detailed features of the amyloid interactome.

(A) Interactions between in vivo amyloidogenic proteins (red-coloured nodes) and in vitro amyloid forming proteins or proteins related to amyloid fibril formation (yellow-coloured nodes). (B) Yellow-coloured nodes represent in vitro amyloid forming proteins or proteins related to amyloid fibril formation and are a delicate feature of the amyloid interactome. (C) Representation of the key role of non-amyloidogenic hubs and bottlenecks in the amyloid interactome. Triangles are proteins acting as hubs, squares are proteins acting as bottlenecks and diamonds are proteins acting as both. (D) Nodes with blue borders represent proteins characterized as chaperones or co-chaperones (Interactive network available at http://83.212.109.111/amyloid_interactome).

https://doi.org/10.1371/journal.pone.0173163.s003

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S4 Fig. GO functional analysis of enriched terms in the biological process ontology for the entire amyloid interactome and the first cluster.

Functionally grouped networks of enriched categories were generated both for the amyloid interactome (A) and cluster 1 (B). GO terms are represented as nodes. The colour gradient of each circle corresponds to the p-value of the associated GO term. White-coloured nodes are not statistically significant nodes, but are parent nodes of statistically significant GO terms. Different node sizes are indicative of varying frequencies of the proteins correlated with each GO term (See S4 and S6 Tables).

https://doi.org/10.1371/journal.pone.0173163.s004

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S1 Table. The non-redundant, detailed catalogue of in vivo and in vitro amyloidogenic proteins or peptide fragments or proteins related to amyloid fibril formation.

This extended list of proteins includes proteins known to self-assemble into typical amyloid fibrils in vivo, along with intracellular inclusions with known biochemical composition, published by Sipe et al. in 2014 [2]. In addition to this, the list includes proteins which form amyloid fibrils in vitro [45], protein segments obtained from AmyLoad [5] and finally, UniProtKB entries [46] of proteins related to amyloid fibril formation. A UniProtKB Accession Number is provided for each protein. The original source library of each protein is tagged with a cross (+). The Digital Object Identifier (DOI) code is provided, when it is available (See Materials and methods).

https://doi.org/10.1371/journal.pone.0173163.s005

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S2 Table. The top 20 hubs of the amyloid interactome.

The 20 proteins with the highest node degrees are considered as hubs in the amyloid interactome. 6 of these proteins belong to the dataset of the amyloidogenic proteins, described in S1 Table, whilst the rest of the hubs exhibit numerous functions, acting mainly as chaperones, signal transducers or structural constituent of the cell (See Results and discussion).

https://doi.org/10.1371/journal.pone.0173163.s006

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S3 Table. The top 20 bottlenecks of the amyloid interactome.

The 20 proteins with the highest betweeness centralities are considered bottlenecks in the amyloid interactome. 6 of these proteins belong to the dataset of the amyloidogenic proteins, described in S1 Table. 15 bottlenecks exhibit high node degree values and are also considered as hubs in this network (S2 Table).

https://doi.org/10.1371/journal.pone.0173163.s007

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S4 Table. Amyloid interactome GO term enrichment. A p-value of 10E-14 was set as a gathering threshold for Biological Process and Cellular Component, whereas a value of 10E-8 was set as threshold for Molecular Function.

Proteins of the entire amyloid interactome were subjected to a GO term enrichment analysis using BiNGO [56]. The UniProtKB ACs of proteins that are characterized by overrepresented GO terms in the entire amyloid interactome are given in this table, along with their number and their frequency in the network. The adjusted p-value suggests the importance of these GO terms in the proteins of the amyloid interactome.

https://doi.org/10.1371/journal.pone.0173163.s008

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S5 Table. GO Terms enrichment of the 18 important, non-amyloidogenic hubs and bottlenecks identified on the amyloid interactome.

The majority of proteins, which are characterised as hubs and bottlenecks are involved in signal transduction and in several metabolic processes. The most abundant GO term, though, is response to stress, in accordance with the most represented group of the amyloid interactome (See S4 Table).

https://doi.org/10.1371/journal.pone.0173163.s009

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S6 Table. Enriched GO categories of Cluster 1, derived from the amyloid interactome. Enriched categories for Biological Process are those with p<10E-12, for Cellular Component with p<10E-14 and for Molecular Function with p<10E-8.

Proteins of the first cluster of the amyloid interactome were subjected to a GO term enrichment analysis using BiNGO [56]. The UniProtKB ACs of proteins that are characterized by overrepresented GO terms in this cluster are given in this table, along with their number and their frequency in the network. The adjusted p-value suggests the importance of these GO terms in the proteins of cluster 1.

https://doi.org/10.1371/journal.pone.0173163.s010

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S1 File. Web application user guide.

Detailed description of the structure of the interactive Amyloid Interactome–Web application is available at http://83.212.109.111/amyloid_interactome.

https://doi.org/10.1371/journal.pone.0173163.s011

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Acknowledgments

This project was financially supported by the Greek State Scholarships Foundation, through the Program: ‘‘RESEARCH PROJECTS FOR EXCELLENCE IKY/SIEMENS” (2015–2017).

Author Contributions

  1. Conceptualization: PLT KCN SJH VAI.
  2. Data curation: PLT KCN KVB.
  3. Formal analysis: KCN KVB.
  4. Funding acquisition: VAI.
  5. Investigation: PLT KCN KVB CVM.
  6. Methodology: PLT KCN.
  7. Project administration: SJH VAI.
  8. Resources: VAI.
  9. Software: KCN.
  10. Supervision: VAI.
  11. Visualization: PLT KCN KVB.
  12. Writing – original draft: PLT KCN KVB SJH VAI.

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