Abstract
One of the hallmarks of the most common neurodegenerative disease, Alzheimer’s disease (AD), is the extracellular deposition and aggregation of Amyloid Beta (Aβ)-peptides in the brain. Previous studies have shown that select metal ions, most specifically copper (Cu) and zinc (Zn) ions, have a synergistic effect on the aggregation of Aβ-peptides. In the present study, inductively coupled plasma mass spectrometry (ICP-MS) was used to determine the metal content of a commercial recombinant human Aβ40 peptide. Cu and Zn were among the metals detected; unexpectedly, nickel (Ni) was one of the most abundant elements. Using a fluorescence-based assay, we found that Aβ40 peptide in vitro aggregation was enhanced by addition of Zn2+ and Ni2+, and Ni2+-induced aggregation was facilitated by acidic conditions. Nickel binding to Aβ40 peptide was confirmed by isothermal titration calorimetry. Addition of the Ni-specific chelator dimethylglyoxime (DMG) inhibited Aβ40 aggregation in absence of added metal, as well as in presence of Cu2+ and Ni2+, but not in presence of Zn2+. Finally, mass spectrometry analysis revealed that DMG can coordinate Cu or Ni, but not Fe, Se or Zn. Taken together, our results indicate that Ni2+ ions enhance, whereas nickel chelation inhibits, Aβ peptide in vitro aggregation. Hence, DMG-mediated Ni-chelation constitutes a promising approach towards inhibiting or slowing down Aβ40 aggregation.
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Introduction
Alzheimer’s disease (AD), discovered more than a century ago by Lois Alzheimer1, is the most common cause of dementia in many elderly people, as well as in individuals with Down syndrome who survive beyond age 50. AD is a major health problem, in the United States and the rest of the world. According to the most recent national vital statistics report available in the USA (year 2017), AD is estimated to be the fifth cause of death for people aged 65 and over, and the third cause of death for people aged 85 and over, behind heart disease and cancer2. In the absence of a cure, and because of the overall aging population, a study from the Alzheimer’s Association predicts that by mid-century 13.8 million Americans will live with the disease, with one new case of AD developing every 33 s, resulting in nearly 1 million new cases per year. Based on the time of onset, AD is classified into two types: early-onset AD (EOAD), which typically develops before the age of 65, and late-onset AD (LOAD) for those older than 653. In addition to intraneuronal tangles of hyperphosphorylated tau (τ) protein4, one hallmark of AD is characterized by various pathological markers in the brain, including accumulation of Amyloid Beta (Aβ) protein (in the form of senile plaques), as first proposed by Hardy and Higgins in a landmark study known as “the amyloid beta cascade hypothesis”5. Sequential proteolysis of the amyloid precursor protein (APP), an ancient and highly conserved protein6, by β-secretase and γ-secretase enzymes yields Aβ peptides of various lengths (38, 40 or 42 amino acids), depending upon the exact site of cleavage by the γ-secretase7. While the most abundant Aβ peptide is Aβ40, the most toxic is Aβ428. The release of Aβ peptides is a normal physiological process. Indeed, not only Aβ peptides are naturally present in both the brain and the cerebrospinal fluid throughout the life of an individual9,10,11, they are also produced by cultured cells during normal metabolism12. However, once Aβ peptides form filamentous aggregates (e.g., amyloids), not only can they propagate their abnormal structures to the same precursor molecules (seeding), they can also propagate to other protein monomers (cross-seeding), such as that involved in Parkinson’s or Type 2 diabetes diseases13.
Alzheimer’s disease occurs sporadically in most cases; however, a sizable number of cases can be linked to mutations in various genes. For instance, mutations in the APP gene, or in genes encoding for enzymes involved in the APP processing (e.g. PSEN1 or PSEN2), are predominantly associated with EOAD, whereas mutations in genes encoding for enzymes related to Aβ turnover, such as the apolipoprotein E (e.g. APOE), are usually associated with LOAD14,15. Besides genetic factors, environmental factors have been shown to play a role in AD, as revealed by a study on twins16. Environmental factors include toxic gases, such as CO, CO2, SO2 and NO217, or metals, several of which have been shown to play a role on Aβ aggregation, fibrillization and toxicity, with potential implications on the progression of AD (for a recent review, see Liu et al.)18. The list includes heavy metals, such as aluminum (Al)19, cadmium (Cd)20 and mercury (Hg)21,22, and essential metals, such as copper (Cu) and zinc (Zn), and, to a lesser extent, iron (Fe)23. The role of Cu(I), Cu(II), or Zn(II) has been well documented24,25,26. Firstly, both Aβ40 and Aβ42 peptides have been shown to bind Cu(II) or Zn(II) with significant affinity in vitro, leading to Aβ aggregation19,27,28,29,30; secondly, a similar effect was observed in vivo, leading to plaque build-up and toxicity in AD animal models, for instance with Cu(II) in rabbits31, or with Zn(II) in mice32; thirdly, post-mortem analysis revealed that respective Cu, Fe and Zn levels in plaques of AD brains were 5.7, 2.8, and 3.1-fold higher compared to normal brains33; fourthly, accumulation of Cu and Zn co-localized with Aβ peptide deposits34. Taken together, these results have given birth to a theory known as the “metal hypothesis of AD”, that links metal homeostasis (especially that of Cu, Fe and Zn) and AD35. Recent discoveries on Aβ peptides-lipid interactions have confirmed the importance of metals in the onset and progression of AD: Aβ peptides can associate with cellular membranes, and Aβ-bound metals (especially Zn and Al) can blockade and disrupt Ca2+ channels, leading to neurotoxicity.
The logical follow up to these observations was the use of chelators to inhibit Aβ peptide aggregation, with the long-term goal of using metal chelation as therapeutic strategy for AD36. This research avenue has been investigated by several groups, with mixed outcomes. Chelators, such as EGTA, “tpen” (N,N,N′,N′-tetrakis(2-pyridyl-methyl) ethylene diamine), and bathocuproine have been shown to solubilize Aβ plaques from post-mortem brain tissue37. The 8-hydroxyquinoline derivatives Clioquinol and BPT-2, two copper-zinc chelators, have shown promising results in vitro35,38. Being able to cross the blood–brain-barrier (BBB), both have been tested in clinical trials, unfortunately the results appear inconclusive39. In another unrelated clinical trial, the rate of decline of daily living skills was significantly reduced in AD patients given desferrioxamine intramuscular twice daily for two years40. The authors originally attributed this effect to aluminum chelation, however desferrioxamine binds preferentially to iron (also copper and zinc, albeit with lower affinity); hence it is hard to draw firm conclusions about this trial. Alternative ways to target and modulate the toxicity of metal-bound (or metal-free) Aβ species include the use of (i) glycosylated polyphenols and their esterified derivatives, which present the advantage of using natural low toxicity compounds41; (ii) synthetic flavonoids and amino-isoflavones, which have shown promising results towards targeting metal sites42; (iii) small molecules, such as N1,N1‐dimethyl‐N4‐(pyridin‐2‐ylmethyl)benzene‐1,4‐diamine (“L2-b”) and its derivatives43,44; (iv) β-sheet breakers, which are small peptides (five amino-acids long) effective in reducing the Aβ1-40 aggregation, even in the presence of metal ions45.
In contrast to Cu, Fe and Zn, which are required cofactors for hundreds of enzymes, and fairly abundant in animals and humans46, nickel (Ni) does not appear to be needed in mammals, as mammalian hosts do not contain known Ni-dependent enzymes47. Furthermore, Ni levels are low, with less than 5 ppm (μg/g of ash) in most human organs, corresponding to less than 1% of the amount of Zn measured in the brain, heart, lung, or muscle, and less than 0.1% of the amount of Zn in the liver and kidney48. Even though Ni is rarely mentioned in association with Aβ peptides, a potential role for this transition metal should not be discarded. For instance, levels of Aβ40 and Aβ42 peptides were significantly increased (72–129%) in brains of mice exposed to a Ni-nanoparticle model of air pollution49, suggesting Ni might play a role in β-amyloid aggregation, at least in mice49. This finding prompted us to investigate the role of Ni in Aβ peptide aggregation, as well as the potential benefit of using the Ni chelator dimethylglyoxime (DMG) to slow down or even inhibit aggregation.
Results
Commercial recombinant Aβ 40 peptide contains metals, including copper, zinc, and nickel
Most Aβ peptide preparations used for in vitro aggregation studies are synthetic (e.g. chemically synthesized) or recombinant peptides (e.g. expressed in prokaryotic or eukaryotic organisms). To determine what type of metals is associated with commercial human recombinant Aβ peptide, a Aβ40 peptide preparation was subjected to a twenty-element ICP-MS analysis (Table 1). Aluminum, copper, manganese and zinc were among the metals found in the Aβ40 peptide preparation, whereas iron was not detected. Surprisingly, the most abundant element associated with the recombinant Aβ40 peptide was selenium, followed by nickel (1 mg of Ni per g of Aβ40 peptide, corresponding to 0.073 moles of Ni per mole of peptide). Taken together, these results suggest that the recombinant Aβ40 peptide used in this study is already metal-bound upon commercialization; metals may be acquired during bacterial expression in the host (E. coli), during the purification process, or both. To our knowledge, it is the first time nickel is found in a commercial recombinant Aβ40 peptide purified preparation, suggesting the peptide (or aggregated peptides) can naturally coordinate the transition metal nickel, in addition to other metals such as aluminum, copper, manganese, selenium and zinc. The metal content of all the other kit components, including TBS, thioflavin and NaOH (used to resuspend the peptide) was also analyzed by ICP-MS (Table S1). Aluminum, manganese, iron, nickel copper, and zinc were detected in these components, however no selenium was detected. Besides, the bulk of nickel in the assay (reaction mix) was brought by the peptide (> 22-fold more Ni in Aβ40 compared to other kit components, see Table S1).
Addition of nickel enhances Aβ 40 peptide aggregation
To determine the effect of nickel on Aβ40 peptide aggregation, a thioflavin-(ThT)-based aggregation kit was used in absence or presence of supplemental Ni(II) (Fig. 1 and Table 2). In absence of supplemental metal, a moderate but steady increase in Aβ40 peptide aggregation was observed (average fluorescence rate of 152 RFU/min, Fig. 1). We hypothesized this might be due to the intrinsic presence of metallic ions, including Cu2+, Ni2+ and Zn2+, as revealed by the ICP-MS metal analysis conducted in the present study (see above). Addition of 10 µM NiSO4 to the mixture increased the average aggregation rate by 2.5-fold (Table 1), while addition of 100 µM NiSO4 resulted in a dramatic 5.7-fold increase compared to the no supplemental metal control, suggesting the divalent cation Ni2+ can bind to the Aβ40 peptide and enhance its aggregation (Fig. 1 and Table 2). A similar effect was observed when NiCl2 was used (instead of NiSO4) as source of Ni2+ (data not shown); hence, the nature of the counterion does not appear to play a role in (or interfere with) the observed aggregation. Upon addition of 10 and 100 µM Zn(II), a fivefold and 14-fold increase in Aβ40 peptide aggregation rate was observed compared to the control, respectively (Table 2), in agreement with previously published studies27,28,29; in contrast, addition of 10 or 100 µM CuSO4 had no significant effect on the aggregation rate (Table 2). This result (lack of aggregation) could be due to the pH used in our study (pH 7.4). Indeed, Cu has been shown to induce Aβ40 peptide aggregation at acidic pH30, while at neutral pH it is known to promote mostly soluble dimers50.
Addition of DMG inhibits Aβ40 peptide aggregation
Addition of 100 µM of the Ni-specific chelator DMG in absence of supplemented metal severely reduced Aβ40 peptide aggregation, by 40 to 85% depending on experiments (Table 2). Furthermore, addition of 500 µM or 1000 µM DMG led to partial or full inhibition of the aggregation; in the latter case, we measured flat or even decreasing average fluorescence rates (reported as < 1% of control, Table 2). Hence this dose-dependent inhibitory effect suggests that (i) DMG is able to pull metals away from the Aβ40 peptide and (ii) the Aβ40 peptide aggregation observed in absence of supplemented metals is likely due to the intrinsic presence of metallic ions (including Ni2+) within the recombinant peptide preparation, since the addition of the chelator leads to inhibition. When increasing amounts of DMG were added to the reaction mixture in presence of 100 µM Ni2+, Cu2+ or Zn2+, results with mixed outcomes were obtained. Complete inhibition was observed in presence of Ni (Fig. 1 and Table 2) and only partial inhibition was seen in presence of Cu or Zn, however Zn was still able to induce Aβ40 peptide aggregation (Table 2). The respective efficacy (or lack thereof) of DMG in presence of Cu, Ni and Zn correlates with the chelator’s respective affinity for each metal, as revealed by mass spectrometry analysis of metal-DMG complexes (see below).
Effect of pH on Aβ40 peptide aggregation in presence of metals or DMG
To study the effect of pH on Aβ40 peptide aggregation (in presence of metals or DMG), additional ThT-based aggregation experiments were conducted at pH 6.5, 7.5 or 8.5, with 25 µM Aβ40, in absence or presence of NiSO4 (25 µM), CuSO4 (25 µM), ZnSO4 (10 µM), or DMG (100 µM) (Fig. 2 and data not shown). Overall, aggregation rates at alkaline pH 8.5 (black symbols) were lower compared to pH 7.5 (grey symbols) or pH 6.5 (white symbols). As previously observed, addition of Zn(II) led to the fastest and sharpest increase in fluorescence (triangles) under all pHs tested. Interestingly, Ni(II)-induced aggregation (squares) was faster at pH 6.5, compared to pH 7.5, while it was absent at pH 8.5 (black squares). Aβ40 peptide aggregation in presence of Cu(II) or DMG was negligible under all 3 pH conditions tested (data not shown).
Nickel binding to human recombinant Aβ40 peptide is confirmed by isothermal titration calorimetry
Isothermal titration calorimetry (ITC) has been already used to analyze copper or zinc binding to various Aβ peptides, including Aβ4051,52,53. In the current study, we used ITC to determine whether nickel can bind to the Aβ40 peptide. The peptide (same used in ThT-based aggregation assays) was present in the sample cell at a concentration of 20 μM. Twenty injections of NiSO4 (1 mM solution, 5 μM increments in sample cell) were performed every 5 min under constant stirring (350 rpm) at 25 °C, and the heat release was measured (Fig. 3). The heat release profile indicates Ni binding to the peptide (Fig. 3, top Panel). The best fit of Ni titration (Fig. 3, bottom Panel) suggests an apparent stoichiometry of less than 1 mol Ni(II) per mole of Aβ40 peptide (~ 0.7), in range with previously reported stoichiometry ratios of 1:1 for Cu(II) or Zn(II), and Aβ4054. The apparent Kd value for Ni is approximately 4.2 μM, similar to that previously reported of 7 ± 3 μM for Zn53. Furthermore, the ΔH (enthalpy) and ΔS (entropy) were found to be − 5 kJ/mol and 86 mol/J/K, suggesting the Ni-Aβ40 binding event can be considered both exothermic and spontaneous. Injection of DMG (instead of nickel) into the sample cell containing Aβ40 peptide did not induce any significant change, indicating that DMG cannot bind to the peptide (data not shown). Hence, this result suggests the inhibitory effect of DMG on Aβ40 peptide aggregation, as observed with ThT-based assays, is due to nickel chelation, rather than direct DMG-Aβ40 peptide inhibitory interaction.
DMG-metal complexes can be detected by FTICR-MS
Aqueous solutions containing only DMG, or DMG in combination with Ni, Cu, Fe, Se or Zn salts were analyzed using Fourier Transform Ion Cyclotron Resonance Mass Spectrometry (FTICR-MS). In absence of added metal, two monomeric isoforms were detected, corresponding to either DMG, H+ (117.06585 m/z) or DMG, Na+ (139.04780 m/z) (Supplementary Fig. S1). In presence of Ni, complexes consisting of two DMG and one Ni, with either H+ (289.04412 m/z) or Na+ (311.02607 m/z) were detected. This was expected, as two DMG are required to chelate one Ni (Supplementary Fig. S1). Surprisingly, FTICR-MS analysis of a DMG-Ni aqueous solution further revealed the presence of [DMG]4-(Ni)2 complexes, mostly in the Na + form (599.06292 m/z) (Supplementary Fig. S1). While [DMG]2-Cu complexes were identified, only monomeric DMG (H+ or Na+) was observed in presence of Fe, Zn or Se; no dimeric or tetrameric DMG-Se or DMG-Zn complexes could be detected, suggesting DMG does not coordinate with Fe, Zn or Se (Supplementary Fig. S1).
Analysis of DMG in brain samples using FTICR-MS and NMR
The fact that DMG inhibits Aβ40 peptide aggregation in vitro suggests it might be able to do the same in vivo, however DMG would first need to cross the blood-brain barrier (BBB). To determine whether DMG can localize to the mouse brain, we used FTICR-MS (see above) and Nuclear Magnetic Resonance (NMR). NMR was successfully used to detect DMG in the livers of mice subjected to daily oral doses (6. 1 mg) of aqueous DMG for 3 days55. In the present study, the same treatment was administered (e.g. one daily oral delivery for 3 days), brain samples were processed and analyzed by NMR and FTICR-MS and compared to brain samples from (no DMG) control mice. Unfortunately, both methods failed to identify DMG (whether by itself or metal-chelated) in brain samples.
Discussion
To study Aβ peptide in vitro aggregation, one can choose to use either chemically synthetic peptides, or recombinant peptides, expressed in, and purified from, organisms such as E. coli. Synthetic Aβ preparations have been associated with various problems, such as presence of impurities in the preparation, incorporation of the L-form of amino-acids (e.g. D-His, D-Met, D-Arg) instead of the L-form during synthesis, or reproducibility issues in terms of quality and yield, to a point that even batch-to-batch variations have been reported56,57,58. On the other hand, the expression and purification of recombinant Aβ peptides also bring their own limitations and issues, including low yield, reduced solubility and presence of oxidized amino-acids (e.g. Met35-sulfoxide)58. One major difference between synthetic and recombinant Aβ peptides though, often overlooked in the literature, is the absence and presence of metals associated with each preparation, respectively. Indeed, any protein or peptide showing natural affinity for one (or several) metal(s), as it is the case with Aβ peptides for copper or zinc24, will likely encounter (and bind to) the metals within the host (E. coli or other hosts). Hence recombinant Aβ peptides are likely to be already associated with metals upon purification, in contrast to synthetic peptides. Given that both Cu and Zn enhance Aβ peptide aggregation, one can expect that Cu or/and Zn-containing recombinant Aβ peptide will be “naturally” more prone to aggregation than their synthetic counterparts. This could account for differences reported in a study by Finder and coworkers, who found that recombinant Aβ42 peptides (likely metal-bound) aggregated faster and were more neurotoxic than synthetic Aβ42 peptides (likely metal-depleted)58. In order to validate our hypothesis (e.g. recombinant Aβ peptides are metal-rich) we subjected a commercial recombinant Aβ40 peptide preparation to ICP-MS metal analysis. Results unambiguously showed the presence of various metals, including Al, Cu, Mn, Zn, Se and Ni, the two latter elements being by far the most abundant (ppm range). Additional metal analysis of other components of the commercial kit revealed the presence of Al, Cu, Fe, Mn, and Ni, but no Se; furthermore, components-associated Ni levels were negligible compared to the peptide-associated Ni levels. Metallic ions, more especially Cu(II) and Zn(II), have been shown to enhance in vitro aggregation of both Aβ40 and Aβ42 peptides19,27,28,29,30. Ni(II) can now be added to the list of Aβ peptide-aggregating metals, based on results from the present study. Indeed, our thioflavin-based assays revealed that Ni(II) enhance Aβ40 aggregation, whereas DMG-mediated Ni-chelation inhibits it . Moreover, Ni(II) was found to be more efficient than Cu(II), and less efficient than Zn(II), respectively, at promoting Aβ40 aggregation, under the conditions tested in our study. Since various parameters (such as pH and temperature) have been previously shown to have an effect on metal-induced aggregation30,59, we tested the effect of pH on Ni-dependent aggregation. Three buffers with similar salt content (192 mM NaCl) but various pHs (6.5, 7.5, or 8.5) were used. Interestingly, acidic pH (6.5) conditions increased Ni-induced aggregation compared to the control pH (7.5), whereas Ni-induced aggregation was abolished at pH 8.5. The increased Ni-induced aggregation at acidic pH, as observed in the present study, is in agreement with previous published data from Atwood et al., who reported an increase of Aβ1–40 aggregation in presence of 1 μM Ni at pH 6.6, compared to pH 7.430. Likewise, the same study correlated acidic pH (6.6) with enhanced aggregation, in presence of either Cu or Zn (both at 20 μM). Herein, Zn-induced aggregation was slightly higher at pH 7.5 compared to 6.5, and significantly faster compared to pH 8.5. The effect of pH on Cu-induced aggregation was negligible, but it is worth noting that the effect of Cu was very limited throughout our ThT-based assays, for a reason yet to be determined. The effect of temperature on Ni-dependent Aβ40 aggregation was not tested with the fluorescence-based method, as all assays were carried out at 37 °C. However, Ni-Aβ40 binding was also observed at 25 °C, as shown by ITC (see below). Although results obtained with both methods cannot be directly compared nevertheless we can report that Ni binding (to Aβ40) happens both at 25 °C and 37 °C.
Since aggregation in presence of a particular metal (e.g., nickel) suggests initial metal-peptide binding, we further investigated the likelihood of Ni binding to Aβ40, by using ITC. The calorimetry-based method has been successfully used in the past to study Zn binding to Aβ40, both at low (10 μM) and high (70 μM) concentrations53. In the current study, we only looked at the effect of Ni on low Aβ40 concentration, with a starting concentration of Aβ40 in the sample cell at 20 μM. After Ni was injected via 20 consecutive injections, every 5 min (5 μM increments), a heat profile characteristic of independent metal-binding was observed. Although the apparent Kd (4.2 μM) is similar to that reported for Zn53, the apparent stoichiometry (0.7 mol of Ni per mole of Aβ40) is significantly lower than that previously reported by Drochioiu and colleagues, who found that synthetic Aβ40 peptide displays high affinity toward nickel ions with up to three Ni2+ ions bound per Aβ40 peptide60.However, the discrepancy between our results and theirs could be due to the nature of Aβ40 peptide used, and the type of analytical method used to analyze Ni-Aβ40. In our study, we used a purified recombinant Aβ40 peptide, and ITC, whereas Drochioiu et al. used synthetic Aβ40 peptide, electrospray ion trap mass spectrometry (ESI–MS) and circular dichroism (CD). Nevertheless, results from both groups indicate that Aβ40 can bind nickel with high affinity. Furthermore, our results confirm that DMG inhibits Aβ40 aggregation through Ni chelation (not direct contact with the peptide), since titration of the peptide with DMG did not induce any peptide conformational change, as observed with ITC.
Given the presence of Cu2+, Ni2+, Zn2+ in recombinant Aβ40 peptide, combined to their respective effect on Aβ40 peptide aggregation, metal chelation therapy towards AD constitutes a valid approach. However, the risk of chelation therapy is that removal of essential metal ions will lead to serious adverse effects (for instance, iron-deficiency anemia) as pointed out by other researchers35. Hence it is preferable to use chelators with select affinity towards non-essential metals: the Ni-specific chelator DMG is therefore a good candidate. Indeed, DMG has been used for many years to detect, quantitate or decrease Ni levels in various environments; it can also be used to inhibit the growth of bacteria, including multidrug resistant Enterobacteriaceae, as recently demonstrated by our group55. Mammalian hosts do not contain known Ni-dependent enzymes, which makes Ni-chelation therapy an attractive approach47. On the other hand, most bacteria, including pathogenic ones, require nickel as cofactor for one or several enzymes, such as [Ni–Fe] hydrogenase(s)61 or urease47. Thus, DMG-mediated inhibition of these enzymes, as demonstrated with Salmonella Typhimurium hydrogenases or Klebsiella pneumoniae urease, leads to bacterial growth inhibition, both in the mouse and in the wax moth animal models55. In the present study, we showed that DMG can drastically reduce, and even abolish Aβ40 peptide aggregation. The inhibitory effect was observed in absence of supplemental metal, as well as in presence of copper, nickel or even zinc (albeit with lower efficacy). Although thioflavin is a popular reporter of amyloid aggregation, it mostly binds to β-sheet rich fibrils62,63. Therefore, our conclusions on the effect of Ni and Ni-chelation (DMG) on Aβ peptide-aggregation must be limited at this time to the β-sheet content. Additional experiments will be needed to determine whether Ni and its chelator have a broader effect on other Aβ peptide conformations. Likewise, further experiments will be conducted to test whether DMG can inhibit the aggregation of other physiologically relevant Aβ peptides, for instance Aβ42.
The current study is not the first one to report inhibitory effect of a nickel chelator on Aβ peptide aggregation. Indeed, Reinhardt and colleagues reported beneficial effects of the nickel chelator disulfiram on AD hallmarks, including inhibitory effects on Aβ42 peptide aggregation64. The study however was not aimed at establishing any link between Ni and AD. The authors found that disulfiram increased synthesis of the metalloproteinase α-secretase, resulting in secretion of the neuroprotective APP cleavage product sAPPα and thus preventing formation of the amyloidogenic βA peptides64. The concentration of disulfiram shown to have inhibitory effects on peptide aggregation was significantly lower compared to DMG concentrations used in our study, however the disulfiram drug is highly toxic, even at low doses, with concentrations higher than 5 μM inducing cytotoxicity64. This finding correlates with previous studies linking disulfiram with negative outcomes, such as elevated nickel levels in rat brains65, elevated nickel levels in body fluids of patients with chronic alcoholism65,66, as well as hepatotoxicity in humans67,68.
If DMG were to be used in a clinical trial against AD, it might not only inhibit Aβ plaque formation, but also Ni-requiring microorganisms. This, however, would not necessarily be a negative outcome, in light of the link between pathogens and AD, known as the “infection hypothesis of AD”69,70,71. The list of pathogens potentially linked to AD includes viral, fungal and bacterial species. Among bacteria directly or indirectly associated with AD, one can find Helicobacter pylori72,73, E. coli74 and Salmonella Typhimurium75, all of which require Ni as cofactor for one or several enzymes (for a review, see Maier and Benoit47). In the case of H. pylori, another protein is relevant to the pathogen/AD link. The gastric pathogen produces abundant amounts (2% of total protein) of a small histidine-rich protein (Hpn) that has been shown to develop amyloid-like fibrils in vitro76. The continuous production of Hpn by the bacterium during decades of chronic gastric infection could result in leakage of the protein, first into the bloodstream and eventually into the brain, potentially triggering AD, as hypothesized by Ge and Sun77. More generally, an antimicrobial role for Aβ peptides (as part of the brain’s ancient immune system) has been proposed, as part of a “new amyloidogenesis model”78. The model is based on findings by Kumar and colleagues, who reported 75 that bacterial infection of the brains of transgenic mice result in accelerated Aβ plaque deposition, closely colocalizing with the invading bacteria (in this case, Salmonella)75.
In summary, Ni could affect the onset and the progression of AD through two different mechanisms, as depicted in our proposed model (Fig. 4). The first mechanism involves the binding of Ni2+ to Aβ (Aβ40, possibly Aβ42), eventually leading to aggregation, plaque formation and AD; this would comply with the metal hypothesis of AD. The second mechanism involves the use of Ni2+ as a required cofactor for various enzymes (e.g. Ni-glyoxalase, Ni-superoxide dismutase, Ni-acireductone dioxygenase, [NiFe] hydrogenases and urease, see47) of pathogens previously shown to play a role in Aβ peptide aggregation; alternatively some of these pathogens might contribute to AD independently of Aβ plaque formation. Both scenarios would fit the “infectious hypothesis of AD”. Whether one Ni-dependent mechanism is preferred over the other, or both actively contribute to the onset and/or the progression of AD, nevertheless a DMG-mediated Ni-chelation strategy is at the intersection of both (the metal and the infectious) hypotheses. Thus, it is likely to interfere and disrupt both mechanisms, eventually slowing down or stopping the progression of AD. More than a century after Alois Alzheimer fist described the disease, and without any cure on the horizon, new therapeutic strategies are urgently needed to combat this neurodegenerative disease; we believe that nickel chelation (via DMG treatment) is a promising AD-combatting strategy that warrants further research.
Materials and methods
Chemicals
The water-soluble form (2Na, 8H2O) of DMG was used in this study (ref # 40400, Honeywell-Fluka, Muskegon, MI, USA). All metals (CuSO4, FeSO4, Na2SeO3, NiCl2, NiSO4, ZnSO4) are from Sigma-Aldrich (Saint Louis, MO, USA).
Amyloid beta metal analysis
Metal levels for 20 elements (Li, Be, Al, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, As, Se, Rb, Sr, Cd, Cs, Ba, Pb, U) were determined by inductively coupled plasma mass spectrometry (ICP-MS). Briefly, 0.5 mg of lyophilized human recombinant Aβ40 peptide (expressed in E. coli, purified and manufactured by rPeptides, Watkinsville, GA) was resuspended in ultrapure water to a final concentration of 5 mg/mL, digested overnight with concentrated trace metal grade nitric acid, heated for 2 h at 95 °C and subjected to ICP-MS using a Thermo X-Series II ICP-MS (Center for Applied Isotope Studies, University of Georgia, Athens, GA). The same treatment and analysis were performed on three other kit components: TBS 10X (reaction buffer), Thioflavin stock (400 μM) and NaOH 10 mM (used to resuspend the Aβ40 peptide).
Amyloid beta aggregation
The effect of metals, DMG, and/or pH on human recombinant Aβ40 aggregation was monitored using a thioflavin T (ThT)-based kit, following the manufacturer’s recommendation (kit# A-1180-1, rPeptides, Watkinsville, GA, USA). This kit contains human recombinant Aβ40 peptide (> 97% pure, as determined by manufacturer’s HPLC) with the following sequence DAEFRHDSGYEVHHQKLVFFAEDVGSNKGAIIGLMVGGVV, as provided by the manufacturer. Briefly, standard assays were conducted in triplicate in black polystyrene 96-well plates, in presence of Tris Buffer Saline (TBS) pH 7.4, or TBS pH 8.5, or 2-(N-morpholino)ethanesulfonic acid (MES) buffer saline pH 6.5, Th-T (20 or 40 μM), and human recombinant Aβ40 peptide (25 or 40 μM), with or without DMG (100, 500, or 1000 μM), CuSO4, NiSO4 or ZnSO4 (10, 25, or 100 μM). The aggregation of Aβ40, as shown by the increase in fluorescence (λex = 440 nm/λem = 485 nm) over time, was followed for 60 min or 120 min, with reading every 3 or 5 min, using a Synergy MX reader (Biotek, Winooski, VT). A ThT-only background control (no Aβ40 peptide) was included in triplicate in all experiments and subtracted from all readings. The aggregation rate, defined as the increase in fluorescence per min (RFU/min), was calculated by using the formula [A(440, 485) at T40 min) − A(440, 485) at T20 min]/20. These time points (20 to 40 min) were chosen because they constantly displayed the best linearity in every assay. Results shown are expressed as (mean and standard deviation of) percentages; they represent the ratio of aggregation rate (RFU/min) for a given (DMG, metal) condition, compared to the aggregation rate obtained for the control (Aβ40 peptide, no DMG, no metal added, set as 100% for each experiment).
Isothermal titration calorimetry
Binding assays of Aβ40 peptide and Ni or DMG were performed using a Nano ITC calorimeter (TA instruments, New Castle, DE). Briefly, 1 mg of lyophilized Aβ40 peptide (# A-1157-2, rPeptides) was resuspended with 1% NH4OH to a concentration of 250 μM, sonicated for 15–20 s, before being diluted to a final concentration of 20 μM Aβ40 using ddH2O and TBS 10X, pH 7.4 (working buffer: NH4OH 0.2%, TBS 1X, pH 7.4 (“NTBS”)). A volume of 500 μL was loaded onto the ITC sample cell, and the injection syringe was filled with 50 μL of either NTBS buffer (control), 1 mM NiSO4, or 1 mM DMG. All samples were degassed for 15 min at 25 °C before use. Titration was initiated using a program for 20 injections (2.38 μL each, every 5 min) with continuous stirring (350 rpm) at constant temperature (25 °C). ITC data were analyzed using NanoAnalyze 1.2 software (TA Instruments). Data obtained with the control experiment (Aβ40 peptide in sample cell, buffer in syringe) were subtracted from each experiment to account for any injection-related heat change. The Ni-Aβ40 experiment was done in triplicate, with a representative data set shown in figures.
Analysis of DMG and DMG-metal complexes in commercial preparations
Aqueous solutions of DMG (0.5 mg/mL or 1.6 mM), with or without Cu, Fe, Ni, Se or Zn solutions (0.16 mM each) were analyzed by Fourier Transform Ion Cyclotron Resonance Mass Spectrometry (FTICR-MS), using a Bruker Solari X ESI/MALDI-12 T FT-ICR high precision mass spectrometer (Proteomics and Mass Spectrometry Facility, University of Georgia). The pH of all aqueous DMG solutions, with or without metal, was approximately 11. All samples were mixed (1:1) with methanol prior to injection.
Detection of DMG and DMG-metal complexes in mouse brains
All procedures were performed in accordance with the relevant guidelines and regulations and approved by the University of Georgia IACU committee, and the study was carried out in compliance with the ARRIVE guidelines (http://www.nc3rs.org.uk/page.asp?id=1357). A group of 6 (C57/BL) mice was used for this experiment: 3 mice were given 0.2 mL of 100 mM DMG (~ 6.1 mg) every day for three days and 3 mice were used as (no DMG) controls. Mice were euthanized by CO2 asphyxiation and cervical dislocation. Brains were quickly removed and frozen at − 80 °C. Upon thawing, brains were cut into pieces and homogenized in 2 mL sterile deionized water, incubated for 1 h at 90 °C, sonicated for 20 s and spun down (16,800 × g for 6 min). Supernatants were passaged through a 0.45 μm filter unit and analyzed by FTICR-MS (see above) and Nuclear Magnetic Resonance (NMR), as previously described 55.
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Acknowledgements
This work was supported by the UGA Foundation (RJM). The authors declare that they have no conflict of interest. The authors acknowledge Kevin Clark (UGA Proteomics and Mass Spectrometry Facility) and John Glushka (UGA CCRC NMR facility) for their help with this project; Vincent Starai (UGA Microbiology) for the use of the Biotek Synergy 96-well microplate reader; Jorge Escalante and Elizabeth Villa (UGA Microbiology) for the use of the Nano-ITC. The in vitro or in vivo use of DMG to inhibit beta-amyloid aggregation and/or onset or progression of Alzheimer’s disease is claimed under international patent application no. PCT/US2020/030483.
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Benoit, S.L., Maier, R.J. The nickel-chelator dimethylglyoxime inhibits human amyloid beta peptide in vitro aggregation. Sci Rep 11, 6622 (2021). https://doi.org/10.1038/s41598-021-86060-1
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DOI: https://doi.org/10.1038/s41598-021-86060-1
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