Importance of the Dimethylamino Functionality on a Multifunctional Framework for Regulating Metals, Amyloid-ß, and Oxidative Stress in Alzheimer's Disease.

The complex and multifaceted pathology of Alzheimer's disease (AD) continues to present a formidable challenge to the establishment of long-term treatment strategies. Multifunctional compounds able to modulate the reactivities of various pathological features, such as amyloid-ß (Aß) aggregation, metal ion dyshomeostasis, and oxidative stress, have emerged as a useful tactic. Recently, an incorporation approach to the rational design of multipurpose small molecules has been validated through the production of a multifunctional ligand (ML) as a potential chemical tool for AD. In order to further the development of more diverse and improved multifunctional reagents, essential pharmacophores must be identified. Herein, we report a series of aminoquinoline derivatives (AQ1-4, AQP1-4, and AQDA1-3) based on ML's framework, prepared to gain a structure-reactivity understanding of ML's multifunctionality in addition to tuning its metal binding affinity. Our structure-reactivity investigations have implicated the dimethylamino group as a key component for supplying the antiamyloidogenic characteristics of ML in both the absence and presence of metal ions. Two-dimensional NMR studies indicate that structural variations of ML could tune its interaction sites along the Aß sequence. In addition, mass spectrometric analyses suggest that the ability of our aminoquinoline derivatives to regulate metal-induced Aß aggregation may be influenced by their metal binding properties. Moreover, structural modifications to ML were also observed to noticeably change its metal binding affinities and metal-to-ligand stoichiometries that were shown to be linked to their antiamyloidogenic and antioxidant activities. Overall, our studies provide new insights into rational design strategies for multifunctional ligands directed at regulating metal ions, Aß, and oxidative stress in AD and could advance the development of improved next-generation multifunctional reagents.

Trimethylamine oxide, dimethylamine, trimethylamine and formaldehyde levels in main traded fish species in Hong Kong.

Levels of trimethylamine oxide (TMAO), dimethylamine (DMA), trimethylamine (TMA) and formaldehyde (FA) were studied in 266 different fishes, including fresh/frozen raw whole fishes of 89 different species that traded in Hong Kong, China. Determination of TMAO can confirm the source of DMA and FA if present in the sample. These samples were purchased from different commercial outlets between April and August 2007. All samples of raw whole fish were identified for their species by the Agriculture, Fisheries and Conservation Department. The content of TMAO was determined by high-performance liquid chromatography (HPLC) coupled with a chemiluminescent nitrogen detector. The possible decomposition products of TMAO, DMA and TMA were analysed by headspace solid-phase micro-extraction gas chromatography-mass spectrometry (HS-SPME-GC-MS), while FA was conducted by steam distillation then quantified by a HPLC. The range for TMAO of all samples was <5-3800 mg kg(-1) with median of 970 mg kg(-1), while the endogenous enzymatic cleavage products DMA, TMA and FA were in the range of <2-320, <1-190 and <1-160 mg kg(-1), respectively. These cleavage products were mainly found in three fish species, Harpadon nehereus, Saurida elongata and Saurida tumbil, that belong to the family Synodontidae (Lizardfishes) and subfamily Harpadontinae. Besides, freshwater fish species, namely, Micropterus salmoides, Oreochromis niloticus niloticus and Siniperca chuatsi, were found to contain TMAO in the range of 510-760, 85-720 and 400-640 mg kg(-1), respectively.

Toxicological evaluation of mixtures of nonionic surfactants, alone and in combination with oil.

The toxicity to human bronchial (16-HBE14o-) epithelium cells of nonionic surfactants, polyoxyethylene-10-oleyl ether (C(18:1)E(10)), polyoxyethylene-10-dodecyl ether (C(12)E(10)), and N,N-dimethyl-dodecylamine-N-oxide (C(12)AO) alone or in combination with a range of pharmaceutically acceptable oils (namely, ethyl esters and triglyceride oils), was determined with the MTT (3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide) assay. Regardless of the presence of oil, all C(12)E(10)- and C(12)AO-containing systems were toxic at concentrations around or below their critical aggregation concentrations (as determined by surface tension measurements), suggesting that surfactant toxicity was due to the disruption caused by the partitioning of monomeric surfactant into the cell membrane. Systems prepared from C(18:1)E(10) alone or in combination with a low-molecular-weight oil, such as ethyl butyrate or tributyrin, were toxic above their critical aggregation concentration. In contrast, systems prepared from C(18:1)E(10) in combination with a high-molecular-volume oil (e.g., ethyl oleate, Miglyol 812, or soybean oil) were toxic only at concentrations significantly greater than their critical aggregation concentration, suggesting that in these cases surfactant toxicity was mediated by the aggregated form of the surfactant solubilizing components of the cell membrane. In the C(18:1)E(10)-stabilized system, it is proposed that toxicity was significantly reduced on incorporation of high-molecular-volume oils because these oils cause formation of a distinct oil core in the aggregates that leads to a reduction in the ability of the system to solubilize components of the cell membrane.

Haploinsufficiency of p18(INK4c) sensitizes mice to carcinogen-induced tumorigenesis.

The INK4 family of cyclin-dependent kinase (CDK) inhibitors negatively regulates cyclin D-dependent CDK4 and CDK6 and thereby retains the growth-suppressive function of Rb family proteins. Mutations in the CDK4 gene conferring INK4 resistance are associated with familial and sporadic melanoma in humans and result in a wide spectrum of tumors in mice. Whereas loss of function of other INK4 genes in mice leads to little or no tumor development, targeted deletion of p18(INK4c) causes spontaneous pituitary tumors and lymphoma late in life. Here we show that treatment of p18 null and heterozygous mice with a chemical carcinogen resulted in tumor development at an accelerated rate. The remaining wild-type allele of p18 was neither mutated nor silenced in tumors derived from heterozygotes. Hence, p18 is a haploinsufficient tumor suppressor in mice.

Two mechanisms for toxic effects of hydroxylamines in human erythrocytes: involvement of free radicals and risk of potentiation.

The toxic potency of three industrially used hydroxylamines was studied in human blood cells in vitro. The parent compound hydroxylamine and the O-ethyl derivative gave very similar results. Both compounds induced a high degree of methemoglobin formation and glutathione depletion. Cytotoxicity was visible as Heinz body formation and hemolysis. High levels of lipid peroxidation occurred, in this respect O-ethyl hydroxylamine was more active than hydroxylamine. In contrast H2O2 induced lipid peroxidation was lowered after O-ethyl hydroxylamine or hydroxylamine treatment, this is explained by the ferrohemoglobin dependence of H2O2 induced radical species formation. Glutathione S-transferase (GST) and NADPH methemoglobin reductase (NADPH-HbR) activities were also impaired, probably as a result of the radical stress occurring. The riboflavin availability was decreased. Other enzyme activities glutathione reductase (GR), glucose 6-phosphate dehydrogenase (G6PDH), glucose phosphate isomerase and NADH methemoglobin reductase, were not or only slightly impaired by hydroxylamine or O-ethyl hydroxylamine treatment. A different scheme of reactivity was found for N,O-dimethyl hydroxylamine. This compound gave much less methemoglobin formation and no hemolysis or Heinz body formation at concentrations up to and including 7 mM. Lipid peroxidase induction was not detectable, but could be induced by subsequent H2O2 treatment. GST and NADPH-HbR activities and riboflavin availability were not decreased. On the other hand GR and G6PDH activities were inhibited. These results combined with literature data indicate the existence of two different routes of hematotoxicity induced by hydroxylamines. Hydroxylamine as well as O-alkylated derivatives primarily induce methemoglobin, a process involving radical formation. The radical stress occurring is probably responsible for most other effects. N-alkylated species like N,O-dimethyl hydroxylamine primarily lead to inhibition of the protective enzymes G6PDH and GR. Since these enzymes play a key role in the protection of erythrocytes against oxidative stress a risk of potentiation during mixed exposure does exist.

In vitro cytotoxicity and DNA damage production in Chinese hamster ovary cells and topoisomerase II inhibition by 2-[2'-(dimethylamino)ethyl]-1, 2-dihydro-3H-dibenz[de,h]isoquinoline-1,3-diones with substitutions at the 6 and 7 positions (azonafides).

The mechanism of action of a group of anthracene-containing analogs of amonafide was studied in Chinese hamster ovary (CHO) cells. These agents differ structurally from amonafide by the replacement of the naphthalene chromophore with an anthracene chromophore, the lack of a primary amine moiety in the 5 position, and substitutions at the 6 and 7 positions on the anthracene nucleus. In this study, five analogs with potent growth inhibitory activity and with low cardiotoxicity were chosen. Cytotoxicity analyses with tetrazolium dye assays (MTT) in vitro and continuous drug exposure revealed IC50 values in CHO cells in the nanomolar range. Intracellular scanning laser confocal microscopy of these drug-treated CHO cells showed that all analogs are able to enter cell nuclei with varying nuclear/cytoplasmic distribution: the more potent dimethylaminoethyl substituted analogs, 47 and 104, were primarily localized in the nucleus. Three analogs, including the unsubstituted parent (1), and numbers 35 (6-amino substituted) and 53 (6-aminoethyl substituted) inhibited DNA and RNA synthesis when assayed immediately after a 1 h exposure. In contrast, analogs 47 and 104 required 24 h post-drug exposure for 1 h to inhibit DNA and RNA synthesis. Using alkaline elution techniques, each analog also produced DNA single- and double-stranded breaks, as well as DNA protein cross-links. Interestingly, the most cytotoxic analogs, 47 and 104, produced minimal DNA strand damage in CHO cells at their IC90 concentrations, whereas the three other compounds with lower growth inhibitory potency produced marked and roughly equivalent DNA damage at equitoxic concentrations. Gel shift analysis of SV40 DNA exposed to the compounds demonstrated that these agents do not directly induce DNA strand breaks. However, catalytic studies with purified human topoisomerase II (Topo II) and plasmid DNA demonstrated that these drugs inhibit this enzyme. These results suggest that the azonafides inhibit Topo II to cause protein-associated strand breaks and impaired DNA and RNA synthesis. However, other mechanisms may also be operant, especially with the more potent dimethylamino ethyl substituted analogs.

In vitro haematotoxic effects of three methylated hydroxylamines.

Hydroxylamine (HYAM, HONH2) and some of its derivatives are known to cause erythrotoxic effects both in vitro and in vivo. Previous studies have shown that the primary in vitro effect of HYAM and O-ethyl hydroxylamine (OEH) is methaemoglobin formation, leading to liberation of free radicals which cause lipid peroxidation, enzyme inhibitions and glutathione depletion. By contrast, N-substituted N,O-dimethyl hydroxylamine (NODMH), primarily induces impairment of glucose 6-phosphate dehydrogenase (G6PDH) and glutathione reductase (GR). The oxidative potency of HYAM and the O-derivative was larger than the potency of the N,O-derivative. This seemed to indicate that attachment of an alkyl group to the nitrogen atom of hydroxylamine leads to decreased reactivity. To achieve a better understanding of the structure activity relationship for hydroxylamines three methylated derivatives were tested: N-methyl hydroxylamine (NMH). N-dimethyl hydroxylamine (NDMH) and O-methyl hydroxylamine (OMH). We were also interested in the erythrotoxic potency of OMH which recently entered industrial production. Methaemoglobin formation, high release of lipid peroxidation products, inhibition of NADPH methaemoglobin reductase and glutathione S-transferase (GST) and depletion of total glutathione (GT) were seen for OMH. The reducing enzymes G6PDH and GR were not impaired by OMH. These findings for OMH are consistent with the proposed mechanism for O-derivatives. Since both the effects caused by OMH and its potency are comparable to those of HYAM and OEH this indicates that possible occupational exposure to this compound may be approached similarly to HYAM and OEH. NMH only inhibited G6PDH and GR activity, which is fully in accord with the proposed mechanism for N-substituted derivatives of HYAM. However, NDMH a double N-substituted compound, caused a strikingly different scheme of reactivity inhibition of G6PDH but not of GR, severe methaemoglobin formation, only little lipid peroxidation and some impairment of NADPH methaemoglobin reductase. This study confirms that O-derivatives of HYAM are potent haemoglobin oxidators, leading to other oxidative effects. The main effect was confirmed for single N-derivatives as inhibition of the two protective enzymes G6PDH and GR. However, the results for NDMH indicate that this simple classification of O-derivatives and N-derivatives has to be extended for double N-substituted compounds which give a mixture of effects.

[Effect of n-nitrosodimethylamine (NDMA) on activity of selected enzymes in blood serum of the rat]. / Wplyw n-nitrozodimetyloaminy (NDMA) na aktywnosc wybranych enzymów w surowicy krwi szczura.

Changes in the activity of GOT, GPT, AP and GGTP in blood of rats intoxicated by low doses of N-Nitrosodimethylamine (NDMA) are presented. A significant increase in the activity of GOT and GPT was found after single doses (20 micrograms/kg b.w.) of NDMA as well as a significant increase in the activity of GOT, GPT, AP and GGTP after a prolonged intoxication per os by doses of 20 micrograms/dm3 given in drinking water.

Genotoxic and biochemical effects of dimethylamine.

The genotoxicity of dimethylamine (DMA) was investigated in the D7 strain of Saccharomyces cerevisiae. DMA was able to induce mitotic gene conversion and point reverse mutation in the presence of metabolic activation (S9 fraction). To study the co-mutagenicity/co-carcinogenicity or toxicity of DMA, changes in xenobiotic metabolizing enzymes were studied in purified microsomes from DMA-induced mice or rats receiving a single or three consecutive doses (25 or 50 mg/kg body wt). Pentoxyresorufin O-dealkylase (class IIB1 P450, PROD), ethoxyresorufin O-deethylase (IA1, EROD) and p-nitrophenol hydroxylase (IIE1, pNPH) were all affected by DMA treatment with a loss of activity of 62, 55 and 54% in the mouse, or 64, 25 and 56% in the rat for PROD, EROD and pNPH activities, respectively, at the highest tested dose. No significant alteration of P450 IIIA-like activity was seen. Results indicated that the metabolites of DMA induced genetic activity in yeast. In addition, a clear non-specific hepatotoxic effect was recorded as a significant reduction in activity of the selected monooxygenases.

Hepatotoxicity and hepatocarcinogenicity in rats fed squid with or without exogenous nitrite.

The popular seafood squid contains high levels of naturally occurring amines such as dimethylamine (DMA) trimethylamine and trimethylamine-N-oxide (TMAO). The hepatotoxicity and hepatocarcinogenicity of squid with or without exogenous nitrite were investigated in rats. Acute necrosis including polymorphogenic neutrophil infiltration, haemorrhage and cholangiofibrosis were observed in the livers of most rats fed squid. Hepatocellular carcinoma (HCC) was induced in two out of 12 rats (16%) by feeding 10% squid in Purina rat chow for 10 months. The incidence of HCC was increased to four out of 10 rats (33%) when 0.3% NaNO2 was added to the above diet. At the end of the experiment a marked elevation of serum gamma-glutamate transferase was observed in treated groups, but no significant changes in the activities of serum glutamic-oxaloacetic transaminase and glutamic-pyruvic transaminase were detected. Vitamin C (0.3%) gave partial protection against hepatic damage. The concentration of DMA in squid is estimated to be 0.19%; this concentration did not induce HCC under the experimental conditions used. Therefore it is suggested that another major naturally occurring amine in squid, TMAO, could be one of the important factors involved in the induction of hepatotoxicity and hepatocarcinogenicity in rats.

Effects of acute and chronic dimethylamine exposure on the nasal mucociliary apparatus of F-344 rats.

Dimethylamine (DMA) is a highly water soluble gas with many industrial applications. Male F-344 rats were exposed to 175 ppm DMA 6 hr per day for 1, 2, 4, or 9 days or 2 years. Gross changes in nasal structure were recorded, effects of DMA on the mucociliary apparatus were assessed using video analysis, and tissues were evaluated for histopathology. In vitro nasal mucociliary flow patterns, mucus flow rates, and ciliary activity were studied and recorded for video motion analysis. There were distinct and generally consistent differences in the shape of the naso-, maxillo-, and ethmoid turbinates between young and old animals. Acute and chronic DMA exposures resulted in erosion of the anterior margins of the naso- and maxilloturbinates and fenestration of the adjacent septum. Ciliastasis and mucostasis were observed only on the anteromedial aspect of the maxilloturbinate. In the chronically exposed rats, mucociliary activity was present in areas adjacent to erosions of the turbinates and septum. Abnormal mucus flow patterns, including altered or reversed direction of flow and "whirlpool-like" formation, were observed in all treated rats, but were more severe following chronic exposure. There was a good correlation between the distribution of responses as assessed by histopathology and abnormal mucociliary function at all time points. In conclusion, the mucociliary apparatus continues to function in the nasal passages of rats having localized destruction of nasal epithelium, induced by DMA exposure, and this clearance system responds to alterations of nasal structure by modification of mucus flow patterns.

Effect of ascorbic acid on the hepatotoxicity due to the daily intake of nitrate, nitrite and dimethylamine.

It is known that nitrates, nitrites and dimethylamine may react in the gastro-intestinal tract synthesizing the powerful hepatotoxic and carcinogenic dimethylnitrosamine. The purpose of this study was to investigate hepatotoxicity due to the daily intake of nitrates and nitrites administered to rats during 14 weeks together with dimethylamine in drinking water, and to evaluate the protecting effect of ascorbic acid against the hepatotoxicity of the presumably endogenous formed dimethylnitrosamine. The toxicity criteria studied were weight of liver (absolute and relative), free and total bilirubin, alkaline phosphatase and pyruvic glutamic transaminase, all in the form of serum, and histopathologic tests of the liver. The results gave evidence of hepatotoxicity induced by the intake of nitrate, nitrite and dimethylamine all together, and not through the only intake of nitrate or nitrite or of amine. Daily doses of ascorbic acid [(211 +/- 40) and (18 +/- 4) mg/kg] seemed to hinder hepatotoxicity according to the criteria under investigation.

Determination of DNA single strand breaks and selective DNA amplification by N-nitrodimethylamine and analogs, and estimation of the indicator cells' metabolic capacities.

N-nitrodimethylamine is metabolized oxidatively to N-nitrohydroxymethylmethylamine, which decomposes to yield formaldehyde and N-nitromethylamine. All four compounds and N-nitromethylamine were tested for their ability to induce DNA single strand breaks in hepatocytes and in SV 40-transformed Chinese hamster embryo cell lines. Only the two monoalkylnitramines were positive. They induced single strand breaks in hepatocytes, but were not effective in the other cells. Formaldehyde and N-nitrohydroxymethylmethylamine were toxic to the cells. None of the compounds tested was able to induce selective DNA amplification in the two transformed cell lines. Enzymes involved in drug metabolism were assayed in the hamster cell lines. The activity of UDP-glucuronosyltransferase and cytosolic epoxide hydrolase were not detectable. N-nitrodimethylamine demethylation was low. The content of reduced glutathione and the activities of glutathione transferase and membrane bound epoxide hydrolase were comparable to values obtained in the rat liver.

The toxicity of dimethylamine in F-344 rats and B6C3F1 mice following a 1-year inhalation exposure.

Dimethylamine is a widely used commodity chemical, for which there are few chronic toxicity data. Male and female F-344 rats and B6C3F1 mice were exposed by inhalation to 0, 10, 50, or 175 ppm dimethylamine (DMA) for 6 hr/day, 5 days/week for 12 months. Groups of 9-10 male and female rats and mice were necropsied after 6 and 12 months of exposure. No male mice were sacrificed at 12 months due to a high incidence of early deaths in that group. The mean body weight gain of rats and mice exposed to 175 ppm DMA was depressed to approximately 90% of control after 3 weeks of exposure. The only other treatment-related changes were concentration-related lesions in the nasal passages. Two distinct locations in the nose were affected: the respiratory epithelium in the anterior nasal passages, and the olfactory epithelium, especially that lining the anterior dorsal meatus. There was focal destruction of the anterior nasoturbinate and nasal septum, local inflammation, and focal squamous metaplasia of the respiratory epithelium in rats and mice. Mild goblet cell hyperplasia was observed only in rats. The olfactory epithelium exhibited extensive loss of sensory cells with less damage to sustentacular cells. There was also loss of olfactory nerves, hypertrophy of Bowman's glands, and distension of the ducts of these glands by serocellular debris in regions underlying degenerating olfactory epithelium. At the 175-ppm exposure level, rats had more extensive olfactory lesions than mice, with hyperplasia of small basophilic cells adjacent to the basement membrane being present in rats but not mice. After 12 months of exposure to 10 ppm DMA, minimal loss of olfactory sensory cells and their axons in olfactory nerve bundles was observed in the nasal passages of a few rats and mice. These results indicate that the olfactory sensory cell is highly sensitive to the toxic effects of DMA, with minor lesions being produced in rodents even at the current threshold limit value of 10 ppm.

Induction of tumours in rats by feeding nitrosatable amines together with sodium nitrite.

Feed containing 0.2% allantoin or diphenhydramine (as the hydrochloride) or 0.1% chlorpheniramine (as the maleate), with or without 0.2% sodium nitrite, was given ad lib. to groups of 20 or 24 male and 20 or 24 female F344 rats for 106 wk. Groups of 24 male and 24 female F344 rats were given drinking-water that contained N,N-dimethyldodecylamine-N-oxide at a concentration of 0.1%, with or without 0.2% sodium nitrite, for 93 wk. Control rats were given untreated feed or drinking-water and nitrite-treated controls were given sodium nitrite at a concentration of 0.2% in feed or drinking-water. At the end of the treatment period the rats were given untreated feed and water and observed until death. There was little or no life-shortening effect in any treatment group. None of the four amines administered alone induced an increase in the incidence of any tumour in comparison with the untreated control groups. In the male rats given diphenhydramine, chlorpheniramine or N,N-dimethyldodecylamine-N-oxide concurrently with nitrite there was a significant increase in the incidence of liver neoplasms (hepatocellular carcinomas and neoplastic nodules). In the groups given untreated feed or drinking-water there were, respectively, five and three male rats that had liver tumours. In contrast the number of male rats with liver tumours was ten in the group given dimethyldodecylamine-N-oxide plus nitrite, 11 in that given diphenhydramine plus nitrite and 14 (eight with carcinomas) in the group given chlorpheniramine plus nitrite. These results suggest that the ingestion of dimethyldodecylamine-N-oxide, diphenhydramine hydrochloride or chlorpheniramine under conditions when they could be nitrosated with nitrite in the stomach might present an increased carcinogenic risk.