Proteolytic imbalance in Alzheimer fibroblasts as potential pathological trait of disease

Stable Co-Cultivation of the Moss Physcomitrella patens with Human Cells in vitro as a New Approach to Support Metabolism of Diseased Alzheimer Cells

Alzheimer's disease (AD) is a devastating slowly progressive neurodegenerative disorder with no cure. While there are many hypotheses, the exact mechanism causing this pathology is still unknown. Among many other features, AD is characterized by brain hypometabolism and decreased sugar availability, to which neurons eventually succumb. In light of this aspect of the disease, we hypothesized that boosting fuel supply to neurons may help them survive or at least alleviate some of the symptoms. Here we demonstrate that live moss Physcomitrella patens cells can be safely co-cultured with human fibroblasts in vitro and thus have a potential for providing human cells with energy and other vital biomolecules. These data may form the foundation for the development of novel approaches to metabolic bioengineering and treatment of diseased cells based on live plants. In addition, by providing alternative energy sources to human tissues, the biotechnological potential of this interkingdom setup could also serve as a springboard to foster innovative dietary processes addressing current challenges of mankind such as famine or supporting long-haul space flight.

Altered proteolysis in fibroblasts of Alzheimer patients with predictive implications for subjects at risk of disease

There is great interest in developing reliable biomarkers to support antemortem diagnosis of late-onset Alzheimer's disease (AD). Early prediction and diagnosis of AD might be improved by the detection of a proteolytic dysfunction in extracts from cultured AD fibroblasts, producing altered isoelectrophoretic forms of the enzyme transketolase (TK-alkaline bands). The TK profile and apolipoprotein E (APOE) genotype were examined in fibroblasts from 36 clinically diagnosed probable late-onset sporadic AD patients and 38 of their asymptomatic relatives, 29 elderly healthy individuals, 12 neurological non-AD patients, and 5 early-onset AD patients. TK alterations occurred in (i) several probable AD patients regardless of age-of-onset and severity of disease; (ii) all early-onset AD patients and APOE ε 4/4 carriers; and (iii) nearly half of asymptomatic AD relatives. Normal subjects and non-AD patients were all negative. Notably, culture conditions promoting TK alterations were also effective in increasing active BACE1 levels. Overall, the TK assay might represent a low-cost laboratory tool useful for supporting AD differential diagnosis and identifying asymptomatic subjects who are at greater risk of AD and who should enter a follow-up study. Moreover, the cultured fibroblasts were confirmed as a useful in vitro model for further studies on the pathogenetic process of AD.

Impaired electro-genesis in skeletal muscle fibers of transgenic Alzheimer mice

Alzheimer's disease (AD) is characterized by memory decline, but is often associated with non-cognitive symptoms, including muscular dysfunction. In the majority of cases these motor disturbances are seen when other neuro-degenerative disorders such as Parkinson's disease overlap dementia, however these can also be directly related to AD itself. Although the patho-mechanism remains largely unclear, β-amyloid peptide (βAP) is thought to be a key role-player in both the brain and periphery. Here we studied the electro-genesis of skeletal muscle fibers in a mouse transgenic AD model. Membrane potential was recorded by standard electro-physiological techniques. Compared to wild-type rodents, AD mice show severe disturbances in skeletal muscle electro-genesis manifested by significant depolarization of myo-fibers. These changes are not affected by short-term βAP treatment, the mark of a chronic degenerative process in the periphery directly related to AD whereby ion pumps on muscle membranes exhibit reduced activity. This phenomenon may explain ionic imbalance and cellular dysfunction both in the neuro-muscular system and in the brain. The observed motor disturbances might play a key role in impaired activities of daily living, and addressing the muscular patho-physiology could improve quality of life in AD.

All-or-nothing type biphasic cytokine production of human lymphocytes after exposure to Alzheimer's beta-amyloid peptide

BACKGROUND

Neuro-inflammation, triggered by beta-amyloid peptide, is implicated as one of the primary contributors to Alzheimer's disease (AD) pathogenesis, and several cytokines were identified as key instigating factors.

METHODS

To reveal the inflammatory response of lymphocytes to the neuro-toxic beta-amyloid peptide, we evaluated the release of several cytokines from peripheral blood mononuclear cells with immuno-assays (ELISA). From hyper-acute to chronic effects of beta-amyloid peptide were assessed at a wide range of concentrations.

RESULTS

The pro-inflammatory interleukin (IL)-1beta, tumor necrosis factor-alpha, monocyte chemotactic protein-1, and Rantes (acronym for regulated on activation, normal T-cell expressed and secreted) as well as the pleiotropic IL-6 showed a biphasic release pattern over time in both low and high doses of amyloid treatment: after an initial increase, their concentration gradually fell to the baseline. The suppressors IL-4 and IL-10 had a sinus-like secretion panel: an acute increase in their levels turned to a depression and later followed by their over-secretion. Interestingly, beta-amyloid below 10(-8) mol/L produced no effect at all, but any molarity above this threshold caused the very same cytokine secretion pattern, the mark of an all-or-nothing response of beta-amyloid peptide.

CONCLUSIONS

These results delineate a highly organized pro- and anti-inflammatory response of cells to the neuro-toxic peptide. This is the first study to describe how the beta-amyloid-induced inflammatory processes in Alzheimer's dementia are regulated.

Haloperidol Attenuates β-Amyloid-Induced Calcium Imbalance in Human Fibroblasts

BACKGROUND

Antipsychotics are widely used in the treatment of behavioral and psychological symptoms of dementia. A low frequency of Alzheimer's disease in patients with schizophrenia is reported, and it has been proposed that antipsychotic medications, such as haloperidol, may be responsible. Disruption of intracellular calcium levels is considered to play a key role in beta-amyloid-induced neurotoxicity in Alzheimer's disease. Haloperidol has also been reported to interact with calcium homeostasis through dopamine-2 and sigma-1 receptors, and other, yet unknown mechanisms.

OBJECTIVE

Therefore, we investigated whether differences in the basal intracellular free calcium levels of cultured cutaneous fibroblasts--cells that do not express dopamine-2 and sigma-1 receptors--derived from sporadic Alzheimer patients and from age-matched control individuals after haloperidol treatment might be present.

METHODS

Intracellular calcium level was measured in Fura-2AM-loaded human fibroblasts by dual wavelength spectrofluorimetry.

RESULTS

Alzheimer cells exhibited significantly lower calcium level as compared to the control cultures. Exposure of fibroblasts to beta-amyloid peptide resulted in increased calcium concentration of the control cells, but not of Alzheimer fibroblasts. Co-incubation of cultures with a therapeutic dose of haloperidol blocked the beta-amyloid-induced elevation of calcium.

CONCLUSION

This finding indicates that haloperidol efficiently countervails ionic imbalance and suggests that it may serve as a potential agent in alleviating neurotoxic effects of beta-amyloid peptide.

Long-term exposition of cells to beta-amyloid results in decreased intracellular calcium concentration

The ubiquitously present beta-amyloid peptide plays an important role in the pathogenesis of Alzheimer's disease. Its neurotoxicity has been blamed on its mal-activity to increase calcium-levels. In the present study, we demonstrate that treatment of fibroblasts with beta-amyloid has, indeed, resulted in a transient rise in the calcium-concentration. Chronic exposition of cultures to the peptide, however, caused a fall in the calcium-level. Apparently, beta-amyloid has biphasic effects: acutely, it increases the calcium-concentration of cells; in contrast, on the long-run, beta-amyloid peptide acts as a calcium-antagonist. Therefore, the idea that beta-amyloid peptide leads to neural degeneration solely by increasing cells' calcium concentration must be replaced with a more complex view of its dual function in intracellular ionic homeostasis.

Comparative studies on [Ca2+]i-level of fibroblasts from Alzheimer patients and control individuals

The accumulation of the beta-amyloid peptide (betaAP) in the brain, produced from the ubiquitously expressed amyloid precursor protein (APP) is a defining feature of Alzheimer's disease (AD). Consistent with studies demonstrating the importance of skin biopsy in the diagnosis of neurodegenerative disorders, we investigated whether differences in intracellular free calcium levels ([Ca2+]i) of cultured cutaneous fibroblasts derived from sporadic AD patients and from age-matched control individuals might be present. [Ca2+]i was measured in Fura-2AM-loaded human fibroblasts by dual wavelength spectrofluorimetry. AD cells exhibited lower [Ca2+]i as compared to the control cultures. Exposure of fibroblasts to betaAP resulted in increased [Ca2+]i of the control cells, but not of AD fibroblasts. Our test could prove useful in supporting the diagnosis of (sporadic) AD in patients suspected of suffering from the disease.

A cystatin-based affinity procedure for the isolation and analysis of papain-like cysteine proteinases from tissue extracts

Cysteine-proteinases (CP) of the papain family can be affinity-adsorbed by egg white cystatin C coupled to Sepharose 4B, thus allowing their selective isolation from either tissue or cultured cell extracts as well as biolological fluids and culture media. CP complexed by immobilized cystatin are further analyzed by means of SDS-PAGE and Western blot followed by serial or parallel immunological detection. The single-step affinity adsorption of papain-like enzymes has the advantage, over immunoprecipitation techniques, of yielding the simultaneous and comprehensive picture of most CP, as both precursor and mature forms, in a given sample. Moreover, cell extraction in the presence of immobilized cystatin ensures a fast complexation of CP, avoiding artifacts, due to conversion, degradation, and, eventually, subtraction of constitutive enzymes from the sample because of their interactions with endogenous inhibitors. This will provide a pattern that might reflect more closely the real CP levels in intact cells. The method may be useful in the field of biochemistry, cell biology, and, possibly, clinical chemistry to perform rapid analyses of papain-like enzymes and to monitor changes in both cellular and extracellular CP profiles along with different physiopathological conditions.

Ionic and signal transduction alterations in Alzheimer's disease: relevance of studies on peripheral cells

Several lines of evidence indicate that Alzheimer's disease (AD) has systemic expression. Systemic changes are manifested as alterations in a number of molecular and cellular processes. Although, these alterations appear to have little or no consequence in peripheral systems, their parallel expression in the central nervous system (CNS) could account for the principal clinical manifestations of the disease. Recent research seems to indicate that alterations in ion channels, calcium homeostasis, and protein kinase C (PKC) can be linked and thereby constitute a model of pathophysiological relevance. Considering the difficulties of studying dynamic pathophysiological processes in the disease-ridden postmortem AD brain, peripheral tissues such as fibroblasts provide a suitable model to study molecular and cellular aspects of the disease.