Klaus Mendla

Cloning and functional characterization of a human A1 adenosine receptor.

A human brain hippocampus cDNA library was screened by hybridization with a dog A1 adenosine receptor cDNA probe. Sequencing of the resulting clones identified a 978 residue open reading frame encoding a 326 amino acid polypeptide showing 95.7% similarity with the dog A1 adenosine receptor. Individual clones of stably transfected CHO cells expressing the human A1 receptor were obtained and tested for their response to the A1 agonist CPA [N6-cyclopentyladenosine] in the presence of forskolin. One clone was further characterized with respect to membrane binding of various adenosine agonists and antagonists. The rank order of affinities observed was typical of an A1 adenosine receptor. A Kd value of 2.28 nM was determined using [3H]DPCPX [dipropylcyclopentyl-xanthine], an A1 selective antagonist.

Muscarinic m1 receptor agonists increase the secretion of the amyloid precursor protein ectodomain

Amyloid deposits in Alzheimers disease are composed of amyloid beta-peptides (A beta) that are derived from the larger amyloid precursor protein (APP). Proteolytic APP processing is activity-dependent, and it can be regulated by muscarinic acetylcholine receptors. In particular, muscarinic m1 receptor subtypes increase cleavage within the A beta domain, followed by the release of the soluble APP ectodomain (APPs). In this study, we show that the m1-selective agonist talsaclidine concentration-dependently increased APPs release from both transfected human astrocytoma cell lines and rat brain slices. This increase was blocked by atropine. In contrast, the M2 antagonist BIBN 99 failed to increase APPs release, and decreased it at higher concentrations. These results show that talsaclidine can effectively modulate alpha-secretase processing of APP in human cell lines and in brain tissue. The data suggest that talsaclidine may be a useful candidate drug to modulate APP processing in Alzheimers disease.

WAL 2014 - A muscarinic agonist with preferential neuron-stimulating properties

The ability of WAL 2014 to elicit muscarinic responses was investigated in various in vitro and in vivo models. In CHO cells transfected with human m1- or m3- receptor genes, WAL 2014 was clearly more effective in stimulating the M1-mediated PI response. In isolated tissue preparations, WAL 2014 exhibited full agonist properties in the rabbit vas deferens (putative M1 receptor) and behaved like a partial agonist at M2 receptors in the atrium and M3 receptors in the ileum of guinea-pigs. In the pithed rat, in which the increase in blood pressure is mediated through a stimulation of M1 receptors in sympathetic ganglia, WAL 2014 produced a full dose response curve, whereas the reference compounds RS 86 and arecoline exhibited a bell-shaped behaviour. This is in accord with the view that WAL 2014 selectively activates M1 receptors in sympathetic ganglia, whereas conventional agonists in the same dose range stimulate both ganglionic M1 and vascular M3 receptors. The preferential neuron-stimulating properties were confirmed by EEG recording in the rabbit, in which muscarinic activation occurred at doses similar to those for ganglionic stimulation in the pithed rat. On the other hand, higher doses of WAL 2014 were needed to elicit muscarinic effects in peripheral effector organs, i.e. bradycardia, urinary bladder contraction and increase in airway resistance. It is concluded that WAL 2014 due to its preferential neuronal activity is a promising candidate for a cholinergic substitution therapy in Alzheimers disease.

Dependence of cerebrospinal fluid Tau protein levels on apolipoprotein E4 allele frequency in patients with Alzheimer's disease

Consistent pathological hallmarks of Alzheimers disease (AD) are the formation of brain amyloid and neurofibrillary tangles (NFTs). Levels of the major protein component of NFTs, the microtubule associated protein Tau, were shown to be increased in cerebrospinal fluid (CSF) of AD patients as compared to age-matched controls. The presence of apolipoprotein E-epsilon 4 allele (APOE4) is a risk factor for sporadic and familial late-onset AD. ApoE may interact with the binding of Tau to microtubules and Tau phosphorylation in an isoform-specific manner. We investigated whether direct evidence of an isoform-specific interaction of apoE and Tau can be demonstrated in the CSF of live AD patients. We measured the apoE genotype and CSF levels of Tau in 19 patients with probable AD and 12 age-matched control subjects. We found that CSF levels of Tau increase with increasing APOE allele frequency (Spearman rank correlation, zeta = 2.71, P = 0.007). This finding may be in agreement with reports of a lesser binding of apoE4 to Tau, compared to apoE2 and apoE3, resulting in higher levels of unbound Tau in CSF.

Constitutive overactivation of protein kinase C in guinea pig brain increases α-secretory APP processing without decreasing β-amyloid generation

Whilst it is generally accepted that the activation of protein kinase C (PKC) increases amyloid precursor protein (APP) secretion in vitro, the role of PKC in the regulation of APP processing and β‐amyloid generation in vivo is still not well understood. In order to address this question, we established the animal model of neocortical microencephalopathy in guinea pigs caused by in utero treatment with methylazoxymethanol acetate, a DNA‐methylating substance that eliminates proliferating cells of neuroepithelial origin. The induction of this neocortical malformation is accompanied by constitutive overactivation of PKC in the neocortex of the offspring. In the cortical and hippocampal tissues of juvenile microencephalic guinea pigs (postnatal day 30), we observed significant increases in basal (by 58% and 74%, respectively,) and phorbol ester‐stimulated PKC enzyme activity (by 47% and 71%) as compared to age‐matched control animals. In the same cortical/hippocampal preparations of methylazoxymethanol‐treated animals, there was increased α‐secretion of APP by 35% and 30% as measured by Western blot analysis using the antibody 6E10, whilst total APP secretion as well as APP mRNA expression remained unaltered. This upregulation of APP α‐secretion was limited to brain areas that displayed elevated PKC activity. However, constitutive overactivation of neocortical PKC did not affect the generation of β‐amyloid peptides 1–40 or 1–42 as measured by ELISA, suggesting that only the α‐secretase pathway of APP processing is affected by chronic PKC overactivation in vivo.

Protein kinase Cα and β1 isoforms are regulators of α‐secretory proteolytic processing of amyloid precursor protein in vivo

We have recently shown that in utero treatment of guinea pigs with the DNA methylating substance methylazoxymethanol acetate (MAM) results in neocortical microencephalopathy, increased protein kinase C (PKC) activity and altered processing of the amyloid precursor protein (APP) in neocortex of offspring. Here we show that PKCα and PKCβ1 are the key regulators of α‐secretory APP processing in guinea pig neocortex under these experimental conditions in vivo. This conclusion is based on the selective translocation of PKCα and PKCβ1 isoforms to the cell membrane in MAM‐treated guinea pigs, as revealed by Western blot analysis and by immunocytochemistry. Additionally, we observed that [3H]phorbol ester binding to protein kinase C increased by 38% and enhanced basal PKC activity by 58% in the neocortex of microencephalic guinea pigs. Inhibition of PKCα/PKCβ1 by Gö6976 abolished this difference, suggesting that constitutive overactivation of these PKC isoforms accounts for the increase in total PKC activity. We also observed a strong positive correlation between levels of α‐secretase‐processed APP and PKC activity in the neocortex of individual animals, providing further evidence for a significant role of classical PKC isoforms in nonamyloidogenic APP processing.

WAL 2014 FU (Talsaclidine) : A preferentially neuron activating muscarinic agonist for the treatment of Alzheimer's disease

The functional selectivity of WAL 2014 FU with regard to stimulation of the neuronal muscarinic M1 receptor subtype in vitro and in vivo is shown in different receptor preparations, isolated organ models, whole animal testing, and finally humans. From receptor binding experiments in membrane preparations from rat tissues and from Chinese hamster ovary cells expressing human muscarinic receptor subtypes, it can be delineated that the ratio between M1 and M2 (hm1 and hm2) is shifted in favour of the M1 receptor affinity, when compared to several classic muscarinic agonists such as carbachol, arecoline, and oxotremorine. The intermediate GTP‐shift of 7.5 for WAL 2014 FU in a M2 muscarinic receptor preparation (rat heart) indicates only partial agonistic activity at this subtype, carbachol (e.g., shows a shift of 51). Moreover, the ratio from agonist to antagonist receptor binding comparing the affinities using [3H]cis‐methyldioxolane and [3H]N‐methylscopolamine as radioligands, suggests only a partial agonist behaviour at M2 receptors, too.