Adenosine A1 receptors mediate inhibition of cAMP formation in vitro in the pontine, REM sleep induction zone.

Microinjection of adenosine A1 receptor agonist or an inhibitor of adenylyl cyclase into the caudal, oral pontine reticular formation (PnOc) of the rat induces a long-lasting increase in REM sleep. Here, we report significant inhibition of forskolin-stimulated cAMP in dissected pontine tissue slices containing the PnOc incubated with the A1 receptor agonist, cyclohexaladenosine (10(-8) M). These data are consistent with adenosine A1 receptor agonist actions on REM sleep mediated through inhibition of cAMP.

Cholinergic neuropathology in a mouse model of Alzheimer's disease.

Transgenic mice overexpressing mutant human amyloid precursor protein (PDAPP mice) develop several Alzheimer's disease (AD)-like lesions including an age-related accumulation of amyloid-beta (Abeta)-containing neuritic plaques. Although aged, heterozygous PDAPP mice also exhibit synaptic and glial cell changes characteristic of AD pathology, no evidence of widespread neuronal loss has been observed. The present study sought to determine whether homozygous PDAPP mice, which express very high levels of Abeta peptide, exhibit AD-like cholinergic degenerative changes, and whether the changes parallel the deposition of Abeta plaques. Mice were examined at 2 and 4 months and at 1 and 2 years of age. There was an age-related increase in the density of Abeta plaques in the cortex and hippocampus of the PDAPP animals; at 4 months of age there were very few plaques, and at 2 years there was a very high density of plaques. There was an age-related reduction in the density of cholinergic nerve terminals in the cerebral cortex; at 2 months there was a normal density of nerve terminals, but as early as age 4 months there was an approximately 50% reduction. However, at age 2 years there was no difference in the number or size of basal forebrain cholinergic somata compared with 2-month-old PDAPP mice. These data indicated that the homozygous PDAPP mouse exhibits cholinergic nerve terminal degenerative pathology and that the cortical neurodegenerative changes occur before the deposition of Abeta-containing neuritic plaques.

MPTP: insights into parkinsonian neurodegeneration.

MPTP burst upon the medical landscape two decades ago, first as a mysterious parkinsonian epidemic, triggering an unparalleled quest for the toxin's identity, and closely followed by an intense pursuit of its cellular mechanisms of action. MPTP treatment created an animal model of many features of Parkinson's disease (PD), used primarily in primates and later in mice. The critical role of oxidative stress damage to vulnerable dopamine neurons, as well as for neurodegenerative diseases in general, emerged from MPTP neurotoxicity. A remarkable cross-fertilization of basic and clinical findings, including genetic and epidemiologic studies, has greatly advanced our understanding of PD and revealed multiple factors contributing to the parkinsonian phenotypes. Brain imaging localizes sites of action and provides potential presymptomatic diagnostic testing. Epidemiologic reports linking PD with pesticide exposure were complimented by supportive evidence from biochemical studies of MPTP and structurally related compounds, especially after low-level, long-term exposure. Genetic studies on the role of risk genes, such as alpha-synuclein or parkin, have been validated by biochemical, anatomical and neurochemical investigations showing factors interacting to produce pathophysiology in the animal model. Focusing on the pivotal role of mitochondria, subcellular pathways participating in cell death have been clarified by unraveling similar sites of action of MPTP. Along the way, compounds antagonizing or potentiating MPTP effects indicated new PD therapies, some of the former achieving clinical trials. The future is encouraging for combating PD and will continue to benefit from the MPTP neurotoxicity model.

C-tau biomarker of neuronal damage in severe brain injured patients: association with elevated intracranial pressure and clinical outcome.

Following traumatic brain injury, the neuronally-localized intracellular protein MAP-tau is proteolytically cleaved (C-tau) and gains access to cerebrospinal fluid (CSF) and serum. The present study compared initial CSF C-tau levels, initial Glasgow Coma Scale (GCS) scores and elevated intracranial pressure (ICP) as predictors of clinical outcome. In this preliminary, prospective study of consecutive severe traumatic brain injured patients (TBI) clinical outcome was quantified with the Glasgow Outcome Scale (GOS) at discharge (n=28). Sensitivity and specificity of initial C-tau levels and initial GCS scores as predictors of clinical outcome is reported. To assess disease specificity C-tau levels were compared between TBI patients and neurologic (n=87) and non-neurologic control patients (n=67). Initial CSF C-tau levels were elevated 40,000 fold in TBI patients compared to either neurologic or non-neurologic control patients (P<0.001). Initial C-tau levels were correlated with clinical outcome (P=0.006) and were a significant predictor of dichotomized clinical outcome (P=0.011) demonstrating a sensitivity of prediction of 92% and a specificity of 94%. Initial C-tau levels were also a significant predictor of subsequent ICP with higher initial C-tau levels associated with elevated ICP (P=0.014). Initial GCS score were correlated with clinical outcome (P=0.026) and demonstrated a sensitivity of 50% and a specificity of 100% for predicting dichotomized clinical outcome. Statistical analysis indicated that initial C-tau levels and initial GCS scores were independent predictors of clinical outcome. The present preliminary study demonstrates that initial CSF C-tau levels are a significant predictor of ICP and clinical outcome with particular sensitivity for identifying severe TBI patients with good clinical outcome. Future studies employing a larger sample size and clinical outcome assessment at longer periods after hospitalization will be needed to determine the utility of initial C-tau levels as a clinical biomarker in TBI.