Evidence for HTR1A and LHPP as interacting genetic risk factors in major depression.

The HTR1A -1019C>G genotype was associated with major depression in the Utah population. Linkage analysis on Utah pedigrees with strong family histories of major depression including only cases with the HTR1A -1019G allele revealed a linkage peak on chromosome 10 (maximum HLOD=4.4). Sequencing of all known genes in the linkage region revealed disease-segregating single-nucleotide polymorphisms (SNPs) in LHPP. LHPP SNPs were also associated with major depression in both Utah and Ashkenazi populations. Consistent with the linkage evidence, LHPP associations depended on HTR1A genotype. Lhpp or a product of a collinear brain-specific transcript, therefore, may interact with Htr1a in the pathogenesis of major depression.

P2X receptor-mediated ionic currents in dorsal root ganglion neurons.

Nociceptive neurons in the dorsal root ganglia (DRG) are activated by extracellular ATP, implicating P2X receptors as potential mediators of painful stimuli. However, the P2X receptor subtype(s) underlying this activity remain in question. Using electrophysiological techniques, the effects of P2X receptor agonists and antagonists were examined on acutely dissociated adult rat lumbar DRG neurons. Putative P2X-expressing nociceptors were identified by labeling neurons with the lectin IB4. These neurons could be grouped into three categories based on response kinetics to extracellularly applied ATP. Some DRG responses (slow DRG) were relatively slowly activating, nondesensitizing, and activated by the ATP analogue alpha,beta-meATP. These responses resembled those recorded from 1321N1 cells expressing recombinant heteromultimeric rat P2X2/3 receptors. Other responses (fast DRG) were rapidly activating and desensitized almost completely during agonist application. These responses had properties similar to those recorded from 1321N1 cells expressing recombinant rat P2X3 receptors. A third group (mixed DRG) activated and desensitized rapidly (P2X3-like), but also had a slow, nondesensitizing component that functionally prolonged the current. Like the fast component, the slow component was activated by both ATP and alpha, beta-meATP and was blocked by the P2X antagonist TNP-ATP. But unlike the fast component, the slow component could follow high-frequency activation by agonist, and its amplitude was potentiated under acidic conditions. These characteristics most closely resemble those of rat P2X2/3 receptors. These data suggest that there are at least two populations of P2X receptors present on adult DRG nociceptive neurons, P2X3 and P2X2/3. These receptors are expressed either separately or together on individual neurons and may play a role in the processing of nociceptive information from the periphery to the spinal cord.

Neurons of the human frontal cortex display apolipoprotein E immunoreactivity: implications for Alzheimer's disease.

Apolipoprotein E (apoE) is a plasma protein that regulates lipid transport and cholesterol homeostasis. In humans, apoE occurs as 3 major isoforms (apoE2, E3, and E4). Genetic evidence demonstrates an overrepresentation of the apoE epsilon 4 allele in Alzheimer's disease (AD). While apoE immunoreactivity (IR) is associated with the amyloid plaques and neurofibrillary tangles of AD, few studies have characterized the localization of apoE in normal human brains. We examined the distribution of apoE in the cerebral cortex of normal aged individuals and compared the results to clinically diagnosed and pathologically confirmed AD cases. In addition, we characterized the apoE IR in brains from high plaque non-demented (HPND) cases. We observed consistent and widespread apoE staining in cortical neurons from normal and HPND individuals. This finding was confirmed by double immunostaining which colocalized apoE with microtubule-associated protein-2, as well as low density lipoprotein receptor-related protein, an apoE receptor found on neurons. In contrast, AD brains displayed apoE IR in plaques and neurofibrillary tangles with little neuronal staining. These data clearly establish the presence of apoE in normal neurons, supporting an intracellular role for apoE. Moreover, the results suggest that this function of apoE is disrupted in AD, where apoE staining of neurons was drastically reduced.