Cellular localization of a metabotropic glutamate receptor in rat brain.

In rat brain, the cellular localization of a phosphoinositide-linked metabotropic glutamate receptor (mGluR1 alpha) was demonstrated using antibodies that recognize the C-terminus of the receptor. mGluR1 alpha, a 142 kd protein, is enriched within the olfactory bulb, stratum oriens of CA1 and polymorph layer of dentate gyrus in hippocampus, globus pallidus, thalamus, substantia nigra, superior colliculus, and cerebellum. Lower levels of mGluR1 alpha are present within neocortex, striatum, amygdala, hypothalamus, and medulla. Dendrites, spines, and neuronal cell bodies contain mGluR1 alpha. mGluR1 alpha is not detectable in presynaptic terminals. mGluR1 alpha and ionotropic alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA) receptor subunits show differential distributions, but in Purkinje cells, mGluR1 alpha and specific AMPA receptor subunits colocalize. The postsynaptic distribution of mGluR1 alpha is consistent with postulated physiological roles of this subtype of glutamate receptor.     

Human GluR6 Kainate Receptor (GRIK2): Molecular Cloning, Expression, Polymorphism, and Chromosomal Assignment

Glutamate receptors mediate the majority of excitatory neurotransmission in the brain, and molecular cloning studies have revealed several distinct families. Because neuropathological states and possibly human disorders may involve kainate-preferring glutamate receptors, we have isolated a cDNA clone for the human GluR6 kainate-preferring receptor. This clone shows a very high sequence similarity with that of the rat, except for a part of the 3′ untranslated region in which there is a TAA triplet repeat. When the protein was overexpressed in human embryonic kidney 293 cells, it had a molecular weight, an antibody recognition, and a glutamate ligand-binding profile similar to those of the rat GluR6 receptor. Northern analysis showed expression in both human cerebral and cerebellar cortices. By PCR analysis of rodent-human monochromosomal cell lines, the human GluR6 could be assigned to chromosome 6. The length of the TAA triplet repeat was polymorphic in the normal population, with at least four alleles and an observed heterozygosity of about 45%. These studies should provide the basis for expression or linkage studies of the GluR6 kainate receptor in human disease or neuropathologic states.     

Why did eukaryotes evolve only once? Genetic and energetic aspects of conflict and conflict mediation

According to multi-level theory, evolutionary transitions require mediating conflicts between lower-level units in favour of the higher-level unit. By this view, the origin of eukaryotes and the origin of multicellularity would seem largely equivalent. Yet, eukaryotes evolved only once in the history of life, whereas multicellular eukaryotes have evolved many times. Examining conflicts between evolutionary units and mechanisms that mediate these conflicts can illuminate these differences. Energy-converting endosymbionts that allow eukaryotes to transcend surface-to-volume constraints also can allocate energy into their own selfish replication. This principal conflict in the origin of eukaryotes can be mediated by genetic or energetic mechanisms. Genome transfer diminishes the heritable variation of the symbiont, but requires the de novo evolution of the protein-import apparatus and was opposed by selection for selfish symbionts. By contrast, metabolic signalling is a shared primitive feature of all cells. Redox state of the cytosol is an emergent feature that cannot be subverted by an individual symbiont. Hypothetical scenarios illustrate how metabolic regulation may have mediated the conflicts inherent at different stages in the origin of eukaryotes. Aspects of metabolic regulation may have subsequently been coopted from within-cell to between-cell pathways, allowing multicellularity to emerge repeatedly.     

A Conserved Role for Atlastin GTPases in Regulating Lipid Droplet Size

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Protein targeting and calcium signaling microdomains in neuronal cells

Over the last several years, a number of optical imaging, physiological, and molecular studies have clarified the mechanisms underlying differential calcium signaling in the postsynaptic neuron. These studies have revealed the existence of membrane-associated calcium microdomains, which are often specifically coupled to distinct protein signaling pathways. In this review, we discuss how these signaling microdomains are organized and regulated, emphasizing the structural and molecular features of synaptic protein complexes containing the metabotropic and N-methyl-D-aspartate (NMDA) glutamate receptors and the L-type voltage-dependent calcium channels (VDCCs). We conclude with a discussion of how these different signaling complexes may interact with one another, relationships which may be important in orchestrating the complex calcium signaling underlying developmental and activity-dependent changes in synaptic function.     

The evolution of a mechanism of cell suicide

In the vertebrates, programmed cell death or apoptosis frequently involves the relocalization of mitochondrial cytochrome c to the cytoplasm. This prominent role in the regulation of apoptosis is in addition to the primary function of cytochrome c in the mitochondrial electron transport chain. These seemingly divergent roles become plausible when considering the symbiotic origin of the mitochondrion. Symbiosis involves conflicts between levels of selection, in this case between the primitive host cell and the protomitochondria. In an aerobic environment, selection on the protomitochondria may have favored routine manipulations of the host cell's phenotype using products and by-products of oxidative phosphorylation, in particular reactive oxygen species (ROS). Blocking the mitochondrial electron transport chain by removing cytochrome c enhances the production of ROS; thus cytochrome c release by protomitochondria may have altered the host cell's phenotype via enhanced ROS production. Subsequently, this signaling pathway may have been refined by selection so that cytochrome c itself became the trigger for changes in the host's phenotype. A mechanism of apoptosis in metazoans may thus be a vestige of evolutionary conflicts within the eukaryotic cell.     

Detection of pathogenic Vibrio parahaemolyticus in oyster enrichments by real time PCR

A real time polymerase chain reaction (PCR) assay was developed and evaluated to detect the presence of the thermostable direct hemolysin gene (tdh), a current marker of pathogenicity in Vibrio parahaemolyticus. The real time PCR fluorogenic probe and primer set was tested against a panel of numerous strains from 13 different bacterial species. Only V. parahaemolyticus strains possessing the tdh gene generated a fluorescent signal, and no cross-reaction was observed with tdh negative Vibrio or non-Vibrio spp. The assay detected a single colony forming unit (CFU) per reaction of a pure culture template. This sensitivity was achieved when the same template amount per reaction was tested in the presence of 2.5 microl of a tdh negative oyster:APW enrichment (oyster homogenate enriched in alkaline peptone water overnight at 35 degrees C). This real time technique was used to test 131 oyster:APW enrichments from an environmental survey of Alabama oysters collected between March 1999 and September 2000. The results were compared to those previously obtained using a streak plate procedure for culture isolation from the oyster:APW enrichment combined with use of a non-radioactive DNA probe for detection of the tdh gene. Real time PCR detected tdh in 61 samples, whereas the streak plate/probe method detected tdh in 15 samples. Only 24 h was required for detection of pathogenic V. parahaemolyticus in oyster:APW enrichments by real time PCR, whereas the streak plate/probe method required 3 days and was more resource intensive. This study demonstrated that real time PCR is a rapid and reliable technique for detecting V. parahaemolyticus possessing the tdh gene in pure cultures and in oyster enrichments.     

Redox control and the evolution of multicellularity

Redox chemistry, involving the transfer of electrons and hydrogen atoms, is central to energy conversion in respiration; in addition, control of gene expression by redox state commonly occurs in bacteria, allowing a rapid response to environmental changes, such as altered food supply. Colonial metazoans often encrust surfaces over which the food supply varies in time or space; hence, in these organisms redox control of the development of feeding structures and gastrovascular connections could be similarly adaptive, allowing colonies to adjust the timing of development and spacing of structures in response to a variable food supply and other environmental factors. Experimental perturbations of redox state in colonial hydroids support this notion of adaptive redox control, and redox signaling in metazoans may have evolved in this ecological context. At the same time, redox signaling has important consequences for the evolutionary transition from unicellular to multicellular organisms. Unlike protein or peptide signaling, redox signaling acting in concert with programmed cell death may automatically inflict a cost on those cells that "defect," that is, selfishly favor their own replication rate over that of the multicellular group. In this way, redox signaling may have allowed multicellular individuality to evolve and more easily be maintained.