Cholecystokinin expression after hippocampal deafferentiation: molecular evidence revealed by differential display-reverse transcription-polymerase chain reaction

Quantitative gene-expression analysis of the ligand-receptor system for classical neurotransmitters and neuropeptides in hippocampal CA1, CA3, and dentate gyrus

We have shown quantitative expression levels of genes coding for the "ligand-receptor system" for classical neurotransmitters and neuropeptides in hippocampal subregions CA1, CA3, and dentate gyrus (DG). Using a combination of DNA microarray and quantitative PCR methods, we found that the three subregions have relatively similar expression patterns of ionotropic receptors for classical neurotransmitters. Expression of ionotropic receptors for glutamate and GABA represents more than 90% of all ionotropic receptors for classical neurotransmitters, and the expression ratio between ionotropic receptors for glutamate and GABA is constant (1.2:1-1.6:1) in each subregion. Meanwhile, the three subregions have different expression patterns of neuropeptide receptors. Furthermore, there are asymmetric expression patterns between neuropeptides and their receptors. Expression of Cck, Npy, Sst, and Penk1 represents 90% of neuropeptides derived locally in the hippocampus, whereas expression of these four neuropeptide receptors accounts for 50% of G protein-coupled receptors for neuropeptides. We propose that CA1, CA3, and DG have different modalities based on the ligand-receptor system, particularly the "neuropeptidergic system." Our quantitative gene-expression analysis provides fundamental data to support functional differences between the three hippocampal subregions regarding ligand-receptor interactions.

Gene expression profiling of neuropeptides in mouse cerebellum, hippocampus, and retina

OBJECTIVE

We examined gene expression profiling in single neuron types and small regions of the nervous system.

METHODS

The RNAs were extracted from mouse cerebellar Purkinje cells, granule cell layer, hippocampal CA1 and CA3 pyramidal cell layers, and three layers of the retina (outer nuclear layer, inner nuclear layer, and ganglion cell layer) were dissected by laser capture microdissection. The gene expression profiling of each sample was examined by Affymetrix GeneChip and real-time reverse transcription polymerase chain reaction. We studied the gene expression of 62 neuropeptide and hormone genes and 387 G-protein-coupled receptor (GPCR) genes.

RESULTS

Among them, cholecystokinin and neuropeptide Y genes were the most widely expressed. The gene expression of cholecystokinin was very high in the hippocampus, suggesting that cholecystokinin transcripts might have unknown roles in the hippocampus. More than 10 neuropeptide genes were expressed in the ganglion cell layer of the retina, whereas the outer nuclear layer of the retina did not express a considerable amount of neuropeptide mRNAs. In total 12 GPCR genes were found in all tissues examined, and half were orphans (6 of 12).

CONCLUSION

The high ratio of orphan GPCR genes suggests our limited knowledge of the ligand-receptor system in the nervous system. These results provide basic information for studying the function of neuropeptides.

Lipid phosphate phosphatases and related proteins: signaling functions in development, cell division, and cancer

Lipid phosphates initiate key signaling cascades in cell activation. Lysophosphatidate (LPA) and sphingosine 1-phosphate (S1P) are produced by activated platelets. LPA is also formed from circulating lysophosphatidylcholine by autotaxin, a protein involved tumor progression and metastasis. Extracellular LPA and S1P stimulate families of G-protein coupled receptors that elicit diverse responses. LPA is involved in wound repair and tumor growth. Exogenous S1P is a potent stimulator of angiogenesis, a process vital in development, tissue repair and the growth of aggressive tumors. Inside the cell, phosphatidate (PA), ceramide 1-phosphate (C1P), LPA, and S1P act as signaling molecules with distinct functions including the stimulation of cell division, cytoskeletal rearrangement, Ca(2+) transients, and membrane movement. These observations imply that phosphatases that degrade lipid phosphates on the cell surface, or inside the cell, regulate cell signaling under physiological and pathological conditions. This occurs through attenuation of signaling by the lipid phosphates and by the production of bioactive products (diacylglycerol, ceramide, and sphingosine). Three lipid phosphate phosphatases (LPPs) and a splice variant dephosphorylate LPA, PA, CIP, and S1P. Two S1P phosphatases (SPPs) act specifically on S1P. In addition, there is family of four LPP-related proteins (LPRs, or plasticity-related genes, PRGs). PRG-1 expression in neurons has been reported to increase extracellular LPA breakdown and attenuate LPA-induced axonal retraction. It is unclear whether the LRPs dephosphorylate LPA directly, stimulate LPP activity, or bind LPA and S1P. Also, the importance of extra- versus intra-cellular actions of the LPPs and SPPs, and the individual roles of different isoforms is not firmly established. Understanding the functions and regulation of the LPPs, SPPs and related proteins will hopefully contribute to interventions to correct dysfunctions in conditions such as wound repair, inflammation, angiogenesis, tumor growth, and metastasis.

Molecular cloning and expression regulation of PRG-3, a new member of the plasticity-related gene family

Phospholipid-mediated signalling on neurons provokes diverse responses such as neurogenesis, pattern formation and neurite remodelling. We have recently uncovered a novel set of molecules in the mammalian brain, named plasticity-related genes (PRGs), which mediate lipid phosphate phosphatase activity and provide evidence for their involvement in mechanisms of neuronal plasticity. Here, we report on a new member of the vertebrate-specific PRG family, which we have named plasticity-related gene-3 (PRG-3). PRG-3 is heavily expressed in the brain and shows a specific expression pattern during brain development where PRG-3 expression is found predominantly in neuronal cell layers and is already expressed at embryonic day 16. In the mature brain, strongest PRG-3 expression occurs in the hippocampus and cerebellum. Overexcitation of neurons induced by kainic acid leads to a transient down-regulation of PRG-3. Furthermore, PRG-3 is expressed on neurite extensions and promotes neurite growth and a spreading-like cell body in neuronal cells and COS-7 cells. In contrast to previously described members of the PRG family, PRG-3 does not perform its function through enzymatic phospholipid degradation. In summary, our findings feature a new member of the PRG family which shows dynamic expression regulation during brain development and neuronal excitation.

Identification of macrophage/microglia activation factor (MAF) associated with late endosomes/lysosomes in microglial cells

Damage to the central nervous system triggers rapid activation and specific migration of glial cells towards the lesion site. There, glial cells contribute heavily to secondary neuronal changes that take place after lesion. In an attempt to identify the molecular cues of glial activation following brain trauma we performed differential display reverse transcription-polymerase chain reaction screenings from lesioned and control hippocampus. Here we report on the identification of the macrophage/microglia activation factor (MAF), a new membrane protein with seven putative transmembrane domains. Expression analysis revealed that MAF is predominantly expressed in microglial cells in the brain, and is upregulated following brain lesion. Overexpression of MAF in non-glial cells shows an intracellular codistribution with the lysosomal marker endosome/lysosome-associated membrane protein-1 (lamp-1). Furthermore, MAF-transfected cells show that MAF is primarily associated with late endosomes/lysosomes, and that this association can be disrupted by activation of protein kinase C-dependent pathways. In conclusion, these results imply that MAF is involved in the dynamics of lysosomal membranes associated with microglial activation following brain lesion.