D2 and D4 dopamine receptor mRNA distribution in pyramidal neurons and GABAergic subpopulations in monkey prefrontal cortex: implications for schizophrenia treatment.

D2 and D4 dopamine receptors play an important role in cognitive functions in the prefrontal cortex and they are involved in the pathophysiology of neuropsychiatric disorders such as schizophrenia. The eventual effect of dopamine upon pyramidal neurons in the prefrontal cortex depends on which receptors are expressed in the different neuronal populations. Parvalbumin and calbindin mark two subpopulations of cortical GABAergic interneurons that differently innervate pyramidal cells. Recent hypotheses about schizophrenia hold that the root of the illness is a dysfunction of parvalbumin chandelier cells that produces disinhibition of pyramidal cells. In the present work we report double in situ hybridization histochemistry experiments to determine the prevalence of D2 receptor mRNA and D4 receptor mRNA in glutamatergic neurons, GABAergic interneurons and both parvalbumin and calbindin GABAergic subpopulations in monkey prefrontal cortex layer V. We found that around 54% of glutamatergic neurons express D2 mRNA and 75% express D4 mRNA, while GAD-positive interneurons express around 34% and 47% respectively. Parvalbumin cells mainly expressed D4 mRNA (65%) and less D2 mRNA (15-20%). Finally, calbindin cells expressed both receptors in similar proportions (37%). We hypothesized that D4 receptor could be a complementary target in designing new antipsychotics, mainly because of its predominance in parvalbumin interneurons.

In situ hybridization for vasopressin mRNA in the human supraoptic and paraventricular nucleus; quantitative aspects of formalin-fixed paraffin-embedded tissue sections as compared to cryostat sections.

In order to study the suitability of formalin-fixed paraffin-embedded brain tissue for vasopressin (AVP)-mRNA detection, we used symmetric halves of 5 human hypothalami. In every case, one half was formalin fixed for 10-35 days and paraffin embedded while the other half was frozen rapidly. Following in situ hybridization (ISH) histochemistry on systematically obtained sections of the supraoptic (SON) and paraventricular nucleus (PVN) of both halves, total amounts of AVP-mRNA in these nuclei were estimated using densitometry of film autoradiographs. Total amounts of radioactivity were found to vary considerably between patients and amounted to 1297 +/- 302 arbitrary units (AU) (PVN) (mean +/- SEM) and 2539 +/- 346 (SON) for the cryostat sections and 868 +/- 94 (PVN) and 1259 +/- 126 (SON) for the paraffin tissue. Variations introduced by the method itself yielded a coefficient of variation of only 0.19. Furthermore, a non-significant negative trend with postmortem delay was found in cryostat tissue, but not in paraffin sections. No effect of fixation time was observed in the paraffin tissue. Both ways of tissue treatment have specific advantages and disadvantages that may be different for other probes or other brain areas. For ISH of a highly abundant mRNA like AVP in a very heterogeneous brain area such as the human hypothalamus, formalin-fixed paraffin-embedded tissue sections can be used for quantitative analysis of entire brain nuclei because of the small variation in this tissue, the remarkably good signal recovery (some 75% as compared to cryostat sections) and its practical advantages with regards to anatomical orientation, storage and sampling of the tissue.

Receptor localization in the human hypothalamus.

In summary, we have illustrated and discussed the applicability of different techniques to the study of neurotransmitter receptors in the human brain. Because of the availability of these techniques it is possible today to examine in detail the alterations in density produced by different physiological or pathological conditions. The use of these techniques will in the future, without any doubt, be of help in understanding the chemical neuroanatomy of the human hypothalamus.

In situ hybridization histochemistry in the human hypothalamus.

We have seen that mRNA for several neuropeptides can be visualized at the microscopic level in human post-mortem brain tissues using in situ hybridization histochemistry and oligonucleotides as probes. The specificity of the hybridization signal detected in each case is supported by several criteria such as Northern blot analysis, use of at least two oligonucleotides complementary to different regions of the same target mRNA, cohybridization of labeled and excess unlabeled oligonucleotide probes, and melting curve analysis of the formed hybrids. Furthermore, factors such as age, post-mortem delay or gender did not show a significant effect in the levels of hybridization in the control population studied. Hybridization signals comparable to those found in the control population were obtained in frozen tissues, stored for up to 6 years before analysis. The results obtained for the different neuropeptides examined are, in general, in good agreement with the available information on their distribution and cellular localization as determined by radioimmunoassay or immunohistochemistry. The use of in situ hybridization histochemistry has clearly revealed the location of neurons synthesizing these neuropeptides, adding important information to that provided by radioimmunoassay or immunohistochemistry. A typical example is the identification of peptide synthesizing neuronal cell bodies by immunohistochemistry. This requires, in some cases, the use of treatments such as colchicine, obviously impossible with human brain tissues. The abundance of mRNA could be further related to transcriptional activity and, when compared with peptide levels, can provide some clues on peptide turnover rates. Thus in the hypothalamus, the paraventricular and supraoptic nuclei were found to contain cells expressing arginine-vasopressin and oxytocin mRNAs. Their distribution was in good agreement with that determined by immunohistochemistry (Dierickx and Vandesande, 1977). We have also found that these nuclei contain transcripts for neuropeptide genes such as preproenkephalin A, neuropeptide Y and somatostatin, in agreement with previously reported immunohistochemical data (Agid and Javoy-Agid, 1985; Emson et al., 1986). In the basal ganglia, numerous cells heterogeneously distributed throughout the caudate and putamen nuclei were found to contain preproenkephalin A mRNA.(ABSTRACT TRUNCATED AT 400 WORDS)

Muscarinic M2 receptor mRNA expression and receptor binding in cholinergic and non-cholinergic cells in the rat brain: a correlative study using in situ hybridization histochemistry and receptor autoradiography.

The goal of the present study was to identify the cells containing mRNA coding for the m2 subtype of muscarinic cholinergic receptors in the rat brain. In situ hybridization histochemistry was used, with oligonucleotides as hybridization probes. The distribution of cholinergic cells was examined in consecutive sections with probes complementary to choline acetyltransferase mRNA. Furthermore, the microscopic distribution of muscarinic cholinergic binding sites was examined with a non-selective ligand ([3H]N-methylscopolamine) and with ligands proposed to be M1-selective ([3H]pirenzepine) or M2-selective ([3H]oxotremorine-M). The majority of choline acetyltransferase mRNA-rich (i.e. cholinergic) cell groups (medial septum-diagonal band complex, nucleus basalis, pedunculopontine and laterodorsal tegmental nuclei, nucleus parabigeminalis, several motor nuclei of the brainstem, motoneurons of the spinal cord), also contained m2 mRNA, strongly suggesting that at least a fraction of these receptors may be presynaptic autoreceptors. A few groups of cholinergic cells were an exception to this fact: the medial habenula and some cranial nerve nuclei (principal oculomotor, trochlear, abducens, dorsal motor nucleus of the vagus). Furthermore, m2 mRNA was not restricted to cholinergic cells but was also present in many other cells throughout the rat brain. The distribution of m2 mRNA was in good, although not complete, agreement with that of binding sites for the M2 preferential agonist [3H]oxotremorine-M, but not with [3H]pirenzepine binding sites. Regions where the presence of [3H]oxotremorine-M binding sites was not correlated with that of m2 mRNA are the caudate-putamen, nucleus accumbens, olfactory tubercle and islands of Calleja. The present results strongly suggest that the M2 receptor is expressed by a majority of cholinergic cells, where it probably plays a role as autoreceptor. However, many non-cholinergic neurons also express this receptor, which would be, presumably, postsynaptically located. Finally, comparison between the distribution of m2 mRNA and that of the proposed M2-selective ligand [3H]oxotremorine-M indicates that this ligand, in addition to M2 receptors, may also recognize in certain brain areas other muscarinic receptor populations, particularly M4.

Localization of the mRNA for the 5-HT2 receptor by in situ hybridization histochemistry. Correlation with the distribution of receptor sites.

32P-labelled oligonucleotides complementary to rat 5-HT2 receptor mRNA were used as probes to study the distribution of cells in rat brain containing the mRNA coding for this receptor by in situ hybridization histochemistry. 5-HT2 receptor binding sites were visualized by autoradiography using [125I]DOI as ligand. Both distributions were comparable, demonstrating that 5-HT2 receptors are expressed by cells intrinsic to the neocortex (lamina Va), claustrum, olfactory bulb and several nuclei of the brainstem.

Regional distribution of the expression of a human stimulatory GTP-binding protein alpha-subunit in the human brain studied by in situ hybridization.

Using a cDNA probe complementary to an mRNA coding for the alpha-subunit of a human GTP-binding protein that stimulates adenylate cyclase we have studied its regional distribution in human brain by in situ hybridization histochemistry. The specificity of the hybridization signal was examined by using a labelled sense probe and RNase treatment. Gs alpha transcripts presented a widespread but heterogeneous distribution in human brain postmortem tissues. The cell bodies of the granular layer of the cerebellum were the most heavily labelled cells in all the cases examined. High levels of hybridization were also seen in the pyramidal cell layer of the hippocampus and over the cell bodies of the granule cells of the dentate gyrus. Several cortical regions also presented high levels of hybridization. Another area rich in the Gs alpha mRNA was the hypothalamus. The caudate and putamen nuclei presented intermediate levels while the globus pallidus, the thalamus, the midbrain and the brainstem presented only very low levels of hybridization. This distribution differs from the known distribution of adenylate cyclase activity and other GTP-binding proteins, and could indicate that this particular Gs alpha clone codes for a subset of the alpha-subunit of the Gs protein family.