Luigi F. Agnati

Molecular Mechanisms and Therapeutical Implications of Intramembrane Receptor/Receptor Interactions among Heptahelical Receptors with Examples from the Striatopallidal GABA Neurons

The molecular basis for the known intramembrane receptor/receptor interactions among G protein-coupled receptors was postulated to be heteromerization based on receptor subtype-specific interactions between different types of receptor homomers. The discovery of GABAB heterodimers started this field rapidly followed by the discovery of heteromerization among isoreceptors of several G protein-coupled receptors such as δ/κ opioid receptors. Heteromerization was also discovered among distinct types of G protein-coupled receptors with the initial demonstration of somatostatin SSTR5/dopamine D2 and adenosine A1/dopamine D1 heteromeric receptor complexes. The functional meaning of these heteromeric complexes is to achieve direct or indirect (via adapter proteins) intramembrane receptor/receptor interactions in the complex. G protein-coupled receptors also form heteromeric complexes involving direct interactions with ion channel receptors, the best example being the GABAA/dopamine D5 receptor heteromerization, as well as with receptor tyrosine kinases and with receptor activity modulating proteins. As an example, adenosine, dopamine, and glutamate metabotropic receptor/receptor interactions in the striatopallidal GABA neurons are discussed as well as their relevance for Parkinsons disease, schizophrenia, and drug dependence. The heterodimer is only one type of heteromeric complex, and the evidence is equally compatible with the existence of higher order heteromeric complexes, where also adapter proteins such as homer proteins and scaffolding proteins can exist. These complexes may assist in the process of linking G protein-coupled receptors and ion channel receptors together in a receptor mosaic that may have special integrative value and may constitute the molecular basis for some forms of learning and memory.

Astrocytes and Glioblastoma cells release exosomes carrying mtDNA

Cells can exchange information not only by means of chemical and/or electrical signals, but also via microvesicles released into the intercellular space. The present paper, for the first time, provides evidence that Glioblastoma and Astrocyte cells release microvesicles, which carry mitochondrial DNA (mtDNA). These microvesicles have been characterised as exosomes in view of the presence of some protein markers of exosomes, such as Tsg101, CD9 and Alix. Thus, the important finding has been obtained that bonafide exosomes, constitutively released by Glioblastoma cells and Astrocytes, can carry mtDNA, which can be, therefore, transferred between cells. This datum may help the understanding of some diseases due to mitochondrial alterations.

Integrated events in central dopamine transmission as analyzed at multiple levels. Evidence for intramembrane adenosine A2A/dopamine D2 and adenosine A1/dopamine D1 receptor interactions in the basal ganglia

An analysis at the network and membrane level has provided evidence that antagonistic interactions between adenosine A2A/dopamine D2 and adenosine A1/dopamine D1 receptors in the ventral and dorsal striatum are at least in part responsible for the motor stimulant effects of adenosine receptor antagonists like caffeine and for the motor depressant actions of adenosine receptor agonists. The results obtained in stably cotransfected cells also underline the hypothesis that the intramembrane A2A/D2 and A1/D1 receptor interactions represent functionally important mechanisms that may be the major mechanism for the demonstrated antagonistic A2A/D2 and A1/D1 receptor interactions found in vivo in behavioural studies and in studies on in vivo microdialysis of the striopallidal and strioentopeduncular GABAergic pathways. A major mechanism for the direct intramembrane A2A/D2 and A1/D1 receptor interactions may involve formation of A2A/D2 and A1/D1 heterodimers leading to allosteric changes that will alter the affinity as well as the G protein coupling and thus the efficacy to control the target proteins in the membranes. This is the first molecular network to cellular integration in the nerve cell membrane and may be well suited for a number of integrated tasks and can be performed in a short-time scale, in comparison with the very long-time scale observed when receptor heteroregulation involves phosphorylation or receptor resynthesis. Multiple receptor-receptor interactions within the membranes through formation of receptor clusters may lead to the storage of information within the membranes. Such molecular circuits can represent hidden layers within the membranes that substantially increase the computational potential of neuronal networks. These molecular circuits are biased and may therefore represent part of the molecular mechanism for the storage of memory traces (engrams) in the membranes.

GM1 ganglioside stimulates the regeneration of dopaminergic neurons in the central nervous system

The effect of GM1 ganglioside on the recovery of nigro-strital dopaminergic neurons was studied in rats after unilateral hemitransection. We find that repeated administration of GM1 significantly increased the HVA content, the tyrosine hydroxylase activity and the tyrosine hydroxylase-related immunofluorescence in the striatum ipsilateral to the lesion. Futhermore, GM1 reduced the sensitivity of lesioned rats to apomorphine. The data comparable with the view that a functional dopaminergic reinnervation of the striatum is facilitated by GM1 treatments after hemitransection.

Detection of heteromerization of more than two proteins by sequential BRET-FRET

Identification of higher-order oligomers in the plasma membrane is essential to decode the properties of molecular networks controlling intercellular communication. We combined bioluminescence resonance energy transfer (BRET) and fluorescence resonance energy transfer (FRET) in a technique called sequential BRET-FRET (SRET) that permits identification of heteromers formed by three different proteins. In SRET, the oxidation of a Renilla luciferase (Rluc) substrate by an Rluc fusion protein triggers acceptor excitation of a second fusion protein by BRET and subsequent FRET to a third fusion protein. We describe two variations of SRET that use different Rluc substrates with appropriately paired acceptor fluorescent proteins. Using SRET, we identified complexes of cannabinoid CB1, dopamine D2 and adenosine A2A receptors in living cells. SRET is an invaluable technique to identify heteromeric complexes of more than two neurotransmitter receptors, which will allow us to better understand how signals are integrated at the molecular level.

Further studies on the effects of central administration of neuropeptide Y on neuroendocrine function in the male rat: relationship to hypothalamic catecholamines.

Following intraventricular (i.v.t.) administration of increasing doses of neuropeptide Y (NPY; 7.5-750 pmol/rat) the catecholamine levels and turnover were quantitatively measured in discrete hypothalamic regions by means of histofluorometry. In the same rats the adenohypophyseal hormones as well as vasopressin, aldosterone (ALDO) and corticosterone (CORTICO) levels in serum were determined. Neuropeptide Y seems to induce a biphasic change in amine utilization in the tuberoinfundibular dopamine (DA) neurons and in the noradrenergic (NA) utilization in various hypothalamic areas. Thus, the lowest doses seem to inhibit the catecholamine utilization while higher doses seem to enhance it. NPY (250-750 pmol) reduced the serum levels of thyreotropine (TSH), prolactin (PRL) and growth hormone (GH) but increased CORTICO, adrenocorticotropin (ACTH) and ALDO serum levels. In conclusion, it is suggested that the NPY induced changes in DA utilization in the tuberoinfundibular DA neurons may contribute to the NPY induced changes in PRL and TSH secretion. The increases in paraventricular NA utilization may contribute to the increases in ACTH, ALDO and CORTICO secretion induced by NPY. These data give further support for NPY as an important neuroendocrine modulator.

The discovery of central monoamine neurons gave volume transmission to the wired brain

The dawn of chemical neuroanatomy in the CNS came with the discovery and mapping of the central dopamine, noradrenaline and 5-hydroxytryptamine neurons by means of transmitter histochemistry using the Falck-Hillarp formaldehyde fluorescence technique in the early 1960s. Our mapping of the central monoamine neurons was continued and further established with tyrosine hydroxylase, dopa decarboxylase and dopamine-beta-hydroxylase immunohistochemistry in collaboration with Menek Goldstein and Tomas Hökfelt. During recent years an evolutionary constraint in the nuclear parcellation of the DA, NA and 5-HT neurons was demonstrated in the order Rodentia and other mammals. The abundant existence of global monoamine varicose nerve terminal networks synthesizing, storing and releasing monoamines in various parts of the CNS, including the release of DA by tubero-infundibular DA neurons as a prolactin inhibitory factor from the external layer of the median eminence into the portal vessels and the appearance of extraneuronal DA fluorescence after, e.g., treatment with amphetamine in nialamide pretreated rats (Falck-Hillarp technique) were also remarkable observations. These observations and others like the discovery of transmitter-receptor mismatches opened up the possibility that monoamines were modulating the wired brain, built up mainly by glutamate and GABA neurons, through diffusion and flow in the extracellular fluid of the extracellular space and in the CSF. This transmission also involved long-distance channels along myelinated fibers and blood vessels and was called volume transmission (VT). The extracellular space (ECS), filled with a 3D matrix, plays a fundamental role in this communication. Energy gradients for signal migration in the ECS are produced via concentration, temperature and pressure gradients, the latter two allowing a flow of the ECF and CSF carrying the VT signals. The differential properties of the wiring transmission (WT) and VT circuits and communication channels will be discussed as well as the role of neurosteroids and oxytocin receptors in volume transmission leading to a new understanding of the integrative actions of neuronal-glial networks. The role of tunneling nanotubes with mitochondrial transfer in CNS inter alia as part of neuron-glia interactions will also be introduced representing a novel type of wiring transmission. The impact of the technicolour approach to the connectome for the future characterization of the wired networks of the brain is emphasized.

Adenosine A2A and dopamine D2 heteromeric receptor complexes and their function

The existence of A2A-D2 heteromeric complexes is based on coimmunoprecipitation studies and on fluorescence resonance energy transfer and bioluminescence resonance energy transfer analyses. It has now become possible to show that A2A and D2 receptors also coimmunoprecipitate in striatal tissue, giving evidence for the existence of A2A-D2 heteromeric receptor complexes also in rat striatal tissue. The analysis gives evidence that these heteromers are constitutive, as they are observed in the absence of A2A and D2 agonists. The A2A-D2 heteromers could either be A2A-D2 heterodimers and/or higher-order A2A-D2 hetero-oligomers. In striatal neurons there are probably A2A-D2 heteromeric complexes, together with A2A-D2 homomeric complexes in the neuronal surface membrane. Their stoichiometry in various microdomains will have a major role in determining A2A and D2 signaling in the striatopallidal GABA neurons. Through the use of D2/D1 chimeras, evidence has been obtained that the fifth transmembrane (TM) domain and/or the 13 of the D2 receptor are part of the A2A-D2 receptor interface, where electrostatic epitope-epitope interactions involving the N-terminal part of 13 of the D2 receptor (arginine-rich epitope) play a major role, interacting with the carboxyl terminus of the A2A receptor. Computerized modeling of A2A-D2 heteromers are in line with these findings. It seems likely that A2A receptor-induced reduction of D2 receptor recognition, G protein coupling, and signaling, as well as the existence of A2A-D2 co-trafficking, are the consequence of the existence of an A2A-D2 receptor heteromer. The relevance of A2A-D2 heteromeric receptor complexes for Parkinson’s disease and schizophrenia is emphasized as well as for the treatment of these diseases. Finally, recent evidence for the existence of antagonistic A2A-D3 heteromeric receptor complexes in cotransfected cell lines has been summarized.

Mapping and computer assisted morphometry and microdensitometry of glucocorticoid receptor immunoreactive neurons and glial cells in the rat central nervous system.

By means of a monoclonal mouse immunoglobulin G2a antibody against the rat liver glucocorticoid receptor and the indirect immunoperoxidase technique, the distribution of glucocorticoid receptors in neuronal and glial cell populations was mapped in the central nervous system of the male rat. The mapping was complemented by computer-assisted morphometric and microdensitometric evaluation of glucocorticoid receptor immunoreactivity in many brain regions. The quantitative analysis allowed us to achieve for the first time an objective characterization of glucocorticoid receptor distribution in the CNS, thus avoiding the ambiguities of previous mapping studies based on subjective evaluations. In addition, a taxonomic analysis of central nervous system regions containing glucocorticoid receptor immunoreactivity was carried out utilizing the quantitative parameters obtained in the morphometric evaluation. Nuclei of neuronal and glial cells containing glucocorticoid receptor immunoreactivity were detected in a widespread, but still highly heterogeneous, fashion in the central nervous system, underlining the view that glucocorticoids can control a large number of central nervous system target cells via effects on gene expression. Many nerve cell populations have been shown to contain substantial amounts of nuclear glucocorticoid receptor immunoreactivity, whereas only a low density of glial cells, in both gray and white matter, show nuclear glucocorticoid receptor immunoreactivity. Thus, in most brain areas, the major target for glucocorticoids appears to be the nerve cells. Interestingly, an inverse correlation was found in the regional density of glucocorticoid receptor-immunoreactive nerve and glial cells, suggesting that glucocorticoids may influence a brain area either via glial cells or, more frequently, via nerve cells. The results on mapping highlight the impact of glucocorticoids in areas both traditionally and not traditionally involved in stress responses. The distribution of glucocorticoid receptor immunoreactivity also emphasizes a role of glucocorticoids in the regulation of the afferent regions of the basal ganglia and the cerebellar cortex, and of both afferent and efferent layers of the cerebral cortex. Glucocorticoid receptor immunoreactivity is widely distributed over the thalamus, probably leading to modulation of activity in the various thalamocortical pathways transmitting inter alia specific sensory information to the cerebral cortex. Many unspecific afferents to the cerebral cortex are potentially regulated by glucocorticoid receptors such as the noradrenaline and 5-hydroxytryptamine afferents, since their nerve cells of origin contain strong glucocorticoid receptor immunoreactivity. Eight brain regions involving sensory, motor and limbic areas were shown to have a similarity with regard to glucocorticoid receptor-immunoreactive parameters at the level of 95%. The density of glucocorticoid receptor-immunoreactive nerve cells appeared to be the main factor in determining such a very high level of similarity. Overall, our results emphasize that glucocorticoids may appropriately tune networks of different areas to obtain optimal integration and in this way improve survival of the animal under challenging conditions.

Effects of methergoline on central monoamine neurones. Evidence for a selective blockade of central 5-HT receptors ☆

Abstract The effects of methargoline have been studied on brain dopamine (DA), noradrenaline (NA) and serotonin (5-HT) levels and turnover using biochemistry and quantitative microfluorimetry. Also, its actions on spinal NA and 5-HT receptor activities and telencephalic DA receptor activity have been evaluated by studies on the flexor and extensor reflex activity, respectively, and on rotational behaviour in rats with unilateral 6-hydroxydopamine (6-OHDA)-induced lesions of the ascending DA pathways. The results indicate that methergoline can selectively block at least some postsynaptic 5-HT receptors in the CNS and can be an important tool in the functional and biochemical analysis of central 5-HT neurones. According to the view of Anden et al. [2] it may have a therapeutic action in certain types of schizophrenia.