Chiara Carone

Receptor-receptor interactions: A novel concept in brain integration.

A brief historical presentation of the hypothesis on receptor-receptor interactions as an important integrative mechanism taking place at plasma membrane level is given. Some concepts derived from this integrative mechanism especially the possible assemblage of receptors in receptor mosaics (high-order receptor oligomers) and their relevance for the molecular networks associated with the plasma membrane are discussed. In particular, the Rodbells disaggregation theory for G-proteins is revisited in the frame of receptor mosaic model. The paper also presents some new indirect evidence on A2A;D2 receptor interactions obtained by means of Atomic Force Microscopy on immunogold preparations of A2A and D2 receptors in CHO cells. These findings support previous data obtained by means of computer-assisted confocal laser microscopy. The allosteric control of G-protein coupled receptors is examined in the light of the new views on allosterism and recent data on a homocysteine analogue capable of modulating D2 receptors are shown. Finally, the hypothesis is introduced on the existence of check-points along the amino acid pathways connecting allosteric and orthosteric binding sites of a receptor and their potential importance for drug development.

Microvesicle and tunneling nanotube mediated intercellular transfer of g-protein coupled receptors in cell cultures.

Recent evidence shows that cells exchange collections of signals via microvesicles (MVs) and tunneling nano-tubes (TNTs). In this paper we have investigated whether in cell cultures GPCRs can be transferred by means of MVs and TNTs from a source cell to target cells. Western blot, transmission electron microscopy and gene expression analyses demonstrate that A(2A) and D(2) receptors are present in released MVs. In order to further demonstrate the involvement of MVs in cell-to-cell communication we created two populations of cells (HEK293T and COS-7) transiently transfected with D(2)R-CFP or A(2A)R-YFP. These two types of cells were co-cultured, and FRET analysis demonstrated simultaneously positive cells to the D(2)R-CFP and A(2A)R-YFP. Fluorescence microscopy analysis also showed that GPCRs can move from one cell to another also by means of TNTs. Finally, recipient cells pre-incubated for 24 h with A(2A)R positive MVs were treated with the adenosine A(2A) receptor agonist CGS-21680. The significant increase in cAMP accumulation clearly demonstrated that A(2A)Rs were functionally competent in target cells. These findings demonstrate that A(2A) receptors capable of recognizing and decoding extracellular signals can be safely transferred via MVs from source to target cells.

A New Hypothesis of Pathogenesis Based on the Divorce between Mitochondria and their Host Cells: Possible Relevance for Alzheimers Disease

On the basis of not only the endosymbiotic theory of eukaryotic cell organization and evolution but also of observations of transcellular communication via Tunneling NanoTubes (TNTs), the hypothesis is put forward that when mitochondria, which were once independently living prokaryote-like organisms, are subjected to detrimental genetic, toxic, or environmental conditions, including age-related endogenous factors, they can regress towards their original independent state. At that point, they can become potentially pathogenic intruders within their eukaryotic host cell. Because of the protoplasmic disequilibrium caused by an altered, or mutated, mitochondral population, certain host cells with a minimal capacity for self-renewal, such as dopaminergic neurons, risk a loss of function and degenerate. It is also proposed that altered mitochondria, as well as their mutated mtDNA, can migrate, via TNTs, into adjacent cells. In this way, neurodegenerative states are propagated between cells (glia and/or neurons) of the Central Nervous System (CNS) and that this leads to conditions such as Alzheimers and Parkinsons disease. This proposal finds indirect support from observations on rotenone-poisoned glioblastoma cells which have been co-cultured with non-poisoned cells. Immunocytochemical techniques revealed that mitochondria, moving along the TNTs, migrated from the poisoned cells towards the healthy cells. It has also been demonstrated by means of immunocytochemistry that, in glioblastoma cell cultures, Amyloid Precursor Protein (APP) is present in TNTs, hence it may migrate from one cell to neighbouring cells. This datum may be of high relevance for a better understanding of Alzheimers Disease (AD) since molecular, cellular, and animal model studies have revealed that the formation of amyloid beta (Abeta) and other derivatives of the APP are key pathogenic factors in AD, causing mitochondrial dysfunction, free radical generation, oxidative damage, and inflammation. Furthermore, the present data demonstrate the presence of alpha-synuclein (alpha-syn) within TNTs, hence a similar pathogenic mechanism to the one surmised for AD, but centred on alpha-syn rather than on Abeta, may play a role in Parkinsons Disease (PD). As a matter of fact, alpha-syn can enter mitochondria and interact with complex I causing respiratory deficiency and increased oxygen free radical production. In agreement with this view, it has been demonstrated that, in comparison with normal subjects, PD patients show a significant accumulation of alpha-syn at Substantia Nigra and Striatal level, predominantly associated with the inner mitochondrial membrane,. These observations suggest that potentially neuropathogenic proteins, such as Abeta and alpha-syn, can not only diffuse via the extracellular space but also move from cell to cell also via TNTs where they can cause mitochondrial damage and cell degeneration. A mathematical model (see Appendix) is proposed to simulate the pathogenic consequences of the migration of altered mitochondria and/or of their mtDNA via TNTs. The results of the present simulation is compatible with the proposal that mutated mitochondrial agents behave as though they were infectious particles migrating through a continuum of interconnected cells.

Influence of f-MLP, ACTH(1–24) and CRH on in vitro Chemotaxis of Monocytes from Centenarians

Objective: The lifelong exposure to a variety of stressors activates a plethora of defense mechanisms, including the hypothalamic-pituitary-adrenal axis which releases neuropeptides affecting the immune responses. Here, we report data on the capability of monocytes from young subjects and centenarians to migrate towards chemotactic stimuli (formyl-methionyl-leucyl-phenylalanine, f-MLP; adrenocorticotropic hormone, ACTH, and corticotrophin-releasing hormone, CRH). Plasma levels of ACTH, CRH and cortisol were measured as an index of ongoing stress response. Methods: Monocyte chemotaxis towards f-MLP (10–8M), ACTH(1–24) (10–14 and 10–8M) and CRH (10–14 and 10–8M) was evaluated in vitro in young subjects (n = 8, age range 25–35 years) and centenarians (n = 9, age >100 years) and expressed as chemotactic index. In 9 young subjects and 6 centenarians, plasma levels of cortisol, ACTH and CRH were measured. Results: Monocyte chemotaxis towards f-MLP, ACTH(1–24) and CRH (10–8M) was well preserved in centenarians, except when the lowest concentration of CRH was used. CRH, ACTH and cortisol plasma levels were significantly higher in centenarians than in young subjects. Conclusions: The capability of monocytes from centenarians to respond to chemotactic neuropeptides is well preserved. The decreased responsiveness to the lowest concentration of CRH might be due to downregulation of CRH receptors or to defects in the intracellular signal transduction pathway. The high plasma levels of cortisol, CRH and ACTH in centenarians indicate an activation of the entire stress axis, likely counteracting the systemic inflammatory process occurring with age. This activation fits with the hypothesis that lifelong low-intensity stressors activate ancient, hormetic defense mechanisms, favoring healthy aging and longevity.

Hyper-Homocysteinemia Alters Amyloid Peptide-Clusterin Interactions and Neuroglial Network Morphology and Function in the Caudate After Intrastriatal Injection of Amyloid Peptides

Amyloid peptides (Abeta) are fragments of the Amyloid Precursor Protein (APP), an integral membrane protein. Abeta peptides are continuously generated by neurons and non-neuronal cells via sequential cleavage of APP by secretases. In particular, Abeta1-42 is the main component of the senile plaques associated with Alzheimers disease (AD). Glial cells participate in the uptake of soluble extra-cellular Abeta and in the clearance of this material at localized sites where the Abeta are concentrated. It has been shown that clusterin (Apo J) and apolipoprotein E (ApoE) exert important additive effects in reducing Abeta deposition. In agreement with the fact that homocysteine (Hcy) potentiates Abeta peptide neurotoxicity, and Hcy brain levels increase with age, it has been demonstrated that high plasma levels of Hcy are a risk factor for AD. In the present paper, we used animals subjected to chronic intake of methionine (1 g/kg/day) in the drinking water, since this treatment can increase plasma Hcy levels by 30%. By means of this animal model, interactions between the Abeta beta-sheet rich fibrils and clusterin, have been evaluated in striata of animals after Abeta injection. Furthermore, it has been demonstrated that Abeta peptides are not only signals capable of activating astrocytes but also capable of reducing tyrosine-hydroxylase immunoreactivity in the basal ganglia probably leading to a reduction of volume transmission. These alterations in the neuroglial network morphology and function can, at least in part, explain the enhanced pain threshold observed in the Abeta intra-striatally injected animals.

A New Interpretative Paradigm for Conformational Protein Diseases

Conformational Protein Diseases (CPDs) comprise over forty clinically and pathologically diverse disorders in which specific altered proteins accumulate in cells or tissues of the body. The most studied are Alzheimerβs disease, Parkinsons disease, Huntingtons disease, amyotrophic lateral sclerosis, prion diseases, inclusion body myopathy, and the systemic amyloidoses. They are characterised by three dimensional conformational alterations, which are often rich in β- structure. Proteins in this non-native conformation are highly stable, resistant to degradation, and have an enhanced tendency to aggregate with like protein molecules. The misfolded proteins can impart their anomalous properties to soluble, monomeric proteins with the same amino acid sequence by a process that has been likened to seeded crystallization. However, these potentially pathogenic proteins also have important physiological actions, which have not completely characterized. This opens up the question of what process transforms physiological actions into pathological actions and most intriguing, is why potentially dangerous proteins have been maintained during evolution and are present from yeasts to humans. In the present paper, we introduce the concept of mis-exaptation and of mis-tinkering since they may help in clarifying some of the double edged sword aspects of these proteins. Against this background an original interpretative paradigm for CPDs will be given in the frame of the previously proposed Red Queen Theory of Aging.

Acute isoproterenol induces anxiety-like behavior in rats and increases plasma content of extracellular vesicles

Several clinical observations have demonstrated a link between heart rate and anxiety or panic disorders. In these patients, β-adrenergic receptor function was altered. This prompted us to investigate whether the β-adrenergic receptor agonist isoproterenol, at a dose that stimulates peripheral β-adrenergic system but has no effects at the central nervous system, can induce anxiety-like behavior in rats. Moreover, some possible messengers involved in the peripheral to brain communication were investigated. Our results showed that isoproterenol (5 mg kg(-1) i.p.) increased heart rate, evoked anxiety-like behavior, did not result in motor impairments and increased extracellular vesicle content in the blood. Plasma corticosterone level was unmodified as well as vesicular Hsp70 content. Vesicular miR-208 was also unmodified indicating a source of increased extracellular vesicles different from cardiomyocytes. We can hypothesize that peripheral extracellular vesicles might contribute to the β-adrenergic receptor-evoked anxiety-like behavior, acting as peripheral signals in modulating the mental state.

Corrigendum to "Acute isoproterenol induces anxiety-like behavior in rats and increases plasma content of extracellular vesicles" [Physiol. Behav. 142 (2015) 79-84]

Giuseppina Leo, Michele Guescini, Susanna Genedani⁎, Vilberto Stocchi, Chiara Carone, Monica Filaferro, Davide Sisti, Manuela Marcoli, Guido Maura, Pietro Cortelli, Diego Guidolin, Kjell Fuxe, Luigi Francesco Agnati a Department of Biomedical, Metabolic Sciences and Neuroscience, Physiology and Neuroscience Unit, University of Modena and Reggio Emilia, via Campi 287, Modena, Italy b Department of Biomolecular Sciences, University of Urbino Carlo Bo, via Aurelio Saffi, 2, Urbino, PU, Italy c Department of Diagnostic, Clinical Medicine and Public Health, University of Modena and Reggio Emilia, via Campi 287, Modena, Italy d Department of Pharmacy, University of Genova, viale Cembrano, 4, Genova, Italy e Department of Biomedical and NeuroMotor Sciences (DIBINEM), Alma Mater Studiorum, University of Bologna, Via Altura 3, Bologna, Italy f IRCCS Institute of Neurological Sciences, Ospedale Bellaria, Via Altura 3, Bologna, Italy g Department of Molecular Medicine, University of Padova, via Gabelli 65, Padova, Italy h Department of Neuroscience, Karolinska Institutet, Retzius vag 8, Stockholm, Sweden