Anti-rheumatic activities of histone deacetylase (HDAC) inhibitors in vivo in collagen-induced arthritis in rodents.

BACKGROUND AND PURPOSE: Rheumatoid arthritis (RA) is a chronic inflammatory disease. Histone deacetylase inhibitors (HDACi), a new class of anti-cancer agents, have recently been reported to exhibit potent anti-inflammatory activities. A proof of concept study was carried out with suberoylanilide hydroxamic acid (SAHA) and MS-275, two HDACi currently undergoing clinical investigations for various oncological indications. EXPERIMENTAL APPROACH: The anti-rheumatic effects of SAHA and MS-275 were assessed in both mouse and rat collagen induced arthritis (CIA) models. KEY RESULTS: SAHA exhibited moderate prophylactic efficacy. It attenuated paw swelling due to inflammation, decreased bone erosion in both mice and rats and reduced slightly the RA-induced bone resorption in rats. However, SAHA could not inhibit the onset of arthritis. In contrast, MS-275 displayed dramatic anti-rheumatic activities. In prophylactic intervention, high doses of MS-275 prevented bone erosion and markedly delayed the onset of arthritis; at low doses, MS-275 strongly attenuated paw swelling, bone erosion, and bone resorption associated with RA. Furthermore, the therapeutic efficacy of MS-275 was also documented. After the onset of arthritis, it could stop the disease progression and joint destruction. An anti inflammatory effect of MS-275 was also confirmed through its capacity to decrease serum IL-6 and IL-1beta levels in the CIA induced mouse model. The anti-rheumatic activity of MS-275 was also confirmed through histological observation. No synovial hyperplasia, pannus formation, cartilage or bone destruction were observed in the high dose prophylactic intervention in mice. CONCLUSION AND IMPLICATION: This study strongly supported HDACi as an innovative therapeutic strategy for RA.

Calcium binding proteins immunohistochemistry and identification of neurons in the mammalian pineal gland of the African giant rat: Cricetomys gambianus.

The presence of true neurons in the rodent pineal gland is still a matter of controversy. In this work, by using immunohistochemistry with five antibodies against calcium-binding proteins (calbindin-D28k, calretinin, calmodulin, neurocalcin and S-100 beta) and Cricetomys gambianus, a rodent belonging to Muridae family living in Africa, we were able to illustrate the presence of neurons in the pineal gland. Anti-calbindin-D28k and anti-calretinin labelled neurons belonging to two neural ganglia. One ganglion was localized in the anterior part of the gland near the pineal stalk and the other one in the posterior portion of the organ. Immunoreactive neurons are medium in size (15-20 microns) and have long thick processes running towards the stalk. Calretinin and calbindin-D28k positive neurons stained with different intensities. Thin processes were detected by anti-calretinin whereas thick processes were preferentially calbindin-D28k positive. Neurocalcin labelled a few smaller neurons and many thin processes within the ganglion. Calmodulin could not be detected immunochemically. Within the ganglia many astrocytic processes were S-100 beta positive. The afferent and the efferent pathways of the pineal ganglia remain to be elucidated.

Recoverin and hippocalcin distribution in the lamprey (Lampreta fluviatilis) retina.

Recoverin is a calcium-sensing protein which is involved in the transduction of light in vertebrate photoreceptors. It is also detected in other retina cell types in which its function is not yet elucidated, and is an autoantigen in a cancer-associated degenerative disease of the retina. Recently, hippocalcin, an homologous protein of recoverin, belonging to the same family of fatty acylated EF-hand calcium binding proteins was described in mammals. The immunohistochemical studies presented in this paper demonstrate, that, in the retina of the lamprey, an Agnathan considered the living ancestor of actual jawed vertebrates, recoverin was present in all photoreceptors and, to a lesser extent in subpopulations of amacrine and ganglion cells whereas hippocalcin was detected in numerous amacrine and ganglion cells and in the inner segments of long photoreceptors. The existence of these calcium-binding proteins shows that they have a high degree of conservation during evolution. Their presence in the same cells that in jawed vertebrates (photoreceptors and ganglion cells for recoverin; amacrine and ganglion cells for hippocalcin) suggests that some retinal functions are well conserved but because they were also found in different cell types than in other species (amacrine for recoverin; photoreceptors for hippocalcin), they may have functions more specific to the lamprey retina.

Cerebellar spongiform degeneration induced by acute lithium intoxication in the rat.

Cerebellar syndrome has been described after acute lithium intoxication in human. Neuropathological studies have demonstrated neuronal loss and spongiosis in the cerebellum. We describe an animal model of acute lithium-induced cerebellar degeneration. Five hours following administration of lithium chloride (250 mg/kg, i.p.), the cerebellar white matter of seven rats out 14 exhibited extensive spongiform changes. Microdialysis study in the rat cerebellar cortex demonstrated basal concentrations of dopamine (DA), hydroxy-3-methoxyphenylacetic acid (HVA) and 5-hydroxy-3-indolacetic acid (5-HIAA). These metabolites were unaffected by acute lithium intoxication suggesting that the cerebellar toxicity is not due to a modification of dopaminergic or serotoninergic neurotransmission.

[A bizarre excrescence of the umbilicus in a 1-month-old child]. / Une excroissance bizarre de l'ombilic chez un enfant de un mois.

We report the case of an umbilical polyp, derived from omphalo-mesenteric remnants in an one-month-old female child. This rare abnormality results from a closure defect of the vitelline duct. The vitelline duct normally closes between the 5th and the 7th weeks of intra embryonic development but can lead to several pathologies in case of closure defects, giving rise to abdominal (Meckel diverticulum, vitelline cyst) or umbilical symptoms (umbilical fistula, umbilical sinus and umbilical polyp). These disorders have a 2% incidence, and may induce clinical symptoms of varied gravity ranging from clinical silence to acute abdomen. We seized the opportunity of this rare clinical observation to review the nosology of vitelline duct defects at the light of embryologic data.

Calmodulin, calbindin-D28k, calretinin and neurocalcin in rat olfactory bulb during postnatal development.

Odorant stimulation of receptor cells results in a calcium influx that activates the transduction pathway. The olfactory neurons extend axons to the olfactory bulb where they synapse onto mitral cells. Ca(2+)-acceptors also may participate in subsequent processing of olfactory information. The present study describes the distribution of calmodulin, calretinin, calbindin-D28k and neurocalcin during rat main olfactory bulb development. From postnatal day 1 (P1) we observed in the olfactory nerve layer a thin external bundle containing calbindin and calretinin whereas calmodulin was present in a large internal bundle. In tufted cells, neurocalcin immunoreactivity was detected at P10 and increased until P20. In mitral cells calmodulin was intensively immunoreactive at P1 but decreased during development to disappear at adulthood whereas calretinin was weakly labelled at P1 but raised in intensity until P20. In granule cells calbindin-D28k and calretinin were detected from P1. Giant neurons were positive for both calretinin and calbindin-D28k from postnatal day 20.

Differential distribution of six calcium-binding proteins in the rat olfactory epithelium during postnatal development and adulthood.

Odorant stimulation of receptor cells results in a calcium influx that activates the transduction pathway. Ca2+ acceptors, such as calmodulin, may mediate between the change in intracellular calcium and the conductance mechanism underlying the initial electrical event. Ca2+ acceptors also may participate in subsequent processing of olfactory information. The identification and characterization of these molecules, therefore, should provide important information about the complex signal transduction pathway involving calcium in olfaction as well as other sensory systems. The present study describes the distribution of six calcium-binding proteins in the rat main olfactory epithelium during postnatal development to determine when different Ca2+ acceptors can be detected and whether they segregate into different layers or portions of the epithelium. Calmodulin, calretinin, calbindin-D28k, neurocalcin, and recoverin were detected immunohistochemically in olfactory receptors but not in basal cells. S-100 immunoreactivity was restricted to glial cells primarily around the cribriform plate. During postnatal development (from P1 to P20), calmodulin, calretinin, calbindin-D28k, and neurocalcin formed a gradient of immunoreactivity descending from the central to the lateral areas in the nasal cavity, whereas recoverin was expressed only in sporadic, mature receptors in the proximal region of the mucosa. At P20, the immunoreactivity pattern for each calcium-binding protein was identical to the adult profile, indicating that the olfactory epithelium had reached maturity by this stage. Olfactory nerve fiber bundles displayed a differential staining pattern from P1 until adulthood for calbindin-D28k and calretinin (internal portions of bundles). Differential calmodulin immunoreactivity of olfactory nerves (large external portions of bundles) appeared at P10. The immunoreactivity of the nerve fiber bundles may reflect a further degree of organization relevant to odor discrimination.

Calbindin-D28k, calretinin, and S-100 immunoreactivities in rat pineal gland during postnatal development.

Profound morphological modifications occur during postnatal development of the rat pineal gland. We have immunohistochemically followed those events from postnatal day 1 to 20 by using three cytoarchitectonic markers (S-100, calbindin-D28k, and calretinin) that belong to the calmodulin/troponin C calcium-binding protein family. In the developing rat pineal, anticalbindin-D28k antibody labels three cell types: immature and mature astrocytes and perivascular type II pinealocytes. During development, calbindin-D28k positive cells migrate from the base of the pineal stalk into the superficial part of the pineal. Calbindin-D28k, usually used as a neuronal marker in the central nervous system, recognizes in rat pineal precursor astrocytes 5 days before S-100 and labels a subpopulation somewhat different from S-100 positive astrocytes. Calretinin immunoreactivity appeared in the postero-superior part of the pineal and was abundant until postnatal day 5, then its density dramatically felt to leave, after postnatal day 20, an occasional population of cells whose morphology is compatible with neuron-like cells.

Hippocalcin in rat retina. Comparison with calbindin-D28k, calretinin and neurocalcin.

The post-natal developmental expression in rat retina of four calcium-binding proteins belonging to the calmodulin-troponin-C family was investigated by immunohistochemistry using anti-calbindin-D28k, anti-calretinin, anti-hippocalcin and anti-neurocalcin polyclonal antibodies on paraffin sections from Wistar rat retinae aged from post-natal days 1 (P1), 5 (P5), 10 (P10), 20 (P20) to adulthood (8 weeks). Immunoblot using anti-hippocalcin and homogenates proteins from retina, cerebellar cortex, hippocampus and cerebellum was also performed. Hippocalcin immunoreactivity in adult rat retina was demonstrated by both immunohistochemistry and Western blot. During post-natal development, calbindin-D28k, calretinin and neurocalcin immunoreactivity were detected at P1 in ganglion cells, whereas hippocalcin immunoreactivity was seen later at P5 in this cell layer. In the amacrine cell layer, neurocalcin immunoreactivity was detected at P5 and hippocalcin at P10. Calbindin-D28k was labelling the immature horizontal cell, calretinin was detected in nearly all ganglion cells and in some amacrine cells since P1. These three calcium-binding proteins do not seem to play a role in synaptogenesis which takes place later. We confirmed that calbindin-D28k appeared to be a good marker for horizontal cells. The presence of hippocalcin, a myristoylated calcium-binding protein belonging to the recovering subfamily and previously localized in few brain areas has been detected for the first time in retina.

Calbindin-D28k, calretinin, and recoverin immunoreactivities in developing chick pineal gland.

Calbindin-D28k, calretinin, and recoverin, three intracellular calcium-binding proteins belonging to the troponin C/calmodulin superfamily, were immunohistochemically localized in chick pineal during development [from embryonic day 16 (E16) to postnatal day 14 (P14)]. At E18, only calretinin immunoreactivity could be detected in nuclei from follicular pinealocytes. With development, calretinin immunoreactivity expanded from nucleus to cytoplasm, and calretinin immuno-positive cell number increased. At P14 almost al pinealocytes were calretinin positive. Calbindin-D28k immunoreactivity was not detected before E20. During development, many follicular and parafollicular pinealocytes became strongly calbindin-D28k positive, reaching a peak both in intensity and in number at P7; thereafter their number decreased. In addition to pinealocytes, neuron-like cells appeared calbindin-D28k positive at E20 and calretinin positive at P7. Recoverin, a myristoylated protein isolated from vertebrate photoreceptor and which might participate in the inactivation of the phototransduction cascade, was transiently expressed in follicular and parafollicular pinealocytes from P1 to P14 with a maximal expression at P7. This transitory expression may coincide with a transitory light sensitivity period in chick pinealocytes, before complete maturity of the pineal gland.

Calmodulin, calbindin-D28K and calretinin in rat and chicken pineal glands: immunocytochemical and immunoblotting analysis.

In pineal gland, melatonin is synthesized in pinealocytes. Pharmacological studies using calmodulin antagonists suggested that melatonin synthesis was regulated through calmodulin. However, immunohistochemical studies showed that calmodulin could only be detected in pineal glial cells, and not in pinealocytes. To further investigate this discrepancy, we have tried to detect calmodulin not seen by immunohistochemical methods. We have used rat and chicken pineal homogenate supernatants and Triton X-100-treated pellets denatured by sodium dodecyl sulfate, subjected to electrophoresis and immunoblotting using anti-calmodulin antibodies. Two different IgG (#465 and #860) purified from anti-calmodulin sera were used. In rat pineal homogenate supernatants, calmodulin could be detected by immunoblotting using both antibodies. Some calmodulin could also be detected in the Triton-treated pellet fractions, but no additional cross-reacting bands were detected. However, in both chicken pineal homogenate supernatants and Triton-extracted pellets, in addition to a calmodulin immunoreactive band, two other proteins with approximate molecular masses (M(r)) of 56 kDa and 60 kDa were detected using anti-calmodulin #465. For comparison, similar immunoblot experiments were performed for detection of calbindin-D28K and calretinin, two other calcium binding proteins expressed in different pineal cell populations. Interestingly, Triton extraction of chicken pineal pellets revealed additional bands cross-reacting with each antibody. Anti-calbindin-D28K cross-reacted strongly with a M(r) = 68 kDa protein and weakly with a M(r) = 56 kDa protein. Anti-calretinin cross-reacted strongly with a M(r) = 93 kDa protein and weakly with a M(r) = 56 kDa protein.

Distribution of calmodulin, calbindin-D28k and calretinin among rat olfactory nerve bundles.

Calmodulin, calbindin-D28k and calretinin are calcium-binding proteins largely distributed in the bipolar olfactory receptor cells. In the olfactory epithelium their distribution seemed to be random. Using immunohistochemistry we have examined their localization in rat olfactory axons extending to the olfactory bulb. Sections were analyzed both horizontally and vertically. Almost all fibers were immunoreactive for one of the three intracellular calcium-binding proteins whose distribution was not random among the bundles. Three different subclasses of fibers could be detected: calbindin-D28k and calretinin immunoreactivities were restricted to external fibers whereas calmodulin immunoreactivity was intense, abundant and largely distributed throughout the internal portion of the olfactory nerve. This additional degree of organization detected in the olfactory axons might play a role in odor discrimination.

Calmodulin immunoreactivity in the chicken pineal gland: comparison with calbindin-D28k, calretinin, and S100.

Calmodulin distribution in the chicken pineal organ was investigated by immunohistochemistry. Calmodulin immunoreactivity was detected in ependymocytes in the follicular zone and in interstitial cells in the parafollicular zone. No calmodulin immunoreactivity was detected in pinealocytes. Lack of calmodulin immunoreactivity in pinealocytes raises questions about its proposed function in melatonin synthesis as suggested by pharmacological studies using calmodulin antagonists. The calmodulin distribution was comparable to that of S100, a glial cell marker. Two other markers, calbindin-D28k and calretinin, which in neuroanatomical studies give excellent cytoarchitectonic staining, in the chick pineal permitted the detection of two subclasses of pinealocytes. One was darkly stained by calbindin-D28k and rare. The other was very abundant and calretinin positive. In the parafollicular zone, calbindin-D28k and/or calretinin antibodies allowed us to visualize cells presenting a neuron-like morphology. Calretinin immunoreactivity was detected in nearly all pinealocytes in which hydroxy-indol-O-methyl transferase was also located. Comparison between the lack of calmodulin and the presence of calretinin, belonging to the same calcium-binding protein family, in chick pinealocytes raises the hypothesis about a possible role of calretinin in melatonin synthesis.

Sexual dimorphism among calbindin-D28K immunoreactive cells in the rat pineal body.

Calbindin antibodies have been used in neuroanatomical studies to give excellent cytoarchitectural staining and visualization of a Golgi-like cellular morphology. Calbindin-D28K immunoreactivity used in rat pineal gland as a marker detected two classes of pineal cells. One class of small cells representing exclusively glial cells was strongly immunoreactive, and presented a large variety of individual shapes. The majority were a pyramidal shape with one or more processes while others displayed a cytoplasmic lipid droplet. Some small cells occurred around pericapillary spaces. The second class of calbindin-D28K positive cells corresponding to type II pinealocytes were characterized by their large size and less intensive labelling. Type II pinealocytes were round or rectangular; the nucleus was infolded and large with a prominent nucleolus. These large cells were preferentially distributed in the vicinity of vessels and assembled in a cluster of more than ten cells. The lack of S-100 and myeloperoxidase immunoreactivities in large calbindin-D28K cells excluded their possible characterization as glial cells and mononuclear phagocytes, while their size (> 15 microns) excluded microglial cells. A sex difference was detected between large calbindin-D28K positive cells. The mean calculated number of large positive cells for males was 6361 +/- 1504 (n = 8) compared to 2162 +/- 1235 (n = 7) for females. No significative difference was detected between males and females for small calbindin-D28K positive cells.

Neurocalcin immunoreactivity in rat olfactory bulb.

Neurocalcin, a newly discovered calcium-binding protein belonging to the recoverin-like superfamily, was detected immunohistochemically in tufted cells from the rat olfactory bulb. More precisely, only periglomerular tufted cells and some tufted cells from the external plexiform layer were expressing neurocalcin. Western blot analysis has confirmed the presence of neurocalcin in rat olfactory bulb. Lack of neurocalcin immunoreactivity in mitral cells and periglomerular cells favor a different phylogenic origin between tufted and mitral or periglomerular cells.

Transient expression of calretinin during development of chick cerebellum. Comparison with calbindin-D28k.

Calcium ions play a critical role in neural development. Insights into the ontogeny of Ca2+ homeostasis were gained by investigating the developmental expression of two E-F hand calcium-binding proteins. Calretinin and calbindin were monitored through their immunoreactivity in the developing chick cerebellum (from E6 to E20). Calbindin was detected from E13 and in Purkinje cells only. Intensity of labelling increased with Purkinje cell development. Calretinin presented a transitory immunoreactivity between E11 and E20 in the internal granular cell layer. This cell layer contains cells which will differentiate into Golgi and granular cells which are calretinin-negative in adult chick cerebellum. Calretinin immunoreactivity presented a peak (both in number of cells and in intensity) at E15 and fell dramatically after E20 while calbindin immunoreactivity was restricted to the Purkinje cells and increased with the development of these cells.

Calmodulin and calbindin localization in retina from six vertebrate species.

Calmodulin is abundant in the central nervous system, including the retina. However, the localization of calmodulin in the retina has not been described in detail. We therefore decided to investigate calmodulin localization in retinae from six vertebrate species, by using immunohistochemical labeling with four different rabbit polyclonal antibodies against calmodulin. The localization of calbindin-D28k, another calcium-binding protein already well described in retina, was compared. We found that calmodulin distribution is more highly conserved among species, contrasting with calbindin variability. The most striking result emerging is that calmodulin could not be detected in photoreceptors although other layers are intensely calmodulin-immunoreactive, casting doubt about a direct role of calmodulin in phototransduction. Horizontal cells are weakly calmodulin-immunoreactive, bipolar cells are calmodulin-immunoreactive except in turtle retina, numerous amacrine and ganglion cells are labeled in all species, and the fiber layer is always labeled. These data demonstrate that, while the calmodulin distribution in retina is similar among vertebrate species, selective differences in localization can be detected not only among the same cell types in different species but also among different cell types in the same species. The results showing differences in calmodulin immunoreactivity among cell types also provide further evidence that calmodulin expression in eukaryotes is not constitutive, in the sense that not every cell expresses similar levels of calmodulin.

Variable distribution, in four rat brain areas, of the three natural forms of peptide histidine isoleucinamide: PHI(1-27)NH2, PHI-Gly, and PHV (1-42).

Three parent peptides were shown to coexist in four rat brain regions: PHI(1-27)NH2 (peptide with an N-terminal histidine and a C-terminal isoleucinamide commonly called PHI), PHI-Gly (PHI(1-27)Gly) and PHV(1-42) (a 42 amino acids form with a C-terminal valine, consisting of PHI(1-27) C-terminally extended by the connecting peptide between PHI and VIP in the precursor molecule except for the terminal basic doublet preceding VIP). A differential distribution of the 3 forms was observed by means of radioimmunoassay, after chromatographic separation on Fractogel, in extracts from temporal cortex, hippocampus, striatum and hypothalamus. Total PHI-IR concentration was found to be higher in the temporal cortex and hippocampus than in the striatum and hypothalamus. PHI(1-27)NH2 was the major form, and accounted for 55% of total PHI-IR in the cortex and hippocampus, 62% in the hypothalamus and as much as 70% in the striatum. PHI-Gly represented 18% of total PHI-IR in the cortex and hippocampus, and 11% in the two other brain areas. PHV(1-42) represented 26% of total PHI-IR in all areas except in the striatum where it represented 18% only.