The Drosophila putative kinase linotte (derailed) prevents central brain axons from converging on a newly described interhemispheric ring.

The lio gene encodes a putative receptor tyrosine kinase, with unique motifs both in the extracellular and catalytic domains (Dura, J.-M., Préat, T., Tully, T., 1993. Identification of linotte, a new gene affecting learning and memory in Drosophila melanogaster. J. Neurogenet. 9, 1-14). We show here that a complete deletion of lio activity causes specific structural defects in the adult brain. Gal4 enhancer-trap lines used as cell markers revealed that in lio mutants central brain axons behave as if they were abnormally attracted by the midbrain area. The Lio protein is expressed in third instar larvae in a few cells at the junction of the cerebral hemispheres. These glial cells form a newly described ring structure, showing an invariable fibrous organization. In the wild-type this ring disappears at midpupation. Our results indicate that the Lio putative kinase plays a major role in the modeling of the adult brain by controlling the fate of the transient interhemispheric ring.

Relationships among placental, uterine, and circulating concentrations of progesterone and fetal survival in the ovariectomized pregnant rat.

Pregnant rats were ovariectomized or sham operated on day 15 postcoitum. Four days later, progesterone was measured by RIA in peripheral and uterine vein plasma, in uteri, and in placentae. Maintenance of pregnancy was not critically affected by ovariectomy, since fetal survival was 65.7 +/- 5.1% (mean +/- SEM) despite a large decrease of peripheral plasma progesterone from 115.7 +/- 3.4 to 9.3 +/- 0.5 ng/ml. Peripheral and uterine vein plasma progesterone (8.3 +/- 0.9 ng/ml) were identical. In contrast, placental progesterone decreased only slightly, although significantly, from 27.3 +/- 1.3 to 20.3 +/- 1.0 ng/mg. The concentrations of uterine progesterone were variable and positively correlated with the concentrations of peripheral plasma progesterone. It was concluded that uterine progesterone originates from peripheral blood but not from placentae and that fetal survival is positively correlated with residual progesterone concentrations in peripheral plasma and in uterus but not in placentae.

Enhancement of quantal transmitter release and mediatophore expression by cyclic AMP in fibroblasts loaded with acetylcholine.

Neuronal properties such as neurotransmitter uptake and release can be expressed in non-neuronal cells. We show here that fibroblasts-mouse cell line L-M(TK-)-are able to take up acetylcholine from the external medium and to release it in response to a calcium influx. Release was assessed biochemically by a luminescence method, but it was also elicited from individual fibroblasts and recorded in real-time using a Xenopus myocyte as an acetylcholine detector. After treatment for three to six days with dibutyryl-cyclic AMP, the cells changed their shape and acetylcholine release was greatly enhanced. Surprisingly, in differentiated fibroblasts the time-course transmitter release exhibited a high degree of variability even for the successive responses evoked from the same cell; many currents recorded in myocytes on electrical stimulation of fibroblasts had an extremely long duration (up to 1 s or more). This suggested that the release sites were kept open for a very long time. Cyclic AMP treatment also caused a marked increase in the expression of mediatophore 16,000 mol. wt proteolipid in fibroblast membranes. Mediatophore is an acetylcholine-translocating protein which is abundant in cholinergic presynaptic plasma membranes. It is concluded that cyclic AMP differentiation of fibroblasts prolongs the duration of acetylcholine release at individual sites and enhances the expression of the 16,000 mol. wt proteolipid-forming mediatophore.

Association of syntaxin with SNAP 25 and VAMP (synaptobrevin) in Torpedo synaptosomes.

Two proteins of the presynaptic plasma membrane, syntaxin and SNAP 25, and VAMP/ synaptobrevin, a synaptic vesicle membrane protein, form stable protein complexes which are involved in the docking and fusion of synaptic vesicles at the mammalian brain presynaptic membrane. Similar protein complexes were revealed in an homogeneous population of cholinergic synaptosomes purified from Torpedo electric organ by combining velocity sedimentation and immunoprecipitation experiments. After CHAPS solubilization, virtually all the nerve terminal syntaxin was found in the form of large 16 S complexes, in association with 65% of SNAP 25 and 15% of VAMP. Upon Triton X100 solubilization, syntaxin was still recovered in association with SNAP 25 and VAMP but in smaller 8 S complexes. A small (2-5%) percentage of the nerve terminal 15 kDa proteolipid subunit of the v-H+ATPase and of mediatophore was copurified with syntaxin, using two different antisyntaxin monoclonal antibodies. The use of an homogeneous population of peripheral cholinergic nerve terminals allowed us to extend results on the composition of the brain presynaptic protein complexes to the Torpedo electric organ synapse, a model of the rapid neuromuscular synapses.

Acetylcholine accumulation and release by hybrid NG108-15, glioma and neuroblastoma cells--role of a 16kDa membrane protein in release.

A procedure is described to fill up cells in culture with ACh and study its calcium dependent release, by-passing the synthesis steps. Whether differentiated or not with dbc-AMP, the NG108-15 cells efficiently released ACh when stimulated with calcium and ionophore A23187. The release was also studied in the parent C6-BU-1 and N18TG2 cells. It was found that C6-BU-1 released ACh much better that N18TG2 in spite of their glial origin. The internalization by NG108-15 cells of an antisense oligonucleotide probe hybridizing the 16 kDa proteolipid messenger common to mediatophore and to the V-ATPase reduced ACh release indicated a role of this proteolipid in ACh translocation. This characteristic protein was found in the membrane extract of NG108-15 cells and also in the C6-BU-1 cells, but its amount was strongly reduced in the N18TG2 cell line and in the NG108-15 cells having internalized the antisense probe.

Identification of two proteolipid antigens with different localization at torpedo neuromuscular synapses.

The cholinergic nerve terminals of Torpedo electric organ are a rich source of a hydrophobic protein, the mediatophore, which endows artificial membranes with a calcium dependent mechanism that translocates acetylcholine. An antiserum raised against purified mediatophore permitted the identification of two different proteolipids of 14 and 15 kDa molecular weight. Mediatophore activity paralleled the abundance of the 15 kDa proteolipid. Antibodies to this 15 kDa proteolipid were affinity purified and the distribution of this antigen was studied at neuromuscular junction, where it was only detected at nerve terminals. An antisynaptic vesicle monoclonal antibody was produced and used as a nerve terminal specific marker. Its binding pattern was very similar to that of anti 15 kDa proteolipid antibodies. Their distribution is markedly different from that of the 14 kDa proteolipid which is associated with Schwann cells and endothelium of blood capilliaries as shown using affinity purified antibodies to the 14 kDa proteolipid.

A syntaxin-SNAP 25-VAMP complex is formed without docking of synaptic vesicles.

We show herein that syntaxin is already associated with SNAP 25 and VAMP during fast axonal transport, and in isolated synaptic vesicles, before docking of these secretory organelles at the active zones.

Pregnenolone and its sulfate ester in the rat brain.

Pregnenolone (P) and its sulfate ester (PS) have been characterized in the brain of adult male rats. The concentration of P (38.4 +/- 6.9 and 22.1 +/- 2.9 ng/g, mean +/- S.D., in anterior and posterior brain, respectively) exceeded that of PS in brain (15.8 +/- 3.0 and 5.7 +/- 2.1 ng/g in the same fractions) and largely those of P and PS in plasma (1.3 +/- 0.2 and 1.4 +/- 0.3 ng/g, respectively). The level of P in brain was much larger than that of dehydroepiandrosterone sulfate (DS), characterized and measured previously (Corpéchot et al.). Brain P and PS levels did not seem to depend on steroidogenic gland secretion: no meaningful difference occurred in brain 15 days after adrenalectomy plus orchiectomy, compared with sham-operated controls. It is proposed that, as that of DS (ref. 5) P and PS formation or accumulation (or both) in the rat brain depend on in situ mechanisms unrelated to the peripheral endocrine gland system.

[Circadian course of delta 5,3 beta-hydroxysteroids and glucocorticosteroids in the plasma and brain of rats]. / Evolution circadienne de delta 5-3 beta-hydroxystéroïdes et de glucocorticostéroïdes dans le plasma et le cerveau de rat.

Corticosterone (B), pregnenolone (P) and dehydroepiandrosterone (D) undergo circadian variations in the rat plasma and brain. When the data are interpreted by the Cosinor method, the acrophases of P in brain and of D in plasma significantly precede the acrophase of B. The asynchrony of delta 5-3 beta-hydroxysteroid and glucocorticosteroid rhythms brings an additional argument in favor of separate regulatory mechanisms.

[Persistence of the circadian rhythm of dehydroepiandrosterone in the brain, but not in the plasma, of castrated and adrenalectomized rats]. / Persistance d'un rythme circadien de la déhydroépiandrostérone dans le cerveau, mais non dans le plasma, de rats castrés et surrénalectomisés.

In adrenalectomized and orchidectomized rats, the removal of the steroidogenic endocrine glands is associated with a near-disappearance of corticosterone (B) from plasma and brain; circadian variations of B and of plasma dehydroepiandrosterone (D), characteristic of the intact rat, are no more detected. By contrast, analyses of brain D measurements by the cosinor method demonstrate a persisting circadian rhythm of large amplitude.

Chronobiologic dynamics of delta 5-3 beta-hydroxysteroids and glucocorticoids in rat brain and plasma and human plasma.

While a different timing of circadian rhythms does not necessarily demonstrate the operation of independent mechanisms, it is one step in the isolation of separate interacting rhythmic factors underlying the dynamics of all life. With this step in mind, circadian rhythms are quantified in rat plasma and brain for corticosterone (B), pregnenolone (P), and dehydroepiandrosterone (D) by the rejection of the zero-amplitude assumption with the single cosinor method, from data obtained every 3 hr for 24 hr on groups of three male Sprague-Dawley rats, 11-12 weeks of age. The rats were killed; steroids were extracted from brain and plasma and were radioimmunoassayed. In relation to the acrophase (phi) of B, the phi of P in brain (P = 0.035) and of D in plasma (P = 0.0012) preceded the phi of B. By contrast, in clinically healthy women, the phi of plasma dehydroepiandrosterone sulfate (DHEA-S) lags behind that of cortisol (F), on the average by 6 hr 28 min. Such a lag is also seen in men. A species difference in the time relations of delta 5-3 beta-hydroxysteroids vs. glucocorticoids in plasma is obvious (P less than 0.01). A difference in time relations of human circulating D, DHEA-S, and F between schizophrenic and clinically healthy men renders the time relations of glucocorticosteroids and delta 5-3 beta-hydroxysteroids in brain particularly interesting, as do relations of an egocentric and expansive personality to the rhythm characteristics of DHEA-S. The fact that the acrophases for some of the steroids investigated in brain and plasma, respectively, are differently timed is in keeping with the assumption that they involve partly different mechanisms, even if differences in the metabolic handling of different steroids also remain to be investigated.

Detection with monoclonal antibodies of a 15-kDa proteolipid in both presynaptic plasma membranes and synaptic vesicles in Torpedo electric organ.

A protein, the mediatophore, has been purified from Torpedo electric organ presynaptic plasma membranes. This protein mediates the release of acetylcholine through artificial membranes when activated by calcium and is made up of 15-kDa proteolipid subunits. After immunization with purified delipidated mediatophore, monoclonal antibodies binding to the 15-kDa proteolipid band on Western blots of purified mediatophore were selected. A 15-kDa proteolipid antigen was also detected in cholinergic synaptic vesicles. Using an immunological assay, it was estimated that presynaptic plasma membranes and synaptic vesicles contain similar proportions of 15-kDa proteolipid antigen. Detection by immunofluorescence in the electric organ showed that only nerve endings were labeled. In electric lobes, the staining was associated with intracellular membranes of the electroneuron cell bodies and in axons. Nerve endings at Torpedo neuromuscular junctions were also labeled with anti-15-kDa proteolipid monoclonal antibodies.

Immunological identification of a new 14X10(3) Mr membrane-bound protein in Torpedo electric organ.

A series of monoclonal antibodies binding to different epitopes shared by a 14 x 10(3)Mr membrane-bound polypeptide has been obtained. By indirect immuno-fluorescence, it was shown that the 14 x 10(3)Mr antigen is present in various cell types in Torpedo electric organ and muscle, especially fibroblasts, capillary endothelial cells, axonal cuff cells and, to a lesser extent, Schwann cells. At the electron-microscope level, after immunogold labelling, the antigen was found associated with the external surface of the plasma membrane of these cells, with the exception of the axonal cuff cells where part of the labelling was intracellular. The possible biological role of this 14 x 10(3)Mr protein is unknown but preliminary experiments suggest that this antigen has affinity for other Torpedo electric organ membrane proteins.

Ex vivo culture of adult microglial cells from previously lesioned rat brains.

In an attempt to study more precisely the glial cells involved in reactions following specific brain injuries, we tried to culture cells derived from surgically-lesioned rat brains or adult rat hippocampus previously treated with kainic acid, a convulsant which induces status epilepticus associated with structural modifications. We find that, contrary to cultures derived from normal adult rat brain, cultures from lesioned rat brains can survive and proliferate in vitro. Characterization of the cell types using double labeling with isolectin B4 for microglia and GFAP antisera for astrocytes shows that cultures from KA-treated adult rats consist of nearly 100% macrophagic-microglial cells, whereas those obtained from surgically-lesioned brains are composed of a mixed population of microglial cells and astrocytes. These models are proposed as suitable for the further study of microglial-neuronal interactions involved in brain damage and repair.

Characterization of aminopeptidase N from Torpedo marmorata kidney.

A major antigen of the brush border membrane of Torpedo marmorata kidney was identified and purified by immunoprecipitation. The sequence of its 18 N terminal amino acids was determined and found to be very similar to that of mammalian amino-peptidase N (EC 3.4.11.2). Indeed aminopeptidase N activity was efficiently immunoprecipitated by monoclonal antibody 180K1. The purified antigen gives a broad band at 180 kDa after SDS-gel electrophoresis, which, after treatment by endoglycosidase F, is converted to a thinner band at 140 kDa. This antigen is therefore heavily glycosylated. Depending on solubilization conditions, both the antigen and peptidase activity were recovered either as a broad peak with a sedimentation coefficient of 18S (2% CHAPS) or as a single peak of 7.8S (1% CHAPS plus 0.2% C12E9), showing that Torpedo aminopeptidase N behaves as an oligomer stabilized by hydrophobic interactions, easily converted into a 160 kDa monomer. The antigen is highly concentrated in the apical membrane of proximal tubule epithelial cells (600 gold particles/microns2 of brush border membrane) whereas no labeling could be detected in other cell types or in other membranes of the same cells (basolateral membranes, vacuoles or vesicles). Monoclonal antibodies prepared here will be useful tools for further functional and structural studies of Torpedo kidney aminopeptidase N.

Neuro-steroids: 3 beta-hydroxy-delta 5-derivatives in rat and monkey brain.

The rat brain accumulates pregnenolone (P) as the unconjugated steroid, the sulfate ester (S) and fatty acid esters (L). P + PS do not disappear from rat brain after combined adrenalectomy (adx) and castration (orx). PL does not serve a source of P after adx + orx. P is metabolized by several rat brain regions to progesterone and to PL. Brain microsomes contain the acyl-transferase which converts P to PL using endogenous substrates. Brain P and dehydroepiandrosterone (D) undergo a prominent circadian variation with their acrophases at the beginning of the dark span. The circadian variation of brain D persists after adx + orx. The monkey brain (Macaca fascicularis) also accumulates P and D. Adrenal suppression with dexamethasone for 4 days does not decrease the concentrations of brain P and 3rd ventricle CSFP and D. The concentrations of brain D are decreased to a much smaller extent than plasma D. D inhibits the aggressive behavior of castrated male mice exposed to lactating female intruders. This is not the case for DS or androst-5-ene-3 beta, 17 beta-diol. The D analog 3 beta-methyl-androst-5-en-17-one, which is not estrogenic and cannot be metabolized to testosterone or estradiol, is as active as D in inhibiting the aggressive behavior of castrated mice.

Cell lines expressing an acetylcholine release mechanism; correction of a release-deficient cell by mediatophore transfection.

Several neuronal and non-neuronal cell lines express a Ca(2+)-dependent mechanism of transmitter release that can be demonstrated after loading the cells with acetylcholine during culture. In contrast, a particular cell line, the neuroblastoma N18TG-2, was found to be deficient for release. We transfected N18TG-2 cells with a plasmid encoding Torpedo mediatophore, a protein able to translocate acetylcholine in response to calcium. The N18TG-2 cells expressed the Torpedo protein which reached their plasma membrane. At the same time, these cells acquired a Ca(2+)-dependent quantal release mechanism similar to the one naturally expressed by other cell lines. Hence, the presence of mediatophore in the plasma membrane seems essential for quantal release.

Evoked acetylcholine release expressed in neuroblastoma cells by transfection of mediatophore cDNA.

Transmitter release was elicited in two ways from cultured cells filled with acetylcholine: (a) in a biochemical assay by successive addition of a calcium ionophore and calcium and (b) electrophysiologically, by electrical stimulation of individual cells and real-time recording with an embryonic Xenopus myocyte. Glioma C6-Bu-1 cells were found to be competent for Ca(2+)-dependent and quantal release. In contrast, no release could be elicited from mouse neuroblastoma N18TG-2 cells. However, acetylcholine release could be restored when N18TG-2 cells were transfected with a plasmid coding for mediatophore. Mediatophore is a protein of nerve terminal membranes purified from the Torpedo electric organ on the basis of its acetylcholine-releasing capacity. The transfected N18TG-2 cells expressed Torpedo mediatophore in their plasma membrane. In response to an electrical stimulus, they generated in the myocyte evoked currents that were curare sensitive and calcium dependent and displayed, discrete amplitude levels, like in naturally occurring synapses.

Quantal acetylcholine release induced by mediatophore transfection.

Mediatophore is a protein of approximately 200 kDa able to translocate acetylcholine in response to calcium. It was purified from the presynaptic plasma membranes of the electric organ nerve terminals. Mediatophore is a homooligomer of a 16-kDa subunit, homologous to the proteolipid of V-ATPase. Cells of the N18TG-2 neuronal line are not able to produce quantal acetylcholine release. We show here that transfection of N18TG-2 cells with a plasmid encoding the mediatophore subunit restored calcium-dependent release. The essential feature of such a release was its quantal nature, similar to what is observed in situ in cholinergic synapses from which mediatophore was purified.