Time-dependent effects of ovarian steroids on tyrosine hydroxylase activity in the limbic forebrain of female rats

Summary In this work, we have studied the time-course of the effects of pharmacological administration of ovarian steroids on tyrosine hydroxylase (TH) activity in the limbic forebrain of ovariectomized rats. Administration of estradiol produced a late decrease in TH activity. This effect was found 24 hours after the last steroid injection, disappearing at 32 hours. It was antagonized by progesterone, since a single injection of this steroid to estradiol-pretreated rats reversed to control values the estradiol-induced decrease. Nevertheless, the administration of progesterone after estradiol treatment caused a short-time decrease in the limbic activity of TH, which was observed 4 hours after the last steroid injection, disappearing subsequently. On the other hand, the administration of progesterone alone produced a biphasic effect, with a reduction at 24 hours, followed by an increase at 32 hours. These effects were only observed in the animals non-treated with estradiol, disappearing with a previous treatment with estrogens. Hence, it can be concluded that both ovarian steroids may affect the limbic TH activity. Thus, estradiol produced a late inhibitory effect on the activity of this enzyme, which was antagonized by progesterone. Administration of the last one to estradiol-treated rats produced a short-time inhibitory effect, whereas its administration to non-treated rats produced a late biphasic effect (inhibition followed by stimulation), which was not observed in estradiol-treated rats.     

Intense immunoreactivity for Mn-superoxide dismutase (Mn-SOD) in cholinergic and non-cholinergic neurons in the rat basal forebrain

The immunohistochemical localization of manganese (Mn)-superoxide dismutase (Mn-SOD) was studied in the rat basal forebrain using polyclonal antibodies to Mn-SOD. Neurons of the basal forebrain exhibit a high density of Mn-SOD immunoreactivity. Double immunostaining with a monoclonal antibody to choline acetyltransferase demonstrated that both cholinergic and non-cholinergic neurons in the basal forebrain are intensely immunoreactive for Mn-SOD.     

Galanin gene expression declines with adulthood in the cholinergic fields of the horizontal diagonal band of male rats

The neuropeptide galanin (GAL) influences leaming and memory processes, perhaps by inhibiting cholinergic function. We recently reported that, in the rat, the nucleus of the horizontal limb of the diagonal band (HDB) exhibits the highest level of GAL mRNA coexpression by basal forebrain (BF) cholinergic neurons and, in the HDB, virtually all GAL mRNA-expressing neurons correspond to the cholinergic cell type. Since GAL gene expression is induced across puberty in many brain regions, we used in situ hybridization histochemistry and quantitative autoradiography to assess GAL gene expression across the rostro-caudal extent of the HDB in prepubertal and adult male rats and to determine whether GAL gene expression is also regulated during maturation in this BF region. Our results show that the number of GAL mRNA-expressing cells per section is significantly reduced in the HDB with adulthood. Post-hoc analysis indicated that these age-associated differences in the number of GAL mRNA-expressing cells per section could be ascribed to the rostral and central subregions of the HDB. Age-related differences in the labeling intensity of GAL mRNA-expressing neurons were also detected in the rostral and central subregions of the HDB. No age-associated differences in GAL gene expression were found in the caudal HDB subregion. These results suggest that: (1) in contrast to other brain regions, GAL gene expression in the cholinergic BF may be negatively regulated by factors concomitant with puberty; and (2) the inhibition of cholinergic function by cosecreted GAL may be enhanced prior to puberty within cholinergic neurons of the rostral and central aspects of the HDB.     

Excitability properties of medial forebrain bundle axons of A9 and A10 dopamine cells

A9 and A10 units identified as dopaminergic were recorded with extracellular micropipettes. The units were antidromically activated by electrical stimulation at the level of the preoptic area. The absolute refractory periods ranged from 1.2 to 2.5 ms. During the 2–8 ms of the relative refractory period, conduction was slower than normal by up to 1.5 ms. The time constant, C, of the strength-duration curve ranged from 0.4 to 0.6 ms. The current (I)-distance (D) relationship, tested by moving the stimulating electrode past the axon, was approximately parabolic (I = K D exp 2), with the constant of the equation, K, ranging from 900 to 2000 μA/mm exp 2, for 0.5 ms pulses. This relationship allows calculation of the radius of the field of dopamine axon excitation at any current. These high K values show that axons of dopamine cells cannot be activated unless high current densities are derivered, even when electrodes are placed near the axons. These data allow determination of the extent to which dopamine axons can be the directly activated substrates for behaviors, such as self-stimulation and circling, which are evoked by electrical stimulation of the medial forebrain bundle or internal capsule.     

The role of the dopaminergic projections in MFB self-stimulation

Psychophysical experiments indicate that the first stage of the reward pathway in medial forebrain bundle self-stimulation consists of small myelinated descending axons. Pharmacological experiments show that neuroleptics attenuate or abolish the rewarding effect. This had led to the hypothesis that the descending myelinated axons synapse on an ascending dopaminergic second stage projection. 2-Deoxy-[¹⁴C]glucose autoradiography in self-stimulating animals or animals receiving automatically administered rewarding stimulation after treatment with reward-blocking doses of pimozide reveals activation of a descending myelinated system but no stimulation-produced activation of an ascending dopaminergic projection system, even though the autoradiographic method reveals the mild elevations and depressions of activity in dopaminergic terminal fields consequent upon injections of neuroleptics and amphetamine, respectively, and the strong activation of the nigrostriatal projection produced by stimulating directly in the substantia nigra. When the effects of neuroleptics and clonidine are measured by the psychophysical method (that is, by lateral shifts in the rate-frequency function), it is found that both drugs produce only gradual and rather small attenuations of rewarding efficacy up to doses at which it is no longer possible to measure their effects. It is suggested that, for neuroleptics at least, the rewarding effect abruptly fails at these doses. It is further suggested that these drugs do not act on the rewarding pathway itself, but on the process by which the rewarding signal is converted to an enduring rewarding effect.     

雌激素对去卵巢大鼠基底前脑NOS及Nestin阳性神经元的影响

目的 观察雌激素替代对去卵巢大鼠基底前脑一氧化氮合酶(NOS)及巢蛋白(Nestin)阳性神经元的影响。方法 将28只健康成年雄性SD大鼠随机分为4个处理组:去势24 h雌激素替代组、去势2周雌激素替代组、去势植物油替代组及假手术组。用组织化学及免疫组织化学染色方法观察基底前脑的内侧隔核(MS)、斜角带垂直支(vDB)及水平支(hDB)的NOS和Nestin阳性神经元数的变化。结果 去势行植物油替代可使MS、vDB的NOS阳性神经元数明显下降(P<0.01);去势24 h或2周行雌激素替代均可使以上亚区的NOS阳性神经元数明显升高至正常水平(P<0.01)。去势行植物油替代或雌激素替代对hDB的:Nestin阳性神经元数的影响趋势与NOS阳性神经元的相似(P<0.01),但对MS及vDB的Nestin阳性神经元数影响不大(P>0.05)。结论 去卵巢行雌激素替代可选择性地使基底前脑不同亚区NOS、Nestin阳性神经元数升高,这可能与雌激素高调了NOS和Nestin的表达有关。     

摘除松果体对大鼠学习记忆及基底前脑胆碱能系统的影响

目的　探讨松果体功能减退对大鼠学习记忆及基底前脑胆碱能系统的影响。方法　选用 3月龄SD大鼠 2 4只 ,随机分为对照组、去松果体组和褪黑素 (MT)组。手术摘除松果体。饲养 1个月后用Morris水迷宫测试学习记忆功能 ,同时用组织化学和免疫组化方法测定海马、前额叶皮质AchE纤维和内侧隔核、斜角带核的ChAT神经元的数量。结果　与对照组比较 ,去松果体组逃避潜伏期明显增加 ,海马、前额叶皮质AchE纤维数量明显减少 ,但内侧隔核、斜角带核的ChAT神经元数量变化不明显。结论　大鼠去松果体可引起大鼠学习记忆能力减弱 ,这可能与基底前脑胆碱能神经元的功能下降有关     

The intra-cortical trajectory of the coeruleo-cortical projection in the rat: A tangentially organized cortical afferent

Cortical and sub-cortical lesions in the rat were used to analyze the intracortical trajectory of the noradrenergic axons, which were visualized by aldehyde-induced catecholamine histofluorescence and by immunohistochemistry using an antibody directed against rat dopamine-β-hydroxylase. Following subcortical lesions there is a slowly progressive reduction in the density of cortical noradrenergic axons, indicating that they undergo asynchronous anterograde degeneration. By 2 weeks after transection of the dorsal noradrenergic bundle, no dopamine β-hydroxylase-immunoreactive fibers are detectable in the ipsilateral cortex. Neither transection of the cingulum bundle, nor parasagittal incisions through the dorsal cortex lateral to the cingulum, diminished the noradrenergic innervation of medial or dorso-lateral cortex. A cortical lesion medial to the cingulum bundle markedly reduced the density of noradrenergic fibers in cingulate cortex caudal to the lesion, but did not affect the innervation of dorso-lateral cortex. In contrast, dorso-lateral frontal incisions and decortication (frontal lobotomy) produced a marked ipsilateral decrease in the noradrenergic fiber density throughout the remaining dorso-lateral cortex, while sparing the innervation of cingulate and infra-rhinal cortex.These results demonstrate that the dorso-lateral cortex is innervated by noradrenergic fibers in the medial forebrain bundle that reach the frontal pole, turn dorsally over the anterior portion of the forceps minor and continue caudally within the deep layers of frontal and dorso-lateral cortex, supplying the noradrenergic innervation throughout their trajectory. The medial cortex is innervated by a separate group of noradrenergic fibers that ascend through the septum, curve over the genu of the corpus callosum, and run caudally in the supracallosal stria.The present results show that the cingulum bundle is not a major intra-cortical noradrenergic pathway and does not provide branches that contribute significantly to the innervation of dorsal or lateral cortex. Thus the medial and lateral cortex can be selectively and differentially denervated of noradrenergic fibers and a coarse topographic order exists in the noradrenergic innervation of cortex. Since noradrenergic fibers travel long distances within the cortical grey matter, a small lesion of frontal cortex can have far-reaching effects on the innervation of distant, more caudal regions of cortex. The coeruleocortical projection has properties that differ from those of the best characterized cortical afferents and may be a useful model for the study of other ascending monoamine systems. The tangential, intracortical trajectory of the noradrenergic fibers would confer upon the coeruleo-cortical system the capacity to modulate neuronal activity simultaneously through a vast expanse of neocortex. A formulation of cortical organization is presented which integrates the tangential organization of the coeruleo-cortical projection with the concept of columnar organization of cortex.     

Ascending and descending components of the medial forebrain bundle in the rat as demonstrated by the horseradish peroxidase-blue reaction

Summary The ascending and descending components of the medial forebrain bundle (MFB) were investigated by means of horseradish peroxidase (HRP) with a sensitive substrate. The HRP was injected iontophoretically into the MFB at various levels from the anterior commissure to the posterior hypothalamus. In order to prevent the diffusion of HRP to other brain areas, a double micropipette system was used. The descending components of the MFB are derived from (1) the anterior cingulate area, infra- or prelimbic area, and sulcal cortex, (2) the lateral septal nucleus and diagonal band, (3) the bed nucleus of the stria terminalis, (4) the paraventricular nucleus (5) the substantia innominata, (6) the amygdaloid complex (AM), (7) the ventromedial (VM) and dorsomedial (DM) hypothalamic nuclei, (8) the entopeduncular nucleus and (9) nucleus periventricularis stellatocellularis. The ascending components of the MFB originate in: (1) the medial preoptic nucleus, (2) the nucleus periventricularis stellatocellularis and rotundocellularis, (3) the posterior hypothalamic nucleus, (4) the parafascicular nucleus, (5) the ventral premammillary nucleus, (6) the substantia grisea periventricularis, (7) the lateral habenular nucleus, (8) the VM and DM, (9) the paratenial nucleus, (10) the AM and (11) the arcuate nucleus.Abbreviations used in Figures and Tables a nucleus accumbens - abl nucleus amygdaloideus basalis, pars lateralis - abm nucleus amygdaloideus basalis, pars medialis - ac nucleus amygdaloideus centralis - AC anterior cingulate area - al nucleus amygdaloideus lateralis - am nucleus amygdaloideus medialis - ar nucleus arcuatus - CC tractus corporis callosi - CSDV commissura supraoptica dorsalis, pars ventralis - DB diagonal band - DM nucleus dorsomedialis hypothalami - EP nucleus entopeduncularis - ha nucleus anterior hypothalami - hl nucleus lateralis hypothalami - hp nucleus posterior hypothalami - IL infralimbic area of frontal cortex - lh nucleus habenulae lateralis - LH₁ medial forebrain bundle (MFB) at the level of commissura anterior - LH₂ lateral preoptic area - LH₃ MFB at the level of the nucleus anterior hypothalami - LH₄ MFB at the level of the nucleus ventromedialis hypothalami - LH₅ MFB at the level of the nucleus posterior hypothalami - MFB medial forebrain bundle - pf nucleus parafascicularis - PL prelimbic area of frontal cortex - pol nucleus preopticus lateralis - pom nucleus preopticus medialis - posc nucleus preopticus, pars suprachiasmatica - pt nucleus parataenialis - pv nucleus premamillaris ventralis - PV nucleus paraventricularis - pvs nucleus periventricularis stellatocellularis - pvr nucleus periventricularis rotundocellularis - SC sulcal cortex - SGPV substantia grisea periventricularis - SI substantia innominata - SL lateral septal nucleus - ST bed nucleus of stria terminalis - sum nucleus supramamillaris - TO tractus opticus - tmm nucleus medialis thalami, pars medialis - VM nucleus ventromedialis hypothalami The nomenclature used in this paper is according to König and Klippel's Stereotaxic Atlas (1967).     

A lectin horseradish peroxidase study of the origin of ascending fibers in the medial forebrain bundle of the rat. The upper brainstem

The origins of projections within the medial forebrain bundle from the upper brainstem were examined with the horseradish peroxidase technique. Labeled cells were found in approximately 15 upper brainstem nuclei following injections of a conjugate of horseradish peroxidase and wheat germ agglutinin at various levels of the medial forebrain bundle. Labeled nuclei included (from caudal to rostral): dorsal and ventral parabrachial nuclei; Kolliker-Fuse nucleus; dorsolateral tegmental nucleus; A7 (lateral pontine tegmentum medial to lateral lemniscus); median and dorsal raphe nuclei; distinct group of cells oriented mediolaterally in the dorsal pontine tegmentum below the central gray; B9 (ventral midbrain tegmentum dorsal to medial lemniscus); retrorubral nucleus; nucleus of Darkschewitsch, interfascicular nucleus; rostral and caudal linear nuclei; ventral tegmental area; medial part of substantia nigra, pars compacta; and the supramammillary nucleus. With the exception of the ventral parabrachial nucleus, Kolliker-Fuse, A7, B9 and substantia nigra, pars compacta, each of the nuclei mentioned above sent strong projections along the medial forebrain bundle to the rostral forebrain. Sparse labeling was observed throughout the pontine and midbrain reticular formation. With the exception of the dorsal raphe nucleus, projections to the most anterior regions of the medial forebrain bundle (level of the anterior commissure) essentially only arose from presumed dopamine-containing nuclei-retrorubral nucleus (A8 area), interfascicular nucleus, rostral and caudal linear nuclei, substantia nigra pars compacta, and ventral tegmental area. Evidence was reviewed indicating that major forebrain sites of termination for these dopaminergic nuclei are structures that have been collectively referred to as the 'ventral striatum'. It is concluded from the present findings that several pontine and mesencephalic cell groups are in a position to exert a strong, direct effect on structures in the anterior forebrain and that the medial forebrain bundle is the main communication route between the upper brainstem and the forebrain.