Neurotrophic regulation of retinal ganglion cell synaptic connectivity: from axons and dendrites to synapses

This review highlights important events during the morphological development of retinal ganglion cells (RGCs), focusing on mechanisms that control axon and dendritic arborization as a means to understand synaptic connectivity with special emphasis on the role of neurotrophins during structural and functional development of RGCs. Neurotrophins and their receptors participate in the development of visual connectivity at multiple levels. In the visual system, neurotrophins have been shown to exert various developmental influences, from guiding the morphological differentiation of neurons to controlling the functional plasticity of visual circuits. This review article examines the role of neurotrophins, and in particular of BDNF, during the morphological development of RGCs, and discusses potential interactions between activity and neurotrophins during development of neuronal connectivity.     

Corticosterone decreases the efficacy of adrenaline to affect passive avoidance retention of adrenalectomized rats

Short-term (48h) adrenalectomy (ADX) resulted in a deficit in the retention of a passive avoidance response. An inverted U-shaped dose-response relationship was found following immediate post-learning administration of adrenaline (A). A in a dose range of 0.005 - 5 micrograms/kg s.c. facilitated later retention. While corticosterone (CS) replacement alone had no effect, pretreatment with CS (300 micrograms/kg) was followed by a shift in the dose-response curve of A in ADX rats. Ten thousand times higher doses of A were required to improve retention behavior. Administration of the potent synthetic glucocorticoid dexamethasone failed to affect the responsiveness to A. It is concluded that corticosterone decreases the efficacy by which adrenaline affects later retention behavior of ADX rats. The specificity of corticosterone in this interaction suggests the involvement of the corticosterone receptor system which has its predominant localization in hippocampal neurons.     

VIP induces the elongation of dendrites and axons in cultured hippocampal neurons: role of microtubules

In neurons from rat hippocampus, VIP induces the elongation of dendrites. In the present study, we have investigated in cultured hippocampal neurons whether VIP changed the actin and tubulin cytoskeleton in dendrites. VIP caused the elongation of dendrites and induced the outgrowth of microtubules, so that they extended up to the tips. In contrast, VIP reduced the F-actin content measured as total pixel after phalloidin staining in dendritic tips. These results suggest that VIP causes dendrite elongation by facilitating the outgrowth of microtubules into the newly formed extensions.     

Differential effects of NgCAM and N-cadherin on the development of axons and dendrites by cultured hippocampal neurons

A fundamental step in neuronal development is the acquisition of a polarized form, with distinct axons and dendrites. Although the ability to develop a polarized form appears to be largely an intrinsic property of neurons, it can be influenced by environmental cues. For example, in cell cultures substrate and diffusible factors can enhance and orient axonal development. In this study we examine the effects of growth on each of two cell adhesion molecules (CAMs), NgCAM and N-cadherin, on the development of polarity by cultured hippocampal neurons. We find that although the same pattern of development occurs on control substrates and the CAMs, the CAMs greatly accelerate the rate and extent of development of axons—axons form sooner and grow longer on the CAMs than on the control substrate. In contrast, the CAMs have opposite effects on dendritic development—N-cadherin enhances, but NgCAM reduces dendritic growth compared to control. These results provide further evidence that the development of polarity is largely determined by a cell-autonomous program, but that environmental cues can independently regulate axonal and dendritic growth.     

Measurement of inactive renin in normal, nephrectomized, and adrenalectomized rats.

In a new method for measurement of inactive rat plasma renin, the trypsin generated angiotensin I immunoreactive material, which was HPLC characterized as similar to tetradecapeptide renin substrate, is removed by a cation exchange resin before the renin incubation step. The method also corrects for trypsin destruction of endogenous angiotensinogen by the addition of exogenous angiotensinogen. When measured with this method inactive renin in rat plasma decreased after nephrectomy and increased after adrenalectomy. This is in accordance with findings in humans. A sexual dimorphism of prorenin (inactive renin) in rat plasma, similar to that reported in humans and mice, was demonstrated. Thus, inactive renin in the rat is no exception among species, and the rat might be a suitable animal model for further studies dealing with the physiology of prorenin in plasma and tissues.     

Parathyroidectomy and the induction of thymic atrophy in normal, adrenalectomized and orchidectomized rats

Parathyroidectomy or thyroparathyroidectomy in the male rat results in the severe atrophy of the thymus gland. This effect is not mediated by a secondary release of the cytolytic adrenal or gonadal steroids since it also occurs in adrenalectomized and orchidectomized animals. The loss of the parathyroid gland decreases the flow of thymic lymphocytes into mitosis; this inhibition of cell production leads to the marked decline in thymic weight. The effect can be partially prevented by administration of parathyroid hormone or calcium gluconate.     

Role of moving growth cone-like "wave" structures in the outgrowth of cultured hippocampal axons and dendrites

Hippocampal neurons exhibit periodically recurring growth cone-like structures, referred to as "waves," that emerge at the base of neurites and travel distally to the tip. As a wave nears the tip, the neurite undergoes retraction, and when it reaches the tip, the neurite undergoes a burst of growth. At 1 day in culture, during early axon outgrowth, axons undergo an average 7.5-microm retraction immediately preceding wave arrival at the tip followed by 12-microm growth immediately after arrival (an average net growth of 4.5 microm). In branched axons, waves often selectively travel down one branch or the other. Growth selectively occurs in the branch chosen by the wave. In dendrites, which grow much slower on average, wave-associated retractions are much greater, resulting in less net growth. In the presence of Brefeldin A, which disrupts membrane traffic through the Golgi apparatus and leads to retraction of the axon, axonal waves continue to be associated with both growth spurts and retractions. The magnitude of the growth spurts is not significantly different from untreated axons, but wave-associated retractions are significantly increased. The close association between waves and cyclical elongation suggests that waves may act to bring about this pattern of growth. Our results also show that modulation of regularly occurring retraction phases plays a prominent role in determining average outgrowth rates.     

Effect of streptozotocin-diabetes on thymus of normal and adrenalectomized rats

The injection of streptozotocin in intact or adrenalectomized rats produced a decrease in the number of thymus lymphoid cells. Bovine serum albumin gradient analyses of thymocytes from control, adrenalectomized, adrenalectomized-diabetic and diabetic animals showed variations in the mature/immature cell ratio. No remarkable changes in the distribution of the different thymocyte subpopulations were observed.     

Fate of ganglionic synapses and ganglion cell axons during normal and induced cell death

In order to understand the significance of cell death in the formation of neural circuits, it is necessary to determine whether before cell death neurons have (a) sent axons to the periphery; (b) reached the proper target organs; and (c) have established synaptic connections with them. Axon counts demonstrated that, after sending out initial axons, ciliary cells sprouted numerous collaterals at the time of peripheral synapse formation. Subsequently, large numbers of axons were lost from the nerves, slightly later than the onset of ganglion cell death. A secondary loss of collaterals later occurred unaccompanied by cell death. Measurements of conduction velocity and axon diameters indicated that all ganglion cell axons grew down the proper pathways from the start, but it was not possible to determine whether all axons had actually formed proper synapses. This was ascertained, however, in the ganglion itself where preganglionic fibres were shown to synapse selectively with all ganglion cells before cell death. During this period, degenerating preganglionic synapses were observed on normal cells. It can therefore be inferred that at least some preganglionics established proper synapses before dying and that a single synapse is not sufficient to prevent cell death. In this system neither preganglionic nor ganglionic cell death seems designed to remove improper connections but rather to remove cells that have not competed effectively for a sufficient number of synapses, resulting in a quantitative matching up of neuron numbers.     

Structural alterations of the hippocampal formation of adrenalectomized rats: an unbiased stereological study

Previous studies have demonstrated that adrenalectomy rapidly induces cell death in hippocampal formation. However, these previous studies have involved only qualitative observations or biased estimates. Therefore, the selectivity of the effects of adrenalectomy and the magnitude of changes occurring, remain controversial. The present work employed unbiased stereological tools to examine the effects of adrenalectomy on the number of neurons in, and the volume of, the hippocampal formation. Male rats were adrenalectomized 15,30 or 120 days before sacrifice at 180 days of age. The total number of neurons in the somal layers and hilus of the hippocampal formation was estimated using the optical fractionator. The volume of the different layers of each subdivision in the hippocampal formation was determined according to the Cavalieri principle. A progressive reduction, reaching 43%, was found in the total number of granule cells. Adrenalectomized animals exhibited a reduction in the volume of all layers of the dentate gyrus. No other region of the hippocampal formation displayed significant cell loss or a reduction in volume. In addition, the main neuronal subpopulations of the dentate gyrus were also evaluated, and a reduction in the total number of GABA- and neuropeptide Y-immunoreactive neurons in the molecular and granule cell layers of adrenalectomized rats was found. No quantitative changes were observed in the hilus. To characterize the glial response to the neuronal degeneration, we estimated the total number of cells immunoreactive for glial fibrillary acidic protein in the dentate gyrus. Although no variation in the total number of glial cells was found, signs of astroglial activation were observed in the adrenalectomized group. The present data strengthen the evidence pointing to the critical role of corticosteroids in maintaining the structural integrity of the dentate gyrus.     

核磁共振磁场照射对子代大鼠海马突触形态的影响

研究观察了孕期磁共振磁场照射对子代大鼠海马突触超微结构的影响。SD孕鼠妊娠第12-18d给予0．35T核磁共振(magnetic resonance imaging,MRI)磁场照射。测量1、2和5月龄雌性仔鼠海马CAl区和齿状回的突触结构参数,用立体计量学方法进行定量测定。结果显示,磁场照射可引起2月龄子代大鼠海马CAl区突触间隙增宽．齿状回突触活性区长度变短、突触界面曲率和活性区面密度减小;5月龄子代大鼠CAl区突触间隙增宽,突触后致密物变薄,突触界面曲率减小,齿状回突触间隙增宽。结果提示,妊娠期接受MRI磁场照射可引起海马突触超微结构的改变。对这些结构变化与行为损害之间的关系进行了讨论。