Circuit Development in the Dorsal Lateral Geniculate Nucleus (dLGN) of the Mouse.

Seabrook, Tania

01 January 2012

The visual system is one of the most widely used and best understood sensory systems and the dorsal lateral geniculate nucleus (dLGN) of the mouse has emerged as a model for investigating the cellular and molecular mechanisms underlying the development and activity-dependent refinement of sensory connections. Thalamic organization is highly conserved throughout species and the dLGN of the mouse possesses many features common to higher mammals, such as carnivores and primates. Two general classes of neuron are present within the dLGN, thalamocortical relay cells and interneurons, both of which receive direct retinal input. Axons of relay cells exit dLGN and convey visual information to layer IV of cortex, whereas interneurons are involved in local circuitry. In addition, dLGN receives rich nonretinal input from numerous areas of the brain. Studies thus far have focused on the retinogeniculate pathway and the development of connections between retinal ganglion cells (RGCs) and relay cells has been well characterized. However, there are still a number of unanswered questions about circuit development in dLGN. Here we examined two aspects that are not well understood, the pattern of retinal convergence onto interneurons and the structural and functional innervation of nonretinal projections. To address the first issue we conducted in vitro whole-cell recordings from acute thalamic slices of GAD67-GFP mice, a transgenic strain in which dLGN interneurons express GFP. We also did 3-D reconstructions of biocytin-labeled interneurons using multi-photon laser scanning microscopy in conjunction with anterograde labeling of retinogeniculate projections to examine the distribution of retinal contacts. To begin to examine the development of nonretinal connections in dLGN we made use of a transgenic mouse (golli-τ-GFP) to visualize corticogeniculate projections, one of the largest sources of nonretinal input to dLGN. Using this mouse we studied the timing and patterning of corticogeniculate innervation in relation to the development of the retinogeniculate pathway. We also used binocular enucleation and genetic deafferentation to test whether the retina plays a role in regulating nonretinal innervation. We found that there is a coordination of retinal and nonretinal innervation in dLGN. Projections from the retina were the first to innervate and they entered dLGN at perinatal ages. They also made functional connections with both relay cells and interneurons at early postnatal ages. Interestingly, relay cells underwent a period of retinogeniculate refinement, whereas the degree of retinal convergence onto interneurons was maintained. This possibly reflects the different roles that these two cell types have in dLGN. Both structural and functional corticogeniculate innervation was delayed in comparison and occurred postnatally, however in the absence of retinal input the timing of corticogeniculate innervation was accelerated. RGCs transmit the visual information encoded in the retina to dLGN so it may be necessary for these connections to be formed before those from nonretinal projections, which serve to modulate that signal on its way to cortex. Thus precise timing of retinal and nonretinal innervation may be important for the appropriate formation of connections in the visual system and the retina seems to be playing an important role in regulating this timing.

dLGN

interneuron

retinogeniculate

corticogeniculate

Medical Sciences

Medicine and Health Sciences

Neurosciences

DEVELOPMENTAL REMODELING OF RELAY CELLS IN THE DORSAL LATERAL GENICULATE NUCLEUS (dLGN) OF THE MOUSE AND THE ROLE OF RETINAL INNERVATION

El-Danaf, Rana

07 September 2011

The dorsal lateral geniculate nucleus (dLGN) has become an important model for studying many aspects of visual system development. To date, studies have focused on the development of retinal projections and the role of activity in shaping the pattern of synaptic connections made with thalamocortical relay cells. By contrast, little is known about relay cells and the factors that regulate the growth and establishment of their dendritic architecture. In many systems, such growth seems consistent with the synaptotrophic hypothesis which states that synapse formation and dendritic growth work in a concerted fashion such that afferent input and the establishment of functional synapses are needed to shape the maturation of dendritic arbors. To address this, we characterized the development of relay cells in the dLGN of wild-type (WT) mouse. By adopting a loss of function approach, we assessed the manner in which growth and maturation of relay cells were affected by retinal innervation. For this, we made use of the math-null (math5-/-) mouse in which progenitors fail to differentiate into retinal ganglion cells (RGCs), and exhibit a >95% cell loss. Anterograde labeling of RGC axons with cholera toxin subunit B (CTB), immunolabeling of RGC-specific presynaptic machinery in dLGN (e.g. vesicular glutamate transporter 2), and ultrastructural analysis at the electron microscopy level demonstrated that the dLGN is devoid of retinal innervation. We examined the functional and morphological characteristics of relay cells in WT and math5-nulls during early postnatal life by conducting in vitro whole cell recordings in slices containing dLGN. Individual relay cells were labeled by intracellular injection of biocytin, and imaged by confocal microscopy to obtain the 3-D reconstructions of their dendritic trees. Morphometric analysis revealed that relay cells in WT undergo two growth spurts: an early one where cell class specification and dendritic complexity are established and a later one marked by an increase in dendritic field and length. Following the third week, relay cells growth was stabilized. In math5-nulls, relay cells maintained their morphological identity whereby cells could be classified in three groups (Y: spherical, X: bi-conical, W: hemi-spherical). However, the dLGN was highly reduced in size, and relay cells showed disrupted growth spurts. Relay cells had smaller somata and exhibited fluctuations in dendritic complexity and field extent compared to age-matched WTs. Exuberance in dendritic branching was noted in week 2, and by week 5, relay cells had significantly smaller surface area resulting from a loss of dendritic segments and a reduction in dendritic field extent. Control experiments using RT-PCR revealed that these changes were not due to the loss of math5 in the dLGN. Whole cell recordings and voltage responses to square wave current pulses showed that math5-nulls possess the full compliment of intrinsic membrane properties, such as relay cells displayed both burst and tonic firing modes. A cross of the math5-null with a transgenic mouse that expresses GFP in layer VI cortical neurons revealed a dense plexus of corticogeniculate terminals throughout the mature dLGN. However, the rate of corticogeniculate innervation was highly accelerated and was complete a week earlier than WT. Electric stimulation of cortical axons revealed that synapses are functional and responses were indistinguishable from WT. Taken altogether, these observations suggest that retinal innervation plays an important trophic role in the maturation of dLGN and is necessary for the continued maintenance of relay cells’ structural integrity. However, the general form and function of relay cells seem largely unaffected by the loss of retinal innervation.

dLGN

thalamus

retinogeniculate

relay cells

Medical Sciences

Medicine and Health Sciences

Neurosciences

Nicotinic Acetylcholine Receptor α3 mRNA in Rat Visual System After Monocular Deprivation

Taylor, James H. (James Harvey), 1970-

08 1900

In situ hybridization was used to examine effects of monocular enucleation on nicotinic acetylcholine receptor subunit cc3 mRNA in the rat dLGNand visual cortex. After 28 days postoperative, there were no significant differences in α3 mRNA density between the contralateral (deprived) and ipsilateral (non-deprived) sides. The lack of obvious effects of visual deprivation on α3 mRNA density suggests that other factors, possibly intrinsic to dLGNand visual cortex, govern the postnatal expression of α3 mRNA.

dLGN

Visual cortex

Alpha 3 mRNA

Nicotinic acetylcholine

Nicotinic receptors.

Acetylcholine -- Receptors.

Visual cortex.

Rats -- Nervous system.

Localization and function of the endocannabinoid system throughout the retinogeniculate pathway of vervet monkeys

Javadi Khomami, Pasha

01 1900

Le système endocannabinoïde (eCB) est présent dans le système nerveux central (SNC) de mammifères, incluant la rétine, et est responsable de la régulation de nombreux processus physiologiques. Bien que la présence du récepteur cannabinoïde de type 1 (CB1R) a bien été documenté dans la rétine de rongeurs et primates, il y a encore une controverse quant à la présence du récepteur cannabinoïde de type 2 (CB2R) au niveau du SNC. En utilisant la microscopie confocale, nous sommes les premiers à signaler les patrons d’expression du CB2R dans la rétine de singe. Nos résultats démontrent que le CB2R est exprimé exclusivement dans les cellules de Müller de la rétine du singe. En outre, nous avons comparé les différents patrons d’expression du système eCB dans la rétine de la souris, du toupaye, ainsi que du singe vervet et macaque. Nous rapportons que les distributions de CB1R, FAAH (fatty acid amid hydrolase), MAGL (monoacylglycerol lipase) et DAGLα (diacylglycerol lipase alpha) sont hautement conservées parmi ces espèces alors que CB2R et NAPE-PLD (N-acyl phosphatidylethanolamine phospholipase D) présentent différents profils d'expression. CB2R n'a pas été détecté dans les cellules neuronales de la rétine des primates. L’immunoréactivité de NAPE-PLD est présente dans les couches de la rétine de souris et toupayes, mais a été limitée à la couche des photorécepteurs des singes vervet et macaque. Pour étudier les corrélats neuronaux et le rôle de la signalisation du système eCB dans la rétine, nous avons établi un protocole standard pour l'électrorétinographie (ERG), puis enregistré la réponse ERG de la rétine après le blocage des récepteurs avec des antagonistes spécifiques pour CB1R (AM251) et CB2R (AM630). Comparé au témoin, dans des conditions photopiques, et à certaines intensités faibles du stimulus, le blocage de CB1R diminue l'amplitude de l'onde-b, alors qu’à des intensités plus élevées, le blocage de CB2R augmente l'amplitude des deux-ondes a et b. De plus, le blocage des récepteurs cannabinoïdes provoque une augmentation de la latence des deux ondes a et b. Dans des conditions d’adaptation à l'obscurité, le blocage de CB1R et CB2R réduit l’amplitudes de l'onde a seulement à des intensités plus élevées et réduit l’onde b à intensités plus faibles. Des augmentations significatives de latence ont été observées dans les deux cas. Ces résultats indiquent que les récepteurs CB1 et CB2 chez les primates non humains sont impliqués dans la fonction rétinienne conditions photopiques. En outre, nous avons évalué le profil d'expression du CB1R, de FAAH et de NAPE-PLD au-delà de la rétine dans le corps géniculé latéral des singes et nous rapportons pour la première fois que CB1R et FAAH sont exprimés davantage dans les couches magnocellulaires. La NAPE-PLD a été localisée à travers les couches magno- et parvocellulaires. Aucune de ces composantes n’est exprimée dans les couches koniocellulaires. Ces résultats nous aident à mieux comprendre les effets des cannabinoïdes sur le système visuel qui pourraient nous mener à trouver éventuellement de nouvelles cibles thérapeutiques. / The endocannabinoid (eCB) system is present in the mammalian central nervous system, including the retina, and is responsible for the regulation of many physiological processes. Anatomical and functional data collected in the retina indicate that cannabinoid receptors are important mediators of retinal function. Although the presence of the cannabinoid receptor type 1 (CB1R) has been documented in the rodent and primate retina, there is still some controversy regarding the presence of the CB2 receptor (CB2R) within the central nervous system. By using confocal microscopy, we are the first to report the distribution patterns of CB2R in the monkey retina. Our results show that CB2R is expressed exclusively in the Müller cells of the primate retina. Furthermore, we compared the eCB system distribution patterns in the retinas of mice, tree shrews, and vervet and macaque monkeys. We report that CB1R, FAAH, MAGL, and DAGLα distributions are highly conserved among these 3 species whereas CB2R and NAPE-PLD exhibit different expression patterns. CB2R was not detected in the neuroretinal cells of primates. NAPE-PLD immunoreactivity was present in the retinal layers of mice and tree shrews but was restricted to the photoreceptor layer in both species of primates studied. To study the neural correlates and the role of eCB signaling in the retina, we first established a standard protocol for electroretinography (ERG) and then recorded the ERG response of the retina after blocking receptors with specific antagonists for CB1R (AM251) and CB2R (AM630). Compare to control, in photopic conditions, at certain low flash intensities, only the blockade of CB1R decreases the amplitude of the a-wave and b-wave, while at some high flash intensities, blockade of CB2R increase the amplitude of both a- and b-waves. Also the blockade of the cannabinoid receptors causes an increase in the latency of both a- and b-waves. In dark-adapted eyes, blockade of the CB1R and CB2R reduces the a-wave only amplitudes in the higher intensities and decrease the b-wave in lower intensities. Some significant increases in latency were observed in both cases. These results indicate that CB1 and CB2 receptors in primates are involved in retinal function under photopic and scotopic conditions. In addition, we assessed the expression pattern of eCB components CB1R, FAAH, and NAPE-PLD beyond the retina in the dorsal lateral geniculate nucleus (dLGN) of primates and report for the first time that while CB1R and FAAH are more abundantly expressed in the magnocellular layer, NAPE-PLD is distributed throughout both the magno- and parvocellular layers. None of these components are expressed in the koniocellular layer. These findings augment our understanding of the effects of cannabinoids on the visual system and may lead to novel therapeutics targeted to eCB signaling.

endocannabinoïdes

Vision

Singe

CB1R

CB2R

FAAH

NAPE-PLD

MAGL

DAGL

dLGN

Monkey

Endocannabinoid

ERG

Segregation within afferent pathways in primate vision

Roy, Sujata

January 2009

The current knowledge of the visual pathways in primates includes the patterns of projection from the retina through the dorsal lateral geniculate nucleus (dLGN) to the striate cortex (V1) and the extra-striate projections towards the dorsal and ventral streams. Cells with short wavelength sensitive cone (S-cone) inputs in the dLGN have been studied extensively in New World marmosets but not in Old World macaques. This thesis presents results from studies in the macaque monkey which are more relevant to humans since humans are closer in evolution to Old World than New World monkeys. / The spatial, temporal, chromatic and orientation preferences of neurons in the dLGN of the macaque were investigated by electrophysiological methods. The physiological findings of cells with S-cone inputs were compared to cells with opponent inputs from the long and medium wavelength sensitive cones (L-cones & M-cones, respectively). The cells receiving S-cone inputs (blue-yellow or B-Y cells) preferred lower spatial frequencies than the cells with opponent L-cone and M-cone inputs (red-green or R-G cells). Orthodromic latencies from optic chiasm stimulation were measured where possible to distinguish differences in conduction velocity between the cell groups. Although the B-Y cells usually had longer latencies than R-G cells, there wasconsiderable overlap between the cell groups. / The recorded cells were localised through histological reconstruction of dLGN sections stained for Nissl substance. The distribution of B-Y cells within the dLGN was compared to the distribution of R-G cells. The majority of B-Y cells were located within the intercalated koniocellular layers as well as the koniocellular bridges (extensions of the koniocellular layers into the adjacent parvocellular layers). The B-Y cells were also largely segregated within the middle dLGN layers (K3, P3, K4 & P4). The R-G cells were mainly concentrated within the parvocellular layers (P3, P4, P5 & P6) and were evenly distributed throughout the middle and outer layers of the dLGN. / The study also included recordings from the extra-striate middle temporal area (MT) to determine whether a fast S-cone input exists from the dLGN to area MT which bypasses V1. The pattern of cone inputs to area MT neurons was investigated before and during inactivation of V1. The inactivation was done through reversible cooling with a Peltier thermocouple device or focal inactivation with y-amino butyric acid (GABA) iontophoresis. Precise inactivation of V1 to the topographically matching visual fields of the recording sites in area MT revealed a preservation of all three coneinputs in many cells. The subcortical sources of these preserved inputs are discussed with their relevance to blindsight, which is the limited retention of visual perception after V1 damage. Analysis of the latencies of area MT cells revealed a rough segregation into latencies faster or slower than 70 ms. Cells both with and without a significant change in response during V1 inactivation were present in each group. The findings reported in this thesis indicate that some of the preserved inputs in area MT during V1 inactivation may be carried by a direct input from the dLGN which bypasses V1.