Dendritic Spine Density Varies Between Unisensory and Multisensory Cortical Regions

Bajwa, Moazzum

07 May 2010

In the brain, the dendritic spine is a point of information exchange that extends the neuronal surface on which synapses occur, as well as facilitates and stabilizes those contacts. Furthermore, dendritic spines dynamically change in shape and number in response to a variety of factors. Dendritic spine numbers are reduced in mental retardation, enhanced during development, sensory enrichment or physical exercise, or fluctuate during the reproductive cycle. Thus, for a given neuron type, it might be expected that dendritic spine number might achieve a dynamic optimum. Indeed, many studies of spine density of pyramidal neurons in sensory cortex indicate that an average of ~1.4 spines/micron occurs is present (Briner et al., 2010). Most such studies examined dendritic spines from primary sensory areas which are dominated by inputs from a single sensory modality. However, there are a large number of neural regions that receive inputs from more than one sensory modality and it is hypothesized that spine density should increase to accommodate these additional inputs. To test this hypothesis, the present experiments used Golgi-Cox stained layer 2-3 pyramidal neurons from ferret primary somatosensory (S1) and auditory (A1) cortical regions, as well as from the higher-level rostral posterior parietal (PPr) and lateral rostral suprasylvian (LRSS) multisensory areas. Spine densities in S1 (avg 1.309 ± 0.247 spines/micron) and A1 (avg 1.343 ± 0.273 spines/micron) were measured to be significantly greater (p<0.05, t-test) than those observed in multisensory regions PPr (avg 1.242 ± 0.205 spines/micron) or LRSS (avg 1.099 ± 0.217 spines/micron). These results also indicate that spine densities are greater in primary (S1, A1) than in higher-level (PPr, LRSS) sensory areas. The functional consequences of such unexpected findings are discussed in light of potential biophysical differences between unisensory and multisensory neurons.

dendritic spine density

multisensory

Anatomy

Medicine and Health Sciences

Nervous System

Differential Effects of NMDA Receptor Antagonism on Spine Density

Ruddy, Rebecca Marie

17 July 2013

Recent studies have demonstrated that an acute, low dose of ketamine, a non-competitive NMDA receptor antagonist, provides rapid and sustained antidepressant effects in patients with major depressive disorder. Studies in rodents have shown that the antidepressant properties of ketamine are due to an increase in dendritic spine density in the cortex. Our goal was to determine whether these effects are specific to ketamine and whether they are dependent on dose, drug regimen and brain region. We observed that the effects of ketamine on spine density were dependent on dose and drug regimen and were also brain region specific. In addition, MK-801, another NMDA receptor antagonist, did not demonstrate the same effects on spine density as ketamine. Furthermore, genetic NMDA receptor hypofunction significantly reduced spine density. Our studies demonstrate that while acute ketamine treatment leads to an increase in cortical spine density, chronic administration has opposite and potentially detrimental effects.

NMDA receptor antagonism

Ketamine

MK-801

Spine density

Depression

0419

Differential Effects of NMDA Receptor Antagonism on Spine Density

Ruddy, Rebecca Marie

17 July 2013

Recent studies have demonstrated that an acute, low dose of ketamine, a non-competitive NMDA receptor antagonist, provides rapid and sustained antidepressant effects in patients with major depressive disorder. Studies in rodents have shown that the antidepressant properties of ketamine are due to an increase in dendritic spine density in the cortex. Our goal was to determine whether these effects are specific to ketamine and whether they are dependent on dose, drug regimen and brain region. We observed that the effects of ketamine on spine density were dependent on dose and drug regimen and were also brain region specific. In addition, MK-801, another NMDA receptor antagonist, did not demonstrate the same effects on spine density as ketamine. Furthermore, genetic NMDA receptor hypofunction significantly reduced spine density. Our studies demonstrate that while acute ketamine treatment leads to an increase in cortical spine density, chronic administration has opposite and potentially detrimental effects.

NMDA receptor antagonism

Ketamine

MK-801

Spine density

Depression

0419

THE EFFECTS OF LONG-TERM DEAFNESS ON DENSITY AND DIAMETER OF DENDRITIC SPINES ON PYRAMIDAL NEURONS IN THE DORSAL ZONE OF THE FELINE AUDITORY CORTEX

Bauer, Rachel J

01 January 2019

Neuroplasticity has been researched in many different ways, from the growing neonatal brain to neural responses to trauma and injury. According to recent research, neuroplasticity is also prevalent in the ability of the brain to repurpose areas that are not of use, like in the case of a loss of a sense. Specifically, behavioral studies have shown that deaf humans (Bavalier and Neville, 2002) and cats have increased visual ability, and that different areas of the auditory cortex enhance specific kinds of sight. One such behavioral test demonstrated that the dorsal zone (DZ) of the auditory cortex enhances sensitivity to visual motion through cross-modal plasticity (Lomber et. al., 2010). Current research seeks to examine the anatomical structures responsible for these changes through analysis of excitatory neuron dendritic spine density and spine head diameter. This present study focuses on the examination of DZ neuron spine density, distribution, and size in deaf and hearing cats to corroborate the visual changes seen in behavioral studies. Using Golgi-stained tissue and light microscopy, our results showed a decrease in overall spine density but slight increase in spine head diameter in deaf cats compared to hearing cats. These results, along with several other studies, support multiple theories on how cross-modal reorganization of the auditory cortex occurs after deafening

Dorsal zone

crossmodal plasticity

spine density

spine diameter

deafness

Anatomy

Nervous System

Recovery of function after lesions of the anterior thalamic nuclei: CA1 neuromorphology

Harland, Bruce

January 2013

The anterior thalamic nuclei (ATN) are a critical part of an extended hippocampal system that supports key elements of episodic memory. Damage or disconnection of the ATN is a component of clinical conditions associated with severe anterograde amnesisa such as the Korsakoff’s syndrome, thalamic stroke, and neurodegenerative disorders. Previous studies have demonstrated that the ATN and hippocampus are often interdependent, and that ATN damage can result in ‘covert pathology’ in ostensibly healthy distal regions of the extended hippocampal system. Adult male rats with neurotoxic bilateral ATN lesions or sham surgery were post-operatively housed in an enriched environment or standard housing after a lesion-induced spatial working memory deficit had been established. These rats were retested on cross-maze and then trained in radial-arm maze spatial memory tasks. Other enriched rats received pseudo-training only after the enrichment period. The detailed neuromorphology of neurons was subsequently examined in the hippocampal CA1. Soma characteristics were also examined in the retrosplenial granular b cortex and the prelimbic cortex. In Experiment 1, ATN lesions produced clear deficits in both the cross-maze and radial-arm maze tasks and reduced hippocampal CA1 dendritic complexity, length, and spine density, while increasing the average diameter of the dendrites. Post-operative enrichment reversed the ATN lesion-induced deficits in the cross-maze and radial-arm maze, and returned CA1 basal and apical spine density to a level comparable to that of sham standard housed trained rats. The sham enriched rats exhibited improved radial-arm maze performance and increased CA1 branching complexity and spine density in both basal and apical arbors compared to sham standard housed rats. The neuromorphological changes observed in the enriched ATN and sham rats may be in part responsible for the spatial working memory improvements observed. Experiment 2 provided support for this contention by demonstrating that the CA1 spine changes were explicitly relevant to spatial learning and memory, because trained enriched sham and ATN rats had increased spines, particularly in the basal tree when compared to closely comparable pseudo-trained enriched rats. Interestingly, spatial memory training increased the numbers of both thin and mushroom spines, whereas enrichment was only associated with an increase in thin spines. In Experiment 3, ATN lesions increased cell body size in layer II of the retrosplenial granular b cortex, whereas enrichment decreased cell body size in layer V of this region. Neither ATN lesions nor enrichment had any effect on cell body morphology in the prelimbic cortex. The current research provides some of the strongest evidence to date of ATN and hippocampal interdependence within the extended hippocampal system, and provides the first evidence of neuromorphological correlates of recovery after ATN lesions.

ATN

anterior thalamic nuclei

extended hippocampal system

CA1

neuromorphology

enrichment

recovery

spine density

dendritic branching

retrosplenial granular b cortex

prelimbic cortex

ATN and hippocampal interdependance

Luteinizing hormone in the central nervous system: a direct role in learning and memory

Blair, Jeffrey A.

11 April 2018

No description available.

Neurosciences

Biomedical Research

Biology

Aging

Neurobiology