Dennis D. Kunkel

Physiologic and Morphologic Characteristics of Granule Cell Circuitry in Human Epileptic Hippocampus

Summary: Morphological and electrophysiological techiques were used to examine granule cells and their mossy fiber axons in nine surgically resected hippocampal specimens from temporal lobe epilepsy (TLE) patients. Timm histochemistry showed mossy fiber sprouting into the inner molecular layer (IML) of the dentate in a subset of tissue samples. In slices from five tissue samples, stimulus‐induced bursting activity could be induced with a low concentration (2.5 μM) of bicuculline; bursts were sensitive to the N‐methyl‐d‐aspartate (NMDA) blocker, APV. There was a general correlation between such sprouting and experimentally induced yperexcit ability. Fourteen granule cells from five tissue samples were intracellularly stained [with lucifer yellow (LY) or neurobiotin]. Axons from a subset of these neurons showed axon collaterals reaching into the IML, but this axon projection pattern for single cells was not directly correlated with degree of mossy fiber sprouting shown grossly by Timm staining. Electron microscopic examination of intracellularly stained elements showed mossy fiber axon terminals making asymmetric synaptic contacts (including autapses on the granule cell dendrite) with dendritic shafts and spines in both apical and basal domains. These data are consistent with the hypothesis that mossy fiber sprouting provides a structural basis for recurrent excitation of granule cells, but does not provide direct support of the hypothesis that mossy fiber sprouting causes hyperexcitability. The data suggest that granule cell bursting activity is at least in part a function of compromised synaptic inhibition, since levels of γ‐aminobutyric acid (GABA) blockade that are generally subthreshold for burst induction were epileptogenic in some tissue samples from human epileptic hippocampus.

Axon arbors and synaptic connections of hippocampal mossy cells in the rat in vivo

The axon collateralization patterns and synaptic connections of intracellularly labeled and electrophysiologically identified mossy cells were studied in rat hippocampus. Light microscopic analysis of 11 biocytin‐filled cells showed that mossy cell axon arbors extended through an average of 57% of the total septotemporal length of the hippocampus (summated two‐dimensional length, not adjusted for tissue shrinkage). Axon collaterals were densest in distant lamellae rather than in lamellae near the soma. Most of the axon was concentrated in the inner one‐third of the molecular layer, with the hilus containing an average of only 26% of total axon length and the granule cell layer containing an average of only 7%. Ultrastructural analysis was carried out on three additional intracellularly stained mossy cells, in which axon collaterals and synaptic targets were examined in serial sections of chosen axon segments. In the central and subgranular regions of the hilus, mossy cell axons established a low density of synaptic contacts onto dendritic shafts, neuronal somata, and occasional dendritic spines. Most hilar synapses were made relatively close to the mossy cell somata. At greater distances from the labeled mossy cell (1–2 mm along the septotemporal axis), the axon collaterals ramified predominantly within the inner molecular layer and made a high density of asymmetric synaptic contacts almost exclusively onto dendritic spines. Quantitative measurements indicated that more than 90% of mossy cell synaptic contacts in the ipsilateral hippocampus are onto spines of proximal dendrites of presumed granule cells. These results are consistent with a primary mossy cell role in an excitatory associational network with granule cells of the dentate gyrus.

Primate neostriatal neurons containing tyrosine hydroxylase: Immunohistochemical evidence

We have detected, in monkey caudate nucleus and putamen, neuronal cell bodies containing tyrosine hydroxylase-like immunoreactivity, as revealed by peroxidase-antiperoxidase immunohistochemistry. Many of these cells are distributed in an outer rim of 1-2 mm throughout the anterior-posterior extent of the neostriatum near its borders with the corona radiata; others are embedded in the adjacent white matter, especially near the ventral putamen and nucleus accumbens. Light and electron microscopy indicate that they are small (8-12 micron), bipolar cells with large nuclei. Such neostriatal neurons, containing tyrosine hydroxylase-like immunoreactivity, number in the tens of thousands.

Development of rabbit hippocampus: Anatomy

The postnatal development of the CA1 region of rabbit hippocampus was studied using a variety of light and electron microscopic (EM) techniques. Nissl and Golgi stains showed high cellular density, small cell soma area, and sparse dendritic branching in neurons of immature animals (less than 1 week old); dendritic spines were also relatively infrequent during this period. Cell branching and spine frequency reached near-adult levels by 3 weeks, with the major area of hippocampal expansion seen in the apical dendritic layer. EM examination of synapse patterns was made using osmicated and E-PTA-treated tissue. Both techniques showed that the vast majority of synapses in immature animals (less than 2 weeks old) occurred in the dendritic region and were of the asymmetric type. Axosomatic synapses became less rare by 2 weeks; they were usually of the symmetric synapse type. The pattern of synaptic contacts in immature hippocampus resembled the mature pattern by 3-4 weeks. These data suggest a relatively late development of inhibitory postsynaptic potentials in CA1 pyramidal cells.

Beta amyloid is neurotoxic in hippocampal slice cultures.

We examined the neurotoxicity of the 40 amino acid fragment of beta amyloid peptide (A beta 1-40) in cultured hippocampal slices. When injected into area CA3, A beta 1-40 produced widespread neuronal damage. Injection of the reverse sequence peptide, A beta 40-1, or vehicle alone produced little damage. The distribution A beta 1-40 was highly correlated with the area of neuronal damage. Thioflavine S and electron microscopic analysis confirmed that injected A beta 1-40 formed 7-9 nm AD type amyloid fibrils in the cultures. A beta 1-40 also altered the number of GFAP immunoreactive astrocytes and ED-1 immunoreactive microglia/macrophages within and around the A beta 1-40 deposit. The observed neurotoxicity of A beta 1-40 in hippocampal slice cultures provides evidence that this peptide may be responsible for the neurodegeneration observed in AD.

Developmental and regional differences in the localization of Na,K-ATPase activity in the rabbit hippocampus

Regional differences in Na,K-ATPase activity, and development of Na,K-ATPase activity were examined in rabbit hippocampus using a histochemical marker of enzyme activity. Stratum lucidum of CA3/CA2, corresponding to the mossy fiber terminal field, showed high Na,K-ATPase activity compared to stratum radiatum of CA1. A significant increase in Na,K-ATPase activity was found between 8 and 15 days postnatal. Tissues with limited Na,K-ATPase activity (immature hippocampus, the mature CA1 region) appear particularly prone to seizure-like abnormalities, perhaps reflecting an inability to regulate extracellular potassium.

Mechanisms of food selection in Daphnia

A conceptual behavioural and mechanistic Holling-type model of food selection in Daphnia pulicaria is derived from SEM observations with animals feeding on mixtures of spherical-cylindrical diatoms, oblongate green algae, and filamentous cyanobacteria, as well as ultrafine particles. The algae used were Stephanodiscus hantzschii (≤6 µm length), Monoraphidium setiforme (≥20 µm), and Oscillatoria aghardii (strands, ≥80 µm). Cell (strand) selection can occur at any or all of three stages: (i) interception from the feeding currents, (ii) collection and channeling to the food groove, and (iii) compaction and transport to the mouth. During each stage, given equal initial cell densities, elongate cells are more likely to escape collection than spherical cells and are more likely to be rejected. In addition, filaments require increased handling time at stages (ii) and (iii) and promote entanglement with limb 5 and the postabdominal claw. Food is collected primarily with the aid of limbs 3 (and 4), but limbs 1 and 2 also intervene. Neither the leaky sieve hypothesis alone nor any other single-process hypothesis explains the observations on examined in corpore positions, morphology, and derived movements of the feeding limbs. Attachment and mucus appear to be important for the ingestion of bacteria and ultrafine particles.

Overexpression of a C-Terminal Portion of the β-Amyloid Precursor Protein in Mouse Brains by Transplantation of Transformed Neuronal Cells

The role of beta-amyloid protein and its precursor protein is a central question in the pathogenesis of Alzheimers disease. We have established several transformants from a mouse embryonic carcinoma cell line, which overproduce a C-terminal region of the beta-amyloid precursor protein from the integrated DNA constructs. These stable transformants degenerated to varying extents when undergoing neural differentiation mediated by retinoic acid. To test the neurotoxicity and the amyloidogenicity of the transgene product and its proteolytic derivatives in vivo, two stable transformants were neuronally differentiated and transplanted into the hippocampal regions of syngeneic mice. Similarly, either a nontransformant or a transformant bearing a cDNA construct for yeast major apurinic endonuclease was transplanted to the contralateral regions of the same mice. Three weeks after transplantation, grafts were identified around needle tracts or in hippocampal regions. The regions where transformants overproducing the C-terminal region were grafted were highly reactive to antibodies raised against beta-amyloid protein and its precursor protein, in contrast to the contralateral regions. At 2 and 5 months after neurotransplantation, remarkable distortion and shrinkage characterized the hippocampus on the sides injected with the transformants overproducing the C-terminal region. This shrinkage was associated particularly with a loss of the hippocampal granule cells. beta-Amyloid protein immunoreactive granular deposits in the neuropil were also found in the same sides. Hippocampal blood vessel walls were also stained with the antibodies. These walls were surrounded by astrocytic processes, suggesting involvement of astroglial cells in vascular deposits of beta-amyloid protein. The results are consistent with the hypothesis that the C-terminal region or its derivatives are neurotoxic and amyloidogenic.

Thylakoid centers: Structures associated with the cyanobacterial photosynthetic membrane system

An ultrastructural study of four cyanobacteria (Anabaena cylindrica, Dermocarpa violaceae, Gleocapsa alpicola, Pleurocapsa minor) indicates the presence of previously undescribed thylakoid centers from which photosynthetic membranes (thylakoids) radiate. These peripherally located thylakoid centers are cylinders 30 nm wide by 320 nm long, consisting of globular subunits oriented in nonparallel stacked arrays. Thylakoids are attached to the outer surface of the cylinder along its longitudinal axis. Thylakoid centers appear to be functionally significant due to their structure, location and thylakoid association.

Electrophysiological actions of somatostatin (SRIF) in hippocampus: an in vitro study.

Summary1.The electrophysiological actions of somatostatin (somatotropin release inhibiting factor; SRIF) were investigated in thein vitro hippocampal slice preparation. Intracellular recordings were obtained from pyramidal neurons in area CA1 in slices of hippocampus from guinea pigs and rabbits.2.Somatostatin, applied via micropressure ejection to CA1 pyramidal-cell somata, was primarily excitatory. The effects, however, were quite variable, with nearly all cells displaying pronounced tachyphylaxis. A majority of cells was depolarized by SRIF, but hyperpolarizations or biphasic depolarization/hyperpolarization responses were also recorded. Only minimal conductance changes were associated with the SRIF-induced voltage changes.3.Depletion of SRIF, by injection of the intact animal with cysteamine several hours before preparing slices, resulted in no obvious abnormalities in hippocampal slice electrophysiology.4.Our results obtained with application of exogenous SRIF are consistent with the concept that SRIF acts as an excitatory neurotransmitter/neuromodulator in hippocampus. However, our attempts to demonstrate endogenous SRIF action have thus far been unsuccessful.