Axonal plasticity of age-defined dentate granule cells in a rat model of mesial temporal lobe epilepsy.

Dentate granule cell (DGC) mossy fiber sprouting (MFS) in mesial temporal lobe epilepsy (mTLE) is thought to underlie the creation of aberrant circuitry which promotes the generation or spread of spontaneous seizure activity. Understanding the extent to which populations of DGCs participate in this circuitry could help determine how it develops and potentially identify therapeutic targets for regulating aberrant network activity. In this study, we investigated how DGC birthdate influences participation in MFS and other aspects of axonal plasticity using the rat pilocarpine-induced status epilepticus (SE) model of mTLE. We injected a retrovirus (RV) carrying a synaptophysin-yellow fluorescent protein (syp-YFP) fusion construct to birthdate DGCs and brightly label their axon terminals, and compared DGCs born during the neonatal period with those generated in adulthood. We found that both neonatal and adult-born DGC populations participate, to a similar extent, in SE-induced MFS within the dentate gyrus inner molecular layer (IML). SE did not alter hilar MF bouton density compared to sham-treated controls, but adult-born DGC bouton density was greater in the IML than in the hilus after SE. Interestingly, we also observed MF axonal reorganization in area CA2 in epileptic rats, and these changes arose from DGCs generated both neonatally and in adulthood. These data indicate that both neonatal and adult-generated DGCs contribute to axonal reorganization in the rat pilocarpine mTLE model, and indicate a more complex relationship between DGC age and participation in seizure-related plasticity than was previously thought.

Intrinsic neurophysiological properties of hilar ectopic and normotopic dentate granule cells in human temporal lobe epilepsy and a rat model.

Hilar ectopic dentate granule cells (DGCs) are a salient feature of aberrant plasticity in human temporal lobe epilepsy (TLE) and most rodent models of the disease. Recent evidence from rodent TLE models suggests that hilar ectopic DGCs contribute to hyperexcitability within the epileptic hippocampal network. Here we investigate the intrinsic excitability of DGCs from humans with TLE and the rat pilocarpine TLE model with the objective of comparing the neurophysiology of hilar ectopic DGCs to their normotopic counterparts in the granule cell layer (GCL). We recorded from 36 GCL and 7 hilar DGCs from human TLE tissue. Compared with GCL DGCs, hilar DGCs in patient tissue exhibited lower action potential (AP) firing rates, more depolarized AP threshold, and differed in single AP waveform, consistent with an overall decrease in excitability. To evaluate the intrinsic neurophysiology of hilar ectopic DGCs, we made recordings from retrovirus-birthdated, adult-born DGCs 2-4 mo after pilocarpine-induced status epilepticus or sham treatment in rats. Hilar DGCs from epileptic rats exhibited higher AP firing rates than normotopic DGCs from epileptic or control animals. They also displayed more depolarized resting membrane potential and wider AP waveforms, indicating an overall increase in excitability. The contrasting findings between disease and disease model may reflect differences between the late-stage disease tissue available from human surgical specimens and the earlier disease stage examined in the rat TLE model. These data represent the first neurophysiological characterization of ectopic DGCs from human hippocampus and prospectively birthdated ectopic DGCs in a rodent TLE model.

Derivation of mesenchymal stem cells from human induced pluripotent stem cells cultured on synthetic substrates.

Human-induced pluripotent stem cells (hiPSCs) may represent an ideal cell source for research and applications in regenerative medicine. However, standard culture conditions that depend on the use of undefined substrates and xenogeneic medium components represent a significant obstacle to clinical translation. Recently, we reported a defined culture system for human embryonic stem cells using a synthetic polymer coating, poly[2-(methacryloyloxy)ethyl dimethyl-(3-sulfopropyl)ammonium hydroxide] (PMEDSAH), in conjunction with xenogeneic-free culture medium. Here, we tested the hypothesis that iPSCs could be maintained in an undifferentiated state in this xeno-free culture system and subsequently be differentiated into mesenchymal stem cells (iPS-MSCs). hiPSCs were cultured on PMEDSAH and differentiated into functional MSCs, as confirmed by expression of characteristic MSC markers (CD166+, CD105+, CD90+,CD73+, CD31-, CD34-, and CD45-) and their ability to differentiate in vitro into adipogenic, chondrogenic, and osteoblastic lineages. To demonstrate the potential of iPS-MSCs to regenerate bone in vivo, the newly derived cells were induced to osteoblast differentiation for 4 days and transplanted into calvaria defects in immunocompromised mice for 8 weeks. MicroCT and histologic analyses demonstrated de novo bone formation in the calvaria defects for animals treated with iPS-MSCs but not for the control group. Moreover, positive staining for human nuclear antigen and human mitochondria monoclonal antibodies confirmed the participation of the transplanted hiPS-MSCs in the regenerated bone. These results demonstrate that hiPSCs cultured in a xeno-free system have the capability to differentiate into functional MSCs with the ability to form bone in vivo.

Analysis of antibody gene rearrangement, usage, and specificity in chronic focal encephalitis.

BACKGROUND: Autoantibodies have been implicated in the development of chronic focal encephalitis (CFE) or Rasmussen's disease, a progressive and intractable form of epilepsy characterized by uncontrollable unilateral focal seizures, brain atrophy, and inflammation. OBJECTIVE: To investigate the origin and characteristics of the B cell population that trigger or sustain brain inflammation in patients with CFE. METHODS: The authors used immunoglobulin (Ig) complementary determining region 3 (CDR3)-size spectratyping and DNA sequencing to examine the rearranged IgG heavy chain (IgGH) transcript repertoire in resected brain samples from four patients with CFE. They also performed Western blotting on human and rat brain homogenates and immunostaining on a human neuronal cell line to test the reactivity of sera from patients with CFE. RESULTS: The authors observed substantial perturbations from the normal, unstimulated repertoire of immunoglobulin genes. Sequencing of randomly selected clones confirmed the restricted profile and provided evidence for somatic mutation patterns characteristic of antigen-specific stimulation. They also observed IgGVH-CDR3 sequence diversity among patients. When sera were assayed from patients with CFE for specificity against rat and human brain homogenates, heterogeneous reactivity patterns were detected among patients. Immunostaining of postmitotic human neuronal cells demonstrated reactivity of some patients' sera against neural antigens. CONCLUSIONS: These findings support an important role for clonally expanded B lymphocytes in some forms of epilepsy, but also indicate a wide spectrum of reactivity characteristic of antigenic heterogeneity.

Differential regulation of basic helix-loop-helix mRNAs in the dentate gyrus following status epilepticus.

In various chemoconvulsant models of human temporal lobe epilepsy, the induction of epileptogenesis by a prolonged period of continuous seizure activity is accompanied by significant changes in hippocampal structure. These changes include an increase in neurogenesis within the proliferative subgranular zone (SGZ) of the dentate gyrus and induction of mossy fiber sprouting in mature dentate granule cells. As dentate granule cell neurogenesis and axon outgrowth are also hallmarks of hippocampal development, we hypothesized that molecules involved in normal development may also play a role in similar changes associated with epileptogenesis. To begin to test this hypothesis, we have analyzed the expression patterns of multiple members of the basic helix-loop-helix (bHLH) family of transcription factors in both normal and epileptic adult rats. bHLH protein expression has been found recently in dentate granule cells at specific developmental stages, and analysis of developmental models suggests specific neural differentiation functions for these molecules. We show that mRNA expression of all seven bHLH family members examined in this study, as well as the divergent homeobox protein Prox1, is present in the adult. Patterns of expression varied considerably between family members, ranging from the limited expression of Mash1 in the neurogenic SGZ of the dentate gyrus to the scattered, widespread profile of Hes5 throughout the dentate gyrus and the hippocampus proper. Moreover, these varied profiles of expression were differentially regulated following status epilepticus, with some increasing (Mash1, Id2), some falling (Hes5, Prox1), and others remaining mostly unchanged (NeuroD/BETA2, NeuroD2/NDRF, Id3, Rath2/Nex1). While the function of these molecules in the adult brain remains to be characterized, our findings support the idea that molecules controlling cell-fate decisions in the developing dentate gyrus are also operative during seizure-induced neurogenesis and plasticity.

X-irradiation causes a prolonged reduction in cell proliferation in the dentate gyrus of adult rats.

The effects of X-irradiation on proliferating cells in the dentate subgranular zone were assessed in young adult Fisher 344 rats exposed to a range of X-ray doses and followed for up to 120 days. Apoptosis was quantified using morphology and end-labeling immunohistochemistry, and cell proliferation was detected using antibodies against the thymidine analog BrdU and the cyclin-dependent kinase p34(cdc2). Radiation-induced apoptosis occurred rapidly, with maximum morphological and end-labeling changes observed 3-6h after irradiation. Twenty-four hours after irradiation cell proliferation was significantly reduced relative to sham-irradiated controls. The number of apoptotic nuclei increased rapidly with radiation dose, reaching a plateau at about 3Gy. The maximum number of apoptotic nuclei was substantially higher than the number of proliferating cells, suggesting that non-proliferating as well as proliferating cells in the subgranular zone were sensitive to irradiation. Subgranular zone cell proliferation was significantly reduced relative to age-matched controls 120 days after doses of 5Gy or higher. These findings suggest that neural precursor cells of the dentate gyrus are very sensitive to irradiation and are not capable of repopulating the subgranular zone at least up to 120 days after irradiation. This may help explain, in part, how ionizing irradiation induces cognitive impairments in animals and humans.

Effect of clomipramine on monoamine metabolites in the cerebrospinal fluid of behaviorally normal dogs.

The tricyclic antidepressant, clomipramine, is an effective treatment for canine compulsive disorder (canine CD). This disorder is a clinical syndrome of abnormal conflict behaviors and its pathophysiology is unknown. However, because clomipramine is an effective treatment, information about the drug's neurochemical effect could enhance the understanding of canine CD. The following experiment used 6 behaviorally normal dogs to assess the effect of clomipramine (3 mg/kg, q24h, PO) on the central turnover of 3 monoamines (serotonin, dopamine, and norepinephrine) as measured by the concentrations of their respective metabolites in cerebrospinal fluid (CSF). In a randomized, placebo-controlled, AB-BA crossover experiment, cisternal CSF was taken after 1, 2, 4, and 6 wk on each treatment. No effect of clomipramine was detected. This contrasts with human studies that have suggested that clomipramine affects the concentrations of monoamine metabolites in lumbar CSF. However, those papers do not address methodological assumptions, such as (i) metabolites in CSF originate only from the brain, and (ii) concentrations of metabolites in cisternal/lumbar CSF reflect the concentrations in local areas of the brain. Notwithstanding the small sample size, our results suggest that more localized sampling techniques (e.g. microdialysis) are needed when examining the effect of drugs on central monoamine metabolites. Clomipramine's efficacy for canine CD indicates the need for neurobiological research and, to our knowledge, our study is the first of its kind in dogs. The resulting data are preliminary but they can inform optimal neurobiological studies of canine CD.

Clinical findings, treatment, and outcome of dogs with status epilepticus or cluster seizures: 156 cases (1990-1995).

OBJECTIVE: To report clinical findings, treatments, and outcomes of dogs admitted to the hospital for status epilepticus or cluster seizures and evaluate factors associated with outcome. DESIGN: Retrospective study. ANIMALS: 156 dogs admitted for status epilepticus or cluster seizures. PROCEDURE: Medical records were reviewed for seizure and medication history, diagnostic test results, types of treatment, hospitalization costs, and outcome of hospital visits. RESULTS: Dogs were admitted for seizures on 194 occasions. Of 194 admissions, 128 (66%), 2 (1%), 32 (16.5%), 2 (1%), and 30 (15.5%) were of dogs with a history of clusters of generalized seizures, clusters of partial complex seizures, convulsive status epilepticus, partial status epilepticus, and > 1 type of seizure, respectively. Underlying causes of seizures were primary epilepsy (26.8%; 52/194), secondary epilepsy (35.1%; 68), reactive epileptic seizures (6.7%; 13), primary or secondary epilepsy with low serum antiepileptic drug concentrations (5.7%; 11), and undetermined (25.8%; 50). One hundred and eighty-six hospital visits resulted in admission to the intensive care unit (ICU). Treatments with continuous i.v. infusions of diazepam or phenobarbital were initiated during 66.8% (124/186) and 18.7% (35) of ICU hospital stays for 22.3 +/- 16.1 hours (mean +/- SD) and 21.9 +/- 15.4 hours, respectively. Of 194 admissions, 74.7% (145) resulted in discharge from the hospital, 2.1% (4) in death, and 23.2% (45) in euthanasia. A poor outcome (death or euthanasia) was significantly associated with granulomatous meningoencephalitis, loss of seizure control after 6 hours of hospitalization, and the development of partial status epilepticus. CONCLUSIONS AND CLINICAL RELEVANCE: Granulomatous meningoencephalitis, loss of seizure control after 6 hours of hospitalization, or the development of partial status epilepticus may indicate a poor prognosis for dogs with seizures.

Inhibition of dentate granule cell neurogenesis with brain irradiation does not prevent seizure-induced mossy fiber synaptic reorganization in the rat.

Aberrant reorganization of dentate granule cell axons, the mossy fibers, occurs in human temporal lobe epilepsy and rodent epilepsy models. Whether this plasticity results from the remodeling of preexisting mossy fibers or instead reflects an abnormality of developing dentate granule cells is unknown. Because these neurons continue to be generated in the adult rodent and their production increases after seizures, mossy fibers that arise from either developing or mature granule cells are potential substrates for this network plasticity. Therefore, to determine whether seizure-induced, mossy fiber synaptic reorganization arises from either developing or mature granule cell populations, we used low-dose, whole-brain x-irradiation to eliminate proliferating dentate granule cell progenitors in adult rats. A single dose of 5 Gy irradiation blocked cell proliferation and eliminated putative progenitor cells in the dentate subgranular proliferative zone. Irradiation 1 d before pilocarpine-induced status epilepticus significantly attenuated dentate granule cell neurogenesis after seizures. Two irradiations, 1 d before and 4 d after status epilepticus, essentially abolished dentate granule cell neurogenesis but failed to prevent mossy fiber reorganization in the dentate molecular layer. These results indicate that dentate granule cell neurogenesis in the mature hippocampal formation is vulnerable to the effects of low-dose ionizing irradiation. Furthermore, the development of aberrant mossy fiber remodeling in the absence of neurogenesis suggests that mature dentate granule cells contribute substantially to seizure-induced network reorganization.

Efficacy of clomipramine in the treatment of canine compulsive disorder.

OBJECTIVE: To assess the efficacy of clomipramine for treatment of canine compulsive disorder (CCD). DESIGN: Randomized, placebo-controlled, double-blind, balanced AB-BA crossover clinical study. ANIMALS: 51 dogs with CCD. PROCEDURES: Dogs were given clomipramine (3 mg/kg [1.3 mg/lb] of body weight, PO, q 12 h) for 4 weeks and placebo for 4 weeks. At the end of each treatment each owner rated the severity of their dog's behavior, using 2 validated rating scales. Statistical analysis was made by ordinal regression. Compliance, adverse effects, and the effectiveness of masking were also assessed. Each dog's behavior was reevaluated 1 to 2 years after completing the study. RESULTS: Behaviors included spinning (n = 17) and self-mutilation by licking (acral lick dermatitis, 12). Both rating scales demonstrated a treatment effect. Compliance was satisfactory, and masking was effective. Sedation and reduced appetite were reported more commonly when dogs were given clomipramine than when they were given placebo. Forty-five dogs available for follow-up evaluation still had their behaviors; 6 dogs were lost to follow-up evaluation. CLINICAL IMPLICATIONS: Results suggest that clomipramine was effective in dogs with CCD and was not associated with serious adverse effects. However, treatment for 4 weeks was not curative. Behavior modification is likely to be necessary to manage CCD.

Increased dentate granule cell neurogenesis following amygdala kindling in the adult rat.

Structural neuronal network plasticity is associated with epileptogenesis during limbic kindling, but the full extent of network changes is not well understood. We investigated whether dentate granule cell (DGC) neurogenesis, which continues into adulthood in the rodent, is altered in the amygdala kindling model of epileptogenesis. Adult rats were stimulated to either 4-6, 9-10 or 19-20 class 4/5 (generalized) kindled seizures. 5-Bromo-2'-deoxyuridine labeling showed that cell proliferation increased in the dentate gyrus only in animals that experienced nine or more class 4/5 kindled seizures. Immunocytochemistry for neuronal markers revealed that many of the newly generated cells differentiated into DGCs in the inner aspect of the DGC layer. The lack of increased DGC neurogenesis after fewer kindled seizures or at early timepoints following kindling suggests that this process is not involved in kindling development. Instead, newly generated DGCs may be important for maintenance of the kindled state or the increased susceptibility to spontaneous recurrent seizures.

Dentate granule cell neurogenesis is increased by seizures and contributes to aberrant network reorganization in the adult rat hippocampus.

The dentate granule cell layer of the rodent hippocampal formation has the distinctive property of ongoing neurogenesis that continues throughout adult life. In both human temporal lobe epilepsy and rodent models of limbic epilepsy, this same neuronal population undergoes extensive remodeling, including reorganization of mossy fibers, dispersion of the granule cell layer, and the appearance of granule cells in ectopic locations within the dentate gyrus. The mechanistic basis of these abnormalities, as well as their potential relationship to dentate granule cell neurogenesis, is unknown. We used a systemic chemoconvulsant model of temporal lobe epilepsy and bromodeoxyuridine (BrdU) labeling to investigate the effects of prolonged seizures on dentate granule cell neurogenesis in adult rats, and to examine the contribution of newly differentiated dentate granule cells to the network changes seen in this model. Pilocarpine-induced status epilepticus caused a dramatic and prolonged increase in cell proliferation in the dentate subgranular proliferative zone (SGZ), an area known to contain neuronal precursor cells. Colocalization of BrdU-immunolabeled cells with the neuron-specific markers turned on after division, 64 kDa, class III beta-tubulin, or microtubule-associated protein-2 showed that the vast majority of these mitotically active cells differentiated into neurons in the granule cell layer. Newly generated dentate granule cells also appeared in ectopic locations in the hilus and inner molecular layer of the dentate gyrus. Furthermore, developing granule cells projected axons aberrantly to both the CA3 pyramidal cell region and the dentate inner molecular layer. Induction of hippocampal seizure activity by perforant path stimulation resulted in an increase in SGZ mitotic activity similar to that seen with pilocarpine administration. These observations indicate that prolonged seizure discharges stimulate dentate granule cell neurogenesis, and that hippocampal network plasticity associated with epileptogenesis may arise from aberrant connections formed by newly born dentate granule cells.

Mossy fiber reorganization in the epileptic hippocampus.

Reorganization of dentate granule cell axons (mossy fibers) is a prominent aspect of the pathological changes observed in human temporal lobe epilepsy. Although recent work has begun to address the significance of mossy fiber reorganization, the specific and overall functional consequences of these network changes remain poorly understood. New studies are beginning to provide insight into molecular mechanisms underlying this process. Advances in our understanding of the causes and effects of mossy fiber reorganization are likely to provide insight into the pathophysiology of temporal lobe epilepsy, as well as the larger issue of network remodeling following nervous system injury.

Diagnostic evaluation of cats with seizure disorders: 30 cases (1991-1993).

OBJECTIVE: To investigate causes of seizure disorders in cats. DESIGN: Case series. ANIMALS: 30 cats referred to the Ontario Veterinary College for recurrent seizures. PROCEDURES: Signalment and seizure pattern were evaluated. Diagnostic procedures included physical, neurologic, and fundic examinations; CBC; serum biochemical analyses, including determination of pre- and postprandial bile acid concentrations; urinalysis; serologic assays for FeLV and feline immunodeficiency virus, feline infectious peritonitis, and Toxoplasma gondii, magnetic resonance imaging of the brain; CSF analysis; and neuropathologic examination of euthanatized cats and of surgical biopsy specimens. RESULTS: All cats were found to have structural brain diseases; nonsuppurative meningoencephalitis of unknown cause was found in 14 cats, feline ischemic encephalopathy in 6, meningioma in 2, polycythemia vera with secondary brain lesions in 2, posttraumatic epilepsy in 1, and cerebral abscess in 1. A definitive diagnosis could not be reached in 4 cats. CLINICAL IMPLICATIONS: The most common cause of seizures in cats is structural brain disease. Structural brain lesions often can be detected on the basis of seizure pattern and results of neurologic examination. Cerebrospinal fluid analysis and brain imaging are essential to determine the cause of these lesions. Causes of seizures found in the cats of this study differ from those reported to be the most common. Nonsuppurative meningoencephalitis of unknown origin appears to be a frequent cause of neurologic disorders in cats, including seizure disorders. Feline ischemic encephalopathy appears to exist in a milder form than the classic disease and may be a common cause of seizures in cats.

Clinical management and outcome of cats with seizure disorders: 30 cases (1991-1993).

OBJECTIVE: To determine outcome of clinical management of cats with seizure disorders. DESIGN: Case series. ANIMALS: 30 cats referred to the Ontario Veterinary College for recurrent seizures. PROCEDURES: Treatment was dictated by the cat's seizure frequency and by the underlying cause. Cats that were having cluster seizures or status epilepticus at the time of admission were treated orally with phenobarbital and with constant IV administration of diazepam. The other cats were treated with long-term oral administration of phenobarbital if the frequency of their seizures justified it. Follow-up included evaluation of seizure frequency, serum antiepileptic drug concentrations, and hematologic and serum biochemical values. Outcome was documented on the basis of survival and seizure frequency at the end of the followup period, which ranged from 3 to 21 months. RESULTS: 6 cats were euthanatized without any therapeutic attempts at the owners' request. Twenty of the remaining 24 cats were alive at the time of final follow-up. Seventeen had a good outcome; 11 were not having any more seizures and 6 were having a low frequency of seizures. For 3 other cats, seizures were not well controlled. Four cats had been euthanatized (2 because of intractable seizures, 1 because of postcraniotomy complications, and 1 because the owners did not want to pursue treatment). CLINICAL IMPLICATIONS: Results suggest that severity of seizure disorder in cats is not a good predictor of outcome and that aggressive treatment is often rewarding, even in the most severe cases.

Intervertebral disk disease in dogs with signs of back pain alone: 25 cases (1986-1993).

OBJECTIVE: To evaluate the population characteristics, historical, clinical, and diagnostic findings; and treatment outcome of dogs with thoracolumbar intervertebral disk disease (IVDD) whose only clinical signs were those of back pain. DESIGN: Retrospective case series. ANIMALS: Dogs with IVDD and clinical signs of back pain only, without neurologic deficits, in which survey radiography of the vertebral column and diagnostic myelographic studies were performed. PROCEDURE: Review of the medical record, evaluation of survey radiographs of the vertebral column, evaluation of myelograms and estimation of apparent extent of spinal cord compression, and follow-up information provided by telephone contact with owners. RESULTS: Spinal cord compression was detected on myelography in 20 of 25 (80%) dogs. Treatment included decompressive surgery in 18 of 25 (72%) dogs and all dogs underwent intervertebral disk fenestration. The condition was improved in 24 of 25 (96%) dogs after surgery. CLINICAL IMPLICATIONS: Dogs with thoracolumbar IVDD that have clinical signs of back pain alone, without neurologic deficits, may have substantial compression of the spinal cord.

Seizures in cats.

Seizures in cats are caused by active structural disease or secondary epilepsy. The most common structural causes are inflammatory diseases, many of which are probably viral (non-FIP) in origin. Toxoplasmosis, FIP, FeLV, and FIV are rare causes of recurrent seizures in cats. The incidence of primary epilepsy is unknown; it is unlikely to occur in domestic cats. The pattern (type and frequency) of the seizures and the age at onset of the seizures are important factors in establishing a differential diagnosis. More than 50% of cats with seizures experience nonconvulsive (mild generalized or partial complex) seizures. Though many cats experience severe cluster seizures and status epilepticus, severity of seizures is not a good predictor of outcome. Many cats stop having seizures or are controlled well with AEDs regardless of the severity of their seizure activity.

Extramedullary hematopoiesis in the choroid plexus of five dogs.

Five dogs euthanatized because of refractory seizures were found to have hematopoietic elements in the interstitium of the choroid plexus at the level of the fourth ventricle. None of the dogs had significant hematologic or cerebrospinal fluid abnormalities. The extramedullary hematopoiesis was confined to the central nervous system and consisted of megakaryocytes, immature granulocytes, and rubricytes in two dogs and of one predominant cell population in each of the other three dogs. These findings are unique, and factors possibly contributing to the formation of a hematopoietic inductive microenvironment in the choroid plexus are cytokine-neurokine homologies, locally altered vascular supply, and aberrant functioning of bone marrow-derived central nervous system macrophages.