Antonio Migheli

Abundant Tau Filaments and Nonapoptotic Neurodegeneration in Transgenic Mice Expressing Human P301S Tau Protein

The identification of mutations in the Tau gene in frontotemporal dementia and parkinsonism linked to chromosome 17 (FTDP-17) has made it possible to express human tau protein with pathogenic mutations in transgenic animals. Here we report on the production and characterization of a line of mice transgenic for the 383 aa isoform of human tau with the P301S mutation. At 5–6 months of age, homozygous animals from this line developed a neurological phenotype dominated by a severe paraparesis. According to light microscopy, many nerve cells in brain and spinal cord were strongly immunoreactive for hyperphosphorylated tau. According to electron microscopy, abundant filaments made of hyperphosphorylated tau protein were present. The majority of filaments resembled the half-twisted ribbons described previously in cases of FTDP-17, with a minority of filaments resembling the paired helical filaments of Alzheimers disease. Sarkosyl-insoluble tau from brains and spinal cords of transgenic mice ran as a hyperphosphorylated 64 kDa band, the same apparent molecular mass as that of the 383 aa tau isoform in the human tauopathies. Perchloric acid-soluble tau was also phosphorylated at many sites, with the notable exception of serine 214. In the spinal cord, neurodegeneration was present, as indicated by a 49% reduction in the number of motor neurons. No evidence for apoptosis was obtained, despite the extensive colocalization of hyperphosphorylated tau protein with activated MAP kinase family members. The latter may be involved in the hyperphosphorylation of tau.

Glial fibrillary acidic protein and vimentin in the experimental glial reaction of the rat brain

Glial reaction has been studied in the rat by the immunohistochemical demonstration of glial fibrillary acidic protein (GFAP) and vimentin (VIM) in two experimental conditions. The first was represented by a necrotic cerebral lesion obtained by laser irradiation and the second by the development of experimental tumors induced by transplacental ethylnitrosourea. Reactive astrocytes develop not only in the proximity of the lesion but also distant from it. The intensity of the glial response seems to depend upon the normal distribution of astrocytes and the perilesional edema. GFAP decorates all the reactive astrocytes, whereas VIM is positive only in those at the edges of the lesion. The significance of the different responses in the two models and between the two intermediate filaments is discussed.

Defective Neurogenesis in Citron Kinase Knockout Mice by Altered Cytokinesis and Massive Apoptosis

Citron-kinase (Citron-K) has been proposed by in vitro studies as a crucial effector of Rho in regulation of cytokinesis. To further investigate in vivo its biologic functions, we have inactivated Citron-K gene in mice by homologous recombination. Citron-K-/- mice grow at slower rates, are severely ataxic, and die before adulthood as a consequence of fatal seizures. Their brains display defective neurogenesis, with depletion of specific neuronal populations. These abnormalities arise during development of the central nervous system due to altered cytokinesis and massive apoptosis. Our results indicate that Citron-K is essential for cytokinesis in vivo but only in specific neuronal precursors. Moreover, they suggest a novel molecular mechanism for a subset of human malformative syndromes of the CNS.

A Study of Apoptosis in Normal and Pathologic Nervous Tissue After In situ End-Labeling of DNA Strand Breaks

Abstract. Programmed cell death (PCD) via apoptosis is characterized by nuclear pyknosis and fragmentation, and biochemically by oligonucleosomal cleavage of DNA. Apoptosis occurs in the developing nervous system, whereas its role in neurodegenerative diseases is still debated. Recognition of apoptotic cells has recently been facilitated by in situ end-labeling (ISEL) techniques which identify DNA strand breaks through incorporation of labeled nucleotides. We have applied two ISEL assays to physiological and pathological conditions affecting the nervous system in which PCD is likely to occur. Terminal transferase assay was more sensitive than DNA polymerase assay and allowed the recognition of a larger number of cells than conventional histology. Apoptotic cells were readily found in the developing spinal cord and dorsal root ganglia. Medulloblastomas, gliomas, brain lymphomas and metastases showed abundant apoptotic cells either isolated or grouped in small foci. Labeling was also found in cells without a clearcut apoptotic morphology. Apoptotic cells were not found in Alzheimers disease, amyotrophic lateral sclerosis and human and mouse prionic encephalopathies. Our results show that ISEL is a useful technique for demonstrating apoptotic cells in nervous tissue during development and in brain tumors. Lack of staining in neurodegenerative diseases suggests that other types of PCD might be involved.

Reactive astrogliosis of the spinal cord in amyotrophic lateral sclerosis

Many observations have been carried out on astrogliosis in the cerebral cortex in amyotrophic lateral sclerosis (ALS), whereas little attention has been paid to astrogliosis in the spinal cord. Twenty autopsy cases of sporadic, common form of ALS have been studied. Spinal cords have been examined at the cervical, thoracic and lumbar levels by histological methods and immunohistochemistry for GFAP, Vimentin, Tau-protein, Neurofilaments, PCNA. A gliosis was found in the ventral horns, in dorsal horns and at the transition between gray matter and anterior and lateral funiculi, especially close to laminae VII, VI and V as being due to secondary gliosis. The findings cannot be interpreted on the only basis of the substitutive role of reacting glia. The proposed pathogenetic mechanisms of ALS are evaluated as possible responsible stimuli; the coincidence of the distribution of reactive astrocytes with the entering points of the corticospinal tracts into the gray matter is considered of primary importance. Of special interest are reactive astrocytes at the transition between laminae VII, VI and V and the lateral funiculus, where dystrophic neurites are known to concentrate.

c-Jun, JNK/SAPK kinases and transcription factor NF-kappa B are selectively activated in astrocytes, but not motor neurons, in amyotrophic lateral sclerosis.

There is increasing evidence that oxidative damage plays a major role in amyotrophic lateral sclerosis (ALS), but how it contributes to motor neuron degeneration and astrocytic gliosis, two pathologic hallmarks of the disease, is unknown. A few studies have suggested that ALS motor neurons die via apoptosis and show upregulation of c-jun, an immediate early gene that is necessary for neuronal apoptosis. In order to elucidate the mechanisms of cell damage induced by oxidant stress, we have studied in ALS and control spinal cord the immunohistochemical expression of c-Jun, of JNK/SAPK, a kinase that activates c-Jun following various types of stress, and of NF-κB, a transcription factor that is induced by oxidant stress and has prominent neuroprotective functions. An in situ end-labeling assay was performed for detecting apoptotic cells. We show that (a) the JNK/SAPK-c-Jun pathway is dramatically overexpressed in ALS spinal cord; (b) the strongest activation occurs in astrocytes, while motor neurons show unusually low expression of the pathway; (c) increased JNK/SAPK expression in glial cells is accompanied by NF-κB activation, indicating the presence of a protective response to oxidant stress, which is deficient in motor neurons; (d) activation of JNK/SAPK, c-Jun and NF-κB is unrelated to apoptotic cell death. These results support the view that astrocytes are directly involved in the pathologic process of ALS, and might explain the selective vulnerability of motor neurons by their relative lack of antioxidant defenses.

Histologic prognostic factors in ependymoma

The prognostic value of a series of histologic signs and clinical features was studied in a series of 298 ependymomas, collected from different institutions. The distribution of tumor sites varied in relation to patient age, with infratentorial cases prevailing under 4 years. Life table univariate analysis demonstrated as highly significant prognostic factors: (1) the number of mitoses; (2) endothelial hyperplasia; (3) necrosis; (4) intracranial site; (5) age <4 years. Multivariate analysis by tumor site revealed mitoses cell density, age >16 years in supratentorial cases, and subependymoma in infratentorial cases to be prognostically important. Comparison of the anaplastic variant with the other tumor types in intracranial cases did not show a significant difference in survival even though the median survival time of anaplastic cases was shorter. The main conclusion is that the histological criteria employed to diagnose anaplasia in gliomas are not useful for recognizing anaplasia in ependymomas. The number of mitoses is a very important prognostic factor in supratentorial cases, whereas endothelial proliferations and necroses are much less important as prognostic factors than in gliomas.

LACK OF APOPTOSIS IN MICE WITH ALS

be detected by this method. However, sublimon-type templates give equally prominent products. Our findings imply that the background of sublimon-derived products generated from control templates makes LX-PCR unreliable as a sole diagnostic method for detecting deleted mtDNAs, except in the case of deletions representing a substantial fraction of mtDNA molecules in a given DNA preparation. We would thus recommend routine serial dilution of all DNA samples to test for the meaningful presence of deleted mtDNA molecules when using LX-PCR, and ideally the verification of all positive findings by Southern blot analysis, before a diagnostic conclusion is reached. Published claims, based exclusively on LX-PCR analysis, that deleted mtDNAs accumulate to high levels in aging and in many disease states , need to be critically re-evaluated in the light of our findings. Acknowledgments We thank M. Niittylahti and O.Lumme for technical assistance, and P. Rustin, I. Holt, S. Khogali and N.-G. Larsson for discussions. This work was supported by grants from the Finnish Academy, Muscular Dystrophy Group, Royal Society, Tampere University Hospital Medical Research Fund, Yrjö Jahnsson Foundation, Finnish Foundation of Alcohol Research and the Pirkanmaa Region Fund of the Finnish Cultural Foundation.

Apoptosis and cell proliferation in human neuroepithelial tumors

Apoptosis and cell proliferation were studied in 180 human neuroepithelial tumors (30 medulloblastomas, 30 intracranial ependymomas, 30 oligodendrogliomas and 90 astrocytic tumors, including 30 astrocytomas, 30 anaplastic astrocytomas and 30 glioblastomas). Apoptotic nuclei were detected by morphology and in situ end-labeling (ISEL) of DNA breaks. The frequency of apoptotic nuclei varied from oncotype to oncotype and their distribution in each oncotype was uneven. An apoptotic index (AI) was calculated; this was high in malignant tumors and in tumors of embryonal origin and lower in tumors of the glial series. The AI/mitotic index (MI) ratio was lower in malignant tumors and higher in benign tumors, suggesting a relationship between apoptosis and cell proliferation. There was no significant correlation of either AI or AI/MI ratio with either labeling index (LI) of Ki-67 clone MIB-1 or with survival. A trends towards low AI/MI ratio in tumors with high LI and short survival was observed. Apoptosis expresses cell loss in tumors, but it did not appear to be a prognostic factor.

Reactive cell proliferation and microglia following injury to the rat brain

The non–astrocytic cells which proliferate in the rat brain after the induction of an area of necrosis have been characterized and counted by means of combined in vivo bromodeoxyuridine (BrdU) administration and immuno–histochemical demonstration of glial fibrillary acid protein (GFAP), vimentin, Ricinus communis agglutinin 120 (RCA–1), Griffonia simplicifolia B4 isolectin (GSI–B4), keratan sulphate (KS), carbonic anhydrase C (CA.C), transferrin (TF) and ferritin. Two days after the injury, 7.5% of the proliferating cells were GFAP–positive reactive astrocytes, 5.7% were RCA–1–positive cells and 17.4% were GSI–B4–positive cells. Lectin–binding cells had the microscopic and ultrastructural aspects of microglia; they proliferated around the needle track and in the corpus callosum. Microglia represented a large fraction of the proliferating cells. Evidence is presented for the origin of at least a proportion of perilesional astrocytes and microglia from the periventricular matrix, and of microglia from blood precursors. Other non–proliferating microglia cells transiently appeared in the normal brain around the wound, in agreement with the existence of two different microglia cell populations reacting with different modalities to an area of necrosis.