Low-dose irradiation prior to bone marrow transplantation results in ATM activation and increased lethality in Atm-deficient mice.

Ataxia telangiectasia is a genetic instability syndrome characterized by neurodegeneration, immunodeficiency, severe bronchial complications, hypersensitivity to radiotherapy and an elevated risk of malignancies. Repopulation with ATM-competent bone marrow-derived cells (BMDCs) significantly prolonged the lifespan and improved the phenotype of Atm-deficient mice. The aim of the present study was to promote BMDC engraftment after bone marrow transplantation using low-dose irradiation (IR) as a co-conditioning strategy. Atm-deficient mice were transplanted with green fluorescent protein-expressing, ATM-positive BMDCs using a clinically relevant non-myeloablative host-conditioning regimen together with TBI (0.2-2.0 Gy). IR significantly improved the engraftment of BMDCs into the bone marrow, blood, spleen and lung in a dose-dependent manner, but not into the cerebellum. However, with increasing doses, IR lethality increased even after low-dose IR. Analysis of the bronchoalveolar lavage fluid and lung histochemistry revealed a significant enhancement in the number of inflammatory cells and oxidative damage. A delay in the resolution of γ-H2AX-expression points to an insufficient double-strand break repair capacity following IR with 0.5 Gy in Atm-deficient splenocytes. Our results demonstrate that even low-dose IR results in ATM activation. In the absence of ATM, low-dose IR leads to increased inflammation, oxidative stress and lethality in the Atm-deficient mouse model.

Bone marrow transplantation improves the outcome of Atm-deficient mice through the migration of ATM-competent cells.

Ataxia telangiectasia (A-T) is a highly pleiotropic disorder. Patients suffer from progressive neurodegeneration, severe bronchial complications, immunodeficiency, hypersensitivity to radiotherapy and elevated risk of malignancies. Leukemia and lymphoma, along with lung failure, are the main causes of morbidity and mortality in A-T patients. At present, no effective therapy for A-T exists. One promising therapeutic approach is bone marrow transplantation (BMT) that is already used as a curative therapy for other genomic instability syndromes. We used an established clinically relevant non-myeloablative host-conditioning regimen and transplanted green fluorescent protein (GFP)-expressing ataxia telangiectasia mutated (ATM)-competent bone marrow-derived cells (BMDCs) into Atm-deficient mice. GFP expression allowed tracking of the potential migration of the cells into the tissues of recipient animals. Donor BMDCs migrated into the bone marrow, blood, thymus, spleen and lung tissue of Atm-deficient mice showing an ATM-competent phenotype. BMT inhibited thymic lymphomas, normalized T-lymphocyte populations, improved weight gain and rearing activity of Atm-deficient mice. In contrast, no GFP(+) cells were found in the cerebellum or cerebrum, and we detected decreased size index in MRI imaging of the cerebellum in 8-month-old transplanted Atm-deficient mice in comparison to wild-type mice. The repopulation with ATM-competent BMDCs is associated with a prolonged lifespan and significantly improved the phenotype of Atm-deficient mice.

Pathoanatomy of cerebellar degeneration in spinocerebellar ataxia type 2 (SCA2) and type 3 (SCA3).

The cerebellum is one of the well-known targets of the pathological processes underlying spinocerebellar ataxia type 2 (SCA2) and type 3 (SCA3). Despite its pivotal role for the clinical pictures of these polyglutamine ataxias, no pathoanatomical studies of serial tissue sections through the cerebellum have been performed in SCA2 and SCA3 so far. Detailed pathoanatomical data are an important prerequisite for the identification of the initial events of the underlying disease processes of SCA2 and SCA3 and the reconstruction of its spread through the brain. In the present study, we performed a pathoanatomical investigation of serial thick tissue sections through the cerebellum of clinically diagnosed and genetically confirmed SCA2 and SCA3 patients. This study demonstrates that the cerebellar Purkinje cell layer and all four deep cerebellar nuclei consistently undergo considerable neuronal loss in SCA2 and SCA3. These cerebellar findings contribute substantially to the pathogenesis of clinical symptoms (i.e., dysarthria, intention tremor, oculomotor dysfunctions) of SCA2 and SCA3 patients and may facilitate the identification of the initial pathological alterations of the pathological processes of SCA2 and SCA3 and reconstruction of its spread through the brain.

Accumulation of phosphorylated I kappaB alpha and activated IKK in nodes of Ranvier.

AIMS: Nuclear factor-kappaB (NF-kappaB) is an ubiquitously expressed transcription factor that modulates inducible gene transcription crucial for the regulation of immunity, inflammatory processes, and cell survival. In the mammalian nervous system, constitutive NF-kappaB activation is considered to promote neuronal cell survival by preventing apoptosis. Increasing evidence suggests a critical role for NF-kappaB activation in acute and chronic neurodegenerative diseases. Recently, a striking enrichment of phosphorylated I kappaB alpha (pI kappaB alpha) and activated I KappaB Kinase (IKK), two key components of the NF-kappaB activation pathway, was demonstrated in the axon initial segment (AIS) of neurons. As the AIS shares fundamental features with nodes of Ranvier (NR), we examined whether pI kappaB alpha and activated IKK are also enriched in NR. METHODS: Double-immunofluorescence labelling was performed with vibratome sections of the rodent central and peripheral nervous system. Sections were analysed using confocal laser scanning microscopy and preembedding electron microscopy. RESULTS: Here we report a remarkable accumulation of pI kappaB alpha and activated IKK in NR in the central and peripheral nervous system. Immunolabelling for both proteins extended from NR into the adjacent paranode. pI kappaB alpha predominantly accumulated within the cytoplasm and was associated with fasciculated microtubules. This association was confirmed by electron microscopy. By comparison, activated IKK preferentially clustered beneath the cytoplasmic membrane. CONCLUSION: In conclusion, the coincident accumulation of pI kappaB alpha and activated IKK in AIS and NR suggests that these specific axonal compartments contribute to neuronal NF-kappaB activation.

Extended pathoanatomical studies point to a consistent affection of the thalamus in spinocerebellar ataxia type 2.

The involvement of the thalamus during the course of the currently known polyglutamine diseases is still a matter of debate. While it is well-known that this diencephalic nuclear complex undergoes neurodegeneration in some polyglutamine diseases such as Huntington's disease (HD), it has remained unclear whether and to what extent the thalamus is also involved in spinocerebellar ataxia type 2 (SCA2) patients. Encouraged by our recent post-mortem findings in one German SCA2 patient and the results of a recent nuclear magnetic resonance (NMR) study, we extended our pathoanatomical analysis to serial thick sections stained for lipofuscin granules and Nissl substance through the thalami of four additional German and Cuban SCA2 patients. According to this analysis the thalamus is consistently affected by the destructive process of SCA2. In particular, during our study we observed a consistent involvement of the lateral geniculate body, the lateral posterior, ventral anterior, ventral lateral, ventral posterior lateral, and ventral posterior medial thalamic nuclei as well as the extraterritorial reticular nucleus. In four of the SCA2 cases studied additional damage was seen in the inferior and lateral nuclei of the pulvinar, whereas in the minority of the patients a subset of the limbic nuclei of the thalamus (i.e. anterodorsal, anteroprincipal, laterodorsal, fasciculosus, mediodorsal, central lateral, central medial, cucullar, and paracentral nuclei, medial nucleus of the pulvinar) underwent neurodegeneration. These interindividual differences in the distribution pattern of thalamic neurodegeneration indicate that the thalamic nuclei differ in their proclivities to degenerate in SCA2 and may suggest that they become involved at different phases in the evolution of the underlying degenerative process.

Damage to the reticulotegmental nucleus of the pons in spinocerebellar ataxia type 1, 2, and 3.

BACKGROUND: The reticulotegmental nucleus of the pons (RTTG) is among the precerebellar nuclei of the human brainstem. Although it represents an important component of the oculomotor circuits crucial for the accuracy of horizontal saccades and the generation of horizontal smooth pursuits, the RTTG has never been considered in CAG repeat or polyglutamine diseases. METHODS: Thick serial sections through the RTTG of 10 patients with spinocerebellar ataxias (SCAs) assigned to the CAG repeat or polyglutamine diseases (2 SCA-1 patients, 4 SCA-2 patients, and 4 SCA-3 patients) were stained for neuronal lipofuscin pigment and Nissl material. RESULTS: The unconventionally thick tissue sections revealed the hitherto overlooked involvement of the RTTG in the degenerative processes underlying SCA-1, SCA-2, and SCA-3, whereby in one of the SCA-1 patients, in two of the SCA-2 patients, and in all of the SCA-3 patients, the RTTG underwent a conspicuous loss of its nerve cells. CONCLUSIONS: Neurodegeneration may not only affect the cranial nerve nuclei (i.e., oculomotor and abducens nuclei) of SCA-1, SCA-2 and SCA-3 patients integrated into the circuits, subserving accuracy of horizontal saccades and the generation of horizontal smooth pursuits, but likewise involves the premotor networks of these circuits. This may explain why the SCA-1, SCA-2, and SCA-3 patients in this study with a heavily damaged reticulotegmental nucleus of the pons developed dysmetric horizontal saccades and impaired smooth pursuits during the course of the disease.

Degeneration of the central vestibular system in spinocerebellar ataxia type 3 (SCA3) patients and its possible clinical significance.

Although the vestibular complex represents an important component of the neural circuits crucial for the maintenance of truncal and postural stability, and it is integrated into specialized oculomotor circuits, knowledge regarding the extent of the involvement of its nuclei and associated fibre tracts in cases with spinocerebellar ataxia type 3 (SCA3) is incomplete. Accordingly, we performed a pathoanatomical analysis of the vestibular complex and its associated fibre tracts in four clinically diagnosed and genetically confirmed SCA3 patients with the aim of providing more exact information as to the involvement of the vestibular system in this disorder. By means of unconventionally thick serial sections through the vestibular nuclei stained for lipofuscin pigment and Nissl material, we could show that all five nuclei of this complex (interstitial, lateral, medial, spinal, and superior vestibular nuclei) are subject to neurodegenerative processes in SCA3, whereby examination of thick serial sections stained for myelin revealed that all associated fibre tracts (ascending tract of Deiters, juxtarestiform body, lateral and medial vestibulospinal tracts, medial longitudinal fascicle, vestibular portion of the eighth cranial nerve) underwent atrophy and demyelinization in all four of the patients studied. The reported lesions can help to explain the truncal and postural instability as well as the impaired optokinetic nystagmus, vestibulo-ocular reaction, and horizontal gaze-holding present in SCA3 cases.

Thalamic involvement in a spinocerebellar ataxia type 2 (SCA2) and a spinocerebellar ataxia type 3 (SCA3) patient, and its clinical relevance.

In spite of the considerable progress in clinical and molecular research, knowledge regarding brain damage in spinocerebellar ataxia type 2 (SCA2) and type 3 (SCA3) still is limited and the extent to which the thalamus is involved in both diseases is uncertain. Accordingly, we performed a pathoanatomical analysis on serial thick sections stained for lipofuscin granules and Nissl substance through the thalami of two genetically confirmed cases: one an SCA2 patient, the other an SCA3 patient. During this systematic study, we detected severe destruction of the reticular (RT), fasciculosus (FA), ventral anterior (VA), ventral lateral (VL), ventral posterior lateral (VPL), ventral posterior medial (VPM), cucullar (CU) and mediodorsal thalamic nuclei (MD), the lateral geniculate body (LGB) and inferior nucleus of the pulvinar (PU i) in the SCA2 case, and a severe neuronal loss in the RT, FA, VA and PU i of the SCA3 case. In the SCA2 patient, additional obvious neuronal loss was observed in all nuclei of the anterior and rostral intra laminar groups, in the lateral posterior nucleus (LP), the lateral (PU l) and the medial subnuclei of the pulvinar (PU m), whereas in the SCA3 patient only two of the nuclei that belong to the anterior thalamic group, the VL, VPL, VPM, LP, LGB, PU l and PU m, displayed marked neurodegeneration. These novel findings indicate that thalamic involvement in SCA2 and SCA3 patients has been underestimated in the past. In view of what is known about the functions of the affected thalamic nuclei, the present findings provide an appropriate pathoanatomical explanation for some of the disease-related symptoms seen in both of our and other SCA2 and SCA3 patients: gait, stance, truncal and limb ataxia, dysarthria or anarthria, falls, dysdiadochokinesia and bradykinesia, problems with writing, somatosensory deficits, saccadic dysfunctions, executive dysfunctions and abnormalities of visual evoked potentials.

Guidelines for the pathoanatomical examination of the lower brain stem in ingestive and swallowing disorders and its application to a dysphagic spinocerebellar ataxia type 3 patient.

Despite the fact that considerable progress has been made in the last 20 years regarding the three-phase process of ingestion and the lower brain stem nuclei involved in it, no comprehensive descriptions of the ingestion-related lower brain stem nuclei are available for neuropathologists confronted with ingestive malfunctions. Here, we propose guidelines for the pathoanatomical investigation of these nuclei based on current knowledge with respect to ingestion and the nuclei responsible for this process. The application of these guidelines is described by drawing upon the example of the lower brain stem of a male patient with spinocerebellar ataxia type 3, also known as Machado-Joseph disease, who displayed malfunctions during the preparatory phase of ingestion, as well as lingual and pharyngeal phases of swallowing. By way of the representative application of the recommended investigation procedure to 100 microm serial sections through the patient's brain stem stained for lipofuscin pigment and Nissl material, we observed neuronal loss together with astrogliosis in nearly all of the ingestion-related lower brain stem nuclei (motor, principal and spinal trigeminal nuclei; facial nucleus; parvocellular reticular nucleus; ambiguous nucleus, motor nucleus of the dorsal glossopharyngeal and vagal area; gelatinous, medial, parvocellular and pigmented solitary nuclei; hypoglossal nucleus). In view of their known functional role in the three-phase process of ingestion, damage to these nuclei not only offers an explanation of the patient's malfunctions related to the preparatory phase of ingestion and lingual and pharyngeal phases of swallowing, but also suggests that the patient may have suffered from additional esophageal phase swallowing malfunctions not mentioned in his medical records.

The intralaminar nuclei assigned to the medial pain system and other components of this system are early and progressively affected by the Alzheimer's disease-related cytoskeletal pathology.

The intralaminar nuclei of the human thalamus are integrated into the ascending reticular activating system and into limbic, oculomotor and somatomotor loops. In addition, some of them also represent important components of the medial pain system. We examined the occurrence and severity of the Alzheimer's disease (AD)-related cytoskeletal pathology and beta-amyloidosis in the seven intralaminar nuclei (central lateral nucleus, CL; central medial nucleus, CEM; centromedian nucleus, CM; cucullar nucleus, CU; paracentral nucleus, PC; parafascicular nucleus, PF; subparafascicular nucleus, SPF) in 27 autopsy cases at different stages of the cortical neurofibrillary pathology (cortical NFT/NT-stages I-VI) and beta-amyloidosis (cortical phases 1-4). The CEM, CL, PF, and SPF are slightly affected at stage II (corresponding to preclinical AD). They are markedly involved at stages III and IV (i.e. incipient AD) and severely affected at stages V and VI (i.e. clinical AD). In the PC and CU, the cytoskeletal pathology is mild at stage III, marked at stage IV, and severe at stages V-VI, whereas the CM is only mildly affected at stages IV-VI. In all of the intralaminar nuclei, deposits of the protein beta-amyloid occur for the first time during the final phase of cortical beta-amyloidosis. Functionally, the cytoskeletal pathology encountered in the intralaminar nuclei may contribute to the memory and affective symptoms, attention deficits, and dysfunctions related to horizontal saccades and smooth pursuits seen in AD patients. Equally important, however, are the findings that the cytoskeletal pathology developing within the intralaminar nuclei assigned to the medial pain system (CEM, CL, CU, PC, PF) as well as within other components of this system begins already during the preclinical or incipient phases of AD. Given this fact, the question arises as to whether non-discriminative aspects mediated by the medial pain system could be employed to identify individuals in the very earliest stages of AD.

Regeneration of entorhinal fibers in mouse slice cultures is age dependent and can be stimulated by NT-4, GDNF, and modulators of G-proteins and protein kinase C.

Axonal regeneration after lesions is normally not possible in the mature central nervous system, but occurs in the embryonic and neonatal nervous system. Slice cultures offer a convenient experimental system to study the decline of axonal regeneration with increasing maturation of central nervous system tissue. We have used mouse entorhinohippocampal slice cultures to assess regeneration of entorhinal fibers after mechanical lesions in vitro. We found that entorhinal axons regenerate well in cultures derived from postnatal days 5-7 mouse pups when the lesion is made at the second and fourth days in vitro (DIV 2 and DIV 4). Only little regenerative outgrowth is seen after lesions made at DIV 6 and DIV 10. This indicates that a maturation of the cultures occurs within a short time period in vitro resulting in a loss of the regenerative potential. We have used this system to screen for neurotrophic factors and pharmacological compounds that may promote axonal regeneration. Treatments were added to the cultures 1 day before the lesion was made. We found that most added factors did not promote regeneration. Only treatment with the neurotrophic factors NT-4 and GDNF stimulated regeneration in cultures where normally little regeneration is found. A similar improvement of regeneration was found after treatment with pertussis toxin, an inhibitor of G(i)-proteins, and with GF109203X, an inhibitor of protein kinase C. These substances may promote regeneration by interfering with intracellular signaling pathways activated by outgrowth inhibitors. Our findings indicate that the application of neurotrophic factors and the modulation of intracellular signal transduction pathways could be useful strategies to enhance axonal regeneration in a complex microenvironment.

Proliferating and differentiating Schwann cell cultures from embryonic chick sciatic nerve maintained for months in vitro without antimitotics or growth factors.

In general, the available methods for culturing Schwann cells require specific antibodies and/or the addition of antimitotics to suppress fibroblasts, plus various factors to support their growth. Moreover, the maximal culture period of Schwann cells normally is limited to a few weeks. Here, three easy novel methods to culture Schwann cells from embryonic chick sciatic nerve are presented, that require no growth factors or agents elevating intracellular cAMP. In contrast to the conventional antimitotic treatment with cytosine arabinoside, we use D-valine to suppress fibroblasts. Our modified medium C leads within a few days to highly enriched Schwann cell cultures (culture I). Passage into a serum-reduced medium D allows for differentiating longterm cultures (culture II). In cultures I and II, the rate of cell division is low. However, after passage into serum-containing SC-medium, proliferation increases within one week to high levels (culture III). Cultures II and III can be grown for several months, during which time spontaneous immortalization can occur. The high purity of the cultures of about 95% is assessed using glia-specific antibodies for S-100 antigen, HNK-1 epitope, glia fibrillary acidic protein (GFAP), galactocerebroside (Gal C) and 3A7. These culture procedures are easy to perform and are suitable for differentiation, proliferation and coculturing experiments.