Amyotrophic Lateral Sclerosis: mechanism behind mutant SOD toxicity and improving current therapeutic strategies

Dennys, Cassandra

01 January 2014

Amyotrophic Lateral Sclerosis (ALS) is an always lethal motor neuron disease with unknown pathogenesis. Inhibitors of the molecular chaperone heat shock protein 90 (Hsp90) have limited neuroprotection in some models of motor neuron degeneration. However the direct effect of Hsp90 inhibition on motor neurons is unknown. Here we show that Hsp90 inhibition induced motor neuron death through activation of the P2X7 receptor. Motor neuron death required phosphatase and tensein homolog (PTEN)-mediated inhibition of the PI3K/AKT pathway leading to Fas receptor activation and caspase dependent death. The relevance of Hsp90 for motor neuron survival was investigated in mutant Cu/Zn superoxide dismutase (SOD) transgenic animal models for ALS. Nitrated Hsp90, a posttranslational modification known to induce cell death (Franco, Ye et al. 2013), was present in motor neurons after intracellular release of zinc deficient (Zn, D83S) and the SOD in which copper binding site was genetically ablated (Q) but not after copper deficient (Cu) wild type SOD. Zn deficient and Q mutant SOD induced motor neuron death in a peroxynitrite mediated and copper dependent mechanism. Nitrated Hsp90 was not detected in the spinal cord of transgenic animals for ALS-mutant SOD animal models until disease onset. Increased nitrated Hsp90 concentrations correlated with disease progression. Addition of Zn or Q SOD to nontransgenic brain homogenate treated with peroxynitrite led to an increase level of nitrotyrosine in comparison to wild type controls. However, in the same samples there was a 2 to 10 time increase in Hsp90 nitration as compared to nitrotyrosine. The selective increase is likely due to the binding of Hsp90 to Zn deficient and Q SOD as oppose to wild type SOD. These results suggest that Hsp90 nitration facilitated by mutant SOD may cause motor neuron degeneration in ALS. Targeted inhibition of nitrated Hsp90 may be a novel therapeutic approach for ALS. An alternative therapeutic strategy is to target the production of survival factors by glial cells. Riluzole is the only FDA approved drug for the treatment of ALS and it shows a small but significant increase in patient lifespan. Our results show that acute riluzole treatment stimulated trophic factor production by astrocytes and Schwann cells. However long-term exposure reversed and even inhibited the production of trophic factors, an observation that may explain the modest increase in patient survival in clinical trials. Discontinuous riluzole treatment can maintain elevated trophic factor levels and prevent trophic factor reduction in spinal cords of nontransgenic animals. These results suggest that discontinuous riluzole administration may improve ALS patient survival. In summary, we demonstrated that Hsp90 has an essential function in the regulation of motor neuron survival. We have also shown that Hsp90 was nitrated in the presence of mutant SOD and was present during symptom onset and increases as disease progresses, which may explain the toxic gain of function of mutant SOD. Finally we demonstrate a biphasic effect of riluzole on trophic factor production and propose changes in administration to improve effects in ALS patients.

Neuroscience and Neurobiology

Rolle von Cardiotrophin-1 für die Pathogenese von Kardiomyopathien

Haßfeld, Sabine

28 April 2004

Cardiotrophin-1 ist ein Zytokin der Familie Interleukin-6-Familie, zu der auch IL-11, CNTF, OSM und LIF gehören. Diese Substanzen wirken über die gemeinsame Rezeptoruntereinheit gp130. CT-1 induziert die Hypertrophie von Kardiomyozyten und inhibiert die Apoptose kardialer und Zellen. In verschiedenen Tiermodellen der Herzinsuffizienz konnte eine gesteigerte myokardiale CT-1 Expression beobachtet werden. Kardiomyopathien sind wiederum kardiale Erkrankungen, die mit einer Hypertrophie und Apoptose einhergehen und zu einer Herzinsuffizienz führen können. Man geht davon aus, dass 25-50 Prozent der familiär sind. Hierbei handelt es sich um eine monogenetische Erkrankung, die überwiegend autosomal-dominant vererbt werden. Daneben konnten aber auch modifizierende Polymorphismen in neurohumoralen Faktoren identifiziert werden. Basierend auf diesen Ergebnissen war das Ziel dieser Arbeit die Analyse der möglichen Beteiligung genetischer Varianten der kodierenden sowie der regulatorischen Region an der Pathogenese der Hypertrophen bzw. Dilatativen Kardiomyopathie. Zusätzlich sollte die mRNA-Expression von CT-1 in Myokardbiopsien von Patienten mit Herzinsuffizienz quantifiziert werden. Hierfür musste zunächst die Sequenzen der 5´-flankierenden Region identifiziert und bezüglich ihrer regulatorischen Eigenschaften analysiert werden. Es konnten 1,1 kb der 5´-flankierenden Region sequenziert werden. Die anschließende Luciferase-Reportergen-Analyse wies regulatorische Aktivitäten für den gesamten Bereich nach. Diese Region enthält zahlreiche cis-aktive DANN-Sequenzen aber keine TATA-Box. Für die Mutationssuche wurden 64 Patienten mit DCM, 53 Patienten mit HCM sowie 100 Kontrollpersonen mittels PCR-SSCP-Analyse untersucht. Es konnte eine kodierende Variante A92T bei jeweils einem DCM- bzw. HCM-Patienten identifiziert werden. Diese Substitution liegt in einem Bereich, der zwischen verschiedenen Spezies (Ratte, Maus, Mensch) konserviert ist. Diese Mutation könnte eine Veränderung der Sekundärstruktur bewirken und liegt in einem möglichen funktionellen Bereich. Die Promotorregion wies eine Basenpaarsubstitution bei -130 (G/T) sowie eine Deletion der Basen CTTT zwischen -992 und -995 auf. Der Polymorphismus an Position -130 fand sich tendenziell häufiger bei Patienten mit Dilatativer Kardiomyopathie. Die CTTT-Deletion konnte nur bei einer Patientin mit HCM nachgewiesen werden. Für die Quantifizierung der CT-1 mRNA wurden rechtsventrikuläre Endomyokardbiopsien von 6 Patienten mit eingeschränkter LVEF (CHI), 5 Patienten nach Herztransplantation (TX) sowie 3 Kontrollpatienten (KO) eingesetzt. Es konnte ein relativer Anstieg der CT-1 Expression um 82% bei den Patienten mit eingeschränkter LVEF festgestellt werden. Interessanterweise besteht eine enge Korrelation zur Schwere der eingeschränkten Herzfunktion sowie zur Zunahme der Hypertrophie. / Cardiotrophin-1 is a cytokine, which belongs to the interleukin-6 family, which includes IL-11, CNTF, OSM and LIF. These factors act via the receptor subunit gp130. CT-1 induces the hypertrophy of cardiomyocytes and inhibits the apoptosis of cardiac cells. Studies in animal models of congestive heart failure showed an enhanced expression of CT-1 in the myocardium. Cardiomyopathies are cardiac diesorders, which are charakterized by hypertrophy and apoptosis and which can terminate with congestive heart failure. About 25-50 percent of all cases are familial. It is a monogenetic mendelian disorder with an autosomal-dominant inheritance in most cases. Beside this, modifying polymorphisms in neurohunoral factors could be identified. Based on these facts, the aim of this study was to identify genetic variants within the coding and regulatory region of the CT-1 gene, which could influence the pathogenesis of hypertrophic or dilated cardiomyopathy. Additionally, the mRNA-expression of CT-1 in myocardial biopsies of heart failure patients should be quantified. First, it was necessary to sequence the 5´-untranslated region and to analyse its regulatory function. We could sequence 1.1 kb of the 5´-UTR. The luciferase reportergene assay showed a significant promoter activity for the whole region. The region contains various cis-active DNA sequences but no TATA-box.The TRANSFAC-analysis identified different binding sites for transcription factors but no TATA-box. The genetic material of 64 DCM and 53 HCM patients and 100 controls was screened for mutaions by using a PCR-based SSCP-analysis. A coding variant A92T could be identified for a patient with DCM and for an HCM patient. This mutation lies within a region which is conserved between different species (rat, mouse, human). This variant could disturb the secondary structure and lies in a probable functional region. Within the promoter we could identify a basepair substitution at position -130 (G/T) and a 4-basepair deletion between -992 and -995 (CTTTdel). The polymorphism at -130 showed a tendency for a higher occurrence in DCM patients. One HCM patient was heterozygous for the CTTT-deletion. To quantify the CT-1 mRNA we used endomyocardial biopsies of 6 patients with reduced LVEF (CHI), 5 patients after heart transplantation (TX) and 3 controls (KO). We performed a semiquantitative analysis by using HPLC and an external standard (PDH mRNA). We found an increased expression of CT-1 by 82% for patients with heart failure. Interestingly, we saw a tight correlation with to the reduction in LV function and to the degree of hypertrophy.

PCR

Apoptose

Cardiotrophin-1

CT-1

Interleukin-6

IL-6

IL-11

LIF

CNTF

OSM

gp130

Hypertrophie

Herzinsuffizienz

Hypertrophe Kardiomyopathie

HCM

Dilatative Kardiomyopathie

DCM

Promotor

Muatation

mRNA-Expression

SSCP

Luciferase Reportergen Analyse

HPLC

PCR

apoptosis

cardiotrophin-1

CT-1

interleukin-6

IL-6

IL-11

LIF

CNTF

OSM

gp130

hypertrophy

heart failure

hypertrophic cardiomyopathy

HCM

dilated cardiomyopathy

DCM

promoter

muatation

mRNA-expression

SSCP

luciferase reportergene assay

HPLC

610 Medizin

33 Medizin

YB 9104

YG 6204

YG 6236

ddc:610