Progression of Parkinson's Disease Pathology is Reproduced by Intragastric Administration of Rotenone in Mice

Pan-Montojo, Francisco, Anichtchik, Oleg, Dening, Yanina, Knels, Lilla, Pursche, Stefan, Jung, Roland, Jackson, Sandra, Gille, Gabriele, Spillantini, Maria Grazia, Reichmann, Heinz, Funk, Richard H. W.

30 November 2015

In patients with Parkinson's disease (PD), the associated pathology follows a characteristic pattern involving inter alia the enteric nervous system (ENS), the dorsal motor nucleus of the vagus (DMV), the intermediolateral nucleus of the spinal cord and the substantia nigra, providing the basis for the neuropathological staging of the disease. Here we report that intragastrically administered rotenone, a commonly used pesticide that inhibits Complex I of the mitochondrial respiratory chain, is able to reproduce PD pathological staging as found in patients. Our results show that low doses of chronically and intragastrically administered rotenone induce alpha-synuclein accumulation in all the above-mentioned nervous system structures of wild-type mice. Moreover, we also observed inflammation and alpha-synuclein phosphorylation in the ENS and DMV. HPLC analysis showed no rotenone levels in the systemic blood or the central nervous system (detection limit [rotenone]<20 nM) and mitochondrial Complex I measurements showed no systemic Complex I inhibition after 1.5 months of treatment. These alterations are sequential, appearing only in synaptically connected nervous structures, treatment time-dependent and accompanied by inflammatory signs and motor dysfunctions. These results strongly suggest that the local effect of pesticides on the ENS might be sufficient to induce PD-like progression and to reproduce the neuroanatomical and neurochemical features of PD staging. It provides new insight into how environmental factors could trigger PD and suggests a transsynaptic mechanism by which PD might spread throughout the central nervous system.

Zentralnervensystem

Dopamin

Ganglien

Immunfärbung

Neuronen

Parkinson

Rückenmark

central nervous system

DAPI staining

Dopamine

Ganglia

Immunostaining

Neurons

parkinson disease

Spinal Cord

ddc:610

rvk:XA 10000

Molekulární diferenciace pohlavních chromosomů předivek rodu \kur{Yponomeuta} / Molecular differentiation of sex chromosomes in ermine moths of genus \kur{ Yponomeuta}

VESELÁ, Jana

January 2012

Structure of the karyotype of three species in ermine moths (Yponomeuta: Yponomeutidae, Lepidoptera) was investigated by means of several cytogenetic methods (DAPI staining, orcein staining, CGH and GISH with telomeric probe) focusing on their sex chromosomes. Additionally, the origin of the Z2 chromosome in the WZ1Z2/Z1Z1Z2Z2 sex chromosome system (specific for this family of butterflies) was tested using southern hybridization.

Progression of Parkinson's Disease Pathology is Reproduced by Intragastric Administration of Rotenone in Mice

Pan-Montojo, Francisco, Anichtchik, Oleg, Dening, Yanina, Knels, Lilla, Pursche, Stefan, Jung, Roland, Jackson, Sandra, Gille, Gabriele, Spillantini, Maria Grazia, Reichmann, Heinz, Funk, Richard H. W.

30 November 2015

In patients with Parkinson's disease (PD), the associated pathology follows a characteristic pattern involving inter alia the enteric nervous system (ENS), the dorsal motor nucleus of the vagus (DMV), the intermediolateral nucleus of the spinal cord and the substantia nigra, providing the basis for the neuropathological staging of the disease. Here we report that intragastrically administered rotenone, a commonly used pesticide that inhibits Complex I of the mitochondrial respiratory chain, is able to reproduce PD pathological staging as found in patients. Our results show that low doses of chronically and intragastrically administered rotenone induce alpha-synuclein accumulation in all the above-mentioned nervous system structures of wild-type mice. Moreover, we also observed inflammation and alpha-synuclein phosphorylation in the ENS and DMV. HPLC analysis showed no rotenone levels in the systemic blood or the central nervous system (detection limit [rotenone]<20 nM) and mitochondrial Complex I measurements showed no systemic Complex I inhibition after 1.5 months of treatment. These alterations are sequential, appearing only in synaptically connected nervous structures, treatment time-dependent and accompanied by inflammatory signs and motor dysfunctions. These results strongly suggest that the local effect of pesticides on the ENS might be sufficient to induce PD-like progression and to reproduce the neuroanatomical and neurochemical features of PD staging. It provides new insight into how environmental factors could trigger PD and suggests a transsynaptic mechanism by which PD might spread throughout the central nervous system.

info:eu-repo/classification/ddc/610

ddc:610

Ancestral vascular lumen formation via basal cell surfaces

Lammert, Eckhard, Laudet, Vincent, Schubert, Michael, Regener, Kathrin, Strilic, Boris, Kucera, Tomas

30 November 2015

The cardiovascular system of bilaterians developed from a common ancestor. However, no endothelial cells exist in invertebrates demonstrating that primitive cardiovascular tubes do not require this vertebrate-specific cell type in order to form. This raises the question of how cardiovascular tubes form in invertebrates? Here we discovered that in the invertebrate cephalochordate amphioxus, the basement membranes of endoderm and mesoderm line the lumen of the major vessels, namely aorta and heart. During amphioxus development a laminin-containing extracellular matrix (ECM) was found to fill the space between the basal cell surfaces of endoderm and mesoderm along their anterior-posterior (A-P) axes. Blood cells appear in this ECM-filled tubular space, coincident with the development of a vascular lumen. To get insight into the underlying cellular mechanism, we induced vessels in vitro with a cell polarity similar to the vessels of amphioxus. We show that basal cell surfaces can form a vascular lumen filled with ECM, and that phagocytotic blood cells can clear this luminal ECM to generate a patent vascular lumen. Therefore, our experiments suggest a mechanism of blood vessel formation via basal cell surfaces in amphioxus and possibly in other invertebrates that do not have any endothelial cells. In addition, a comparison between amphioxus and mouse shows that endothelial cells physically separate the basement membranes from the vascular lumen, suggesting that endothelial cells create cardiovascular tubes with a cell polarity of epithelial tubes in vertebrates and mammals.

Amphioxus

Lanzettfischchen

Basalzellen

Basalmembran

endotheliale Zellen

wirbellos

Blutkörperchen

Blutgefäße

Amphioxus

basal cells

basement membran

endothelial cells

Invertebrates

blood cells

DAPI staining

blood vessels

ddc:570

ddc:610

rvk:XA 10000

rvk:WD 1500

Ancestral vascular lumen formation via basal cell surfaces

Lammert, Eckhard, Laudet, Vincent, Schubert, Michael, Regener, Kathrin, Strilic, Boris, Kucera, Tomas

30 November 2015

The cardiovascular system of bilaterians developed from a common ancestor. However, no endothelial cells exist in invertebrates demonstrating that primitive cardiovascular tubes do not require this vertebrate-specific cell type in order to form. This raises the question of how cardiovascular tubes form in invertebrates? Here we discovered that in the invertebrate cephalochordate amphioxus, the basement membranes of endoderm and mesoderm line the lumen of the major vessels, namely aorta and heart. During amphioxus development a laminin-containing extracellular matrix (ECM) was found to fill the space between the basal cell surfaces of endoderm and mesoderm along their anterior-posterior (A-P) axes. Blood cells appear in this ECM-filled tubular space, coincident with the development of a vascular lumen. To get insight into the underlying cellular mechanism, we induced vessels in vitro with a cell polarity similar to the vessels of amphioxus. We show that basal cell surfaces can form a vascular lumen filled with ECM, and that phagocytotic blood cells can clear this luminal ECM to generate a patent vascular lumen. Therefore, our experiments suggest a mechanism of blood vessel formation via basal cell surfaces in amphioxus and possibly in other invertebrates that do not have any endothelial cells. In addition, a comparison between amphioxus and mouse shows that endothelial cells physically separate the basement membranes from the vascular lumen, suggesting that endothelial cells create cardiovascular tubes with a cell polarity of epithelial tubes in vertebrates and mammals.

info:eu-repo/classification/ddc/570

ddc:570

info:eu-repo/classification/ddc/610

ddc:610