Your search keyword '"Brinda Ravikumar"' showing total 5 results

1. Pharmacological mTOR-inhibition facilitates clearance of AD-related tau aggregates in the mouse brain

Author

Martina P. Morawe, Fan Liao, Willi Amberg, Jeroen van Bergeijk, Rui Chang, Mary Gulino, Caitlin Hamilton, Carolin Hoft, Casey Lumpkin, Bryan Mastis, Emily McGlame, Judith Nuber, Christian Plaas, Brinda Ravikumar, Kaushambi Roy, Marion Schanzenbächer, Joseph Tierno, Viktor Lakics, Tammy Dellovade, and Matthew Townsend

Subjects

Sirolimus, Pharmacology, Mice, Disease Models, Animal, Alzheimer Disease, TOR Serine-Threonine Kinases, Animals, Brain, tau Proteins, Mice, Transgenic

Abstract

In this study we aimed to reduce tau pathology, a hallmark of Alzheimer's Disease (AD), by activating mTOR-dependent autophagy in a transgenic mouse model of tauopathy by long-term dosing of animals with mTOR-inhibitors. Rapamycin treatment reduced the burden of hyperphosphorylated and aggregated pathological tau in the cerebral cortex only when applied to young mice, prior to the emergence of pathology. Conversely, PQR530 which exhibits better brain exposure and superior pharmacokinetic properties, reduced tau pathology even when the treatment started after the onset of pathology. Our results show that dosing animals twice per week with PQR530 resulted in intermittent, rather than sustained target engagement. Nevertheless, this pulse-like mTOR inhibition followed by longer intervals of re-activation was sufficient to reduce tau pathology in the cerebral cortex in P301S tau transgenic mice. This suggests that balanced therapeutic dosing of blood-brain-barrier permeable mTOR-inhibitors can result in a disease-modifying effect in AD and at the same time prevents toxic side effects due to prolonged over activation of autophagy.

Published

2022

2. Autophagosome Precursor Maturation Requires Homotypic Fusion

Author

Maurizio Renna, Kevin Moreau, Claudia Puri, David C. Rubinsztein, Brinda Ravikumar, Moreau, Kevin, Ravikumar, Brinda, Renna, Maurizio, Puri, Claudia, and Rubinsztein, David C.

Subjects

Autophagosome, Intracellular Membrane, SNARE Protein, Autophagy-Related Proteins, Mitochondrion, Biology, Syntaxin 17, HeLa Cell, General Biochemistry, Genetics and Molecular Biology, Cytoplasmic Vesicle, Article, R-SNARE Proteins, 03 medical and health sciences, R-SNARE Protein, Phagosomes, Autophagy, Humans, Phagosome, 030304 developmental biology, 0303 health sciences, Biochemistry, Genetics and Molecular Biology (all), Biochemistry, Genetics and Molecular Biology(all), Endoplasmic reticulum, Vesicle, 030302 biochemistry & molecular biology, Cytoplasmic Vesicles, Intracellular Membranes, Cell biology, Autophagy-Related Protein, Carrier Protein, Carrier Proteins, SNARE Proteins, Biogenesis, Human, HeLa Cells

Abstract

Summary Autophagy is a catabolic process in which lysosomes degrade intracytoplasmic contents transported in double-membraned autophagosomes. Autophagosomes are formed by the elongation and fusion of phagophores, which can be derived from preautophagosomal structures coming from the plasma membrane and other sites like the endoplasmic reticulum and mitochondria. The mechanisms by which preautophagosomal structures elongate their membranes and mature toward fully formed autophagosomes still remain unknown. Here, we show that the maturation of the early Atg16L1 precursors requires homotypic fusion, which is essential for subsequent autophagosome formation. Atg16L1 precursor homotypic fusion depends on the SNARE protein VAMP7 together with partner SNAREs. Atg16L1 precursor homotypic fusion is a critical event in the early phases of autophagy that couples membrane acquisition and autophagosome biogenesis, as this step regulates the size of the vesicles, which in turn appears to influence their subsequent maturation into LC3-positive autophagosomes., Graphical Abstract Highlights ► Homotypic fusion of Atg16L1 vesicles enables their maturation into autophagosomes ► VAMP7 regulates Atg16L1 vesicle homotypic fusion and autophagosome formation ► Plasma membrane is a likely source of SNAREs required for Atg16L1 vesicle fusion ► Starvation, which induces autophagy, triggers Atg16L1 vesicle homotypic fusion

Published

2011

3. Role of autophagy in the clearance of mutant huntingtin: A step towards therapy?

Author

David C. Rubinsztein and Brinda Ravikumar

Subjects

Huntingtin, Clinical Biochemistry, Mutant, Autophagy, Nuclear Proteins, Nerve Tissue Proteins, General Medicine, Vacuole, Biology, medicine.disease, BAG3, Biochemistry, Cell biology, Cytosol, Huntington Disease, Mutation, Spinocerebellar ataxia, medicine, Animals, Humans, Molecular Medicine, Molecular Biology, PI3K/AKT/mTOR pathway

Abstract

Macroautophagy (henceforth referred to simply as autophagy) is a bulk degradation process involved in the clearance of long-lived proteins, protein complexes and organelles. A portion of the cytosol, with its contents to be degraded, is enclosed by double-membrane structures called autophagosomes/autophagic vacuoles, which ultimately fuse with lysosomes where their contents are degraded. In this review, we will describe how induction of autophagy is protective against toxic intracytosolic aggregate-prone proteins that cause a range of neurodegenerative diseases. Autophagy is a key clearance pathway involved in the removal of such proteins, including mutant huntingtin (that causes Huntington’s disease), mutant ataxin-3 (that causes spinocerebellar ataxia type 3), forms of tau that cause tauopathies, and forms of alpha-synuclein that cause familial Parkinson’s disease. Induction of autophagy enhances the clearance of both soluble and aggregated forms of such proteins, and protects against toxicity of a range of these mutations in cell and animal models. Interestingly, the aggregates formed by mutant huntingtin sequester and inactivate the mammalian target of rapamycin (mTOR), a key negative regulator of autophagy. This results in induction of autophagy in cells with these aggregates.

Published

2006

4. The roles of the ubiquitin-proteasome and autophagy–lysosome pathways in Huntington's disease and related conditions

Author

David C. Rubinsztein, Zdenek Berger, Brinda Ravikumar, and Sovan Sarkar

Subjects

Genetics, Cellular pathology, Huntingtin, Protein degradation, Biology, Polyglutamine tract, medicine.disease, Psychiatry and Mental health, Neuropsychology and Physiological Psychology, Neurology, Huntington's disease, SETD2, Mutant protein, medicine, Neurology (clinical), Trinucleotide repeat expansion, Biological Psychiatry

Abstract

Huntington's disease (HD) is one of nine known conditions caused by a CAG trinucleotide repeat expansion that is translated into a polyglutamine tract in the disease protein. Genetic and transgenic data suggest that the primary effect of these CAG/polyglutamine expansions is to confer a toxic gain-of-function on the mutant protein. The cellular pathology of all known polyglutamine diseases is characterised by the accumulation of the relevant mutant protein along with other proteins in aggregates (also known as inclusions) in neurons in the disease brain. Such aggregates are seen in neuronal nuclei and processes in HD. The role of aggregates in these diseases has been a subject of vigorous debate. However, irrespective of the nature(s) of the toxic species of huntingtin, it is desirable for cells to be able to control the levels of these toxic proteins and restrict their accumulation. In this paper we will review the ubiquitin-proteasome and autophagy–lysosome routes for protein degradation and how they may be involved in the clearance of aggregate-prone proteins, exemplified by mutant huntingtin exon 1. We will also consider the possibilities that these protein degradation pathways may be perturbed as a consequence of the mutations that form the aggregate-prone proteins.

Published

2003

5. α-Synuclein Is Degraded by Both Autophagy and the Proteasome

Author

Julie L. Webb, Jane Atkins, Brinda Ravikumar, Jeremy N. Skepper, and David C. Rubinsztein

Subjects

Proteasome Endopeptidase Complex, animal diseases, Synucleins, Nerve Tissue Proteins, Substantia nigra, Biology, PC12 Cells, Biochemistry, Pathogenesis, chemistry.chemical_compound, Chaperone-mediated autophagy, Multienzyme Complexes, mental disorders, Organelle, Autophagy, Animals, Humans, Molecular Biology, Sirolimus, Alpha-synuclein, Antibiotics, Antineoplastic, Dopaminergic, Cell Biology, Rats, nervous system diseases, Cell biology, Cysteine Endopeptidases, nervous system, chemistry, Proteasome, alpha-Synuclein

Abstract

Parkinson's disease (PD) is characterized by the loss of dopaminergic neurons in the substantia nigra and the formation of aggregates (Lewy bodies) in neurons. alpha-Synuclein is the major protein in Lewy bodies and rare mutations in alpha-synuclein cause early-onset PD. Consequently, alpha-synuclein is implicated in the pathogenesis of PD. Here, we have investigated the degradation pathways of alpha-synuclein, using a stable inducible PC12 cell model, where the expression of exogenous human wild-type, A30P, or A53T alpha-synuclein can be switched on and off. We have used a panel of inhibitors/stimulators of autophagy and proteasome function and followed alpha-synuclein degradation in these cells. We found that not only is alpha-synuclein degraded by the proteasome, but it is also degraded by autophagy. A role for autophagy was further supported by the presence of alpha-synuclein in organelles with the ultrastructural features of autophagic vesicles. Since rapamycin, a stimulator of autophagy, increased clearance of alpha-synuclein, it merits consideration as a potential therapeutic for Parkinsons disease, as it is designed for chronic use in humans.

Published

2003