Difference: DavidEliezer (1 vs. 24)

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: WMCCU

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

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Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

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There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-AUG-2005 Project End: 31-JUL-2009 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: WMCCU

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

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• TWikiPreferences has site-level preferences of TWiki.
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Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-AUG-2005 Project End: 31-JUL-2009 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: WMCCU
• Country: USA

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: WMCCU
• Country: USA

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/

• Country: USA

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-AUG-2005 Project End: 31-JUL-2009 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

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Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-AUG-2005 Project End: 31-JUL-2009 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu

• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
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• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
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Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

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Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-AUG-2005 Project End: 31-JUL-2009 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

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• TWikiPreferences has site-level preferences of TWiki.
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• TWikiUsers has a list of other TWiki users.

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-AUG-2005 Project End: 31-JUL-2009 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-AUG-2005 Project End: 31-JUL-2009 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 1R01AG025440-01A1 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Tau

Abstract: DESCRIPTION (provided by applicant): Tau is a microtubule (MT) associated protein (MAP) that is found aggregated into straight (SF) or paired helical (PHF) filaments within neurofibrillary tangle deposits in Alzheimer's disease (AD) and other neurodegenerative disorders. Mutations in the gene encoding tau are associated with the hereditary syndrome FTDP-17 (frontotemporal dementia and Parkinsonism linked to chromosome 17) indicating that tau plays a causative role in the pathogenesis of this and possibly other diseases such as AD. Many of the FTDP-17 linked mutations fall within the MT binding domain (MBD) of tau, a region that contains, depending on the isoform, three or four pseudo-repeats (3R vs. 4R) of a 31 to 32 residue MT interaction motif. These mutations disrupt tau-MT interactions and tau-promoted MT assembly, and several also enhance tau PHF formation in vitro. A different class of FTDP-17 associated mutations influence tau mRNA splicing and alter the ratio of 4R to 3R tau isoforms in vivo, which can both modulate the normal functions of tau and enhance tau aggregation by altering the relative populations of free and MT-bound isoforms. Thus, tau mutations may exert pathogenic effects by interfering with tau function, by enhancing tau aggregation, or by both means. Tau is intrinsically unstructured when free in solution but undergoes structural transitions upon binding to MTs, upon filament formation, and upon associating with lipid membranes. Residual structure in free tau may play an important role in mediating these various intermolecular interactions. We propose to characterize, at high resolution, the structural and dynamic properties of tau in its free state using NMR spectroscopy. We will also elucidate in detail the structure of detergent micelle associated tau and the topology of lipid vesicle and MT-bound tau. We will probe the effects of FTDP-17 linked mutations on the structural properties of free, lipid-associated and MT-bound tau and will use newly designed mutations to elucidate the structural basis for these intermolecular interactions. Our studies will focus on 3R and 4R forms of the tau MBD. The results will clarify the molecular mechanisms underlying both normal tau function and tau induced neurodegeneration and may suggest strategies for developing new therapeutics. This work may also have broader implications for understanding and treating other protein aggregation diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-AUG-2005 Project End: 31-JUL-2009 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

Thesaurus Terms:

There are no thesaurus terms on file for this project.

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

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Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

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Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

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Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
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Public information on Grants associated with NYSBC

Grant Number: 2R01AG019391-05 PI Name: ELIEZER, DAVID PI Email: dae2005@med.cornell.edu PI Title: ASSISTANT PROFESSOR Project Title: Structure and Function of Alpha-Synuclein

Abstract: DESCRIPTION (provided by applicant): Aggregation of a-synuclein (aS) plays an important but still poorly understood role in the pathogenesis of Parkinson's disease (PD). The normal function of aS remains unknown, but the protein binds to phospholipid membranes and is believed to regulate synaptic vesicle pool size, vesicle recycling, neurotransmitter transport and release, and synaptic plasticity. Since the discovery of the link between aS and PD, there has been great interest in identifying aS interaction partners that influence either the pathogenic or normal roles of the protein. In the past few years, a growing number of proteins, polymers, and small molecules have been reported to bind to aS and alter its aggregation kinetics and/or its lipid-associated functions. Among these are two other members of the synuclein family, B-synuclein (BS) and y-synuclein (yS). Covalent modifications also affect aS aggregation and function. However, the mechanisms by which these various binding interactions and modifications influence aS behavior are not well understood. We have shown that residual structure in free aS may play an important role in mediating the intermolecular interactions that precede amyloid fibril formation by this protein. We hypothesize that upon covalent modification or partner interactions, aS undergoes conformational changes that underlie the consequent effects on the aggregation or normal functions of the protein. We therefore propose to characterize, at high resolution, the structural changes that occur in aS as a function of its modifications and its interactions with different partners, with an initial focus on (BS, yS, histones, HSP70, PLD2, copper and other metals and polycations. We also propose to elucidate in detail the structure of (BS and yS in their free and lipid-bound states to clarify why aS exhibits different self-assembly behavior from these close relatives. Finally, we plan to test our conclusions regarding the role of structural changes in aS by introducing rationally designed mutants, collaboratively, into yeast and fly models of aS toxicity and function. The proposed studies are focused on improving our understanding of the molecular mechanisms underlying PD and may suggest strategies for developing new PD therapeutics. The results may have broader implications for understanding and treating other amyloid diseases, including Alzheimer's disease and the prion diseases.

Thesaurus Terms:

There are no thesaurus terms on file for this project.

Institution: WEILL MEDICAL COLLEGE OF CORNELL UNIV NEW YORK, NY 10021 Fiscal Year: 2005 Department: BIOCHEMISTRY Project Start: 01-APR-2001 Project End: 31-MAR-2010 ICD: NATIONAL INSTITUTE ON AGING IRG: NDBG

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu/research/deliezer/
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
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• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
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• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU

• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Retrieve from PubMed

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

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• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu
• Location: 1300 York Avenue, Rm. Whitney 306
• Country: USA
• Comment:

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu

• Country: USA
• Comment:

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu
• Location: (Please specify office location)
• Country: USA
• Comment:

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu
• Location: (Please specify office location)
• Country: USA
• Comment:

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu
• Location: (Please specify office location)
• Country: USA
• Comment:

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.

• Name: David Eliezer
• Email: dae2005@med.cornell.edu
• Company Name: WMCCU
• Company URL: http://www.med.cornell.edu
• Location: (Please specify office location)
• Country: USA
• Comment:

Personal Preferences (details in TWikiVariables)

• Horizontal size of text edit box:
  • Set EDITBOXWIDTH = 70
• Vertical size of text edit box:
  • Set EDITBOXHEIGHT = 17
• Style of text edit box. width: 99% for full window width (default), width: auto to disable.
  • Set EDITBOXSTYLE = width: 99%
• Optionally write protect your home page: (set it to your WikiName)
  • Set ALLOWTOPICCHANGE =

Related topics

• TWikiPreferences has site-level preferences of TWiki.
• WebPreferences has preferences of the TWiki.Main web.
• TWikiUsers has a list of other TWiki users.