Your search keyword '"Oren-Giladi, P"' showing total 8 results

1. Sip1 regulates the generation of the inner nuclear layer retinal cell lineages in mammals

Author

Menuchin-Lasowski, Y, Oren-Giladi, P, Xie, Q, Ezra-Elia, R, Ofri, R, Peled-Hajaj, S, Farhy, C, Higashi, Y, van de Putte, T, Kondoh, H, Huylebroeck, Danny, Cvekl, A, Ashery-Padan, R, and Cell biology

Published

2016

2. Sip1 regulates the generation of the inner nuclear layer retinal cell lineages in mammals

Author

Menuchin-Lasowski, Y. (Yotam), Oren-Giladi, P. (Pazit), Xie, Q. (Qing), Ezra-Elia, R. (Raaya), Ofri, R. (Ron), Peled-Hajaj, S. (Shany), Farhy, C. (Chen), Higashi, Y. (Yujiro), Putte, T. (Tom) van de, Kondoh, H. (H.), Huylebroeck, D. (Danny), Cvekl, A. (Ales), Ashery-Padan, R. (Ruth), Menuchin-Lasowski, Y. (Yotam), Oren-Giladi, P. (Pazit), Xie, Q. (Qing), Ezra-Elia, R. (Raaya), Ofri, R. (Ron), Peled-Hajaj, S. (Shany), Farhy, C. (Chen), Higashi, Y. (Yujiro), Putte, T. (Tom) van de, Kondoh, H. (H.), Huylebroeck, D. (Danny), Cvekl, A. (Ales), and Ashery-Padan, R. (Ruth)

Abstract

The transcription factor Sip1 (Zeb2) plays multiple roles during CNS development from early acquisition of neural fate to cortical neurogenesis and gliogenesis. In humans, SIP1 (ZEB2) haploinsufficiency leads to Mowat–Wilson syndrome, a complex congenital anomaly including intellectual disability, epilepsy and Hirschsprung disease. Here we uncover the role of Sip1 in retinogenesis. Somatic deletion of Sip1 from mouse retinal progenitors primarily affects the generation of inner nuclear layer cell types, resulting in complete loss of horizontal cells and reduced numbers of amacrine and bipolar cells, while the number of Muller glia is increased. Molecular analysis places Sip1 downstream of the eye field transcription factor Pax6 and upstream of Ptf1a in the gene network required for generating the horizontal and amacrine lineages. Intriguingly, characterization of differentiation dynamics reveals that Sip1 has a role in promoting the timely differentiation of retinal interneurons, assuring generation of the proper number of the diverse neuronal and glial cell subtypes that constitute the functional

Published

2016

3. Proteomics of Microparticles with SILAC Quantification (PROMIS-Quan): A Novel Proteomic Method for Plasma Biomarker Quantification*[S]

Author

Harel, Michal, Oren-Giladi, Pazit, Kaidar-Person, Orit, Shaked, Yuval, and Geiger, Tamar

Abstract

Unbiased proteomic analysis of plasma samples holds the promise to reveal clinically invaluable disease biomarkers. However, the tremendous dynamic range of the plasma proteome has so far hampered the identification of such low abundant markers. To overcome this challenge we analyzed the plasma microparticle proteome, and reached an unprecedented depth of over 3000 plasma proteins in single runs. To add a quantitative dimension, we developed PROMIS-Quan“PROteomics of MIcroparticles with Super-Stable Isotope Labeling with Amino Acids in Cell Culture (SILAC) Quantification, a novel mass spectrometry-based technology for plasma microparticle proteome quantification. PROMIS-Quan enables a two-step relative and absolute SILAC quantification. First, plasma microparticle proteomes are quantified relative to a super-SILAC mix composed of cell lines from distinct origins. Next, the absolute amounts of selected proteins of interest are quantified relative to the super-SILAC mix. We applied PROMIS-Quan to prostate cancer and compared plasma microparticle samples of healthy individuals and prostate cancer patients. We identified in total 5374 plasma-microparticle proteins, and revealed a predictive signature of three proteins that were elevated in the patient-derived plasma microparticles. Finally, PROMIS-Quan enabled determination of the absolute quantitative changes in prostate specific antigen (PSA) upon treatment. We propose PROMIS-Quan as an innovative platform for biomarker discovery, validation, and quantification in both the biomedical research and in the clinical worlds.

Published

2015

4. Pax6 Regulates Gene Expression in the Vertebrate Lens through miR-204

Author

Carmit Levy, Dina Grinberg, Pazit Oren-Giladi, Sandro Banfi, Ivan Conte, Karen Gueta, Noa Davis, Noam Shomron, Ales Cvekl, Ohad Shaham, Shaul Raviv, Qing Xie, Maya Keydar-Prizant, Eyal Mor, Ruth Ashery-Padan, Rachel E. Bell, Raffaella Avellino, Metsada Pasmanik-Chor, Shaham, O, Gueta, K, Mor, E, Oren Giladi, P, Grinberg, D, Xie, Q, Cvekl, A, Shomron, N, Davis, N, Keydar Prizant, M, Raviv, S, Pasmanik Chor, M, Bell, Re, Levy, C, Avellino, R, Banfi, Sandro, Conte, I, Ashery Padan, R., Shaham, O., Gueta, K., Mor, E., Oren-Giladi, P., Grinberg, D., Xie, Q., Cvekl, A., Shomron, N., Davis, N., Keydar-Prizant, M., Raviv, S., Pasmanik-Chor, M., Bell, R. E., Levy, C., Avellino, R., Banfi, S., Conte, I., and Ashery-Padan, R.

Subjects

Cancer Research, PAX6 Transcription Factor, MicroRNA Gene, Eye, Mice, 0302 clinical medicine, Gene expression, Paired Box Transcription Factors, Genetics (clinical), Genetics, Regulation of gene expression, 0303 health sciences, Gene Expression Regulation, Developmental, Homeodomain Protein, MicroRNA, Cell Differentiation, SOXC Transcription Factors, Paired Box Transcription Factor, SOXC Transcription Factor, Vertebrates, TRPM Cation Channel, Research Article, TBX1, Crystallin, lcsh:QH426-470, TRPM Cation Channels, Biology, Evolution, Molecular, 03 medical and health sciences, Animals, Eye Proteins, Molecular Biology, Transcription factor, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Homeodomain Proteins, Binding Sites, Animal, Vertebrate, Binding Site, Eye Protein, Crystallins, eye diseases, Repressor Proteins, lcsh:Genetics, MicroRNAs, Gene Expression Regulation, Eye development, PAX6, sense organs, 030217 neurology & neurosurgery

Abstract

During development, tissue-specific transcription factors regulate both protein-coding and non-coding genes to control differentiation. Recent studies have established a dual role for the transcription factor Pax6 as both an activator and repressor of gene expression in the eye, central nervous system, and pancreas. However, the molecular mechanism underlying the inhibitory activity of Pax6 is not fully understood. Here, we reveal that Trpm3 and the intronic microRNA gene miR-204 are co-regulated by Pax6 during eye development. miR-204 is probably the best known microRNA to function as a negative modulator of gene expression during eye development in vertebrates. Analysis of genes altered in mouse Pax6 mutants during lens development revealed significant over-representation of miR-204 targets among the genes up-regulated in the Pax6 mutant lens. A number of new targets of miR-204 were revealed, among them Sox11, a member of the SoxC family of pro-neuronal transcription factors, and an important regulator of eye development. Expression of Trpm/miR-204 and a few of its targets are also Pax6-dependent in medaka fish eyes. Collectively, this study identifies a novel evolutionarily conserved mechanism by which Pax6 controls the down-regulation of multiple genes through direct up-regulation of miR-204., Author Summary The transcription factor Pax6 is reiteratively employed in space and time for the establishment of progenitor pools and the differentiation of neuronal and non-neuronal lineages of the CNS, pancreas, and eye. Execution of these diverse developmental programs depends on simultaneous activation and repression of gene networks functioning downstream of Pax6. MicroRNAs function as inhibitors of gene expression. Many microRNA genes are transcribed through common promoters of host genes. In this study, using wide-scale analysis of changes in gene expression following Pax6 deletion in the lens, we discover that Pax6 regulates the gene Trpm3 and its hosted microRNA, miR-204. We then show that miR-204 suppresses several target genes in the lens, notably the neuronal gene Sox11. Lastly, by conducting parallel experiments in the medaka fish, we show that Pax6 control of miR-204 and its target genes is evolutionarily conserved between mammals and fish, stressing the biological importance of this pathway. Pax6 regulation of miR-204 explains part of the complex, divergent inhibitory activity of Pax6 in ocular progenitor cells, which is required to establish and maintain the identity and function of ocular tissues.

Published

2013

5. APOL1-Mediated Cell Injury Involves Disruption of Conserved Trafficking Processes.

Author

Kruzel-Davila E, Shemer R, Ofir A, Bavli-Kertselli I, Darlyuk-Saadon I, Oren-Giladi P, Wasser WG, Magen D, Zaknoun E, Schuldiner M, Salzberg A, Kornitzer D, Marelja Z, Simons M, and Skorecki K

Subjects

Alleles, Animals, Apolipoprotein L1, Apolipoproteins genetics, Drosophila melanogaster cytology, Humans, Hydrogen-Ion Concentration, Lipoproteins, HDL genetics, Protein Transport, Saccharomyces cerevisiae cytology, Apolipoproteins metabolism, Apolipoproteins physiology, Cell Death physiology, Lipoproteins, HDL metabolism, Lipoproteins, HDL physiology

Abstract

APOL1 harbors C-terminal sequence variants (G1 and G2), which account for much of the increased risk for kidney disease in sub-Saharan African ancestry populations. Expression of the risk variants has also been shown to cause injury to podocytes and other cell types, but the underlying mechanisms are not understood. We used Drosophila melanogaster and Saccharomyces cerevisiae to help clarify these mechanisms. Ubiquitous expression of the human APOL1 G1 and G2 disease risk alleles caused near-complete lethality in D. melanogaster , with no effect of the G0 nonrisk APOL1 allele, corresponding to the pattern of human disease risk. We also observed a congruent pattern of cellular damage with tissue-specific expression of APOL1. In particular, expression of APOL1 risk variants in D. melanogaster nephrocytes caused cell-autonomous accumulation of the endocytic tracer atrial natriuretic factor-red fluorescent protein at early stages and nephrocyte loss at later stages. We also observed differential toxicity of the APOL1 risk variants compared with the APOL1 nonrisk variants in S. cerevisiae , including impairment of vacuole acidification. Yeast strains defective in endosomal trafficking or organelle acidification but not those defective in autophagy displayed augmented APOL1 toxicity with all isoforms. This pattern of differential injury by the APOL1 risk alleles compared with the nonrisk alleles across evolutionarily divergent species is consistent with an impairment of conserved core intracellular endosomal trafficking processes. This finding should facilitate the identification of cell injury pathways and corresponding therapeutic targets of interest in these amenable experimental platforms., (Copyright © 2017 by the American Society of Nephrology.)

Published

2017

6. Sip1 regulates the generation of the inner nuclear layer retinal cell lineages in mammals.

Author

Menuchin-Lasowski Y, Oren-Giladi P, Xie Q, Ezra-Elia R, Ofri R, Peled-Hajaj S, Farhy C, Higashi Y, Van de Putte T, Kondoh H, Huylebroeck D, Cvekl A, and Ashery-Padan R

Subjects

Animals, Cell Cycle genetics, Cell Cycle physiology, Cell Differentiation genetics, Cell Differentiation physiology, Cell Lineage, Chromatin Immunoprecipitation, Female, Fluorescent Antibody Technique, Mice, Nerve Tissue Proteins genetics, Neurogenesis genetics, Neurogenesis physiology, PAX6 Transcription Factor genetics, PAX6 Transcription Factor metabolism, Pregnancy, Transcription Factors genetics, Transcription Factors metabolism, Nerve Tissue Proteins metabolism, Retina cytology, Retina metabolism

Abstract

The transcription factor Sip1 (Zeb2) plays multiple roles during CNS development from early acquisition of neural fate to cortical neurogenesis and gliogenesis. In humans, SIP1 (ZEB2) haploinsufficiency leads to Mowat-Wilson syndrome, a complex congenital anomaly including intellectual disability, epilepsy and Hirschsprung disease. Here we uncover the role of Sip1 in retinogenesis. Somatic deletion of Sip1 from mouse retinal progenitors primarily affects the generation of inner nuclear layer cell types, resulting in complete loss of horizontal cells and reduced numbers of amacrine and bipolar cells, while the number of Muller glia is increased. Molecular analysis places Sip1 downstream of the eye field transcription factor Pax6 and upstream of Ptf1a in the gene network required for generating the horizontal and amacrine lineages. Intriguingly, characterization of differentiation dynamics reveals that Sip1 has a role in promoting the timely differentiation of retinal interneurons, assuring generation of the proper number of the diverse neuronal and glial cell subtypes that constitute the functional retina in mammals., Competing Interests: The authors declare no competing or financial interests., (© 2016. Published by The Company of Biologists Ltd.)

Published

2016

7. Pax6 regulates gene expression in the vertebrate lens through miR-204.

Author

Shaham O, Gueta K, Mor E, Oren-Giladi P, Grinberg D, Xie Q, Cvekl A, Shomron N, Davis N, Keydar-Prizant M, Raviv S, Pasmanik-Chor M, Bell RE, Levy C, Avellino R, Banfi S, Conte I, and Ashery-Padan R

Subjects

Animals, Binding Sites, Cell Differentiation genetics, Crystallins genetics, Crystallins metabolism, Gene Expression Regulation, Gene Expression Regulation, Developmental, Mice, PAX6 Transcription Factor, SOXC Transcription Factors metabolism, TRPM Cation Channels genetics, TRPM Cation Channels metabolism, Vertebrates genetics, Vertebrates metabolism, Evolution, Molecular, Eye growth & development, Eye metabolism, Eye Proteins genetics, Eye Proteins metabolism, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, MicroRNAs genetics, MicroRNAs metabolism, Paired Box Transcription Factors genetics, Paired Box Transcription Factors metabolism, Repressor Proteins genetics, Repressor Proteins metabolism

Abstract

During development, tissue-specific transcription factors regulate both protein-coding and non-coding genes to control differentiation. Recent studies have established a dual role for the transcription factor Pax6 as both an activator and repressor of gene expression in the eye, central nervous system, and pancreas. However, the molecular mechanism underlying the inhibitory activity of Pax6 is not fully understood. Here, we reveal that Trpm3 and the intronic microRNA gene miR-204 are co-regulated by Pax6 during eye development. miR-204 is probably the best known microRNA to function as a negative modulator of gene expression during eye development in vertebrates. Analysis of genes altered in mouse Pax6 mutants during lens development revealed significant over-representation of miR-204 targets among the genes up-regulated in the Pax6 mutant lens. A number of new targets of miR-204 were revealed, among them Sox11, a member of the SoxC family of pro-neuronal transcription factors, and an important regulator of eye development. Expression of Trpm/miR-204 and a few of its targets are also Pax6-dependent in medaka fish eyes. Collectively, this study identifies a novel evolutionarily conserved mechanism by which Pax6 controls the down-regulation of multiple genes through direct up-regulation of miR-204., Competing Interests: The authors have declared that no competing interests exist.

Published

2013

8. Cop9 signalosome subunit 8 (CSN8) is essential for Drosophila development.

Author

Oren-Giladi P, Krieger O, Edgar BA, Chamovitz DA, and Segal D

Subjects

Adaptor Proteins, Signal Transducing, Animals, Animals, Genetically Modified, COP9 Signalosome Complex, Drosophila Proteins metabolism, Gene Targeting, Genes, Lethal, Intracellular Signaling Peptides and Proteins genetics, Larva genetics, Larva growth & development, Life Cycle Stages genetics, Meiosis, Mutation, Nuclear Proteins metabolism, Oogenesis genetics, Phenotype, RNA, Messenger genetics, Reverse Transcriptase Polymerase Chain Reaction, Drosophila genetics, Drosophila growth & development, Drosophila Proteins genetics, Melanoma genetics, Multiprotein Complexes genetics, Nuclear Proteins genetics, Peptide Hydrolases genetics

Abstract

The COP9 signalosome (CSN) is a multisubunit regulator highly conserved in evolution. We show here that CSN subunit 8 (CSN8) is essential for Drosophila development. CSN8 is maternally contributed and present throughout development. Null mutants generated in this study are larval lethal, showing phenotypes associated with mutations in either CSN4 (molting defects) or CSN5 (melanotic tumors). Analysis of mitotic and germ-line csn8(null) clones revealed the requirement of CSN8 for multiple developmental processes. The germ-line clones arrested at mid-oogenesis, while the mitotic clones led to deformed adult eyes or wings. CSN8 is present exclusively as part of the CSN holo-complex, and lack of CSN8 in the mutants leads to CSN instability. Consistent with this, Cullin deneddylation is impaired in the csn8(null) mutants.

Published

2008