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2. LAB-ANGIOGENESIS AND INVASION

Author

Proescholdt, M. A., primary, Merrill, M. J., additional, Stoerr, E.-M., additional, Lohmeier, A., additional, Brawanski, A., additional, Sim, H., additional, Hu, B., additional, Pineda, C. A., additional, Yoon, S.-O., additional, Viapiano, M. S., additional, Rajappa, P., additional, Cobb, W. S., additional, Huang, Y., additional, Lyden, D. C., additional, Bromberg, J., additional, Greenfield, J. P., additional, Li, M., additional, Mukasa, A., additional, Inda, M. d.-M., additional, Zhang, J., additional, Chin, L., additional, Cavenee, W., additional, Furnari, F., additional, Zheng, P.-P., additional, van der Weiden, M., additional, van der Spek, P. J., additional, Vincent, A. J., additional, Kros, J. M., additional, Fathallah-Shaykh, H. M., additional, Saut, O., additional, Lagaert, J.-B., additional, Colin, T., additional, Araysi, L., additional, Tang, Z., additional, Duck, K. A., additional, Ponnuru, P., additional, Neely, E. B., additional, Connor, J. R., additional, Esencay, M., additional, Gonzalez, P., additional, Gaziel, A., additional, Safraz, Y., additional, Mira, H., additional, Hernando, E., additional, Zagzag, D., additional, McDermott, R. A., additional, Ulasov, I., additional, Kaverina, N., additional, Gabikian, P., additional, Lesniak, M., additional, Iranmahboob, A., additional, Haber, M., additional, Fatterpekar, G., additional, Raz, E., additional, Placantonakis, D., additional, Eoli, M., additional, Rabascio, C., additional, Cuppini, L., additional, Anghileri, E., additional, Pellegatta, S., additional, Calleri, A., additional, Mancuso, P., additional, Porrati, P., additional, Bertolini, F., additional, Finocchiaro, G., additional, Seals, D. F., additional, Burger, K. L., additional, Gibo, D. M., additional, Debinski, W., additional, Tran, N. L., additional, Tuncali, S., additional, Kloss, J., additional, Yang, Z., additional, Schumacher, C. A., additional, Diegel, C., additional, Ross, J. T., additional, Williams, B. O., additional, Eschbacher, J. M., additional, Loftus, J. C., additional, Whiteman, M., additional, Dombovy-Johnson, M., additional, Vangellow, A., additional, Liu, Y., additional, Carson-Walter, E., additional, Walter, K. A., additional, Walter, K., additional, Cortes-Santiago, N., additional, Gabrusiewicz, K., additional, Liu, D., additional, Hossain, M. B., additional, Gumin, J., additional, Fan, X., additional, Conrad, C., additional, Aldape, K., additional, Gilbert, M., additional, Raghunathan, A., additional, Yung, W. K. A., additional, Fueyo, J., additional, Gomez-Manzano, C., additional, Bae, E., additional, Huang, P., additional, Burgett, M., additional, Muller-Greven, G., additional, Kar, N., additional, Gladson, C. L., additional, Engler, J. R., additional, Robinson, A. E., additional, Molinaro, A., additional, Phillips, J. J., additional, Zadeh, G., additional, Burrell, K., additional, Hill, R., additional, Piao, Y., additional, Liang, J., additional, Henry, V., additional, Holmes, L., additional, Sulman, E., additional, deGroot, J. F., additional, de Groot, J. F., additional, Rong, W., additional, Funato, K., additional, Georgala, P., additional, Shimizu, F., additional, Droms, L., additional, Tabar, V., additional, Parker, J. J., additional, Dionne, K. R., additional, Massarwa, R., additional, Klaassen, M., additional, Foreman, N. K., additional, Niswander, L., additional, Canoll, P., additional, Kleinschmidt-DeMasters, B. K., additional, and Waziri, A., additional

Published
2012
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3. ANGIOGENESIS AND INVASION

Author

Hu, Y.-L., primary, De Lay, M., additional, Rose, S. D., additional, Carbonell, W. S., additional, Aghi, M. K., additional, Hu, Y.-L., additional, Paquette, J., additional, Tokuyasu, T., additional, Tsao, S., additional, Chaumeil, M., additional, Ronen, S., additional, Matlaf, L. A., additional, Soroceanu, L., additional, Cobbs, C., additional, Matlaf, L., additional, Harkins, L., additional, Garzon-Muvdi, T., additional, Rhys, C. a., additional, Smith, C., additional, Kim, D.-H., additional, Kone, L., additional, Farber, H., additional, An, S., additional, Levchenko, A., additional, Quinones-Hinojosa, A., additional, Lemke, D., additional, Pfenning, P.-N., additional, Sahm, F., additional, Klein, A.-C., additional, Kempf, T., additional, Schnolzer, M., additional, Platten, M., additional, Wick, W., additional, Smith, S. J., additional, Rahman, R., additional, Rahman, C., additional, Barrow, J., additional, Macarthur, D., additional, Rose, F., additional, Grundy, R. G., additional, Kaley, T. J., additional, Huse, J., additional, Karimi, S., additional, Rosenblum, M., additional, Omuro, A., additional, DeAngelis, L. M., additional, de Groot, J. F., additional, Kong, L.-Y., additional, Wei, J., additional, Wang, T., additional, Piao, Y., additional, Liang, J., additional, Fuller, G. N., additional, Qiao, W., additional, Heimberger, A. B., additional, Jhaveri, N., additional, Cho, H., additional, Torres, S., additional, Wang, W., additional, Schonthal, A., additional, Petasis, N., additional, Louie, S. G., additional, Hofman, F., additional, Chen, T. C., additional, Yamada, R., additional, Sumual, S., additional, Buljan, V., additional, Bennett, M. R., additional, McDonald, K. L., additional, Weiler, M., additional, Thiepold, A.-L., additional, Jestaedt, L., additional, Gronych, J., additional, Dittmann, L. M., additional, Jugold, M., additional, Kosch, M., additional, Combs, S. E., additional, von Deimling, A., additional, Weller, M., additional, Bendszus, M., additional, Kwiatkowska, A., additional, Paulino, V., additional, Tran, N. L., additional, Symons, M., additional, Stockham, A. L., additional, Borden, E., additional, Peereboom, D., additional, Hu, Y., additional, Chaturbedi, A., additional, Hamamura, M., additional, Mark, E., additional, Zhou, Y.-H., additional, Abbadi, S., additional, Guerrero-Cazares, H., additional, Pistollato, F., additional, Smith, C. L., additional, Ruff, W., additional, Puppa, A. D., additional, Basso, G., additional, Monje, M., additional, Freret, M. E., additional, Masek, M., additional, Fisher, P. G., additional, Haddix, T., additional, Vogel, H., additional, Kijima, N., additional, Hosen, N., additional, Kagawa, N., additional, Hashimoto, N., additional, Fujimoto, Y., additional, Kinoshita, M., additional, Sugiyama, H., additional, Yoshimine, T., additional, Anneke, N., additional, Bob, H., additional, Pieter, W., additional, Arend, H., additional, William, L., additional, Eoli, M., additional, Calleri, A., additional, Cuppini, L., additional, Anghileri, E., additional, Pellegatta, S., additional, Prodi, E., additional, Bruzzone, M. G., additional, Bertolini, F., additional, Finocchiaro, G., additional, Zhu, D., additional, Hunter, S. B., additional, Vertino, P. M., additional, Van Meir, E. G., additional, Cork, S. M., additional, Kaur, B., additional, Cooper, L., additional, Saltz, J. H., additional, Sandberg, E. M., additional, Burrell, K., additional, Hill, R., additional, Zadeh, G., additional, Parker, J. J., additional, Dionne, K., additional, Massarwa, R., additional, Klaassen, M., additional, Niswander, L., additional, Kleinschmidt-DeMasters, B. K., additional, Waziri, A., additional, Jalali, S., additional, Wataya, T., additional, Salehi, F., additional, Croul, S., additional, Gentili, F., additional, Foltz, W., additional, Lee, J.-I., additional, Agnihorti, S., additional, Menard, C., additional, Chung, C., additional, Schonthal, A. H., additional, Hofman, F. M., additional, Elena, P., additional, Faivre, G., additional, Demopoulos, A., additional, Taillibert, S., additional, Kirsch, M., additional, Martin, K. D., additional, Bertram, A., additional, uckermann, O., additional, Leipnitz, E., additional, Weigel, P., additional, Temme, A., additional, Schackert, G., additional, Geiger, K., additional, Gerstner, E., additional, Jennings, D., additional, Chi, A. S., additional, Plotkin, S., additional, Kwon, S. J., additional, Pinho, M., additional, Polaskova, P., additional, Batchelor, T. T., additional, Sorensen, A. G., additional, Hossain, M. B., additional, Gururaj, A. E., additional, Cortes-Santiago, N., additional, Gabrusiewicz, K., additional, Yung, W. K. A., additional, Fueyo, J., additional, Gomez-Manzano, C., additional, Gil, O. D., additional, Noticewala, S., additional, Ivkovic, S., additional, Esencay, M., additional, Zagzagg, D., additional, Rosenfeld, S., additional, Bruce, J. N., additional, Canoll, P., additional, Chang, J. H., additional, Seol, H. J., additional, Weeks, A., additional, Smith, C. A., additional, Rutka, J. T., additional, Georges, J., additional, Samuelson, G., additional, Misra, A., additional, Joy, A., additional, Huang, Y., additional, McQuilkin, M., additional, Yoshihiro, A., additional, Carpenter, D., additional, Butler, L., additional, Feuerstein, B., additional, Murphy, S. F., additional, Vaghaiwalla, T., additional, Wotoczek-Obadia, M., additional, Albright, R., additional, Mack, D., additional, Lawn, S., additional, Henderson, F., additional, Jung, M., additional, Dakshanamurthy, S., additional, Brown, M., additional, Forsyth, P., additional, Brem, S., additional, Sadr, M. S., additional, Maret, D., additional, Sadr, E. S., additional, Siu, V., additional, Alshami, J., additional, Trinh, G., additional, Denault, J.-S., additional, Faury, D., additional, Jabado, N., additional, Nantel, A., additional, and Del Maestro, R., additional

Published
2011
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7. Principles of signaling pathway modulation for enhancing human naive pluripotency induction.

Author

Bayerl J, Ayyash M, Shani T, Manor YS, Gafni O, Massarwa R, Kalma Y, Aguilera-Castrejon A, Zerbib M, Amir H, Sheban D, Geula S, Mor N, Weinberger L, Naveh Tassa S, Krupalnik V, Oldak B, Livnat N, Tarazi S, Tawil S, Wildschutz E, Ashouokhi S, Lasman L, Rotter V, Hanna S, Ben-Yosef D, Novershtern N, Viukov S, and Hanna JH

Subjects
Animals, Cell Differentiation, Embryo, Mammalian, Humans, Mice, Signal Transduction, Trophoblasts, Pluripotent Stem Cells
Abstract

Isolating human MEK/ERK signaling-independent pluripotent stem cells (PSCs) with naive pluripotency characteristics while maintaining differentiation competence and (epi)genetic integrity remains challenging. Here, we engineer reporter systems that allow the screening for defined conditions that induce molecular and functional features of human naive pluripotency. Synergistic inhibition of WNT/β-CATENIN, protein kinase C (PKC), and SRC signaling consolidates the induction of teratoma-competent naive human PSCs, with the capacity to differentiate into trophoblast stem cells (TSCs) and extraembryonic naive endodermal (nEND) cells in vitro. Divergent signaling and transcriptional requirements for boosting naive pluripotency were found between mouse and human. P53 depletion in naive hPSCs increased their contribution to mouse-human cross-species chimeric embryos upon priming and differentiation. Finally, MEK/ERK inhibition can be substituted with the inhibition of NOTCH/RBPj, which induces alternative naive-like hPSCs with a diminished risk for deleterious global DNA hypomethylation. Our findings set a framework for defining the signaling foundations of human naive pluripotency., Competing Interests: Declaration of interests Two patent applications based on the findings reported in this work have been filed by the relevant authors, and some of the findings are being commercialized., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2021
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8. Ex utero mouse embryogenesis from pre-gastrulation to late organogenesis.

Author

Aguilera-Castrejon A, Oldak B, Shani T, Ghanem N, Itzkovich C, Slomovich S, Tarazi S, Bayerl J, Chugaeva V, Ayyash M, Ashouokhi S, Sheban D, Livnat N, Lasman L, Viukov S, Zerbib M, Addadi Y, Rais Y, Cheng S, Stelzer Y, Keren-Shaul H, Shlomo R, Massarwa R, Novershtern N, Maza I, and Hanna JH

Subjects
Animals, Embryo, Mammalian cytology, Female, Gastrulation, Male, Mice, Time Factors, Uterus, Embryo Culture Techniques methods, Embryo, Mammalian embryology, Embryonic Development, In Vitro Techniques, Organogenesis
Abstract

The mammalian body plan is established shortly after the embryo implants into the maternal uterus, and our understanding of post-implantation developmental processes remains limited. Although pre- and peri-implantation mouse embryos are routinely cultured in vitro 1,2 , approaches for the robust culture of post-implantation embryos from egg cylinder stages until advanced organogenesis remain to be established. Here we present highly effective platforms for the ex utero culture of post-implantation mouse embryos, which enable the appropriate development of embryos from before gastrulation (embryonic day (E) 5.5) until the hindlimb formation stage (E11). Late gastrulating embryos (E7.5) are grown in three-dimensional rotating bottles, whereas extended culture from pre-gastrulation stages (E5.5 or E6.5) requires a combination of static and rotating bottle culture platforms. Histological, molecular and single-cell RNA sequencing analyses confirm that the ex utero cultured embryos recapitulate in utero development precisely. This culture system is amenable to the introduction of a variety of embryonic perturbations and micro-manipulations, the results of which can be followed ex utero for up to six days. The establishment of a system for robustly growing normal mouse embryos ex utero from pre-gastrulation to advanced organogenesis represents a valuable tool for investigating embryogenesis, as it eliminates the uterine barrier and allows researchers to mechanistically interrogate post-implantation morphogenesis and artificial embryogenesis in mammals.

Published
2021
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9. Deterministic Somatic Cell Reprogramming Involves Continuous Transcriptional Changes Governed by Myc and Epigenetic-Driven Modules.

Author

Zviran A, Mor N, Rais Y, Gingold H, Peles S, Chomsky E, Viukov S, Buenrostro JD, Scognamiglio R, Weinberger L, Manor YS, Krupalnik V, Zerbib M, Hezroni H, Jaitin DA, Larastiaso D, Gilad S, Benjamin S, Gafni O, Mousa A, Ayyash M, Sheban D, Bayerl J, Aguilera-Castrejon A, Massarwa R, Maza I, Hanna S, Stelzer Y, Ulitsky I, Greenleaf WJ, Tanay A, Trumpp A, Amit I, Pilpel Y, Novershtern N, and Hanna JH

Subjects
Animals, Cell Lineage genetics, Chromatin metabolism, Demethylation, Humans, Induced Pluripotent Stem Cells metabolism, Kruppel-Like Factor 4, Mice, Protein Binding, RNA, Transfer metabolism, Transcription Factors metabolism, Cellular Reprogramming genetics, Epigenesis, Genetic, Proto-Oncogene Proteins c-myc metabolism, Transcription, Genetic
Abstract

The epigenetic dynamics of induced pluripotent stem cell (iPSC) reprogramming in correctly reprogrammed cells at high resolution and throughout the entire process remain largely undefined. Here, we characterize conversion of mouse fibroblasts into iPSCs using Gatad2a-Mbd3/NuRD-depleted and highly efficient reprogramming systems. Unbiased high-resolution profiling of dynamic changes in levels of gene expression, chromatin engagement, DNA accessibility, and DNA methylation were obtained. We identified two distinct and synergistic transcriptional modules that dominate successful reprogramming, which are associated with cell identity and biosynthetic genes. The pluripotency module is governed by dynamic alterations in epigenetic modifications to promoters and binding by Oct4, Sox2, and Klf4, but not Myc. Early DNA demethylation at certain enhancers prospectively marks cells fated to reprogram. Myc activity drives expression of the essential biosynthetic module and is associated with optimized changes in tRNA codon usage. Our functional validations highlight interweaved epigenetic- and Myc-governed essential reconfigurations that rapidly commission and propel deterministic reprogramming toward naive pluripotency., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published
2019
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10. Neutralizing Gatad2a-Chd4-Mbd3/NuRD Complex Facilitates Deterministic Induction of Naive Pluripotency.

Author

Mor N, Rais Y, Sheban D, Peles S, Aguilera-Castrejon A, Zviran A, Elinger D, Viukov S, Geula S, Krupalnik V, Zerbib M, Chomsky E, Lasman L, Shani T, Bayerl J, Gafni O, Hanna S, Buenrostro JD, Hagai T, Masika H, Vainorius G, Bergman Y, Greenleaf WJ, Esteban MA, Elling U, Levin Y, Massarwa R, Merbl Y, Novershtern N, and Hanna JH

Subjects
Animals, Cells, Cultured, Female, Induced Pluripotent Stem Cells cytology, Male, Mice, Mice, Inbred C57BL, Mice, Inbred CBA, Mice, Knockout, Mice, Transgenic, DNA Helicases metabolism, DNA-Binding Proteins metabolism, GATA Transcription Factors metabolism, Induced Pluripotent Stem Cells metabolism, Mi-2 Nucleosome Remodeling and Deacetylase Complex metabolism, Transcription Factors metabolism
Abstract

Mbd3, a member of nucleosome remodeling and deacetylase (NuRD) co-repressor complex, was previously identified as an inhibitor for deterministic induced pluripotent stem cell (iPSC) reprogramming, where up to 100% of donor cells successfully complete the process. NuRD can assume multiple mutually exclusive conformations, and it remains unclear whether this deterministic phenotype can be attributed to a specific Mbd3/NuRD subcomplex. Moreover, since complete ablation of Mbd3 blocks somatic cell proliferation, we aimed to explore functionally relevant alternative ways to neutralize Mbd3-dependent NuRD activity. We identify Gatad2a, a NuRD-specific subunit, whose complete deletion specifically disrupts Mbd3/NuRD repressive activity on the pluripotency circuitry during iPSC differentiation and reprogramming without ablating somatic cell proliferation. Inhibition of Gatad2a facilitates deterministic murine iPSC reprogramming within 8 days. We validate a distinct molecular axis, Gatad2a-Chd4-Mbd3, within Mbd3/NuRD as being critical for blocking reestablishment of naive pluripotency and further highlight signaling-dependent and post-translational modifications of Mbd3/NuRD that influence its interactions and assembly., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published
2018
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11. Establishing the human naïve pluripotent state.

Author

Manor YS, Massarwa R, and Hanna JH

Subjects
Animals, Blastocyst cytology, Blastocyst metabolism, Cell Lineage genetics, Embryonic Stem Cells metabolism, Germ Layers growth & development, Germ Layers metabolism, Humans, Mice, Pluripotent Stem Cells metabolism, Cell Differentiation genetics, Cellular Reprogramming genetics, Embryonic Stem Cells cytology, Pluripotent Stem Cells cytology
Abstract

Pluripotency is first assembled within the inner-cell-mass of developing pre-implantation blastocysts, and is gradually reconfigured and dismantled during early post-implantation development, before overt differentiation into somatic lineages ensues. This transition from pre-implantation to post-implantation pluripotent states, respectively referred to as naïve and primed, is accompanied by dramatic changes in molecular and functional characteristics. Remarkably, pluripotent states can be artificially preserved in a self-renewing state in vitro by continuous supplementation of a variety of exogenous cytokines and small molecule inhibitors. Different exogenous factors endow the cells with distinct configurations of pluripotency that have direct influence on stem cell characteristics both in mice and humans. Here we overview pluripotent states captured from rodents and humans under different growth conditions, and provide a conceptual framework for classifying pluripotent cell states on the basis of a combination of multiple characteristics that a pluripotent cell can simultaneously retain. We further highlight the complexity and dynamic nature of these artificially isolated in vitro pluripotent states in humans., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published
2015
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12. Transient acquisition of pluripotency during somatic cell transdifferentiation with iPSC reprogramming factors.

Author

Maza I, Caspi I, Zviran A, Chomsky E, Rais Y, Viukov S, Geula S, Buenrostro JD, Weinberger L, Krupalnik V, Hanna S, Zerbib M, Dutton JR, Greenleaf WJ, Massarwa R, Novershtern N, and Hanna JH

Subjects
Animals, Cells, Cultured, Female, Kruppel-Like Factor 4, Male, Mice, Mice, Transgenic, Cell Transdifferentiation genetics, Cellular Reprogramming genetics, Induced Pluripotent Stem Cells physiology, Transcription Factors metabolism
Abstract

Somatic cells can be transdifferentiated to other cell types without passing through a pluripotent state by ectopic expression of appropriate transcription factors. Recent reports have proposed an alternative transdifferentiation method in which fibroblasts are directly converted to various mature somatic cell types by brief expression of the induced pluripotent stem cell (iPSC) reprogramming factors Oct4, Sox2, Klf4 and c-Myc (OSKM) followed by cell expansion in media that promote lineage differentiation. Here we test this method using genetic lineage tracing for expression of endogenous Nanog and Oct4 and for X chromosome reactivation, as these events mark acquisition of pluripotency. We show that the vast majority of reprogrammed cardiomyocytes or neural stem cells obtained from mouse fibroblasts by OSKM-induced 'transdifferentiation' pass through a transient pluripotent state, and that their derivation is molecularly coupled to iPSC formation mechanisms. Our findings underscore the importance of defining trajectories during cell reprogramming by various methods.

Published
2015
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14. Stem cells. m6A mRNA methylation facilitates resolution of naïve pluripotency toward differentiation.

Author

Geula S, Moshitch-Moshkovitz S, Dominissini D, Mansour AA, Kol N, Salmon-Divon M, Hershkovitz V, Peer E, Mor N, Manor YS, Ben-Haim MS, Eyal E, Yunger S, Pinto Y, Jaitin DA, Viukov S, Rais Y, Krupalnik V, Chomsky E, Zerbib M, Maza I, Rechavi Y, Massarwa R, Hanna S, Amit I, Levanon EY, Amariglio N, Stern-Ginossar N, Novershtern N, Rechavi G, and Hanna JH

Subjects
Adenosine metabolism, Animals, Blastocyst enzymology, Cell Differentiation genetics, Cell Line, Embryo Loss genetics, Epigenesis, Genetic, Female, Gene Knockout Techniques, Male, Methylation, Methyltransferases genetics, Mice, Mice, Knockout, Pluripotent Stem Cells enzymology, Adenosine analogs & derivatives, Cell Differentiation physiology, Methyltransferases physiology, Pluripotent Stem Cells cytology, RNA, Messenger metabolism
Abstract

Naïve and primed pluripotent states retain distinct molecular properties, yet limited knowledge exists on how their state transitions are regulated. Here, we identify Mettl3, an N(6)-methyladenosine (m(6)A) transferase, as a regulator for terminating murine naïve pluripotency. Mettl3 knockout preimplantation epiblasts and naïve embryonic stem cells are depleted for m(6)A in mRNAs, yet are viable. However, they fail to adequately terminate their naïve state and, subsequently, undergo aberrant and restricted lineage priming at the postimplantation stage, which leads to early embryonic lethality. m(6)A predominantly and directly reduces mRNA stability, including that of key naïve pluripotency-promoting transcripts. This study highlights a critical role for an mRNA epigenetic modification in vivo and identifies regulatory modules that functionally influence naïve and primed pluripotency in an opposing manner., (Copyright © 2015, American Association for the Advancement of Science.)

Published
2015
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15. Histopathological evaluation of the effects of variable extraoral dry times and enamel matrix proteins (enamel matrix derivatives) application on replanted dogs' teeth.

Author

Barbizam JV, Massarwa R, da Silva LA, da Silva RA, Nelson-Filho P, Consolaro A, and Cohenca N

Subjects
Animals, Dental Amalgam, Dogs, Periodontal Ligament cytology, Root Canal Therapy, Time Factors, Tooth Avulsion, Wound Healing, Bicuspid surgery, Dental Enamel Proteins pharmacology, Tooth Replantation methods, Tooth Root surgery
Abstract

The extra-alveolar dry period and storage medium in which the tooth was kept prior to replantation remain the critical factors affecting the survival and regeneration of the damaged periodontium. When the replantation is delayed, replacement root resorption is the most common complication following replantation of an avulsed tooth. The aim of this histological study was to evaluate the periodontal healing of replanted dogs' teeth after 20 min (short) and 60 min (long) extraoral dry time with and without the application of enamel matrix proteins. Eighty mature premolar roots (40 teeth) maxillary and mandibular premolars were extracted, the root canals were accessed, instrumented, and filled using a lateral condensation technique, and the access cavity was restored with amalgam. Each root was randomly assigned to one of experimental groups: Groups I and II: Roots were replanted after an extraoral dry time of 20 min. In group II, Emdogain(®) (Biora, Malmo, Sweden) was applied directly to the external root surface with complete coverage. Groups III and IV: Roots were replanted after an extraoral dry time of 60 min. In group IV, Emdogain(®) was applied to the whole external root surface before replantation. Roots that replanted within a total extraoral dry time of 10 min were used as negative controls, while those replanted after 90 min of extraoral dry time were assigned as positive controls. After 4 months, the dogs were euthanized, and the maxillary and mandibular processes were processed for histology and microscopically evaluated. Statistical analysis showed no significant differences (P = 0.1075) among the experimental groups. The results of this study show that 20 min of extraoral dry time is as detrimental to the PDL cells as 60 or 90 min of extraoral dry time, with avulsed dogs' teeth, even when replanted with an inductive material such as EMD. This study provides strong evidence in relation to the threshold of the extraoral dry time of avulsed teeth, suggesting that the extraoral dry time threshold of PDL cell viability is significantly less than that which current guidelines promote., (© 2014 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published
2015
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16. N-wasp is required for structural integrity of the blood-testis barrier.

Author

Xiao X, Mruk DD, Tang EI, Massarwa R, Mok KW, Li N, Wong CK, Lee WM, Snapper SB, Shilo BZ, Schejter ED, and Cheng CY

Subjects
Actin-Related Protein 2-3 Complex metabolism, Actins genetics, Actins metabolism, Animals, Male, Mice, Seminiferous Epithelium metabolism, Sertoli Cells metabolism, Spermatids metabolism, Spermatocytes growth & development, Spermatocytes metabolism, Testis metabolism, Actin-Related Protein 2-3 Complex genetics, Blood-Testis Barrier, Spermatogenesis genetics, Wiskott-Aldrich Syndrome Protein, Neuronal genetics
Abstract

During spermatogenesis, the blood-testis barrier (BTB) segregates the adluminal (apical) and basal compartments in the seminiferous epithelium, thereby creating a privileged adluminal environment that allows post-meiotic spermatid development to proceed without interference of the host immune system. A key feature of the BTB is its continuous remodeling within the Sertoli cells, the major somatic component of the seminiferous epithelium. This remodeling is necessary to allow the transport of germ cells towards the seminiferous tubule interior, while maintaining intact barrier properties. Here we demonstrate that the actin nucleation promoting factor Neuronal Wiskott-Aldrich Syndrome Protein (N-WASP) provides an essential function necessary for BTB restructuring, and for maintaining spermatogenesis. Our data suggests that the N-WASP-Arp2/3 actin polymerization machinery generates branched-actin arrays at an advanced stage of BTB remodeling. These arrays are proposed to mediate the restructuring process through endocytic recycling of BTB components. Disruption of N-WASP in Sertoli cells results in major structural abnormalities to the BTB, including mis-localization of critical junctional and cytoskeletal elements, and leads to disruption of barrier function. These impairments result in a complete arrest of spermatogenesis, underscoring the critical involvement of the somatic compartment of the seminiferous tubules in germ cell maturation.

Published
2014
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17. Morphogenetic movements in the neural plate and neural tube: mouse.

Author

Massarwa R, Ray HJ, and Niswander L

Subjects
Anencephaly genetics, Anencephaly pathology, Animals, Mice, Neural Plate pathology, Neural Tube pathology, Neural Tube Defects genetics, Neural Tube Defects pathology, Spinal Dysraphism genetics, Spinal Dysraphism pathology, Morphogenesis, Neural Crest growth & development, Neural Plate growth & development, Neural Tube growth & development
Abstract

The neural tube (NT), the embryonic precursor of the vertebrate brain and spinal cord, is generated by a complex and highly dynamic morphological process. In mammals, the initially flat neural plate bends and lifts bilaterally to generate the neural folds followed by fusion of the folds at the midline during the process of neural tube closure (NTC). Failures in any step of this process can lead to neural tube defects (NTDs), a common class of birth defects that occur in approximately 1 in 1000 live births. These severe birth abnormalities include spina bifida, a failure of closure at the spinal level; craniorachischisis, a failure of NTC along the entire body axis; and exencephaly, a failure of the cranial neural folds to close which leads to degeneration of the exposed brain tissue termed anencephaly. The mouse embryo presents excellent opportunities to explore the genetic basis of NTC in mammals; however, its in utero development has also presented great challenges in generating a deeper understanding of how gene function regulates the cell and tissue behaviors that drive this highly dynamic process. Recent technological advances are now allowing researchers to address these questions through visualization of NTC dynamics in the mouse embryo in real time, thus offering new insights into the morphogenesis of mammalian NTC., (© 2013 Wiley Periodicals, Inc.)

Published
2014
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18. Derivation of novel human ground state naive pluripotent stem cells.

Author

Gafni O, Weinberger L, Mansour AA, Manor YS, Chomsky E, Ben-Yosef D, Kalma Y, Viukov S, Maza I, Zviran A, Rais Y, Shipony Z, Mukamel Z, Krupalnik V, Zerbib M, Geula S, Caspi I, Schneir D, Shwartz T, Gilad S, Amann-Zalcenstein D, Benjamin S, Amit I, Tanay A, Massarwa R, Novershtern N, and Hanna JH

Subjects
Animals, Blastocyst cytology, Cellular Reprogramming, Chimera embryology, Chromatin metabolism, DNA Methylation, Embryo, Mammalian cytology, Embryo, Mammalian embryology, Embryonic Stem Cells cytology, Embryonic Stem Cells metabolism, Epigenesis, Genetic, Female, Germ Layers cytology, Histones metabolism, Humans, Induced Pluripotent Stem Cells metabolism, Induced Pluripotent Stem Cells transplantation, Male, Mice, Morula cytology, Organogenesis, Promoter Regions, Genetic genetics, Regenerative Medicine, Reproducibility of Results, Signal Transduction, X Chromosome Inactivation, Induced Pluripotent Stem Cells cytology
Abstract

Mouse embryonic stem (ES) cells are isolated from the inner cell mass of blastocysts, and can be preserved in vitro in a naive inner-cell-mass-like configuration by providing exogenous stimulation with leukaemia inhibitory factor (LIF) and small molecule inhibition of ERK1/ERK2 and GSK3β signalling (termed 2i/LIF conditions). Hallmarks of naive pluripotency include driving Oct4 (also known as Pou5f1) transcription by its distal enhancer, retaining a pre-inactivation X chromosome state, and global reduction in DNA methylation and in H3K27me3 repressive chromatin mark deposition on developmental regulatory gene promoters. Upon withdrawal of 2i/LIF, naive mouse ES cells can drift towards a primed pluripotent state resembling that of the post-implantation epiblast. Although human ES cells share several molecular features with naive mouse ES cells, they also share a variety of epigenetic properties with primed murine epiblast stem cells (EpiSCs). These include predominant use of the proximal enhancer element to maintain OCT4 expression, pronounced tendency for X chromosome inactivation in most female human ES cells, increase in DNA methylation and prominent deposition of H3K27me3 and bivalent domain acquisition on lineage regulatory genes. The feasibility of establishing human ground state naive pluripotency in vitro with equivalent molecular and functional features to those characterized in mouse ES cells remains to be defined. Here we establish defined conditions that facilitate the derivation of genetically unmodified human naive pluripotent stem cells from already established primed human ES cells, from somatic cells through induced pluripotent stem (iPS) cell reprogramming or directly from blastocysts. The novel naive pluripotent cells validated herein retain molecular characteristics and functional properties that are highly similar to mouse naive ES cells, and distinct from conventional primed human pluripotent cells. This includes competence in the generation of cross-species chimaeric mouse embryos that underwent organogenesis following microinjection of human naive iPS cells into mouse morulas. Collectively, our findings establish new avenues for regenerative medicine, patient-specific iPS cell disease modelling and the study of early human development in vitro and in vivo.

Published
2013
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19. In toto live imaging of mouse morphogenesis and new insights into neural tube closure.

Author

Massarwa R and Niswander L

Subjects
Animals, Cell Differentiation genetics, Female, Male, Mice, Mice, Transgenic, Molecular Imaging methods, Neural Plate cytology, Neurulation genetics, Skull cytology, Skull embryology, Video Recording methods, Neural Tube cytology, Neural Tube embryology
Abstract

In the field of developmental biology, live imaging is a powerful tool for studying, in real time, the dynamic behaviors of tissues and cells during organ formation. Mammals, which develop in utero, have presented a challenge for live imaging. Here, we offer a novel, prolonged and robust live imaging system for visualizing the development of a variety of embryonic tissues in the midgestation mouse embryo. We demonstrate the advantages of this imaging system by following the dynamics of neural tube closure during mouse embryogenesis and reveal extensive movements of the cranial neural tissue that are independent of neural fold zipping.

Published
2013
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20. Making muscles: Arp, two, three.

Author

Gildor B, Massarwa R, Shilo BZ, and Schejter ED

Subjects
Animals, Cell Fusion, Microfilament Proteins physiology, Models, Biological, Myoblasts physiology, Wiskott-Aldrich Syndrome Protein physiology, Actin-Related Protein 2-3 Complex physiology, Drosophila Proteins physiology, Drosophila melanogaster embryology, Drosophila melanogaster physiology, Muscle Development physiology
Abstract

In Drosophila embryos, muscle fiber formation via myoblast fusion relies on essential contributions made by the conserved Arp2/3 microfilament nucleation machinery. Two key nucleation promoting factors (NPFs), SCAR and WASp, have been shown to mediate this aspect of Arp2/3 function. We have used these unique circumstances, to study the requirements and coordination of distinct NPF activities, within a common developmental setting. Our results suggest that, although operating within close spatial and temporal proximity, the two regulators of actin polymerization are used in a step-wise manner and perform separate functional roles. Our approach also allows us to assess the involvement of the Arp2/3 machinery in formation of a distinct, fusion-associated actin structure.

Published
2010
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21. The SCAR and WASp nucleation-promoting factors act sequentially to mediate Drosophila myoblast fusion.

Author

Gildor B, Massarwa R, Shilo BZ, and Schejter ED

Subjects
Actins metabolism, Animals, Cell Fusion, Cell Movement, Drosophila Proteins genetics, Drosophila melanogaster embryology, Drosophila melanogaster genetics, Gene Expression Regulation, Developmental, Microfilament Proteins genetics, Microscopy, Electron, Phenotype, Wiskott-Aldrich Syndrome Protein genetics, Cell Nucleus metabolism, Drosophila Proteins metabolism, Drosophila melanogaster cytology, Drosophila melanogaster metabolism, Microfilament Proteins metabolism, Myoblasts cytology, Myoblasts metabolism, Wiskott-Aldrich Syndrome Protein metabolism
Abstract

The actin nucleation-promoting factors SCAR/WAVE and WASp, together with associated elements, mediate the formation of muscle fibres through myoblast fusion during Drosophila embryogenesis. Our phenotypic analysis, following the disruption of these two pathways, suggests that they function in a sequential manner. Suppressor of cyclic AMP receptor (SCAR) activity is required before the formation of pores in the membranes of fusing cells, whereas Wiskott-Aldrich syndrome protein (WASp) promotes the expansion of nascent pores and completion of the fusion process. Genetic epistasis experiments are consistent with this step-wise temporal progression. Our observations further imply a separate, Rac-dependent role for the SCAR complex in promoting myoblast migration. In keeping with the sequential utilization of the two systems, we observe abnormal accumulations of filamentous actin at the fusion sites when both pathways are disrupted, resembling those present when only SCAR-complex function is impaired. This observation further suggests that actin-filament accumulation at the fusion sites might not depend on Arp2/3 activity altogether.

Published
2009
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22. Apical secretion in epithelial tubes of the Drosophila embryo is directed by the Formin-family protein Diaphanous.

Author

Massarwa R, Schejter ED, and Shilo BZ

Subjects
Actin Cytoskeleton metabolism, Actins metabolism, Animals, Biological Transport, Carrier Proteins genetics, Drosophila Proteins genetics, Drosophila melanogaster metabolism, Embryo, Nonmammalian metabolism, Formins, Gene Expression Regulation, Developmental, Guanine Nucleotide Exchange Factors metabolism, Mutation genetics, Myosin Type V metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, Rho Guanine Nucleotide Exchange Factors, Secretory Vesicles metabolism, rho GTP-Binding Proteins metabolism, Carrier Proteins metabolism, Cell Polarity, Drosophila Proteins metabolism, Drosophila melanogaster cytology, Drosophila melanogaster embryology, Embryo, Nonmammalian cytology, Epithelium metabolism, Microfilament Proteins metabolism
Abstract

Apical localization of filamentous actin (F-actin) is a common feature of epithelial tubes in multicellular organisms. However, its origins and function are not known. We demonstrate that the Diaphanous (Dia)/Formin actin-nucleating factor is required for generation of apical F-actin in diverse types of epithelial tubes in the Drosophila embryo. Dia itself is apically localized both at the RNA and protein levels, and apical localization of its activators, including Rho1 and two guanine exchange factor proteins (Rho-GEFs), contributes to its activity. In the absence of apical actin polymerization, apical-basal polarity and microtubule organization of tubular epithelial cells remain intact; however, secretion through the apical surface to the lumen of tubular organs is blocked. Apical secretion also requires the Myosin V (MyoV) motor, implying that secretory vesicles are targeted to the apical membrane by MyoV-based transport, along polarized actin filaments nucleated by Dia. This mechanism allows efficient utilization of the entire apical membrane for secretion.

Published
2009
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23. WIP/WASp-based actin-polymerization machinery is essential for myoblast fusion in Drosophila.

Author

Massarwa R, Carmon S, Shilo BZ, and Schejter ED

Subjects
Animals, Animals, Genetically Modified, Cell Fusion, Cell Line, Drosophila Proteins genetics, Drosophila melanogaster embryology, Drosophila melanogaster genetics, Drosophila melanogaster physiology, Embryo, Nonmammalian, Immunoglobulins metabolism, Models, Biological, Muscles embryology, Muscles metabolism, Myoblasts metabolism, Wiskott-Aldrich Syndrome Protein genetics, Actins metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Muscle Development, Myoblasts physiology, Wiskott-Aldrich Syndrome Protein metabolism
Abstract

Formation of syncytial muscle fibers involves repeated rounds of cell fusion between growing myotubes and neighboring myoblasts. We have established that Wsp, the Drosophila homolog of the WASp family of microfilament nucleation-promoting factors, is an essential facilitator of myoblast fusion in Drosophila embryos. D-WIP, a homolog of the conserved Verprolin/WASp Interacting Protein family of WASp-binding proteins, performs a key mediating role in this context. D-WIP, which is expressed specifically in myoblasts, associates with both the WASp-Arp2/3 system and with the myoblast adhesion molecules Dumbfounded and Sticks and Stones, thereby recruiting the actin-polymerization machinery to sites of myoblast attachment and fusion. Our analysis demonstrates that this recruitment is normally required late in the fusion process, for enlargement of nascent fusion pores and breakdown of the apposed cell membranes. These observations identify cellular and developmental roles for the WASp-Arp2/3 pathway, and provide a link between force-generating actin polymerization and cell fusion.

Published
2007
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24. Axoplasmic importins enable retrograde injury signaling in lesioned nerve.

Author

Hanz S, Perlson E, Willis D, Zheng JQ, Massarwa R, Huerta JJ, Koltzenburg M, Kohler M, van-Minnen J, Twiss JL, and Fainzilber M

Subjects
Animals, Cells, Cultured, Humans, Karyopherins genetics, Male, Mice, Mice, Inbred C57BL, RNA, Messenger biosynthesis, RNA, Messenger genetics, Rats, Rats, Sprague-Dawley, Retrograde Degeneration genetics, Sciatic Neuropathy genetics, Up-Regulation physiology, Axonal Transport physiology, Karyopherins biosynthesis, Retrograde Degeneration metabolism, Sciatic Neuropathy metabolism
Abstract

Axoplasmic proteins containing nuclear localization signals (NLS) signal retrogradely by an unknown mechanism in injured nerve. Here we demonstrate that the importin/karyopherin alpha and beta families underlie this process. We show that importins are found in axons at significant distances from the cell body and that importin beta protein is increased after nerve lesion by local translation of axonal mRNA. This leads to formation of a high-affinity NLS binding complex that traffics retrogradely with the motor protein dynein. Trituration of synthetic NLS peptide at the injury site of axotomized dorsal root ganglion (DRG) neurons delays their regenerative outgrowth, and NLS introduction to sciatic nerve concomitantly with a crush injury suppresses the conditioning lesion induced transition from arborizing to elongating growth in L4/L5 DRG neurons. These data suggest a model whereby lesion-induced upregulation of axonal importin beta may enable retrograde transport of signals that modulate the regeneration of injured neurons.

Published
2003
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