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3. Patient-reported outcomes (PROs) including treatment expectation and satisfaction in HR+/HER2- Advanced Breast Cancer patients treated: Real-world Results of the PERFORM study from interim analysis 3 (IA3).

Author

Bjelic-Radisic, V., Korell, M., Pfeiler, G., Radosa, J., Decker, T., Deryal, M., Fietz, T., Köhler, A., Schöttker, B., Wilke, J., Knoblich, J., Petersen, V., Dietrich, M., Gabrysiak, T., Kontou, M., Glasstetter, M., Oppermann, U., Glastetter, E., Adams, A., and Bartsch, R.

Published
2024
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4. LifeTime and improving European healthcare through cell-based interceptive medicine

Author

Rajewsky, N., Almouzni, G., Gorski, S., Aerts, S., Amit, I., Bertero, M., Bock, C., Bredenoord, A., Cavalli, G., Chiocca, S., Clevers, H., Strooper, B., Eggert, A., Ellenberg, J., Fernández, X., Figlerowicz, M., Gasser, S., Hubner, N., Kjems, J., Knoblich, J., Krabbe, G., Lichter, P., Linnarsson, S., Marine, J., Marioni, J., Marti-Renom, M., Netea, M., Nickel, D., Nollmann, M., Novak, H., Parkinson, H., Piccolo, S., Pinheiro, I., Pombo, A., Popp, C., Reik, W., Roman-Roman, S., Rosenstiel, P., Schultze, J., Stegle, O., Tanay, A., Testa, G., Thanos, D., Theis, F., Torres-Padilla, M., Valencia, A., Vallot, C., van Oudenaarden, A., Vidal, M., Voet, T., Alberi, L., Alexander, S., Alexandrov, T., Arenas, E., Bagni, C., Balderas, R., Bandelli, A., Becher, B., Becker, M., Beerenwinkel, N., Benkirame, M., Beyer, M., Bickmore, W., Biessen, E., Blomberg, N., Blumcke, I., Bodenmiller, B., Borroni, B., Boumpas, D., Bourgeron, T., Bowers, S., Braeken, D., Brooksbank, C., Brose, N., Bruining, H., Bury, J., Caporale, N., Cattoretti, G., Chabane, N., Chneiweiss, H., Cook, S., Curatolo, P., de Jonge, M., Deplancke, B., de Witte, P., Dimmeler, S., Draganski, B., Drews, A., Dumbrava, C., Engelhardt, S., Gasser, T., Giamarellos-Bourboulis, E., Graff, C., Grün, D., Gut, I., Hansson, O., Henshall, D., Herland, A., Heutink, P., Heymans, S., Heyn, H., Huch, M., Huitinga, I., Jackowiak, P., Jongsma, K., Journot, L., Junker, J., Katz, S., Kehren, J., Kempa, S., Kirchhof, P., Klein, C., Koralewska, N., Korbel, J., Kühnemund, M., Lamond, A., Lauwers, E., Le Ber, I., Leinonen, V., Tobon, A., Lundberg, E., Lunkes, A., Maatz, H., Mann, M., Marelli, L., Matser, V., Matthews, P., Mechta-Grigoriou, F., Menon, R., Nielsen, A., Pagani, M., Pasterkamp, R., Pitkänen, A., Popescu, V., Pottier, C., Puisieux, A., Rademakers, R., Reiling, D., Reiner, O., Remondini, D., Ritchie, C., Rohrer, J., Saliba, A., Sanchez-Valle, R., Santosuosso, A., Sauter, A., Scheltema, R., Scheltens, P., Schiller, H., Schneider, A., Seibler, P., Sheehan-Rooney, K., Shields, D., Sleegers, K., Smit, A., Smith, K., Smolders, I., Synofzik, M., Tam, W., Teichmann, S., Thom, M., Turco, M., van Beusekom, H., Vandenberghe, R., den Hoecke, S., de Poel, I., van der Ven, A., van der Zee, J., van Lunzen, J., van Minnebruggen, G., Paesschen, W., van Swieten, J., van Vught, R., Verhage, M., Verstreken, P., Villa, C., Vogel, J., von Kalle, C., Walter, J., Weckhuysen, S., Weichert, W., Wood, L., Ziegler, A., Zipp, F., HZI,Helmholtz-Zentrum für Infektionsforschung GmbH, Inhoffenstr. 7,38124 Braunschweig, Germany., Medical Research Council (MRC), UK DRI Ltd, TWINCORE, Zentrum für experimentelle und klinische Infektionsforschung GmbH,Feodor-Lynen Str. 7, 30625 Hannover, Germany., Barcelona Supercomputing Center, LifeTime Community Working Groups, Cardiology, Neurology, Institut de génétique humaine (IGH), Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS), Amsterdam Neuroscience - Cellular & Molecular Mechanisms, Human genetics, Rajewsky N., Almouzni G., Gorski S.A., Aerts S., Amit I., Bertero M.G., Bock C., Bredenoord A.L., Cavalli G., Chiocca S., Clevers H., De Strooper B., Eggert A., Ellenberg J., Fernandez X.M., Figlerowicz M., Gasser S.M., Hubner N., Kjems J., Knoblich J.A., Krabbe G., Lichter P., Linnarsson S., Marine J.-C., Marioni J.C., Marti-Renom M.A., Netea M.G., Nickel D., Nollmann M., Novak H.R., Parkinson H., Piccolo S., Pinheiro I., Pombo A., Popp C., Reik W., Roman-Roman S., Rosenstiel P., Schultze J.L., Stegle O., Tanay A., Testa G., Thanos D., Theis F.J., Torres-Padilla M.-E., Valencia A., Vallot C., van Oudenaarden A., Vidal M., Voet T., Alberi L., Alexander S., Alexandrov T., Arenas E., Bagni C., Balderas R., Bandelli A., Becher B., Becker M., Beerenwinkel N., Benkirame M., Beyer M., Bickmore W., Biessen E.E.A.L., Blomberg N., Blumcke I., Bodenmiller B., Borroni B., Boumpas D.T., Bourgeron T., Bowers S., Braeken D., Brooksbank C., Brose N., Bruining H., Bury J., Caporale N., Cattoretti G., Chabane N., Chneiweiss H., Cook S.A., Curatolo P., de Jonge M.I., Deplancke B., de Witte P., Dimmeler S., Draganski B., Drews A., Dumbrava C., Engelhardt S., Gasser T., Giamarellos-Bourboulis E.J., Graff C., Grun D., Gut I., Hansson O., Henshall D.C., Herland A., Heutink P., Heymans S.R.B., Heyn H., Huch M., Huitinga I., Jackowiak P., Jongsma K.R., Journot L., Junker J.P., Katz S., Kehren J., Kempa S., Kirchhof P., Klein C., Koralewska N., Korbel J.O., Kuhnemund M., Lamond A.I., Lauwers E., Le Ber I., Leinonen V., Tobon A.L., Lundberg E., Lunkes A., Maatz H., Mann M., Marelli L., Matser V., Matthews P.M., Mechta-Grigoriou F., Menon R., Nielsen A.F., Pagani M., Pasterkamp R.J., Pitkanen A., Popescu V., Pottier C., Puisieux A., Rademakers R., Reiling D., Reiner O., Remondini D., Ritchie C., Rohrer J.D., Saliba A.-E., Sanchez-Valle R., Santosuosso A., Sauter A., Scheltema R.A., Scheltens P., Schiller H.B., Schneider A., Seibler P., Sheehan-Rooney K., Shields D., Sleegers K., Smit A.B., Smith K.G.C., Smolders I., Synofzik M., Tam W.L., Teichmann S., Thom M., Turco M.Y., van Beusekom H.M.M., Vandenberghe R., Van den Hoecke S., Van de Poel I., van der Ven A., van der Zee J., van Lunzen J., van Minnebruggen G., Van Paesschen W., van Swieten J., van Vught R., Verhage M., Verstreken P., Villa C.E., Vogel J., von Kalle C., Walter J., Weckhuysen S., Weichert W., Wood L., Ziegler A.-G., Zipp F., Center for Neurogenomics and Cognitive Research, Functional Genomics, Rajewsky, N, Almouzni, G, Gorski, S, Aerts, S, Amit, I, Bertero, M, Bock, C, Bredenoord, A, Cavalli, G, Chiocca, S, Clevers, H, De Strooper, B, Eggert, A, Ellenberg, J, Fernández, X, Figlerowicz, M, Gasser, S, Hubner, N, Kjems, J, Knoblich, J, Krabbe, G, Lichter, P, Linnarsson, S, Marine, J, Marioni, J, Marti-Renom, M, Netea, M, Nickel, D, Nollmann, M, Novak, H, Parkinson, H, Piccolo, S, Pinheiro, I, Pombo, A, Popp, C, Reik, W, Roman-Roman, S, Rosenstiel, P, Schultze, J, Stegle, O, Tanay, A, Testa, G, Thanos, D, Theis, F, Torres-Padilla, M, Valencia, A, Vallot, C, van Oudenaarden, A, Vidal, M, Voet, T, Cattoretti, G, Alliance for Modulation in Epilepsy, Pharmaceutical and Pharmacological Sciences, Experimental Pharmacology, RS: Carim - H02 Cardiomyopathy, MUMC+: MA Med Staf Spec Cardiologie (9), and Cardiologie

Subjects
0301 basic medicine, Male, Artificial intelligence, Legislation, Medical, [SDV]Life Sciences [q-bio], Molecular datasets, lnfectious Diseases and Global Health Radboud Institute for Molecular Life Sciences [Radboudumc 4], Cell- and Tissue-Based Therapy, Diseases, LifeTime Community Working Groups, Disease, Biomarkers, Systems biology, Health data, Pharmacology, Toxicology and Pharmaceutics(all), 0302 clinical medicine, Conjunts de dades, ethics [Delivery of Health Care], Health care, Pathology, Medicine, European healthcare, BRAIN, Single-cell multi-omics, GENE-EXPRESSION, Multidisciplinary, methods [Medicine], Education, Medical, Settore BIO/13, Intel.ligència artificial, 3. Good health, ALZHEIMERS-DISEASE, Europe, Health, Management system, Perspective, Female, ddc:500, Single-Cell Analysis, Biomarkers, Diseases, Systems biology, Complex diseases, Informàtica::Aplicacions de la informàtica::Bioinformàtica [Àrees temàtiques de la UPC], medicine.medical_specialty, General Science & Technology, Cells, MEDLINE, cell-based interceptive medicine, LifeTime Initiative, 03 medical and health sciences, SDG 3 - Good Health and Well-being, Clinical datasets, Artificial Intelligence, REVEALS, LifeTime Community, standards [Medicine], Humans, OMICS, RECONSTRUCTION, Intensive care medicine, trends [Medicine], trends [Delivery of Health Care], business.industry, Disease progression, standards [Delivery of Health Care], methods [Delivery of Health Care], 030104 developmental biology, lnfectious Diseases and Global Health Radboud Institute for Health Sciences [Radboudumc 4], single cell, personalized therapy, machine learning, bioinformatics, systems biology, disease, cell-based interceptive medicine, Early Diagnosis, Cardiovascular and Metabolic Diseases, Human medicine, business, Delivery of Health Care, 030217 neurology & neurosurgery, Cell based
Abstract

Here we describe the LifeTime Initiative, which aims to track, understand and target human cells during the onset and progression of complex diseases, and to analyse their response to therapy at single-cell resolution. This mission will be implemented through the development, integration and application of single-cell multi-omics and imaging, artificial intelligence and patient-derived experimental disease models during the progression from health to disease. The analysis of large molecular and clinical datasets will identify molecular mechanisms, create predictive computational models of disease progression, and reveal new drug targets and therapies. The timely detection and interception of disease embedded in an ethical and patient-centred vision will be achieved through interactions across academia, hospitals, patient associations, health data management systems and industry. The application of this strategy to key medical challenges in cancer, neurological and neuropsychiatric disorders, and infectious, chronic inflammatory and cardiovascular diseases at the single-cell level will usher in cell-based interceptive medicine in Europe over the next decade., The LifeTime initiative is an ambitious, multidisciplinary programme that aims to improve healthcare by tracking individual human cells during disease processes and responses to treatment in order to develop and implement cell-based interceptive medicine in Europe.

Published
2020
Full Text
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6. Organoid modeling of Zika and herpes simplex virus 1 infections reveals virus-specific responses leading to microcephaly

Author

Krenn, V, Bosone, C, Burkard, T, Spanier, J, Kalinke, U, Calistri, A, Salata, C, Rilo Christoff, R, Pestana Garcez, P, Mirazimi, A, Knoblich, J, Krenn, Veronica, Bosone, Camilla, Burkard, Thomas R, Spanier, Julia, Kalinke, Ulrich, Calistri, Arianna, Salata, Cristiano, Rilo Christoff, Raissa, Pestana Garcez, Patricia, Mirazimi, Ali, Knoblich, Jürgen A, Krenn, V, Bosone, C, Burkard, T, Spanier, J, Kalinke, U, Calistri, A, Salata, C, Rilo Christoff, R, Pestana Garcez, P, Mirazimi, A, Knoblich, J, Krenn, Veronica, Bosone, Camilla, Burkard, Thomas R, Spanier, Julia, Kalinke, Ulrich, Calistri, Arianna, Salata, Cristiano, Rilo Christoff, Raissa, Pestana Garcez, Patricia, Mirazimi, Ali, and Knoblich, Jürgen A

Abstract

Viral infection in early pregnancy is a major cause of microcephaly. However, how distinct viruses impair human brain development remains poorly understood. Here we use human brain organoids to study the mechanisms underlying microcephaly caused by Zika virus (ZIKV) and herpes simplex virus (HSV-1). We find that both viruses efficiently replicate in brain organoids and attenuate their growth by causing cell death. However, transcriptional profiling reveals that ZIKV and HSV-1 elicit distinct cellular responses and that HSV-1 uniquely impairs neuroepithelial identity. Furthermore, we demonstrate that, although both viruses fail to potently induce the type I interferon system, the organoid defects caused by their infection can be rescued by distinct type I interferons. These phenotypes are not seen in 2D cultures, highlighting the superiority of brain organoids in modeling viral infections. These results uncover virus-specific mechanisms and complex cellular immune defenses associated with virus-induced microcephaly.

Published
2021

7. Neurotransmitter signaling regulates distinct phases of multimodal human interneuron migration

Author

Bajaj, S, Bagley, J, Sommer, C, Vertesy, A, Nagumo Wong, S, Krenn, V, Lévi-Strauss, J, Knoblich, J, Bajaj, Sunanjay, Bagley, Joshua A, Sommer, Christoph, Vertesy, Abel, Nagumo Wong, Sakurako, Krenn, Veronica, Lévi-Strauss, Julie, Knoblich, Juergen A, Bajaj, S, Bagley, J, Sommer, C, Vertesy, A, Nagumo Wong, S, Krenn, V, Lévi-Strauss, J, Knoblich, J, Bajaj, Sunanjay, Bagley, Joshua A, Sommer, Christoph, Vertesy, Abel, Nagumo Wong, Sakurako, Krenn, Veronica, Lévi-Strauss, Julie, and Knoblich, Juergen A

Abstract

Inhibitory GABAergic interneurons migrate over long distances from their extracortical origin into the developing cortex. In humans, this process is uniquely slow and prolonged, and it is unclear whether guidance cues unique to humans govern the various phases of this complex developmental process. Here, we use fused cerebral organoids to identify key roles of neurotransmitter signaling pathways in guiding the migratory behavior of human cortical interneurons. We use scRNAseq to reveal expression of GABA, glutamate, glycine, and serotonin receptors along distinct maturation trajectories across interneuron migration. We develop an image analysis software package, TrackPal, to simultaneously assess 48 parameters for entire migration tracks of individual cells. By chemical screening, we show that different modes of interneuron migration depend on distinct neurotransmitter signaling pathways, linking transcriptional maturation of interneurons with their migratory behavior. Altogether, our study provides a comprehensive quantitative analysis of human interneuron migration and its functional modulation by neurotransmitter signaling.

Published
2021

10. LifeTime and improving European healthcare through cell-based interceptive medicine

Author

Rajewsky, N, Almouzni, G, Gorski, S, Aerts, S, Amit, I, Bertero, M, Bock, C, Bredenoord, A, Cavalli, G, Chiocca, S, Clevers, H, De Strooper, B, Eggert, A, Ellenberg, J, Fernández, X, Figlerowicz, M, Gasser, S, Hubner, N, Kjems, J, Knoblich, J, Krabbe, G, Lichter, P, Linnarsson, S, Marine, J, Marioni, J, Marti-Renom, M, Netea, M, Nickel, D, Nollmann, M, Novak, H, Parkinson, H, Piccolo, S, Pinheiro, I, Pombo, A, Popp, C, Reik, W, Roman-Roman, S, Rosenstiel, P, Schultze, J, Stegle, O, Tanay, A, Testa, G, Thanos, D, Theis, F, Torres-Padilla, M, Valencia, A, Vallot, C, van Oudenaarden, A, Vidal, M, Voet, T, Cattoretti, G, Rajewsky, Nikolaus, Almouzni, Geneviève, Gorski, Stanislaw A, Aerts, Stein, Amit, Ido, Bertero, Michela G, Bock, Christoph, Bredenoord, Annelien L, Cavalli, Giacomo, Chiocca, Susanna, Clevers, Hans, De Strooper, Bart, Eggert, Angelika, Ellenberg, Jan, Fernández, Xosé M, Figlerowicz, Marek, Gasser, Susan M, Hubner, Norbert, Kjems, Jørgen, Knoblich, Jürgen A, Krabbe, Grietje, Lichter, Peter, Linnarsson, Sten, Marine, Jean-Christophe, Marioni, John, Marti-Renom, Marc A, Netea, Mihai G, Nickel, Dörthe, Nollmann, Marcelo, Novak, Halina R, Parkinson, Helen, Piccolo, Stefano, Pinheiro, Inês, Pombo, Ana, Popp, Christian, Reik, Wolf, Roman-Roman, Sergio, Rosenstiel, Philip, Schultze, Joachim L, Stegle, Oliver, Tanay, Amos, Testa, Giuseppe, Thanos, Dimitris, Theis, Fabian J, Torres-Padilla, Maria-Elena, Valencia, Alfonso, Vallot, Céline, van Oudenaarden, Alexander, Vidal, Marie, Voet, Thierry, Cattoretti, Giorgio, Rajewsky, N, Almouzni, G, Gorski, S, Aerts, S, Amit, I, Bertero, M, Bock, C, Bredenoord, A, Cavalli, G, Chiocca, S, Clevers, H, De Strooper, B, Eggert, A, Ellenberg, J, Fernández, X, Figlerowicz, M, Gasser, S, Hubner, N, Kjems, J, Knoblich, J, Krabbe, G, Lichter, P, Linnarsson, S, Marine, J, Marioni, J, Marti-Renom, M, Netea, M, Nickel, D, Nollmann, M, Novak, H, Parkinson, H, Piccolo, S, Pinheiro, I, Pombo, A, Popp, C, Reik, W, Roman-Roman, S, Rosenstiel, P, Schultze, J, Stegle, O, Tanay, A, Testa, G, Thanos, D, Theis, F, Torres-Padilla, M, Valencia, A, Vallot, C, van Oudenaarden, A, Vidal, M, Voet, T, Cattoretti, G, Rajewsky, Nikolaus, Almouzni, Geneviève, Gorski, Stanislaw A, Aerts, Stein, Amit, Ido, Bertero, Michela G, Bock, Christoph, Bredenoord, Annelien L, Cavalli, Giacomo, Chiocca, Susanna, Clevers, Hans, De Strooper, Bart, Eggert, Angelika, Ellenberg, Jan, Fernández, Xosé M, Figlerowicz, Marek, Gasser, Susan M, Hubner, Norbert, Kjems, Jørgen, Knoblich, Jürgen A, Krabbe, Grietje, Lichter, Peter, Linnarsson, Sten, Marine, Jean-Christophe, Marioni, John, Marti-Renom, Marc A, Netea, Mihai G, Nickel, Dörthe, Nollmann, Marcelo, Novak, Halina R, Parkinson, Helen, Piccolo, Stefano, Pinheiro, Inês, Pombo, Ana, Popp, Christian, Reik, Wolf, Roman-Roman, Sergio, Rosenstiel, Philip, Schultze, Joachim L, Stegle, Oliver, Tanay, Amos, Testa, Giuseppe, Thanos, Dimitris, Theis, Fabian J, Torres-Padilla, Maria-Elena, Valencia, Alfonso, Vallot, Céline, van Oudenaarden, Alexander, Vidal, Marie, Voet, Thierry, and Cattoretti, Giorgio

Abstract

Here we describe the LifeTime Initiative, which aims to track, understand and target human cells during the onset and progression of complex diseases, and to analyse their response to therapy at single-cell resolution. This mission will be implemented through the development, integration and application of single-cell multi-omics and imaging, artificial intelligence and patient-derived experimental disease models during the progression from health to disease. The analysis of large molecular and clinical datasets will identify molecular mechanisms, create predictive computational models of disease progression, and reveal new drug targets and therapies. The timely detection and interception of disease embedded in an ethical and patient-centred vision will be achieved through interactions across academia, hospitals, patient associations, health data management systems and industry. The application of this strategy to key medical challenges in cancer, neurological and neuropsychiatric disorders, and infectious, chronic inflammatory and cardiovascular diseases at the single-cell level will usher in cell-based interceptive medicine in Europe over the next decade.

Published
2020

13. Simultaneous neoadjuvant radiochemotherapy with capecitabine and oxaliplatin for locally advanced rectal cancer: Treatment outcome outside clinical trials

Author

Winkler, J., Zipp, L., Knoblich, J., Zimmermann, F., Winkler, J., Zipp, L., Knoblich, J., and Zimmermann, F.

Abstract

Background: Phase II trials of neoadjuvant treatment in UICC-TNM stageII and III rectal cancer with capecitabine and oxaliplatin demonstrated favourable rates on tumour regression with acceptable toxicity. Patients and methods: Retrospective evaluation of 34 patients treated from 2005-2008 outside clinical trials (CTR) with neoadjuvant irradiation (45-50.4Gy) and simultaneous capecitabine 825mg/m2 b.i.d. on days 1-14 and 22-35 and oxaliplatin 50mg/m2 on days 1, 8, 22 and 29 (CAPOX). Twenty-six (77%) patients received one or two courses of capecitabine 1,000mg/m2 b.i.d. on days 1-14 and oxaliplatin 130mg/m2 on day 1 (XELOX) prior to simultaneous chemoradiotherapy. Results: UICC-TNM stage regression was observed in 60% (n = 20). Dworak's regression grades 3 and 4 were achieved in 18.2% (n = 6) and 15.1% (n = 5) of the patients. Sphincter-preserving surgery was performed in 53% (n = 8) of patients with a tumour of the lower rectum. Within the mean observation of 24 months, none of the patients relapsed locally, 1patient had progressive disease and 5patients (15%) relapsed distantly. Toxicity of grade 3 and 4 was mainly diarrhoea 18% (n = 6) and perianal pain 9% (n = 3). Nevertheless, severe cardiac events (n = 2), severe electrolyte disturbances (n = 2), and syncopes (n = 2) were observed as well. Conclusion: Treatment efficacy and common toxicity are similar to the reports of phaseI/II trials. However, several severe adverse events were observed in our cohort study. The predisposing factors for these events have yet to be studied and may have implications for the selection of patients outside CTR

Published
2018

14. Limited clinical relevance of imaging techniques in the follow-up of patients with advanced chronic lymphocytic leukemia: results of a meta-analysis

Author

Eichhorst, Barbara F, Fischer, Kirsten, Fink, Anna Maria, Elter, Thomas, Wendtner, Clemens M, Goede, Valentin, Bergmann, Manuela, Stilgenbauer, Stephan, Hopfinger, Georg, Ritgen, Matthias, Bahlo, Jasmin, Busch, Raymonde, Hallek, Michael, Oduncu, F, Dreyling, M, Forstpointner, R, Schneller, F, Bogner, C, Peschel, C, Ringshausen, I, Götze, K, Goebeler, Me, Rückle, Lanz, Ritgen, M, Schawitzke, A, Heydrich, B, Kern, K, Böttcher, S, Irmer, S, Strack, U, Borries, V, Klima, Km, Scholz, C, Herold, M, Härtwig, K, Dürig, J, Dührsen, U, Müller Beissenhirtz, H, Noppeney, R, Schüttrumpf, S, Hohloch, K, Binder, C, Hasenkamp, J, Trümper, L, Bäsecke, J, Rieger, M, Witzens Harig, M, Friedrichs, B, Rieger, K, Uharek, L, Kubuschok, B, Murawski, N, Held, G, Zwick, C, Pfreundschuh, M, Fingerle Rowson, G, Reiser, M, Elter, T, Eichhorst, B, Pallasch, C, Hallek, M, Borchmann, P, Hacker, U, Schinkel, S, Wieker, K, Sökler, M, Wolf, Hh, Eucker, J, Staib, P, Schlegel, F, Kropff, M, Kahl, C, Hess, G, Beck, J, Wölfel, T, Bokemeyer, C, Schilling, G, Dierlamm, J, Schüler, F, Busemann, C, Dölken, G, Trendelenburg, Tk, Bühler, A, Stilgenbauer, S, Viardot, A, Greiner, J, Zenz, T, Gaidzik, V, Langer, C, Döhner, H, Werner, I, Dienst, A, Habersang, K, Härtel, N, Leitner, A, Kehrer, G, Middeke, H, Heinisch, K, Adorf, D, Ismer, B, Hering Schubert, C, Jäckle, J, Aulmann, C, Söllner, S, Majunke, P, Fuss, H, Käfer, G, Potenberg, J, Dietrich, G, Hartung, E, Pronath, A, Riedhammer, Fj, Zehrfeld, T, Prümmer, O, Gatter, J, Meier, A, Wattad, M, Heit, W, Sauer, I, Hilgers, K, Geissler, M, Bauer, J, Stein, W, Voigtmann, R, Natt, F, Nickelsen, M, Zeis, M, Schmitz, N, Lange, E, Stoltefuss, A, Schubert, J, Dürk, Ha, Kloke, O, Fauser, A, Roemer, E, Kraut, L, Musch, E, Kohl, S, Link, H, Kirsch, Jf, Schatz, M, Mezger, J, Kempf, B, Heil, G, Derigs, Hg, Roll, C, Kettner, E, Dübbers, Hw, Lutz, L, Hentrich, M, Hoffmann, U, Ibe, M, Falge, C, Schäfer Eckart, K, Rothmann, F, Raghavachar, A, Beckmann, K, Behringer, D, Stauder, H, Hempfling, C, Matzdorff, A, Hähling, D, Kaesberger, Kj, Mück, R, Waladkhani, Ar, Clemens, M, Kraft, J, Ehlert, T, N. N., Schloen, A, Sandritter, B, Scholz, Diekmann, C, Pflüger, Kh, Hausner, G, Fetscher, S, Aulitzky, W, Brugger, W, Frickhofen, N, Fuhr, Lange, C, Lambertz, H, Schulz, L, Schmier, M, Bentz, M, Tauchmann, Gm, Schmidt, M, Meiler, J, Sandmann, M, Kürschner, D, Maier Bay, B, Lindemann, W, Diers, J, Riemeier Sievers, C, Daun, M, Mergenthaler, Hg, Hiller, S, Schirmer, V, Kirchner, H, Langer, W, Günther, B, Gassmann, W, Franke, K, Burghardt, F, Abele, U, Celikel Becker, D, von Weikersthal LF, Brög, G, Hauch, U, Heinrich, B, Brudler, O, Häcker, B, Eckart, Mj, Bolouri, H, Göttler, B, Kindler, M, Zuchold, K, Strohbach, F, Plingen, Ml, Seibt Jung, H, Kirsch, A, Herrenberger, J, Doering, G, von Grünhagen, U, Franke, H, Weniger, J, Kerzel, W, Schmalfeld, M, Rohrberg, R, Hurtz, Hj, Gehbauer, G, Hahnfeld, S, Vehling Kaiser, U, Abenhardt, W, Bosse, D, Böning, L, Schmidt, B, Schick, Hd, Jacobs, G, Stauch, M, Hoffmann, R, Müller, S, Hahn, M, Freier, W, Dietzfelbinger, H, Rassmann, I, Söling, U, Siehl, S, Rudolph, R, Weinert, R, Sauer, A, Meyer, B, Eschenburg, H, Schadeck Gressel, C, Grabenhorst, U, Perker, M, Otremba, B, Reschke, D, Hinrichs, Hf, Zirpel, I, Höring, E, Respondek, M, Köppler, H, Heymanns, J, Weide, R, Hünermund, K, Thiel, C, Reiber, T, Spohn, C, Springer, G, Fiechtner, H, Hübner, A, Kurschel, E, Weiss, J, Schlag, R, Schäfer, E, Hartwich, G, Schmitz, S, Steinmetz, T, Kim, Ts, Lerchenmüller, C, Wehmeyer, J, Laubenstein, Hp, Rendenbach, B, Lebahn, H, Kröning, H, Uhle, R, Balló, H, Gaede, B, Zumbrink, S, Eckert, R, Kamp, T, Reimann, B, Burkhard, O, Mittermüller, J, Hansen, R, Hitz, H, Schliesser, G, Schmitt, Hr, Forstbauer, H, Grundeis, M, Schulze, M, Baldus, M, Lakner, V, Haen, M, Müller, C, Dörfel, S, Göhler, T, Welslau, M, Achtzehn, V, Culmann, H, Gerhardt, S, Ulshöfer, T, Koschuth, A, Schmidt, P, Müller, L, Schneider, M, Koniczek, K, Porowski, P, Glados, M, Knoblich, J, Ben Yehuda, D, Jäger, U, Gaiger, A, Schwarzmeier, J, Nösslinger, T, Smith, M, Patton, N, Gibbons, S, Bouabdallah, R, Gandhi, M, Marlton, P, Mills, T, Angelucci, E, Sorano, Gg, Casula, P, Berneman, Z, Kohser, P, Hudcova Burgetova, A, Machová, R, Papajik, T, Kubová, Z, Fineman, R, Mayer, J, Doubek, M, Brychtova, Y, Ciceri, F, Caligaris Cappio, F, Crocchiolo, R, Dauriac, C, Bernard, M, Escoffre Barbe, M, Lamy, T, Zikesova, E, Karban, J, Salkova, J, Trnený, M, Pytlik, R, Tiley, C, Forsyth, C, Vokurka, S, Koza, V, Van Hoof, A, Selleslag, D, Sebban, C, Baker, B, Belada, D, Jebavy, L, Smolej, L, Pavel, Z, Di Ianni, M, Castaigne, S, Del Poeta, G, Amadori, S, Catalano, J, Ganju, V, Hertzberg, M, Laurenti, L, Dalseg, Am, Bron, D, Morton, J, Durrant, S, Casado, Lf, Theunissen, K, Atias, D, Berkhan, L, Seymour, J, Wolf, M, Bosly, A, Osma Cordoba MM, Portois, C, Jaubert, J, Ferrant, A, Lambert, C, Maerevoet, E, Van den Neste, E, Gadeberg, O, Carney, B, Cannell, P, Eghbali, H, Legouffe, E, Bordessoule, D, Chaury, M, Moreau, S, Pierri, I, Gobbi, M, Berrebi, A, Lishner, M, Yerushazim, R, Yermiaku, T, Kosolov, V, Ambrosetti, Achille, Andreoli, Al, Huguet, F, Laurent, G, Orsucci, L, Forconi, F, Musuraca, G, Zinzani, Pl, Loscertales, J, Mcquillan, A, Cordingley, F, Leahy, M, Cazin, B, Taylor, Mulligan, S, Herbrecht, Cull, G, Seldon, M, Rowlings, P, Ludwig, H, Zojer, N, Solal Céligny, P, Pomponi, F, Savdkova, L, Kozák, T, Christiansen, I, Pérez, I, Campbell, P, Canales Albendea, M, De Paz, R, Arthur, C, Gisselbrecht, C., Eichhorst B.F., Fischer K., Fink A.M., Elter T., Wendtner C.M., Goede V., Bergmann M., Stilgenbauer S., Hopfinger G., Ritgen M., Bahlo J., Busch R., Hallek M., and Zinzani P.L.

Subjects
Male, medicine.medical_specialty, Cyclophosphamide, Chronic lymphocytic leukemia, Immunology, Medizin, Antineoplastic Combined Chemotherapy Protocols, Blood Cell Count, Disease Progression, Disease-Free Survival, Female, Follow-Up Studies, Humans, Leukemia, Lymphocytic, Chronic, B-Cell, Middle Aged, Prognosis, Recurrence, Remission Induction, Tomography, X-Ray Computed, Physical examination, Biochemistry, Chemoimmunotherapy, medicine, Chronic, Tomography, Leukemia, medicine.diagnostic_test, business.industry, B-Cell, Cancer, Cell Biology, Hematology, medicine.disease, Lymphocytic, imaging techniques, X-Ray Computed, Fludarabine, Surgery, chronic lymphocytic leukemia, Radiology, business, Progressive disease, medicine.drug
Abstract

The clinical value of imaging is well established for the follow-up of many lymphoid malignancies but not for chronic lymphocytic leukemia (CLL). A meta-analysis was performed with the dataset of 3 German CLL Study Group phase 3 trials (CLL4, CLL5, and CLL8) that included 1372 patients receiving first-line therapy for CLL. Response as well as progression during follow-up was reassessed according to the National Cancer Institute Working Group1996 criteria. A total of 481 events were counted as progressive disease during treatment or follow-up. Of these, 372 progressions (77%) were detected by clinical symptoms or blood counts. Computed tomography (CT) scans or ultrasound were relevant in 44 and 29 cases (9% and 6%), respectively. The decision for relapse treatment was determined by CT scan or ultrasound results in only 2 of 176 patients (1%). CT scan results had an impact on the prognosis of patients in complete remission only after the administration of conventional chemotherapy but not after chemoimmunotherapy. In conclusion, physical examination and blood count remain the methods of choice for staging and clinical follow-up of patients with CLL as recommended by the International Workshop on Chronic Lymphocytic Leukemia 2008 guidelines. These trials are registered at http://www.isrctn.org as ISRCTN 75653261 and ISRCTN 36294212 and at http://www.clinicaltrials.gov as NCT00281918.

Published
2011
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15. Safeguarding gene drive experiments in the laboratory

Author

Akbari, OS, Bellen, HJ, Bier, E, Bullock, SL, Burt, A, Church, GM, Cook, KR, Duchek, P, Edwards, OR, Esvelt, KM, Gantz, VM, Golic, KG, Gratz, SJ, Harrison, MM, Hayes, KR, James, AA, Kaufman, TC, Knoblich, J, Malik, HS, Matthews, KA, O'Connor-Giles, KM, Parks, AL, Perrimon, N, Port, F, Russell, S, Ueda, R, and Wildonger, J

Published
2015
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17. Characterization of 35 new cases with four different MPLW515 mutations and essential thrombocytosis or primary myelofibrosis

Author

Schnittger, S., primary, Bacher, U., additional, Haferlach, C., additional, Beelen, D., additional, Bojko, P., additional, Burkle, D., additional, Dengler, R., additional, Distelrath, A., additional, Eckart, M., additional, Eckert, R., additional, Fries, S., additional, Knoblich, J., additional, Kochling, G., additional, Laubenstein, H.-P., additional, Petrides, P., additional, Planker, M., additional, Pihusch, R., additional, Weide, R., additional, Kern, W., additional, and Haferlach, T., additional

Published
2009
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21. Inscuteable-dependent apical localization of the microtubule-binding protein Cornetto suggests a role in asymmetric cell division.

Author

S, Bulgheresi, E, Kleiner, and A, Knoblich J

Abstract

Drosophila neuroblasts divide asymmetrically along the apical-basal axis. The Inscuteable protein localizes to the apical cell cortex in neuroblasts from interphase to metaphase, but disappears in anaphase. Inscuteable is required for correct spindle orientation and for asymmetric localization of cell fate determinants to the opposite (basal) cell cortex. Here, we show that Inscuteable also directs asymmetric protein localization to the apical cell cortex during later stages of mitosis. In a two-hybrid screen for Inscuteable-binding proteins, we have identified the coiled-coil protein Cornetto, which shows a highly unusual subcellular distribution in neuroblasts. Although the protein is uniformly distributed in the cytoplasm during metaphase, it concentrates apically in anaphase and forms an apical crescent during telophase in an inscuteable-dependent manner. Upon overexpression, Cornetto localizes to astral microtubules and microtubule spin-down experiments demonstrate that Cornetto is a microtubule-binding protein. After disruption of the actin cytoskeleton, Cornetto localizes with microtubules throughout the cell cycle and decorates the mitotic spindle during metaphase. Our results reveal a novel pattern of asymmetric protein localization in Drosophila neuroblasts and are consistent with a function of Cornetto in anchoring the mitotic spindle during late phases of mitosis, even though our cornetto mutant analysis suggests that this function might be obscured by genetic redundancy.

Published
2001

22. Drosophila Cyclin B3 is required for female fertility and is dispensable for mitosis like Cyclin B.

Author

Jacobs, H W, Knoblich, J A, and Lehner, C F

Abstract

Cyclin B3 has been conserved during higher eukaryote evolution as evidenced by its identification in chicken, nematodes, and insects. We demonstrate that Cyclin B3 is present in addition to Cyclins A and B in mitotically proliferating cells and not detectable in endoreduplicating tissues of Drosophila embryos. Cyclin B3 is coimmunoprecipitated with Cdk1(Cdc2) but not with Cdk2(Cdc2c). It is degraded abruptly during mitosis like Cyclins A and B. In contrast to these latter cyclins, which accumulate predominantly in the cytoplasm during interphase, Cyclin B3 is a nuclear protein. Genetic analyses indicate functional redundancies. Double and triple mutant analyses demonstrate that Cyclins A, B, and B3 cooperate to regulate mitosis, but surprisingly single mutants reveal that neither Cyclin B3 nor Cyclin B is required for mitosis. However, both are required for female fertility and Cyclin B also for male fertility.

Published
1998

23. Miranda as a multidomain adapter linking apically localized Inscuteable and basally localized Staufen and Prospero during asymmetric cell division in Drosophila.

Author

Shen, C P, Knoblich, J A, Chan, Y M, Jiang, M M, Jan, L Y, and Jan, Y N

Abstract

Neuroblasts in the developing Drosophila CNS asymmetrically localize the cell fate determinants Numb and Prospero as well as prospero RNA to the basal cortex during mitosis. The localization of Prospero requires the function of inscuteable and miranda, whereas prospero RNA localization requires inscuteable and staufen function. We demonstrate that Miranda contains multiple functional domains: an amino-terminal asymmetric localization domain, which interacts with Inscuteable, a central Numb interaction domain, and a more carboxy-terminal Prospero interaction domain. We also show that Miranda and Staufen have similar subcellular localization patterns and interact in vitro. Furthermore, miranda function is required for the asymmetric localization of Staufen. Miranda localization is disrupted by the microfilament disrupting agent latrunculin A. Our results suggest that Miranda directs the basal cortical localization of multiple molecules, including Staufen and prospero RNA, in mitotic neuroblasts in an actin-dependent manner.

Published
1998

24. Caenorhabditis elegans cyclin A- and B-type genes: a cyclin A multigene family, an ancestral cyclin B3 and differential germline expression.

Author

Kreutzer, M A, Richards, J P, De Silva-Udawatta, M N, Temenak, J J, Knoblich, J A, Lehner, C F, and Bennett, K L

Abstract

We have cloned cDNAs for Caenorhabditis elegans cyclins A1, B and B3. While cyclins A1 and B are most closely related to either A- or B-type cyclins of other species, cyclin B3 is less related to these cyclins. However, this cyclin is most similar to the recently identified chicken cyclin B3. Our identification of a Caenorhabditis homolog demonstrates that cyclin B3 has been conserved in evolution. Cyclin A1 is a member of an A-type multigene family; however the cyclin A1 cDNA only recognizes a single band on northern blots. A single-sized RNA is also observed for the cyclin B3 cDNA. In contrast, three different transcripts are observed for the cyclin B cDNA. Based on our analyses using RNAs from germline-defective mutants and from populations enriched for males, one cyclin B transcript is specific to the paternal germline. The two other cyclin B transcripts, as well as the cyclin A1 and cyclin B3 transcripts, are most abundant in the maternal germline and are only present at low levels in other tissues. Moreover, the 3' untranslated regions of each Caenorhabditis cyclin cDNA possess several copies of potential translational control elements shown in Xenopus and Drosophila maternal cyclin mRNAs to function during oogenesis and early embryogenesis.

Published
1995

27. Simultaneous neoadjuvant radiochemotherapy with capecitabine and oxaliplatin for locally advanced rectal cancer: Treatment outcome outside clinical trials

Author

Winkler, J., Zipp, L., Knoblich, J., Zimmermann, F., Winkler, J., Zipp, L., Knoblich, J., and Zimmermann, F.

Abstract

Background: Phase II trials of neoadjuvant treatment in UICC-TNM stageII and III rectal cancer with capecitabine and oxaliplatin demonstrated favourable rates on tumour regression with acceptable toxicity. Patients and methods: Retrospective evaluation of 34 patients treated from 2005-2008 outside clinical trials (CTR) with neoadjuvant irradiation (45-50.4Gy) and simultaneous capecitabine 825mg/m2 b.i.d. on days 1-14 and 22-35 and oxaliplatin 50mg/m2 on days 1, 8, 22 and 29 (CAPOX). Twenty-six (77%) patients received one or two courses of capecitabine 1,000mg/m2 b.i.d. on days 1-14 and oxaliplatin 130mg/m2 on day 1 (XELOX) prior to simultaneous chemoradiotherapy. Results: UICC-TNM stage regression was observed in 60% (n = 20). Dworak's regression grades 3 and 4 were achieved in 18.2% (n = 6) and 15.1% (n = 5) of the patients. Sphincter-preserving surgery was performed in 53% (n = 8) of patients with a tumour of the lower rectum. Within the mean observation of 24 months, none of the patients relapsed locally, 1patient had progressive disease and 5patients (15%) relapsed distantly. Toxicity of grade 3 and 4 was mainly diarrhoea 18% (n = 6) and perianal pain 9% (n = 3). Nevertheless, severe cardiac events (n = 2), severe electrolyte disturbances (n = 2), and syncopes (n = 2) were observed as well. Conclusion: Treatment efficacy and common toxicity are similar to the reports of phaseI/II trials. However, several severe adverse events were observed in our cohort study. The predisposing factors for these events have yet to be studied and may have implications for the selection of patients outside CTR

29. Transfer priting with reactive dyes.

Author

Knoblich, J. and Grote, G.

Subjects
REACTIVE dyes, DYES & dyeing, TEXTILE printing, COLOR in the textile industries, COLOR in textile crafts, TEXTILE industry
Abstract

For years, a way to use the advantages of thermal transfer printing with disperse dyes for natural fibers has been looked for. However, all known systems have failed on the normal market demands on adhesion and fastness. This report presents a new system based on reactive dyes. INSET: Recipe of transfer liquid..

Published
2004

32. Neurotransmitter signaling regulates distinct phases of multimodal human interneuron migration

Author

Sunanjay Bajaj, Sakurako Nagumo Wong, Julie Lévi-Strauss, Joshua A. Bagley, Juergen A. Knoblich, Ábel Vértesy, Veronica Krenn, Christoph Sommer, Bajaj, S, Bagley, J, Sommer, C, Vertesy, A, Nagumo Wong, S, Krenn, V, Lévi-Strauss, J, and Knoblich, J

Subjects
BIO/12 - BIOCHIMICA CLINICA E BIOLOGIA MOLECOLARE CLINICA, Neurogenesis, cerebral organoid fusion, BIO/18 - GENETICA, Biology, Inhibitory postsynaptic potential, General Biochemistry, Genetics and Molecular Biology, Interneuron migration, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Cell Movement, Interneurons, Humans, News & Views, RNA-Seq, Neurotransmitter, Molecular Biology, 5-HT receptor, 030304 developmental biology, Cerebral Cortex, Neurotransmitter Agents, 0303 health sciences, General Immunology and Microbiology, cortical interneuron migration, General Neuroscience, BIO/13 - BIOLOGIA APPLICATA, Glutamate receptor, neurotransmitter signaling pathway, Cortex (botany), Organoids, live cell imaging, HEK293 Cells, nervous system, chemistry, human brain development, GABAergic, Single-Cell Analysis, Signal transduction, Neuroscience, 030217 neurology & neurosurgery
Abstract

Inhibitory GABAergic interneurons migrate over long distances from their extracortical origin into the developing cortex. In humans, this process is uniquely slow and prolonged, and it is unclear whether guidance cues unique to humans govern the various phases of this complex developmental process. Here, we use fused cerebral organoids to identify key roles of neurotransmitter signaling pathways in guiding the migratory behavior of human cortical interneurons. We use scRNAseq to reveal expression of GABA, glutamate, glycine, and serotonin receptors along distinct maturation trajectories across interneuron migration. We develop an image analysis software package, TrackPal, to simultaneously assess 48 parameters for entire migration tracks of individual cells. By chemical screening, we show that different modes of interneuron migration depend on distinct neurotransmitter signaling pathways, linking transcriptional maturation of interneurons with their migratory behavior. Altogether, our study provides a comprehensive quantitative analysis of human interneuron migration and its functional modulation by neurotransmitter signaling.

Published
2021
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33. Organoid modeling of Zika and herpes simplex virus 1 infections reveals virus-specific responses leading to microcephaly

Author

Patricia P. Garcez, Ali Mirazimi, Veronica Krenn, Thomas R Burkard, Arianna Calistri, Jürgen A. Knoblich, Cristiano Salata, Raissa R. Christoff, Julia Spanier, Ulrich Kalinke, Camilla Bosone, Krenn, V, Bosone, C, Burkard, T, Spanier, J, Kalinke, U, Calistri, A, Salata, C, Rilo Christoff, R, Pestana Garcez, P, Mirazimi, A, and Knoblich, J

Subjects
Microcephaly, neural progenitor, viruses, neural progenitors, Herpesvirus 1, Human, medicine.disease_cause, brain organoid, Article, Virus, Zika virus, 03 medical and health sciences, 0302 clinical medicine, Immune system, Pregnancy, Interferon, brain organoids, microcephaly, Zika virus, herpes simplex virus, neural progenitors, neuroepithelial polarity, interferons, innate immune response, Genetics, medicine, Organoid, Humans, 030304 developmental biology, 0303 health sciences, Innate immune system, brain organoids, neuroepithelial polarity, biology, Zika Virus Infection, BIO/13 - BIOLOGIA APPLICATA, interferon, Zika Virus, Cell Biology, herpes simplex virus, medicine.disease, biology.organism_classification, herpes simplex viru, Virology, Zika viru, interferons, Organoids, Herpes simplex virus, innate immune response, Molecular Medicine, Female, 030217 neurology & neurosurgery, medicine.drug
Abstract

Viral infections in early pregnancy are a major cause of microcephaly. However, how distinct viruses impair human brain development remains poorly understood. Here we use human brain organoids to study the mechanisms underlying microcephaly caused by Zika Virus (ZIKV) and Herpes Simplex Virus (HSV-1). We find that both viruses efficiently replicate in brain organoids and attenuate their growth by causing cell death. However, transcriptional profiling reveals that ZIKV and HSV-1 elicit distinct cellular responses and HSV-1 uniquely impairs neuroepithelial identity. Furthermore, we demonstrate that while both viruses fail to potently induce the type I interferon system, the organoid defects caused by their infection can be rescued by distinct type I interferons. These phenotypes are not seen in 2D cultures, highlighting the superiority of brain organoids in modeling viral infections. Together, these results uncover virus-specific mechanisms and complex cellular immune defenses associated with virus-induced microcephaly.

Published
2021
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34. Molecular Characterization and Genetic Subclassification Comparison of Diffuse Large B-Cell Lymphoma: Real-Life Experience with 74 Cases.

Author

Ivanova VS, Vela V, Dirnhofer S, Dobbie M, Stenner F, Knoblich J, Tzankov A, and Menter T

Subjects
Humans, Male, Female, Middle Aged, Aged, Adult, Immunohistochemistry, Proto-Oncogene Proteins c-bcl-2 genetics, Aged, 80 and over, Algorithms, Proto-Oncogene Proteins c-bcl-6 genetics, Biomarkers, Tumor genetics, Cohort Studies, Prognosis, Proto-Oncogene Proteins c-myc genetics, Lymphoma, Large B-Cell, Diffuse genetics, Lymphoma, Large B-Cell, Diffuse classification, Lymphoma, Large B-Cell, Diffuse pathology, In Situ Hybridization, Fluorescence, High-Throughput Nucleotide Sequencing
Abstract

Introduction: Diffuse large B-cell lymphoma (DLBCL) is a heterogeneous entity. Lately, several algorithms achieving therapeutically and prognostically relevant DLBCL subclassification have been published., Methods: A cohort of 74 routine DLBCL cases was broadly characterized by immunohistochemistry (IHC), fluorescence in situ hybridization (FISH) of the BCL2, BCL6, and MYC loci, and comprehensive high-throughput sequencing (HTS). Based on the genetic alterations found, cases were reclassified using two probabilistic tools - LymphGen and Two-step classifier, allowing for comparison of the two models., Results: Hans and Tally's overall IHC-based subclassification success rate was 96% and 82%, respectively. HTS and FISH data allowed the LymphGen algorithm to successfully classify 11/55 cases (1 - BN2, 7 - EZB, 1 - MCD, and 2 - genetically composite EZB/N1). The total subclassification rate was 20%. On the other hand, the Two-step classifier categorized 36/55 cases, with 65.5% success (9 - BN2, 12 - EZB, 9 - MCD, 2 - N1, and 4 - ST2). Clinical correlations highlighted MCD as an aggressive subtype associated with higher relapse and mortality., Conclusions: The Two-step algorithm has a better success rate at subclassifying DLBCL cases based on genetic differences. Further improvement of the classifiers is required to increase the number of classifiable cases and thus prove their applicability in routine diagnostics., (© 2023 The Author(s). Published by S. Karger AG, Basel.)

Published
2024
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35. Human organoids: a new dimension in cell biology.

Author

Lehmann R, Lee CM, Shugart EC, Benedetti M, Charo RA, Gartner Z, Hogan B, Knoblich J, Nelson CM, and Wilson KM

Subjects
Animals, Biomedical Research, Cell Culture Techniques methods, Humans, Models, Biological, Organoids cytology, Regenerative Medicine, Reproducibility of Results, Stem Cells, Tissue Engineering methods, Organoids metabolism, Organoids physiology
Abstract

Organoids derived from stem cells or tissues in culture can develop into structures that resemble the in vivo anatomy and physiology of intact organs. Human organoid cultures provide the potential to study human development and model disease processes with the same scrutiny and depth of analysis customary for research with nonhuman model organisms. Resembling the complexity of the actual tissue or organ, patient-derived human organoid studies may accelerate medical research, creating new opportunities for tissue engineering and regenerative medicine, generating knowledge and tools for preclinical studies, including drug development and testing. Biologists are drawn to this system as a new "model organism" to study complex disease phenotypes and genetic variability among individuals using patient-derived tissues. The American Society for Cell Biology convened a task force to report on the potential, challenges, and limitations for human organoid research. The task force suggests ways to ease the entry for new researchers into the field and how to facilitate broader use of this new model organism within the research community. This includes guidelines for reproducibility, culturing, sharing of patient materials, patient consent, training, and communication with the public.

Published
2019
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36. BIOSAFETY. Safeguarding gene drive experiments in the laboratory.

Author

Akbari OS, Bellen HJ, Bier E, Bullock SL, Burt A, Church GM, Cook KR, Duchek P, Edwards OR, Esvelt KM, Gantz VM, Golic KG, Gratz SJ, Harrison MM, Hayes KR, James AA, Kaufman TC, Knoblich J, Malik HS, Matthews KA, O'Connor-Giles KM, Parks AL, Perrimon N, Port F, Russell S, Ueda R, and Wildonger J

Subjects
Animals, CRISPR-Cas Systems, Endonucleases metabolism, Genome, Clustered Regularly Interspaced Short Palindromic Repeats, Containment of Biohazards, Genetic Engineering, Genetic Research, Organisms, Genetically Modified, Safety
Published
2015
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38. The PDZ protein Canoe regulates the asymmetric division of Drosophila neuroblasts and muscle progenitors.

Author

Speicher S, Fischer A, Knoblich J, and Carmena A

Subjects
Animals, Cell Cycle Proteins, Cell Lineage, Cytoskeletal Proteins metabolism, GTP-Binding Protein alpha Subunits, Gi-Go metabolism, Guanine Nucleotide Dissociation Inhibitors metabolism, Heart embryology, Intracellular Signaling Peptides and Proteins metabolism, Membrane Proteins metabolism, Muscle Development physiology, Muscles cytology, Nerve Tissue Proteins metabolism, PDZ Domains, Spindle Apparatus physiology, Cell Division physiology, Drosophila embryology, Drosophila Proteins metabolism, Neurons cytology, Stem Cells physiology
Abstract

Asymmetric cell division is a conserved mechanism to generate cellular diversity during animal development and a key process in cancer and stem cell biology. Despite the increasing number of proteins characterized, the complex network of proteins interactions established during asymmetric cell division is still poorly understood. This suggests that additional components must be contributing to orchestrate all the events underlying this tightly modulated process. The PDZ protein Canoe (Cno) and its mammalian counterparts AF-6 and Afadin are critical to regulate intracellular signaling and to organize cell junctions throughout development. Here, we show that Cno functions as a new effector of the apical proteins Inscuteable (Insc)-Partner of Inscuteable (Pins)-Galphai during the asymmetric division of Drosophila neuroblasts (NBs). Cno localizes apically in metaphase NBs and coimmunoprecipitates with Pins in vivo. Furthermore, Cno functionally interacts with the apical proteins Insc, Galphai, and Mushroom body defect (Mud) to generate correct neuronal lineages. Failures in muscle and heart lineages are also detected in cno mutant embryos. Our results strongly support a new function for Cno regulating key processes during asymmetric NB division: the localization of cell-fate determinants, the orientation of the mitotic spindle, and the generation of unequal-sized daughter cells.

Published
2008
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39. Protein localization during asymmetric cell division.

Author

Schaefer M and Knoblich JA

Subjects
Animals, Caenorhabditis elegans cytology, Caenorhabditis elegans Proteins metabolism, Carrier Proteins genetics, Carrier Proteins metabolism, Drosophila Proteins metabolism, Drosophila melanogaster cytology, Green Fluorescent Proteins, Indicators and Reagents metabolism, Luminescent Proteins genetics, Luminescent Proteins metabolism, Macromolecular Substances, Models, Biological, Neurons physiology, Nuclear Proteins genetics, Nuclear Proteins metabolism, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Caenorhabditis elegans physiology, Cell Division physiology, Cell Polarity physiology, Drosophila melanogaster physiology, Proteins metabolism
Published
2001
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40. Heterotrimeric G proteins direct two modes of asymmetric cell division in the Drosophila nervous system.

Author

Schaefer M, Petronczki M, Dorner D, Forte M, and Knoblich JA

Subjects
Animals, Animals, Genetically Modified, Cytoskeletal Proteins metabolism, Drosophila, GTP-Binding Proteins physiology, Heterotrimeric GTP-Binding Proteins metabolism, Insect Proteins metabolism, Microscopy, Fluorescence, Mitosis, Models, Biological, Mutation, Neurons metabolism, Neuropeptides, Protein Binding, Transgenes, Cell Cycle Proteins, Cell Division, Drosophila Proteins, GTP-Binding Proteins metabolism, Nervous System metabolism
Abstract

In Drosophila, distinct mechanisms orient asymmetric cell division along the apical-basal axis in neuroblasts and along the anterior-posterior axis in sensory organ precursor (SOP) cells. Here, we show that heterotrimeric G proteins are essential for asymmetric cell division in both cell types. The G protein subunit G(alpha)i localizes apically in neuroblasts and anteriorly in SOP cells before and during mitosis. Interfering with G protein function by G(alpha)i overexpression or depletion of heterotrimeric G protein complexes causes defects in spindle orientation and asymmetric localization of determinants. G(alpha)i is colocalized and associated with Pins, a protein that induces the release of the betagamma subunit and might act as a receptor-independent G protein activator. Thus, asymmetric activation of heterotrimeric G proteins by a receptor-independent mechanism may orient asymmetric cell divisions in different cell types.

Published
2001
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41. Inscuteable-dependent apical localization of the microtubule-binding protein Cornetto suggests a role in asymmetric cell division.

Author

Bulgheresi S, Kleiner E, and Knoblich JA

Subjects
Amino Acid Sequence, Animals, Bridged Bicyclo Compounds, Heterocyclic pharmacology, Cytoskeleton metabolism, Drosophila Proteins chemistry, Drosophila Proteins genetics, Drosophila melanogaster, Epithelial Cells physiology, In Situ Hybridization, Microscopy, Fluorescence, Microtubule-Associated Proteins chemistry, Microtubule-Associated Proteins genetics, Microtubules metabolism, Molecular Sequence Data, Neuropeptides, Recombinant Fusion Proteins metabolism, Spindle Apparatus metabolism, Thiazoles pharmacology, Thiazolidines, Two-Hybrid System Techniques, Cell Polarity, Cytoskeletal Proteins metabolism, Drosophila Proteins metabolism, Microtubule-Associated Proteins metabolism, Mitosis physiology, Neurons physiology
Abstract

Drosophila neuroblasts divide asymmetrically along the apical-basal axis. The Inscuteable protein localizes to the apical cell cortex in neuroblasts from interphase to metaphase, but disappears in anaphase. Inscuteable is required for correct spindle orientation and for asymmetric localization of cell fate determinants to the opposite (basal) cell cortex. Here, we show that Inscuteable also directs asymmetric protein localization to the apical cell cortex during later stages of mitosis. In a two-hybrid screen for Inscuteable-binding proteins, we have identified the coiled-coil protein Cornetto, which shows a highly unusual subcellular distribution in neuroblasts. Although the protein is uniformly distributed in the cytoplasm during metaphase, it concentrates apically in anaphase and forms an apical crescent during telophase in an inscuteable-dependent manner. Upon overexpression, Cornetto localizes to astral microtubules and microtubule spin-down experiments demonstrate that Cornetto is a microtubule-binding protein. After disruption of the actin cytoskeleton, Cornetto localizes with microtubules throughout the cell cycle and decorates the mitotic spindle during metaphase. Our results reveal a novel pattern of asymmetric protein localization in Drosophila neuroblasts and are consistent with a function of Cornetto in anchoring the mitotic spindle during late phases of mitosis, even though our cornetto mutant analysis suggests that this function might be obscured by genetic redundancy.

Published
2001
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42. Bazooka and PAR-6 are required with PAR-1 for the maintenance of oocyte fate in Drosophila.

Author

Huynh JR, Petronczki M, Knoblich JA, and St Johnston D

Subjects
Animals, Body Patterning, Carrier Proteins genetics, Cell Differentiation, Cell Polarity, Female, Insect Proteins genetics, Oocytes physiology, Ovum physiology, Protein Serine-Threonine Kinases genetics, Proteins genetics, Caenorhabditis elegans Proteins, Carrier Proteins metabolism, Drosophila physiology, Drosophila Proteins, Insect Proteins metabolism, Intracellular Signaling Peptides and Proteins, Oogenesis physiology, Protein Serine-Threonine Kinases metabolism, Proteins metabolism
Abstract

The anterior-posterior axis of C. elegans is defined by the asymmetric division of the one-cell zygote, and this is controlled by the PAR proteins, including PAR-3 and PAR-6, which form a complex at the anterior of the cell, and PAR-1, which localizes at the posterior [1-4]. PAR-1 plays a similar role in axis formation in Drosophila: the protein localizes to the posterior of the oocyte and is necessary for the localization of the posterior and germline determinants [5, 6]. PAR-1 has recently been shown to have an earlier function in oogenesis, where it is required for the maintenance of oocyte fate and the posterior localization of oocyte-specific markers [7, 8]. Here, we show that the homologs of PAR-3 (Bazooka) and PAR-6 are also required to maintain oocyte fate. Germline clones of mutants in either gene give rise to egg chambers that develop 16 nurse cells and no oocyte. Furthermore, oocyte-specific factors, such as Orb protein and the centrosomes, still localize to one cell but fail to move from the anterior to the posterior cortex. Thus, PAR-1, Bazooka, and PAR-6 are required for the earliest polarity in the oocyte, providing the first example in Drosophila where the three homologs function in the same process. Although these PAR proteins therefore seem to play a conserved role in early anterior-posterior polarity in C. elegans and Drosophila, the relationships between them are different, as the localization of PAR-1 does not require Bazooka or PAR-6 in Drosophila, as it does in the worm.

Published
2001
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43. Asymmetric cell division during animal development.

Author

Knoblich JA

Subjects
Animals, Caenorhabditis elegans cytology, Caenorhabditis elegans growth & development, Cell Polarity, Drosophila melanogaster cytology, Drosophila melanogaster growth & development, Helminth Proteins physiology, Heterotrimeric GTP-Binding Proteins physiology, Insect Proteins physiology, Models, Biological, Stem Cells cytology, Cell Division physiology
Abstract

Although most cells produce two equal daughters during mitosis, some can divide asymmetrically by segregating protein determinants into one of their two daughter cells. Interesting parallels exist between such asymmetric divisions and the polarity established in epithelial cells, and heterotrimeric G proteins might connect these aspects of cell polarity. The discovery of asymmetrically segregating proteins in vertebrates indicates that the results obtained in invertebrate model organisms might also apply to mammalian stem cells.

Published
2001
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44. DmPAR-6 directs epithelial polarity and asymmetric cell division of neuroblasts in Drosophila.

Author

Petronczki M and Knoblich JA

Subjects
Animals, Binding Sites genetics, Body Patterning genetics, Caenorhabditis elegans Proteins, Carrier Proteins genetics, Cell Cycle Proteins metabolism, Cell Differentiation genetics, Drosophila cytology, Drosophila metabolism, Embryo, Nonmammalian embryology, Embryo, Nonmammalian metabolism, Epithelium metabolism, Gene Expression Regulation, Developmental physiology, Juvenile Hormones metabolism, Nervous System metabolism, Neurons cytology, Neurons metabolism, Proteins genetics, Carrier Proteins metabolism, Cell Division physiology, Cell Polarity physiology, Drosophila embryology, Drosophila Proteins, Epithelium embryology, Intracellular Signaling Peptides and Proteins, Nervous System embryology, Proteins metabolism
Abstract

The Drosophila protein Bazooka is required for both apical-basal polarity in epithelial cells and directing asymmetric cell division in neuroblasts. Here we show that the PDZ-domain protein DmPAR-6 cooperates with Bazooka for both of these functions. DmPAR-6 colocalizes with Bazooka at the apical cell cortex of epithelial cells and neuroblasts, and binds to Bazooka in vitro. DmPAR-6 localization requires Bazooka, and mislocalization of Bazooka through overexpression redirects DmPAR-6 to ectopic sites of the cell cortex. In the absence of DmPAR-6, Bazooka fails to localize apically in neuroblasts and epithelial cells, and is distributed in the cytoplasm instead. Epithelial cells lose their apical-basal polarity in DmPAR-6 mutants, asymmetric cell divisions in neuroblasts are misorientated, and the proteins Numb and Miranda do not segregate correctly into the basal daughter cell. Bazooka and DmPAR-6 are Drosophila homologues of proteins that direct asymmetric cell division in early Caenorhabditis elegans embryos, and our results indicate that homologous protein machineries may direct this process in worms and flies.

Published
2001
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45. The Drosophila nervous system as a model for asymmetric cell division.

Author

Knoblich JA

Subjects
Animals, Carrier Proteins physiology, Cell Differentiation physiology, Cell Division physiology, Drosophila Proteins physiology, Frizzled Receptors, Insect Proteins physiology, Juvenile Hormones physiology, Membrane Proteins metabolism, Membrane Proteins physiology, Models, Biological, Receptors, G-Protein-Coupled, Receptors, Notch, Signal Transduction physiology, Cell Cycle Proteins, Drosophila embryology, Intracellular Signaling Peptides and Proteins, Nervous System embryology
Published
2001

46. Epithelial polarity: the ins and outs of the fly epidermis.

Author

Knoblich JA

Subjects
Animals, Drosophila genetics, Embryo, Nonmammalian cytology, Epidermis embryology, Fluorescent Dyes, Microscopy methods, Wheat Germ Agglutinins metabolism, Cell Membrane metabolism, Cell Polarity, Drosophila embryology, Epidermal Cells, Epithelial Cells cytology
Abstract

Epithelial cells must polarize and establish apical and basolateral membrane domains during development. Recent experiments have shed light on how apical-basal polarity is generated during cellularization in Drosophila, when around 6000 epithelial cells are created synchronously from a syncytium.

Published
2000
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47. A protein complex containing Inscuteable and the Galpha-binding protein Pins orients asymmetric cell divisions in Drosophila.

Author

Schaefer M, Shevchenko A, Shevchenko A, and Knoblich JA

Subjects
Amino Acid Sequence, Animals, Biological Transport, Carrier Proteins metabolism, Cell Division, Epithelial Cells cytology, Insect Proteins genetics, Models, Biological, Molecular Sequence Data, Neuropeptides, Signal Transduction, Stem Cells cytology, Cell Cycle Proteins, Cell Polarity, Cytoskeletal Proteins metabolism, Drosophila cytology, Drosophila Proteins, Heterotrimeric GTP-Binding Proteins metabolism, Insect Proteins metabolism, Intracellular Signaling Peptides and Proteins, Nerve Tissue cytology
Abstract

Background: In the fruit fly Drosophila, the Inscuteable protein localises to the apical cell cortex in neuroblasts and directs both the apical-basal orientation of the mitotic spindle and the basal localisation of the protein determinants Numb and Prospero during mitosis. Asymmetric localisation of Inscuteable is initiated during neuroblast delamination by direct binding to Bazooka, an apically localised protein that contains protein-interaction motifs known as PDZ domains. How apically localised Inscuteable directs asymmetric cell divisions is unclear., Results: A novel 70 kDa protein called Partner of Inscuteable (Pins) and a heterotrimeric G-protein alpha subunit were found to bind specifically to the functional domain of Inscuteable in vivo. The predicted sequence of Pins contained tetratrico-peptide repeats (TPRs) and motifs implicated in binding Galpha proteins. Pins colocalised with Inscuteable at the apical cell cortex in interphase and mitotic neuroblasts. Asymmetric localisation of Pins required both Inscuteable and Bazooka. In epithelial cells, which do not express inscuteable, Pins was not apically localised but could be recruited to the apical cortex by ectopic expression of Inscuteable. In pins mutants, these epithelial cells were not affected, but neuroblasts showed defects in the orientation of their mitotic spindle and the basal asymmetric localisation of Numb and Miranda during metaphase. Although localisation of Inscuteable in pins mutants was initiated correctly during neuroblast delamination, Inscuteable became homogeneously distributed in the cytoplasm during mitosis., Conclusions: Pins and Inscuteable are dependent on each other for asymmetric localisation in delaminated neuroblasts. The binding of Pins to Galpha protein offers the intriguing possibility that Inscuteable and Pins might orient asymmetric cell divisions by localising or locally modulating a heterotrimeric G-protein signalling cascade at the apical cell cortex.

Published
2000
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48. Bazooka recruits Inscuteable to orient asymmetric cell divisions in Drosophila neuroblasts.

Author

Schober M, Schaefer M, and Knoblich JA

Subjects
Animals, Cell Cycle Proteins physiology, Cell Differentiation physiology, Cell Division physiology, Cell Movement, Cell Polarity, Cytoskeletal Proteins genetics, Drosophila embryology, Drosophila genetics, Drosophila physiology, Insect Proteins physiology, Juvenile Hormones physiology, Mutation, Neuropeptides, Precipitin Tests, Protein Binding, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Carrier Proteins physiology, Cytoskeletal Proteins physiology, Drosophila Proteins, Intracellular Signaling Peptides and Proteins, Neurons physiology
Abstract

Asymmetric cell divisions can be generated by the segregation of determinants into one of the two daughter cells. In Drosophila, neuroblasts divide asymmetrically along the apical-basal axis shortly after their delamination from the neuroectodermal epithelium. Several proteins, including Numb and Miranda, segregate into the basal daughter cell and are needed for the determination of its correct cell fate. Both the apical-basal orientation of the mitotic spindle and the localization of Numb and Miranda to the basal cell cortex are directed by Inscuteable, a protein that localizes to the apical cell cortex before and during neuroblast mitosis. Here we show that the apical localizaton of Inscuteable requires Bazooka, a protein containing a PDZ domain that is essential for apical-basal polarity in epithelial cells. Bazooka localizes with Inscuteable in neuroblasts and binds to the Inscuteable localization domain in vitro and in vivo. In embryos lacking both maternal and zygotic bazooka function, Inscuteable no longer localizes asymmetrically in neuroblasts and is instead uniformly distributed in the cytoplasm. Mitotic spindles in neuroblasts are misoriented in these embryos, and the proteins Numb and Miranda fail to localize asymmetrically in metaphase. Our results suggest that direct binding to Bazooka mediates the asymmetric localization of Inscuteable and connects the asymmetric division of neuroblasts to the axis of epithelial apical-basal polarity.

Published
1999
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49. Deletion analysis of the Drosophila Inscuteable protein reveals domains for cortical localization and asymmetric localization.

Author

Knoblich JA, Jan LY, and Jan YN

Subjects
Animals, Cell Cycle Proteins metabolism, Cell Division, Cell Polarity, Cytoskeletal Proteins genetics, In Situ Hybridization, Insect Proteins genetics, Juvenile Hormones metabolism, Microscopy, Fluorescence, Nerve Tissue Proteins genetics, Nervous System cytology, Nervous System embryology, Neuropeptides, Nuclear Proteins metabolism, Recombinant Fusion Proteins metabolism, Stem Cells chemistry, Stem Cells ultrastructure, Cytoskeletal Proteins metabolism, Drosophila Proteins, Drosophila melanogaster genetics, Insect Proteins metabolism, Nerve Tissue Proteins metabolism, Sequence Deletion, Transcription Factors
Abstract

The Drosophila Inscuteable protein acts as a key regulator of asymmetric cell division during the development of the nervous system [1] [2]. In neuroblasts, Inscuteable localizes into an apical cortical crescent during late interphase and most of mitosis. During mitosis, Inscuteable is required for the correct apical-basal orientation of the mitotic spindle and for the asymmetric segregation of the proteins Numb [3] [4] [5], Prospero [5] [6] [7] and Miranda [8] [9] into the basal daughter cell. When Inscuteable is ectopically expressed in epidermal cells, which normally orient their mitotic spindle parallel to the embryo surface, these cells reorient their mitotic spindle and divide perpendicularly to the surface [1]. Like the Inscuteable protein, the inscuteable RNA is asymmetrically localized [10]. We show here that inscuteable RNA localization is not required for Inscuteable protein localization. We found that a central 364 amino acid domain - the Inscuteable asymmetry domain - was necessary and sufficient for Inscuteable localization and function. Within this domain, a separate 100 amino acid region was required for asymmetric localization along the cortex, whereas a 158 amino acid region directed localization to the cell cortex. The same 158 amino acid fragment could localize asymmetrically when coexpressed with the full-length protein, however, and could bind to Inscuteable in vitro, suggesting that this domain may be involved in the self-association of Inscuteable in vivo.

Published
1999
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50. The N terminus of the Drosophila Numb protein directs membrane association and actin-dependent asymmetric localization.

Author

Knoblich JA, Jan LY, and Jan YN

Subjects
Animals, Bridged Bicyclo Compounds, Heterocyclic pharmacology, Drosophila Proteins, Juvenile Hormones chemistry, Juvenile Hormones genetics, Myristic Acid metabolism, Thiazoles pharmacology, Thiazolidines, Drosophila metabolism, Juvenile Hormones metabolism
Abstract

Drosophila Numb is a membrane associated protein of 557 amino acids (aa) that localizes asymmetrically into a cortical crescent in mitotic neural precursor cells and segregates into one of the daughter cells, where it is required for correct cell fate specification. We demonstrate here that asymmetric localization but not membrane localization of Numb in Drosophila embryos is inhibited by latrunculin A, an inhibitor of actin assembly. We also show that deletion of either the first 41 aa or aa 41-118 of Numb eliminates both localization to the cell membrane and asymmetric localization during mitosis, whereas C-terminal deletions or deletions of central portions of Numb do not affect its subcellular localization. Fusion of the first 76 or the first 119 aa of Numb to beta-galactosidase results in a fusion protein that localizes to the cell membrane, but fails to localize asymmetrically during mitosis. In contrast, a fusion protein containing the first 227 aa of Numb and beta-galactosidase localizes asymmetrically during mitosis and segregates into the same daughter cell as the endogenous Numb protein, demonstrating that the first 227 aa of the Numb protein are sufficient for asymmetric localization.

Published
1997
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