TY  - JOUR
A1  - Galluzzi, L.
A1  - Bravo-San Pedro, J. M.
A1  - Vitale, I.
A1  - Aaronson, S. A.
A1  - Abrams, J. M.
A1  - Adam, D.
A1  - Alnemri, E. S.
A1  - Altucci, L.
A1  - Andrews, D.
A1  - Annicchiarico-Petruzelli, M.
A1  - Baehrecke, E. H.
A1  - Bazan, N. G.
A1  - Bertrand, M. J.
A1  - Bianchi, K.
A1  - Blagosklonny, M. V.
A1  - Blomgren, K.
A1  - Borner, C.
A1  - Bredesen, D. E.
A1  - Brenner, C.
A1  - Campanella, M.
A1  - Candi, E.
A1  - Cecconi, F.
A1  - Chan, F. K.
A1  - Chandel, N. S.
A1  - Cheng, E. H.
A1  - Chipuk, J. E.
A1  - Cidlowski, J. A.
A1  - Ciechanover, A.
A1  - Dawson, T. M.
A1  - Dawson, V. L.
A1  - De Laurenzi, V.
A1  - De Maria, R.
A1  - Debatin, K. M.
A1  - Di Daniele, N.
A1  - Dixit, V. M.
A1  - Dynlacht, B. D.
A1  - El-Deiry, W. S.
A1  - Fimia, G. M.
A1  - Flavell, R. A.
A1  - Fulda, S.
A1  - Garrido, C.
A1  - Gougeon, M. L.
A1  - Green, D. R.
A1  - Gronemeyer, H.
A1  - Hajnoczky, G.
A1  - Hardwick, J. M.
A1  - Hengartner, M. O.
A1  - Ichijo, H.
A1  - Joseph, B.
A1  - Jost, P. J.
A1  - Kaufmann, T.
A1  - Kepp, O.
A1  - Klionsky, D. J.
A1  - Knight, R. A.
A1  - Kumar, S.
A1  - Lemasters, J. J.
A1  - Levine, B.
A1  - Linkermann, A.
A1  - Lipton, S. A.
A1  - Lockshin, R. A.
A1  - López-Otín, C.
A1  - Lugli, E.
A1  - Madeo, F.
A1  - Malorni, W.
A1  - Marine, J. C.
A1  - Martin, S. J.
A1  - Martinou, J. C.
A1  - Medema, J. P.
A1  - Meier, P.
A1  - Melino, S.
A1  - Mizushima, N.
A1  - Moll, U.
A1  - Muñoz-Pinedo, C.
A1  - Nuñez, G.
A1  - Oberst, A.
A1  - Panaretakis, T.
A1  - Penninger, J. M.
A1  - Peter, M. E.
A1  - Piacentini, M.
A1  - Pinton, P.
A1  - Prehn, J. H.
A1  - Puthalakath, H.
A1  - Rabinovich, G. A.
A1  - Ravichandran, K. S.
A1  - Rizzuto, R.
A1  - Rodrigues, C. M.
A1  - Rubinsztein, D. C.
A1  - Rudel, T.
A1  - Shi, Y.
A1  - Simon, H. U.
A1  - Stockwell, B. R.
A1  - Szabadkai, G.
A1  - Tait, S. W.
A1  - Tang, H. L.
A1  - Tavernarakis, N.
A1  - Tsujimoto, Y.
A1  - Vanden Berghe, T.
A1  - Vandenabeele, P.
A1  - Villunger, A.
A1  - Wagner, E. F.
A1  - Walczak, H.
A1  - White, E.
A1  - Wood, W. G.
A1  - Yuan, J.
A1  - Zakeri, Z.
A1  - Zhivotovsky, B.
A1  - Melino, G.
A1  - Kroemer, G.
T1  - Essential versus accessory aspects of cell death: recommendations of the NCCD 2015
JF  - Cell Death and Differentiation
N2  - Cells exposed to extreme physicochemical or mechanical stimuli die in an uncontrollable manner, as a result of their immediate structural breakdown. Such an unavoidable variant of cellular demise is generally referred to as 'accidental cell death' (ACD). In most settings, however, cell death is initiated by a genetically encoded apparatus, correlating with the fact that its course can be altered by pharmacologic or genetic interventions. 'Regulated cell death' (RCD) can occur as part of physiologic programs or can be activated once adaptive responses to perturbations of the extracellular or intracellular microenvironment fail. The biochemical phenomena that accompany RCD may be harnessed to classify it into a few subtypes, which often (but not always) exhibit stereotyped morphologic features. Nonetheless, efficiently inhibiting the processes that are commonly thought to cause RCD, such as the activation of executioner caspases in the course of apoptosis, does not exert true cytoprotective effects in the mammalian system, but simply alters the kinetics of cellular demise as it shifts its morphologic and biochemical correlates. Conversely, bona fide cytoprotection can be achieved by inhibiting the transduction of lethal signals in the early phases of the process, when adaptive responses are still operational. Thus, the mechanisms that truly execute RCD may be less understood, less inhibitable and perhaps more homogeneous than previously thought. Here, the Nomenclature Committee on Cell Death formulates a set of recommendations to help scientists and researchers to discriminate between essential and accessory aspects of cell death.
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-121207
VL  - 22
ER  - 
TY  - JOUR
A1  - Davis, Lea K.
A1  - Yu, Dongmei
A1  - Keenan, Clare L.
A1  - Gamazon, Eric R.
A1  - Konkashbaev, Anuar I.
A1  - Derks, Eske M.
A1  - Neale, Benjamin M.
A1  - Yang, Jian
A1  - Lee, S. Hong
A1  - Evans, Patrick
A1  - Barr, Cathy L.
A1  - Bellodi, Laura
A1  - Benarroch, Fortu
A1  - Berrio, Gabriel Bedoya
A1  - Bienvenu, Oscar J.
A1  - Bloch, Michael H.
A1  - Blom, Rianne M.
A1  - Bruun, Ruth D.
A1  - Budman, Cathy L.
A1  - Camarena, Beatriz
A1  - Campbell, Desmond
A1  - Cappi, Carolina
A1  - Cardona Silgado, Julio C.
A1  - Cath, Danielle C.
A1  - Cavallini, Maria C.
A1  - Chavira, Denise A.
A1  - Chouinard, Sylvian
A1  - Conti, David V.
A1  - Cook, Edwin H.
A1  - Coric, Vladimir
A1  - Cullen, Bernadette A.
A1  - Deforce, Dieter
A1  - Delorme, Richard
A1  - Dion, Yves
A1  - Edlund, Christopher K.
A1  - Egberts, Karin
A1  - Falkai, Peter
A1  - Fernandez, Thomas V.
A1  - Gallagher, Patience J.
A1  - Garrido, Helena
A1  - Geller, Daniel
A1  - Girard, Simon L.
A1  - Grabe, Hans J.
A1  - Grados, Marco A.
A1  - Greenberg, Benjamin D.
A1  - Gross-Tsur, Varda
A1  - Haddad, Stephen
A1  - Heiman, Gary A.
A1  - Hemmings, Sian M. J.
A1  - Hounie, Ana G.
A1  - Illmann, Cornelia
A1  - Jankovic, Joseph
A1  - Jenike, Micheal A.
A1  - Kennedy, James L.
A1  - King, Robert A.
A1  - Kremeyer, Barbara
A1  - Kurlan, Roger
A1  - Lanzagorta, Nuria
A1  - Leboyer, Marion
A1  - Leckman, James F.
A1  - Lennertz, Leonhard
A1  - Liu, Chunyu
A1  - Lochner, Christine
A1  - Lowe, Thomas L.
A1  - Macciardi, Fabio
A1  - McCracken, James T.
A1  - McGrath, Lauren M.
A1  - Restrepo, Sandra C. Mesa
A1  - Moessner, Rainald
A1  - Morgan, Jubel
A1  - Muller, Heike
A1  - Murphy, Dennis L.
A1  - Naarden, Allan L.
A1  - Ochoa, William Cornejo
A1  - Ophoff, Roel A.
A1  - Osiecki, Lisa
A1  - Pakstis, Andrew J.
A1  - Pato, Michele T.
A1  - Pato, Carlos N.
A1  - Piacentini, John
A1  - Pittenger, Christopher
A1  - Pollak, Yehunda
A1  - Rauch, Scott L.
A1  - Renner, Tobias J.
A1  - Reus, Victor I.
A1  - Richter, Margaret A.
A1  - Riddle, Mark A.
A1  - Robertson, Mary M.
A1  - Romero, Roxana
A1  - Rosàrio, Maria C.
A1  - Rosenberg, David
A1  - Rouleau, Guy A.
A1  - Ruhrmann, Stephan
A1  - Ruiz-Linares, Andreas
A1  - Sampaio, Aline S.
A1  - Samuels, Jack
A1  - Sandor, Paul
A1  - Sheppard, Broke
A1  - Singer, Harvey S.
A1  - Smit, Jan H.
A1  - Stein, Dan J.
A1  - Strengman, E.
A1  - Tischfield, Jay A.
A1  - Valencia Duarte, Ana V.
A1  - Vallada, Homero
A1  - Van Nieuwerburgh, Flip
A1  - Veenstra-VanderWeele, Jeremy
A1  - Walitza, Susanne
A1  - Wang, Ying
A1  - Wendland, Jens R.
A1  - Westenberg, Herman G. M.
A1  - Shugart, Yin Yao
A1  - Miguel, Euripedes C.
A1  - McMahon, William
A1  - Wagner, Michael
A1  - Nicolini, Humberto
A1  - Posthuma, Danielle
A1  - Hanna, Gregory L.
A1  - Heutink, Peter
A1  - Denys, Damiaan
A1  - Arnold, Paul D.
A1  - Oostra, Ben A.
A1  - Nestadt, Gerald
A1  - Freimer, Nelson B.
A1  - Pauls, David L.
A1  - Wray, Naomi R.
A1  - Stewart, S. Evelyn
A1  - Mathews, Carol A.
A1  - Knowles, James A.
A1  - Cox, Nancy J.
A1  - Scharf, Jeremiah M.
T1  - Partitioning the Heritability of Tourette Syndrome and Obsessive Compulsive Disorder Reveals Differences in Genetic Architecture
JF  - PLoS Genetics
N2  - The direct estimation of heritability from genome-wide common variant data as implemented in the program Genome-wide Complex Trait Analysis (GCTA) has provided a means to quantify heritability attributable to all interrogated variants. We have quantified the variance in liability to disease explained by all SNPs for two phenotypically-related neurobehavioral disorders, obsessive-compulsive disorder (OCD) and Tourette Syndrome (TS), using GCTA. Our analysis yielded a heritability point estimate of 0.58 (se = 0.09, p = 5.64e-12) for TS, and 0.37 (se = 0.07, p = 1.5e-07) for OCD. In addition, we conducted multiple genomic partitioning analyses to identify genomic elements that concentrate this heritability. We examined genomic architectures of TS and OCD by chromosome, MAF bin, and functional annotations. In addition, we assessed heritability for early onset and adult onset OCD. Among other notable results, we found that SNPs with a minor allele frequency of less than 5% accounted for 21% of the TS heritability and 0% of the OCD heritability. Additionally, we identified a significant contribution to TS and OCD heritability by variants significantly associated with gene expression in two regions of the brain (parietal cortex and cerebellum) for which we had available expression quantitative trait loci (eQTLs). Finally we analyzed the genetic correlation between TS and OCD, revealing a genetic correlation of 0.41 (se = 0.15, p = 0.002). These results are very close to previous heritability estimates for TS and OCD based on twin and family studies, suggesting that very little, if any, heritability is truly missing (i.e., unassayed) from TS and OCD GWAS studies of common variation. The results also indicate that there is some genetic overlap between these two phenotypically-related neuropsychiatric disorders, but suggest that the two disorders have distinct genetic architectures.
KW  - TIC disorders
KW  - missing heritability
KW  - complex diseases
KW  - neuropsychiatric disorders
KW  - common SNPS
KW  - gilles
KW  - family
KW  - brain
KW  - expression
KW  - autism
Y1  - 2013
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-127377
SN  - 1553-7390
VL  - 9
IS  - 10
ER  - 
TY  - JOUR
A1  - Hartmann, Oliver
A1  - Reissland, Michaela
A1  - Maier, Carina R.
A1  - Fischer, Thomas
A1  - Prieto-Garcia, Cristian
A1  - Baluapuri, Apoorva
A1  - Schwarz, Jessica
A1  - Schmitz, Werner
A1  - Garrido-Rodriguez, Martin
A1  - Pahor, Nikolett
A1  - Davies, Clare C.
A1  - Bassermann, Florian
A1  - Orian, Amir
A1  - Wolf, Elmar
A1  - Schulze, Almut
A1  - Calzado, Marco A.
A1  - Rosenfeldt, Mathias T.
A1  - Diefenbacher, Markus E.
T1  - Implementation of CRISPR/Cas9 Genome Editing to Generate Murine Lung Cancer Models That Depict the Mutational Landscape of Human Disease
JF  - Frontiers in Cell and Developmental Biology
N2  - Lung cancer is the most common cancer worldwide and the leading cause of cancer-related deaths in both men and women. Despite the development of novel therapeutic interventions, the 5-year survival rate for non-small cell lung cancer (NSCLC) patients remains low, demonstrating the necessity for novel treatments. One strategy to improve translational research is the development of surrogate models reflecting somatic mutations identified in lung cancer patients as these impact treatment responses. With the advent of CRISPR-mediated genome editing, gene deletion as well as site-directed integration of point mutations enabled us to model human malignancies in more detail than ever before. Here, we report that by using CRISPR/Cas9-mediated targeting of Trp53 and KRas, we recapitulated the classic murine NSCLC model Trp53fl/fl:lsl-KRasG12D/wt. Developing tumors were indistinguishable from Trp53fl/fl:lsl-KRasG12D/wt-derived tumors with regard to morphology, marker expression, and transcriptional profiles. We demonstrate the applicability of CRISPR for tumor modeling in vivo and ameliorating the need to use conventional genetically engineered mouse models. Furthermore, tumor onset was not only achieved in constitutive Cas9 expression but also in wild-type animals via infection of lung epithelial cells with two discrete AAVs encoding different parts of the CRISPR machinery. While conventional mouse models require extensive husbandry to integrate new genetic features allowing for gene targeting, basic molecular methods suffice to inflict the desired genetic alterations in vivo. Utilizing the CRISPR toolbox, in vivo cancer research and modeling is rapidly evolving and enables researchers to swiftly develop new, clinically relevant surrogate models for translational research.
KW  - non-small cell lung cancer
KW  - CRISPR-Cas9
KW  - mouse model
KW  - lung cancer
KW  - MYC
KW  - JUN
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-230949
SN  - 2296-634X
VL  - 9
ER  -