Generation of mice with longer and better preserved telomeres in the absence of genetic manipulations

Although telomere length is genetically determined, mouse embryonic stem (ES) cells with telomeres of twice the normal size have been generated. Here, we use such ES cells with 'hyper-long' telomeres, which also express green fluorescent protein (GFP), to generate chimaeric mice containing cells with both hyper-long and normal telomeres. We show that chimaeric mice contain GFP-positive cells in all mouse tissues, display normal tissue histology and normal survival. Both hyper-long and normal telomeres shorten with age, but GFP-positive cells retain longer telomeres as mice age. Chimaeric mice with hyper-long telomeres also accumulate fewer cells with short telomeres and less DNA damage with age, and express lower levels of p53. In highly renewing compartments, such as the blood, cells with hyper-long telomeres are longitudinally maintained or enriched with age. We further show that wound-healing rates in the skin are increased in chimaeric mice. Our work demonstrates that mice with functional, longer and better preserved telomeres can be generated without the need for genetic manipulations, such as TERT overexpression.M. A. Blasco’s laboratory is funded by the Spanish Ministry of Economy and Competitiveness Project SAF2013-45111RETOS, the European Union FP7 Project EUROBATS, the European Research Council (ERC) Project TEL STEM CELL (GA#232854), the Regional Government of Madrid 2þ2 ReCaRe, the AXA Research Fund and the Fundacion BotınS

Endogenous retroviruses shape pluripotency specification in mouse embryos.

The smooth and precise transition from totipotency to pluripotency is a key process in embryonic development, generating pluripotent stem cells capable of forming all cell types. While endogenous retroviruses (ERVs) are essential for early development, their precise roles in this transition remains mysterious. Using cutting-edge genetic and biochemical techniques in mice, we identify MERVL-gag, a retroviral protein, as a crucial modulator of pluripotent factors OCT4 and SOX2 during lineage specification. MERVL-gag tightly operates with URI, a prefoldin protein that concurs with pluripotency bias in mouse blastomeres, and which is indeed required for totipotency-to-pluripotency transition. Accordingly, URI loss promotes a stable totipotent-like state and embryo arrest at 2C stage. Mechanistically, URI binds and shields OCT4 and SOX2 from proteasome degradation, while MERVL-gag displaces URI from pluripotent factor interaction, causing their degradation. Our findings reveal the symbiotic coevolution of ERVs with their host cells to ensure the smooth and timely progression of early embryo development.acknowledgments: We thank all mouse providers as described in Materials and Methods. We also thank the cniO Animal Facility for mouse maintenance. We acknowledge M. Ko (Keio University, Systems Medicine, Japan) for providing the pZscan4- emerald reporter plasmid. Funding: S.d.l.R. was supported by a fellowship from the comunidad de Madrid and by funds from the Severo Ochoa- cniO. this work was funded by grants to n.d. supported by the State Research Agency (Aei; 10.13039/501100011033) from the Spanish Ministry of Science and innovation (Rti2018- 094834- B- i00 and Pid2021- 122695OB- i00), also including the idiFFeR network of excellence (Red2022- 134792- t), cofunded by european Regional development Fund (eRdF), by the comunidad Autónoma de Madrid (S2017/BMd- 3817), and by the Asociación española contra el cáncer (Aecc) (PRYGn211184dJOU). this work was developed at the cniO funded by the health institute carlos iii (iSciii) and the Spanish Ministry of Science and innovation. Author contributions: S.d.l.R. designed and performed the experiments and analyzed all the data. S.d.l.R. analyzed all the bioinformatics data. M.d.M.R. performed some experiments. P.v. and S.O. performed microinjection in vivo and chimera embryo assay. S.d.l.R and n.d. developed the project and wrote the manuscript. n.d. conceived the project and secured funding. Competing interests:the authors declare that they have no competing interests. Data and materials availability: All data are available in the main text or Materials and Methods. Materials are available upon request to n.d. and the sharing of materials described in this work will be subject to standard material transfer agreementsS

A Genome-wide CRISPR Screen Identifies CDC25A as a Determinant of Sensitivity to ATR Inhibitors

One recurring theme in drug development is to exploit synthetic lethal properties as means to preferentially damage the DNA of cancer cells. We and others have previously developed inhibitors of the ATR kinase, shown to be particularly genotoxic for cells expressing certain oncogenes. In contrast, the mechanisms of resistance to ATR inhibitors remain unexplored. We report here on a genome-wide CRISPR-Cas9 screen that identified CDC25A as a major determinant of sensitivity to ATR inhibition. CDC25A-deficient cells resist high doses of ATR inhibitors, which we show is due to their failure to prematurely enter mitosis in response to the drugs. Forcing mitotic entry with WEE1 inhibitors restores the toxicity of ATR inhibitors in CDC25A-deficient cells. With ATR inhibitors now entering the clinic, our work provides a better understanding of the mechanisms by which these compounds kill cells and reveals genetic interactions that could be used for their rational use.We thank the laboratories of Feng Zhang and Kosuke Yusa for sharing all CRISPR-related plasmids used here through Addgene (plasmids 42230, 50946, and 50947) and Edna Fonseca for her comments on the manuscript. Research was funded by Fundacion Botin, Banco Santander, through its Santander Universities Global Division and by grants from the Spanish Ministry of Economy and Competitiveness (MINECO) (SAF2011-23753 and SAF2014-57791-REDC), Fundacio La Marato de TV3, the Howard Hughes Medical Institute, and the European Research Council (ERC-617840) to O.F.-C.; by a PhD fellowship from La Caixa Foundation to C.M.-R.; by grants from MINECO to S.R. (RYC2011-09242 and SAF2013-49147P, this last project co-financed with European FEDER funds); and by a grant from MINECO (SAF2013-44866-R) to S.O.S

A Chemical Screen Identifies Compounds Capable of Selecting for Haploidy in Mammalian Cells

The recent availability of somatic haploid cell lines has provided a unique tool for genetic studies in mammals. However, the percentage of haploid cells rapidly decreases in these cell lines, which we recently showed is due to their overgrowth by diploid cells present in the cultures. Based on this property, we have now performed a phenotypic chemical screen in human haploid HAP1 cells aiming to identify compounds that facilitate the maintenance of haploid cells. Our top hit was 10-Deacetyl-baccatin-III (DAB), a chemical precursor in the synthesis of Taxol, which selects for haploid cells in HAP1 and mouse haploid embryonic stem cultures. Interestingly, DAB also enriches for diploid cells in mixed cultures of diploid and tetraploid cells, including in the colon cancer cell line DLD-1, revealing a general strategy for selecting cells with lower ploidy in mixed populations of mammalian cells.We would like to thank the members of the O.F.-C. laboratory and MonicaAlvarez-Fernandez for insightful comments and the Transgenic Mice, FlowCytometry, and Confocal Microscopy Units from the CNIO for their technicalhelp. T.O. was funded by a PhD fellowship from Boehringer IngelheimFonds. Research was funded by Fundacion Botı n, Banco Santander throughits Santander Universities Global Division, and by grants from MINECO(SAF2014-57791-REDC and SAF2014-59498-R to O.F.-C., SAF-2013-44866-R to S.O., and SAF2013-49147-P and SAF2016-80874-P to S.R.; pro-jects that were co-financed with ERDF-EU funds) and the EuropeanResearch Council (ERC-617840). Research at the G.d.C. laboratory is fundedby the AECC Scientific Foundation (LABAE16017DECA).S

ERF deletion rescues RAS deficiency in mouse embryonic stem cells

MEK inhibition in combination with a glycogen synthase kinase-3β (GSK3β) inhibitor, referred as the 2i condition, favors pluripotency in embryonic stem cells (ESCs). However, the mechanisms by which the 2i condition limits ESC differentiation and whether RAS proteins are involved in this phenomenon remain poorly understood. Here we show that RAS nullyzygosity reduces the growth of mouse ESCs (mESCs) and prohibits their differentiation. Upon RAS deficiency or MEK inhibition, ERF (E twenty-six 2 [Ets2]-repressive factor), a transcriptional repressor from the ETS domain family, translocates to the nucleus, where it binds to the enhancers of pluripotency factors and key RAS targets. Remarkably, deletion of Erf rescues the proliferative defects of RAS-devoid mESCs and restores their capacity to differentiate. Furthermore, we show that Erf loss enables the development of RAS nullyzygous teratomas. In summary, this work reveals an essential role for RAS proteins in pluripotency and identifies ERF as a key mediator of the response to RAS/MEK/ERK inhibition in mESCs.We thank Cian Lynch, Jorge Monsech, and Diego Megias for their help with microarray, ChIP-seq, and high-throughput microscopy analyses. We also thank Dr. Manuel Serrano and Dr. André Nussenzweig for their input on the manuscript, and Dr. Diego Sanz for his support throughout the project. C.M.-R. was funded by a PhD fellowship from La Caixa Foundation, T.O. was funded by a PhD fellowship from the Boehringer Ingelheim Fonds, and S.R. was funded by a Ramon y Cajal contract (RYC-2011-09242). Research was funded by Fundación Botín and Banco Santander through its Santander Universities Global Division; grants from the Spanish Ministry of Economy and Competitiveness (SAF2011-23753 and SAF2014- 57791-REDC; these projects were cofinanced with European Fonds Européen de Développement Économique et Régional [FEDER] funds), Fundació La Marato de TV3, Howard Hughes Medical Institute, and the European Research Council (ERC- 617840) to O.F.-C.; and grants from the Spanish Ministryof Economy and Competitiveness (SAF2013-49147-P and SAF2016-80874-P; these projects were cofinanced with European FEDER funds) to S.R. Author contributions: C.M.-R. and S.R. conducted most of the experiments; T.O. helped with the characterization of RASlox/lox mESCs and with ERF localization studies; E.L. helped with ChIP-seq experiments; M.D., S.O., and M.B. contributed to the work on RAS-deficient cells; M.V.-S. provided technical help; O.D. helped with genomics experiments and bioinformatics analysis; and S.R. and O.F.-C. coordinated the study and wrote the manuscript.S

KRAS4A induces metastatic lung adenocarcinomas in vivo in the absence of the KRAS4B isoform.

In mammals, the KRAS locus encodes two protein isoforms, KRAS4A and KRAS4B, which differ only in their C terminus via alternative splicing of distinct fourth exons. Previous studies have shown that whereas KRAS expression is essential for mouse development, the KRAS4A isoform is expendable. Here, we have generated a mouse strain that carries a terminator codon in exon 4B that leads to the expression of an unstable KRAS4B154 truncated polypeptide, hence resulting in a bona fide Kras4B-null allele. In contrast, this terminator codon leaves expression of the KRAS4A isoform unaffected. Mice selectively lacking KRAS4B expression developed to term but died perinatally because of hypertrabeculation of the ventricular wall, a defect reminiscent of that observed in embryos lacking the Kras locus. Mouse embryonic fibroblasts (MEFs) obtained from Kras4B-/- embryos proliferated less than did wild-type MEFs, because of limited expression of KRAS4A, a defect that can be compensated for by ectopic expression of this isoform. Introduction of the same terminator codon into a Kras FSFG12V allele allowed expression of an endogenous KRAS4AG12V oncogenic isoform in the absence of KRAS4B. Exposure of Kras +/FSF4AG12V4B- mice to Adeno-FLPo particles induced lung tumors with complete penetrance, albeit with increased latencies as compared with control Kras +/FSFG12V animals. Moreover, a significant percentage of these mice developed proximal metastasis, a feature seldom observed in mice expressing both mutant isoforms. These results illustrate that expression of the KRAS4AG12V mutant isoform is sufficient to induce lung tumors, thus suggesting that selective targeting of the KRAS4BG12V oncoprotein may not have significant therapeutic consequences.We thank Marta San Roman, Raquel Villar, and Nuria Cabrera for excellent technical assistance; Mayte Lamparero and Isabel Blanco (Animal Facility) for mouse work; the Histopathology Unit for processing of mouse tissues; Lola Martinez (Flow Cytometry Unit) for her help with flow cytometry analyses; Diego Megias and Manuel Perez (Confocal Microscopy Unit) for assistance with confocal microscopy; and the Mouse Genome Editing Unit for support with the generation of the mouse strains described here. We also thank Ignacio Perez de Castro (Instituto de Salud Carlos III, Madrid, Spain) for sharing the EGFP-KRAS4B plasmid and Orlando Dominguez (Genomics Unit) and Pedro P. Lopez-Casas (Clinical Research Program) for their advice on exome sequencing. This work was supported by grants from the European Research Council (ERC-2015-AdG/695566, THERACAN), the Spanish Ministry of Science, Innovation and Universities (RTC-2017-6576-1), and the Autonomous Community of Madrid (B2017/BMD-3884 iLUNG-CM); a grant from the CRIS Cancer Foundation (to M.B.); and a grant from the Spanish Ministry of Science, Innovation and Universities (RTI2018-094664-B-I00, to M.B. and M.M.). M.B. is a recipient of an Endowed Chair from the AXA Research Fund. M.S. was supported by predoctoral contract "Severo Ochoa" (BES-2016-079096) from the SpanishMinistry of Science, Innovation and Universities. G.P. was a recipient of a "Young Ph.D." grant from the Government of the Community of Madrid. F.F.-G. was supported by a formacion de profesorado universitario (FPU) fellowship from the Spanish Ministry of Science, Innovation and Universities.S

Live imaging of neolymphangiogenesis identifies acute antimetastatic roles of dsRNA mimics.

Long-range communication between tumor cells and the lymphatic vasculature defines competency for metastasis in different cancer types, particularly in melanoma. Nevertheless, the discovery of selective blockers of lymphovascular niches has been compromised by the paucity of experimental systems for whole-body analyses of tumor progression. Here, we exploit immunocompetent and immunodeficient mouse models for live imaging of Vegfr3-driven neolymphangiogenesis, as a versatile platform for drug screening in vivo. Spatiotemporal analyses of autochthonous melanomas and patient-derived xenografts identified double-stranded RNA mimics (dsRNA nanoplexes) as potent inhibitors of neolymphangiogenesis, metastasis, and post-surgical disease relapse. Mechanistically, dsRNA nanoplexes were found to exert a rapid dual action in tumor cells and in their associated lymphatic vasculature, involving the transcriptional repression of the lymphatic drivers Midkine and Vegfr3, respectively. This suppressive function was mediated by a cell-autonomous type I interferon signaling and was not shared by FDA-approved antimelanoma treatments. These results reveal an alternative strategy for targeting the tumor cell-lymphatic crosstalk and underscore the power of Vegfr3-lymphoreporters for pharmacological testing in otherwise aggressive cancers.The authors thank previous and present colleagues in the CNIO Melanoma Group, particularly Damia Tormo and Lisa Osterloh for help and support at the initial stages of this study; Jose A Esteban (CSIC-UAM) for critical reading of this manuscript; Lionel Larue (INSERM; France) and Martin McMahon (Hunstman Cancer Center, USA) for the Tyr:CreERT2 and BrafCA mouse strains, respectively; and Ignacio Melero at Hospital Clinico, Pamplona, Spain, for Ifnar1-deficient mice. The authors thank Isabel Blanco, Soraya Ruiz, and Virginia Granda (CNIO-Animal Facility Unit), Diego Megias (CNIO-Confocal Unit), and Eduardo Jose Caleiras and Patricia Gonzalez (CNIO-Histopathology Unit) for technical assistance. M.S.S. is funded by grants from the Spanish Ministry of Economy and Innovation (SAF2017-89533-R), the Asociacion Espanola Contra el Cancer (AECC), Fundacion La Caixa, and an Established Investigator Award by the Melanoma Research Alliance (MRA). D.O. is funded by grants from the Spanish Ministry of Health (AES-PIS PI18/1057) and "Beca Leonardo a Investigadores y Creadores Culturales 2018 de la Fundacion BBVA". The CNIO Proteomics Unit belongs to ProteoRed, PRB3-ISCIII, supported by grant PT17/0019. S.O. is also supported by a grant from the Spanish Ministry of Economy, Industry and Competitiveness (BFU2015-71376-R).S

The RNA Polymerase II Factor RPAP1 Is Critical for Mediator-Driven Transcription and Cell Identity

The RNA polymerase II-associated protein 1 (RPAP1) is conserved across metazoa and required for stem cell differentiation in plants; however, very little is known about its mechanism of action or its role in mammalian cells. Here, we report that RPAP1 is essential for the expression of cell identity genes and for cell viability. Depletion of RPAP1 triggers cell de-differentiation, facilitates reprogramming toward pluripotency, and impairs differentiation. Mechanistically, we show that RPAP1 is essential for the interaction between RNA polymerase II (RNA Pol II) and Mediator, as well as for the recruitment of important regulators, such as the Mediator-specific RNA Pol II factor Gdown1 and the C-terminal domain (CTD) phosphatase RPAP2. In agreement, depletion of RPAP1 diminishes the loading of total and Ser5-phosphorylated RNA Pol II on many genes, with super-enhancer-driven genes among the most significantly downregulated. We conclude that Mediator/RPAP1/RNA Pol II is an ancient module, conserved from plants to mammals, critical for establishing and maintaining cell identity.We are grateful to Elisa Varela for assistance with morula and blastocyst fixa- tion. Work in the laboratory of M.S. is funded by the CNIO and the IRB and by grants from the Spanish Ministry of Economy co-funded by the European Regional Development Fund (ERDF) (SAF2013-48256-R), the European Research Co uncil (ERC-2014-AdG/66 9622), the Region al Government of Ma- drid co-funded by the Euro pean Social Fund (ReCaRe project), the Euro pean Union (RISK-IR project), the Botin Foundation and Banco Santander (Santander Universities Glo bal Division), the Ramon Areces Found ation, and the AXA Foundation. S.R. was funded by a contract from the Ramon y Cajal Program(RYC-2011-09242) and by the Spanish Ministry of Economy co- funded by the ERDF (SAF2013-49147- P and SAF2016-80874-PS

Functional reprogramming of polyploidization in megakaryocytes.

Polyploidization is a natural process that frequently accompanies differentiation; its deregulation is linked to genomic instability and cancer. Despite its relevance, why cells select different polyploidization mechanisms is unknown. Here we report a systematic genetic analysis of endomitosis, a process in which megakaryocytes become polyploid by entering mitosis but aborting anaphase. Whereas ablation of the APC/C cofactor Cdc20 results in mitotic arrest and severe thrombocytopenia, lack of the kinases Aurora-B, Cdk1, or Cdk2 does not affect megakaryocyte polyploidization or platelet levels. Ablation of Cdk1 forces a switch to endocycles without mitosis, whereas polyploidization in the absence of Cdk1 and Cdk2 occurs in the presence of aberrant re-replication events. Importantly, ablation of these kinases rescues the defects in Cdc20 null megakaryocytes. These findings suggest that endomitosis can be functionally replaced by alternative polyploidization mechanisms in vivo and provide the cellular basis for therapeutic approaches aimed to discriminate mitotic and polyploid cells.S