Caracterización de una población de neutrófilos envejecidos y su efecto sobre nichos hematopoyéticos

Tesis doctoral inédita leída en la Universidad Autónoma de Madrid, Facultad de Ciencias, Departamento de Biología. Fecha de lectura: 22-12-2014Los neutrófilos son células que se caracterizan por su potencial citotóxico y constituyen la primera línea de defensa del sistema inmune innato. Una elevada tasa de producción diaria y su corta vida media, plantean la necesidad de eliminar estas células correctamente y así evitar potenciales efectos adversos en el organismo. La eliminación de células apoptóticas o en proceso de muerte genera señales necesarias para mantener la homeostasis del organismo. En este trabajo hemos explorado la respuesta fisiológica que se genera como consecuencia de la eliminación de neutrófilos. Nuestros resultados han revelado que la eliminación de neutrófilos en médula ósea es fundamental para la modulación de la actividad del nicho hematopoyético. Mediante citometría de flujo, hemos identificado una población de neutrófi los que envejecen en circulación y que se discriminan por la expresión de los marcadores Ly6G+CXCR4HI CD62LLO. Esta población infiltra la médula ósea y es eliminada diariamente por macrófagos al final del periodo de descanso de los ratones. La eliminación de neutrófilos envejecidos y la activación de señales LXR sincronizada, tiene como consecuencia una reducción en el número de células y en la quimioquina CXCL12 lo cual determina la movilización diaria de progenitores hematopoyéticos a la circulación. Este trabajo muestra además que la eliminación homeostática de neutrófilos ocurre de manera virtualmente ubicua en el organismo. Hemos observado que la eliminación de neutrófi los circulantes en otros órganos diferentes de la médula ósea, permite la modulación remota del nicho hematopoyético. En concreto, nuestro trabajo sugiere que la eliminación de neutrófilos en piel e intestino regula los niveles de progenitores en sangre. Por tanto, la eliminación en tejidos periféricos de los neutrófilos constituye otro nivel de control en la homeostasis del nicho hematopoyético. En resumen, nuestros resultados revelan que la eliminación de neutrófilos en condiciones homeostáticas o de inflamación regula la actividad del nicho hematopoyético localmente en médula ósea o mediante señales remota

RXRs control serous macrophage neonatal expansion and identity and contribute to ovarian cancer progression

Tissue-resident macrophages (TRMs) populate all tissues and play key roles in homeostasis, immunity and repair. TRMs express a molecular program that is mostly shaped by tissue cues. However, TRM identity and the mechanisms that maintain TRMs in tissues remain poorly understood. We recently found that serous-cavity TRMs (LPMs) are highly enriched in RXR transcripts and RXR-response elements. Here, we show that RXRs control mouse serous-macrophage identity by regulating chromatin accessibility and the transcriptional regulation of canonical macrophage genes. RXR deficiency impairs neonatal expansion of the LPM pool and reduces the survival of adult LPMs through excess lipid accumulation. We also find that peritoneal LPMs infiltrate early ovarian tumours and that RXR deletion diminishes LPM accumulation in tumours and strongly reduces ovarian tumour progression in mice. Our study reveals that RXR signalling controls the maintenance of the serous macrophage pool and that targeting peritoneal LPMs may improve ovarian cancer outcomes.This work was supported by a HFSP fellowship to M.C-A. (LT000110/2015-L/1), grants from the Spanish Ministerio de Ciencia e Innovación (MCI) (SAF2015-64287R, SAF2017-90604-REDT-NurCaMein, RTI2018-095928-B100), La Marató de TV3 Foundation (201605-32) and Comunidad de Madrid (MOIR-B2017/BMD-3684) to M.R, and the Formación de Profesorado Universitario (FPU17/01731) programme (MCI) to J.P. The CNIC is supported by the MCI and the Pro CNIC Foundation and is a Severo Ochoa Center of Excellence (SEV-2015-0505).S

Nanobodies Protecting From Lethal SARS-CoV-2 Infection Target Receptor Binding Epitopes Preserved in Virus Variants Other Than Omicron

The emergence of SARS-CoV-2 variants that escape from immune neutralization are challenging vaccines and antibodies developed to stop the COVID-19 pandemic. Thus, it is important to establish therapeutics directed toward multiple or specific SARS-CoV-2 variants. The envelope spike (S) glycoprotein of SARS-CoV-2 is the key target of neutralizing antibodies (Abs). We selected a panel of nine nanobodies (Nbs) from dromedary camels immunized with the receptor-binding domain (RBD) of the S, and engineered Nb fusions as humanized heavy chain Abs (hcAbs). Nbs and derived hcAbs bound with subnanomolar or picomolar affinities to the S and its RBD, and S-binding cross-competition clustered them in two different groups. Most of the hcAbs hindered RBD binding to its human ACE2 (hACE2) receptor, blocked cell entry of viruses pseudotyped with the S protein and neutralized SARS-CoV-2 infection in cell cultures. Four potent neutralizing hcAbs prevented the progression to lethal SARS-CoV-2 infection in hACE2-transgenic mice, demonstrating their therapeutic potential. Cryo-electron microscopy identified Nb binding epitopes in and out the receptor binding motif (RBM), and showed different ways to prevent virus binding to its cell entry receptor. The Nb binding modes were consistent with its recognition of SARS-CoV-2 RBD variants; mono and bispecific hcAbs efficiently bound all variants of concern except omicron, which emphasized the immune escape capacity of this latest variant.This work was partially funded by Ministerio de Ciencia e Innovación (MICIN; https://www.ciencia.gob.es/) and the Spanish Research Council (CSIC; https://www.csic.es/) under grants PIE-RD-COVID 19 (No 202020E079) and PTI+ Salud Global REC_EU (No SGL 2103051, NextGenerationEU) to LF, JMC, PG, and UG, and (No SGL 2103053, NextGenerationEU) to MM-A. This study was partially conducted within the CSIC Antiviral Screening Network, an infrastructure supported by NextGeneration EU funds (https://ec.europa.eu/info/strategy/recovery-plan-europe_es) from the European Union and the European Virus Archive Global (EVag) of the European Union’s Horizon 2020 (https://ec.europa.eu/programmes/horizon2020/en/home) research and innovation programme (No 871029) to PG and UG. EM facilities of CNB-CSIC were supported by Ministerio de Ciencia e Innovación (MICIN; https://www.ciencia.gob.es/), EU-FEDER (https://ec.europa.eu/regional_policy/es/funding/erdf/) CRIOMECORR project (ESFRI-2019-01-CSIC-16). JMC access to the European Synchrotron Radiation Facility (ESRF) CM01 line through the Iberian-BAG, and to the Instruct Image Processing Center (I2PC, http://i2pc.es/) by projects PID16168 and PID14989. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.Peer reviewe

A Neutrophil Timer Coordinates Immune Defense and Vascular Protection

Neutrophils eliminate pathogens efficiently but can inflict severe damage to the host if they over-activate within blood vessels. It is unclear how immunity solves the dilemma of mounting an efficient anti-microbial defense while preserving vascular health. Here, we identify a neutrophil-intrinsic program that enabled both. The gene Bmal1 regulated expression of the chemokine CXCL2 to induce chemokine receptor CXCR2-dependent diurnal changes in the transcriptional and migratory properties of circulating neutrophils. These diurnal alterations, referred to as neutrophil aging, were antagonized by CXCR4 (C-X-C chemokine receptor type 4) and regulated the outer topology of neutrophils to favor homeostatic egress from blood vessels at night, resulting in boosted anti-microbial activity in tissues. Mice engineered for constitutive neutrophil aging became resistant to infection, but the persistence of intravascular aged neutrophils predisposed them to thrombo-inflammation and death. Thus, diurnal compartmentalization of neutrophils, driven by an internal timer, coordinates immune defense and vascular protection. Neutrophils display circadian oscillations in numbers and phenotype in the circulation. Adrover and colleagues now identify the molecular regulators of neutrophil aging and show that genetic disruption of this process has major consequences in immune cell trafficking, anti-microbial defense, and vascular health.This study was supported by Intramural grants from A∗STAR to L.G.N., BES-2013-065550 to J.M.A., BES-2010-032828 to M.C.-A, and JCI-2012-14147 to L.A.W (all from Ministerio de Economía, Industria y Competitividad; MEIC). Additional MEIC grants were SAF2014-61993-EXP to C.L.-R.; SAF2015-68632-R to M.A.M. and SAF-2013-42920R and SAF2016-79040Rto D.S. D.S. also received 635122-PROCROP H2020 from the European Commission and ERC CoG 725091 from the European Research Council (ERC). ERC AdG 692511 PROVASC from the ERC and SFB1123-A1 from the Deutsche Forschungsgemeinschaft were given to C.W.; MHA VD1.2/81Z1600212 from the German Center for Cardiovascular Research (DZHK) was given to C.W. and O.S.; SFB1123-A6 was given to O.S.; SFB914-B08 was given to O.S. and C.W.; and INST 211/604-2, ZA 428/12-1, and ZA 428/13-1 were given to A.Z. This study was also supported by PI12/00494 from Fondo de Investigaciones Sanitarias (FIS) to C.M.; PI13/01979, Cardiovascular Network grant RD 12/0042/0054, and CIBERCV to B.I.; SAF2015-65607-R, SAF2013-49662-EXP, and PCIN-2014-103 from MEIC; and co-funding by Fondo Europeo de Desarrollo Regional (FEDER) to A.H. The CNIC is supported by the MEIC and the Pro CNIC Foundation and is a Severo Ochoa Center of Excellence (MEIC award SEV-2015-0505)