Suchergebnisse

Dopamine (DA) is one of the main neurotransmitters found in the central nervous system and has a vital role in the function of dopaminergic (DArgic) neurons. A progressive loss of this specific subset of cells is one of the hallmarks of age-related neurodegenerative disorders such as Parkinson's disease (PD). Symptomatic therapy for PD has been centered in the precursor l-DOPA administration, an amino acid precursor of DA that crosses the blood-brain barrier (BBB) while DA does not, although this approach presents medium- to long-term side effects. To overcome this limitation, DA-nanoencapsulation therapies are actively being searched as an alternative for DA replacement. However, overcoming the low yield of encapsulation and/or poor biodistribution/bioavailability of DA is still a current challenge. Herein, we report the synthesis of a family of neuromelanin bioinspired polymeric nanoparticles. Our system is based on the encapsulation of DA within nanoparticles through its reversible coordination complexation to iron metal nodes polymerized with a bis-imidazol ligand. Our methodology, in addition to being simple and inexpensive, results in DA loading efficiencies of up to 60%. In vitro, DA nanoscale coordination polymers (DA-NCPs) exhibited lower toxicity, degradation kinetics, and enhanced uptake by BE(2)-M17 DArgic cells compared to free DA. Direct infusion of the particles in the ventricle of rats in vivo showed a rapid distribution within the brain of healthy rats, leading to an increase in striatal DA levels. More importantly, after 4 days of nasal administrations with DA-NCPs equivalent to 200 μg of the free drug per day, the number and duration of apomorphine-induced rotations was significantly lower from that in either vehicle or DA-treated rats performed for comparison purposes. Overall, this study demonstrates the advantages of using nanostructured DA for DA-replacement therapy. ; This work was supported by grants RTI2018-098027-B-C21 and RTI2018-098027-B-C22 from the Spanish Government funds and by the European Regional Development Fund (ERDF). The ICN2 is funded by the CERCA program/Generalitat de Catalunya. The ICN2 is supported by the Severo Ochoa Centres of Excellence program, funded by the Spanish Research Agency (AEI, grant no. SEV-2017-0706). M.V. received funding from "la Caixa" Foundation (ID 1178 100010434, under the agreement LCF/PR/HR17/52150003) 1179, Ministry of Economy and Competitiveness (MINECO, Spain) (SAF2016-77541-R) and The Michael J. Fox Foundation for Parkinson's Research 1180 (Grant ID: 15291.01). A.P.C. received funding from the ATTRACT project funded by the EC under Grant Agreement 777222. The authors thank the support from COST Action CA17121.

Aging and cancer are two interrelated processes, with aging being a major risk factor for the development of cancer. Parallel epigenetic alterations have been described for both, although differences, especially within the DNA hypomethylation scenario, have also been recently reported. Although many of these observations arise from the use of mouse models, there is a lack of systematic comparisons of human and mouse epigenetic patterns in the context of disease. However, such comparisons are significant as they allow to establish the extent to which some of the observed similarities or differences arise from pre-existing species-specific epigenetic traits. Here, we have used reduced representation bisulfite sequencing to profile the brain methylomes of young and old, tumoral and nontumoral brain samples from human and mouse. We first characterized the baseline epigenomic patterns of the species and subsequently focused on the DNA methylation alterations associated with cancer and aging. Next, we described the functional genomic and epigenomic context associated with the alterations, and finally, we integrated our data to study interspecies DNA methylation levels at orthologous CpG sites. Globally, we found considerable differences between the characteristics of DNA methylation alterations in cancer and aging in both species. Moreover, we describe robust evidence for the conservation of the specific cancer and aging epigenomic signatures in human and mouse. Our observations point toward the preservation of the functional consequences of these alterations at multiple levels of genomic regulation. Finally, our analyses reveal a role for the genomic context in explaining disease- and species-specific epigenetic traits. ; This work was supported by the Spanish Association Against Cancer (PROYE18061FERN to M.F.F.), the Asturias Government (PCTI) cofunding 2018-2022/FEDER (IDI/2018/146 to M.F.F.), Fundación General CSIC (0348_CIE_6_E to M.F.F.), and the Health Institute Carlos III (Plan Nacional de I + D+I) cofunding FEDER (PI15/00892 and PI18/01527 to M.F.F and A.F.F.). They also acknowledge support from the Ramón Areces Foundation (CIVP18A3891 to P.J.F.M.), the AECC (SIRTBIO to P.J.F.M.), the MICINN (SAF2017-85766-R to P.J.F.M.), a Ramón y Cajal fellowship (MICINN, RYC-2017-22335 to P.J.F.M.), and the European Commission ATTRACT project (777222 to A.P.C.). J.R.T. is supported by a Juan de la Cierva fellowship from the Spanish Ministry of Science and Innovation (FJCI-2015-26965). R.F.P. and P.S.O. are supported by the Severo Ochoa program (BP17-114 and BP17-165, respectively). R.G.U. is supported by the Centro de Investigación Biomédica en Red de Enfermedades Raras (Health Institute Carlos III). L.V. was supported by the UAB Predoctoral training programme (PIF predoctoral fellowships). They also acknowledge support from the IMDEA Food Institute and IUOPA-ISPA-FINBA (the IUOPA is supported by the Obra Social Cajastur-Liberbank, Spain). ; Peer reviewed