Integration-free mRNA reprogramming of human fibroblasts: The study of aging upon reprogramming

Rohanisarvestani, Leili

28 January 2015

The ability to reprogram adult somatic cells into induced pluripotent stem (iPS) cells could provide a valuable implement for in vitro disease modeling and drug discovery. More importantly, they may potentially serve as an unlimited source of cells for regenerative medicine. However, most of the iPS cells have been generated by retroviral vectors, and therefore they carry the risk of viral integration into the host genome. This problem prevents their use for clinical applications and regenerative medicine. mRNA-mediated delivery of reprogramming factors is an alternative approach for cellular reprogramming. mRNA-based reprogramming offers the advantage of being completely free of genomic integration and is therefore highly suitable for clinical translation. However, there are some limitations which must be overcome so that mRNA can be widely used for successful cellular reprogramming. In the current thesis, the attempt was to generate stable mRNA-iPS cells through overcoming those limitations. Several human donor cells were transfected with mRNA encoding reprogramming factors and the generation of two stable mRNA-iPS cell lines was shown. The resultant mRNA-iPS colonies were assessed for pluripotency markers. Their pluripotency features were evaluated by the viral-iPS cells produced by conventional retroviral vectors. It was noticed that the generation of mRNA-iPS cells was largely affected by the parental cells from which they were derived. However, characterization and evaluation of the generated mRNA-iPS cells proved their pluripotency states comparable to the viral-iPS cells. On the other hand, the aging hallmarks of the iPS cells were assessed in the second part of this thesis. The potential aging signatures of the iPS cells should be conducted before their use in clinical applications. Currently, there are controversial data regarding the ability of reprogramming to fully rejuvenate an aged somatic cell and reverse agerelated changes such as shortened telomeres, dysfunctional mitochondria and DNA damage. Moreover, mixed findings have been published regarding whether the iPS cells are fully rejuvenated or they might retain some of the aging hallmarks from the cells which they were derived. This thesis studied these controversies through the investigation of three hallmarks of aging including telomere length, mitochondrial alteration and DNA damage. Telomere elongation was indicated in the iPS cells. Furthermore, mitochondrial morphology and function were improved into more immature features in iPS cell lines than their corresponding fibroblasts. Moreover, the iPS cell lines were shown to have less amount of DNA damage compared to their parental fibroblasts. In summary, it can be concluded that generation of mRNA-iPS cells is largely affected by the primary donor cells from which they are derived. Furthermore, it seems that reprogramming enables reversion of aging signatures to a more youthful state.

iPS Zellen

Reprogrammierung

Alterungsprozess

iPS cells

reprogramming

aging process

ddc:610

Integration-free mRNA reprogramming of human fibroblasts: The study of aging upon reprogramming

Rohanisarvestani, Leili

15 January 2015

The ability to reprogram adult somatic cells into induced pluripotent stem (iPS) cells could provide a valuable implement for in vitro disease modeling and drug discovery. More importantly, they may potentially serve as an unlimited source of cells for regenerative medicine. However, most of the iPS cells have been generated by retroviral vectors, and therefore they carry the risk of viral integration into the host genome. This problem prevents their use for clinical applications and regenerative medicine. mRNA-mediated delivery of reprogramming factors is an alternative approach for cellular reprogramming. mRNA-based reprogramming offers the advantage of being completely free of genomic integration and is therefore highly suitable for clinical translation. However, there are some limitations which must be overcome so that mRNA can be widely used for successful cellular reprogramming. In the current thesis, the attempt was to generate stable mRNA-iPS cells through overcoming those limitations. Several human donor cells were transfected with mRNA encoding reprogramming factors and the generation of two stable mRNA-iPS cell lines was shown. The resultant mRNA-iPS colonies were assessed for pluripotency markers. Their pluripotency features were evaluated by the viral-iPS cells produced by conventional retroviral vectors. It was noticed that the generation of mRNA-iPS cells was largely affected by the parental cells from which they were derived. However, characterization and evaluation of the generated mRNA-iPS cells proved their pluripotency states comparable to the viral-iPS cells. On the other hand, the aging hallmarks of the iPS cells were assessed in the second part of this thesis. The potential aging signatures of the iPS cells should be conducted before their use in clinical applications. Currently, there are controversial data regarding the ability of reprogramming to fully rejuvenate an aged somatic cell and reverse agerelated changes such as shortened telomeres, dysfunctional mitochondria and DNA damage. Moreover, mixed findings have been published regarding whether the iPS cells are fully rejuvenated or they might retain some of the aging hallmarks from the cells which they were derived. This thesis studied these controversies through the investigation of three hallmarks of aging including telomere length, mitochondrial alteration and DNA damage. Telomere elongation was indicated in the iPS cells. Furthermore, mitochondrial morphology and function were improved into more immature features in iPS cell lines than their corresponding fibroblasts. Moreover, the iPS cell lines were shown to have less amount of DNA damage compared to their parental fibroblasts. In summary, it can be concluded that generation of mRNA-iPS cells is largely affected by the primary donor cells from which they are derived. Furthermore, it seems that reprogramming enables reversion of aging signatures to a more youthful state.

info:eu-repo/classification/ddc/610

ddc:610

iPS cells, reprogramming, aging process

Funktionelle Analyse von Proteasom-Subtypen aus Leber von Ratten verschiedener Altersstufen

Gohlke, Sabrina

03 June 2013

20S Proteasomen der Leber gehören ausschließlich zur Population der Intermediär-Proteasomen. Chromatographisch sind drei proteasomale Subpopulationen aufgrund unterschiedlicher Oberflächenhydrophobizität trennbar. Diese beinhalten unterschiedliche Mengen der Standard- und Immunountereinheiten und zeigen unterschiedliche spezifische Aktivitäten gegenüber kurzen fluorigenen Peptidsubstraten. Außerdem lassen sie sich deutlich anhand der Schnittfrequenzen bei Hydrolyse von Polypeptidsubstraten unterscheiden. Jede dieser Subpopulationen konnte aufgrund unterschiedlicher Oberflächenladung in bis zu 5 verschiedene 20S Proteasom-Subtypen unterteilt werden, die wiederum unterschiedliche Mengen an Standard- und Immununtereinheiten enthielten. Jeder dieser Subtypen zeigte unterschiedliche Eigenschaften bezüglich der spezifischen Aktivitäten und Hydrolysegeschwindigkeiten von Polypeptidsubstraten. Unterschiede wurden auch bezüglich ihrer Peptid-Spleiß-Aktivitäten nachgewiesen. In der vorliegenden Arbeit wurden darüber hinaus Veränderungen der Spektren proteasomaler Subtypen- und ihrer Eigenschaften im Lebergewebe von 2, 8 und 23 Monate alten Ratten nachgewiesen. Während die Gesamtmenge der Leber-Proteasomen mit steigendem Alter abnahm, nahm die Menge der Subtypen mit integrierten Immununtereinheiten zu. Gleichzeitig kam es zu einer altersabhängigen Zunahme der Hydrolysegeschwindigkeit gegenüber Polypeptide-Substraten sowie veränderten Schnitthäufigkeiten. Die altersabhängigen intramolekularen Umgestaltungen von Leberproteasomen könnten eine funktionelle Anpassung an die altersbedingten zellulären Veränderungen in Verbindung mit Veränderungen der MHC Klasse I Antigen-Präsentation darstellen. / 20S proteasomes isolated from rat liver belong to the population of intermediate type proteasomes. Three subpopulations were separated by chromatography due to their differences in surface hydrophobicity. These subpopulations contain different types of intermediate type proteasomes with standard- and immunosubunits exhibiting distinct specific activities towards short fluorogenic substrates. However, depending on the substrate their hydrolyzing activity of long polypeptide substrates was significantly different. Additional separation of the three 20S proteasome subpopulations due to their different surface charges allowed further resolution of each subpopulation to at least five 20S proteasome subtypes. The subunit composition of these subtypes varied with regard to the content of exchangeable subunits. The pattern of proteolytic activities measured with short fluorogenic peptides differed between the various subtypes as well as the ability to hydrolyze polypeptide substrate. Above all, each subtype displayed a specific pattern regarding the peptide-splice-activity. Furthermore, the present work showed age-dependent alterations in the subtype patterns, which were analyzed in livers of 2, 8 and 23 month old rats. While the total amount of proteasome declines with age, in all subtypes from aged animals standard subunits were widely replaced by immunosubunits. This resulted in a relative increase of immunosubunit-containing proteasomes, paralleled by age-dependent changes regarding the hydrolyzing activity of long polypeptide substrates. Such modifications could have implications on protein homeostasis as well as on MHC class I antigen presentation as part of the immunosenescence process.

20S Proteasom

Proteasom-Subpopulationen

Proteasom-Subtypen

Ratten-Leber

Alterungsprozess

proteolytische Aktivität

20S proteasome

proteasome-subpopulation

proteasome-subtype

ratliver

aging

proteolytic activity

570 Biowissenschaften, Biologie

32 Biologie

ddc:570

Risk and Resilience: a Multimodal Neuroimaging Integration in Aging and Alzheimer’s Disease

Spielmann-Benson, Gloria

06 December 2019

Der Alterungsprozess ist mit einem breiten Spektrum von Veränderungen der Gehirnstruktur und -funktion, sowie altersbedingter kognitiver Verschlechterung und pathologischer Neurodegeneration verbunden. Jahrelange Forschungen haben gezeigt, dass Pathologien wie neurofibrilläre Bündel, Amyloid Ablagerungen (Aβ) und zerebrovaskuläre Störungen zur Abnahme der kognitiven Leistungsfähigkeit im Alter und bei der Alzheimer Demenz (AD) beitragen. Jüngste Forschungsergebnisse deuten darauf hin, dass bestimmte Lebensstilfaktoren die Fähigkeit, mit Pathologien umzugehen, fördern. Hierbei handelt es sich um die sogenannten Resilienzfaktoren. Im Gegensatz dazu stehen die Risikofaktoren, welche die Vulnerabilität für kognitive Verschlechterung und Neurodegeneration erhöhen und diese Prozesse beschleunigen können. Diese Arbeit exploriert Risiko- und Resilienzfaktoren in einem breiten Spektrum von Probanden, von kognitiv normalen älteren Menschen über Personen mit leichter kognitiver Beeinträchtigung bis hin zu Personen mit klinischer AD mittels einer holistischen Integration behavioraler Messungen und Markern multimodaler Neurobildgebung. Basierend auf vier Studien untersucht diese Dissertation die Assoziation von AD und zerebrovaskulärer Störungen, funktioneller Konnektivitätsnetzwerke und Kognition in einem gepoolten Datensatz bestehend aus 645 Individuen. Zusammenfassend erweitern die Ergebnisse der vorliegenden Dissertation die Literatur zu Resilienz- und Risikofaktoren im Kontext gesunden Alterns und AD, indem sie eine holistische Integration der komplexen Mechanismen während des Alterungsprozesses liefert. / Aging alone is associated with a wide range of alterations in brain structure and function as well as age-associated cognitive decline and pathological neurodegeneration. Years of research have shown that brain pathology such as neurofibrillary tangles, amyloid deposition (Aβ), and cerebrovascular pathology contribute to decline of cognitive functions in aging and Alzheimer’s Disease (AD). Recent research has pointed out that certain lifestyle factors contribute to the ability to cope with pathology, known as resilience factors, while in contrast, risk factors can accelerate and increase the vulnerability towards cognitive decline and neurodegeneration. This work explores risk and resilience factors across a diverse spectrum of participants ranging from cognitively intact older adults, to mild cognitive impairment (MCI), and clinical AD with a holistic integration of behavioral measures and multimodal neuroimaging markers. Based on four studies this dissertation investigates the association of AD and cerebrovascular pathology, functional connectivity networks and cognition in a pooled data set of 645 individuals. In summary, our results shed light on the diverse mechanistic underpinning of functional brain networks, hinting at the complex interplay between the brain’s functionality at-rest and the multiple pathological processes. Overall, these findings extend the literature on the resilience and risk factors in the context of healthy aging and AD, while providing a holistic integration of the complex mechanisms at play during the aging process.

Resilienzfaktoren

Risikofaktoren

Alterungsprozess

Alzheimerdemenz

Bildgebung

Risk

Resilience

Aging

Alzheimer's Disease

neuroimaging

150 Psychologie

CQ 7400

CU 4500

CZ 1370

YH 5404

ddc:150