In vivo transcriptomic profiling using cell encapsulation identifies effector pathways of systemic aging

Sustained exposure to a young systemic environment rejuvenates aged organisms and promotes cellular function. However, due to the intrinsic complexity of tissues it remains challenging to pinpoint niche-independent effects of circulating factors on specific cell populations. Here, we describe a method for the encapsulation of human and mouse skeletal muscle progenitors in diffusible polyethersulfone hollow fiber capsules that can be used to profile systemic aging in vivo independent of heterogeneous short-range tissue interactions. We observed that circulating long-range signaling factors in the old systemic environment lead to an activation of Myc and E2F transcription factors, induce senescence, and suppress myogenic differentiation. Importantly, in vitro profiling using young and old serum in 2D culture does not capture all pathways deregulated in encapsulated cells in aged mice. Thus, in vivo transcriptomic profiling using cell encapsulation allows for the characterization of effector pathways of systemic aging with unparalleled accuracy.

Bioengineering stem cell niches in 2D and 3D

Nora Leonardi

Muscle degenerative disorders, such as Duchenne muscular dystrophy, have a profound impact on the quality of life and survival of patients. Transplantation of myoblasts to restore muscle function has been discouraging since these cells die and don't migrate but it has more recently been reported that muscle stem cells, known as satellite cells, have an extraordinary potential to contribute to muscle fiber regeneration, home to their niche and replenish the stem cell pool when injected freshly into damaged muscle. These cells however quickly lose their regenerative potential when cultured in vitro. Adult stem cells are known to be regulated by their microenvironment through a complex mixture of signals including soluble factors, matrix bound proteins, neural input and mechanical properties and the identification of extrinsic factors that can regulate muscle stem cell quiescence and self-renewal has been a focus of research in the Blau lab. Strikingly, recent studies in the Blau lab have shown that muscle stem cells cultured on compliant hydrogels coated with laminin were more viable than those cultured on tissue culture plastic and robustly contributed to muscle regeneration when transplanted into irradiated mouse leg muscles. The aim of this project was to follow up on these findings and to further elucidate the role biophysical and biochemical microenvironmental cues play in the regulation of muscle stem cell fate. Hydrogels have emerged as a popular material to recreate the stem cell niche in vitro due to their biocompatibility, high water content, tissue-like elasticity and diffusive properties and were employed here to fabricate substrates of varying rigidities. The physicochemical properties and tethered protein densities of a range of poyl(ethylene glycol) hydrogels were first characterized to define a suitable set of cell culture substrates. Gel stiffness could be linearly modulated from 2.5 to 45 kPa and the ligand density was found to be in the low femtomolar range. ELISA showed similar protein density on gels of different stiffnesses but immunofluorescence could not fully confirm this. Committed myoblasts were then seeded on these gels and shown to respond to substrate stiffness and ligand density in terms of morphology. Lastly, freshly isolated muscle stem cells were cultured on these gels and on rigid tissue culture plastic and shown to spread more, be more viable and grow more rapidly on stiffer gels as compared to soft ones. Myogenic progression was retrospectively analysed using immunohistochemistry but no differences between culture conditions were observed. Based on the influences of gel rigidity and ligand density observed in vitro, an in vivo assay, the ultimate test of stem cell function, is currently underway.

2009

Identification and functional characterization of protein kinases that modulate Notch signaling under physiological conditions and in cancer

Chhavi Jain

The Notch signaling pathway is a key regulator of cell fate decisions in embryonic development and in adult tissue homeostasis. Mounting evidence suggests that Notch signaling is frequently deregulated in human neoplasms, where depending upon the cellular context it can function both as an oncogene or a tumor suppressor. A plethora of studies shed light on how Notch crosstalks with signaling pathways downstream to manifest either its oncogenic or tumor suppressive activity. However, regulatory networks upstream of the Notch signaling pathway are still poorly understood. Since protein kinases are well-known regulators of a majority of cell signaling pathways, the aim of the current study was to identify novel positive and negative regulatory kinases that modulate Notch signaling. Using a HeLa cell based co-culture assay to read Notch-dependent luciferase activity, a small interference RNA (siRNA) library against the human kinase genome was previously tested in a high-throughput manner. Validation of top candidate kinases from the screening using both siRNA as well as pharmacological inhibitors led to further elimination of false positives and identification of Protein Kinase B (AKT2) and Calmodulin Kinase II (CaMKII) as key positive while Janus kinases (JAKs) as key negative regulators of the Notch signaling pathway. In the first part of the study, we analyzed the positive regulation of AKT2 and CaMKII kinases on Notch signaling in the T-cell acute lymphoblastic leukemia (T-ALL) cells where Notch is oncogenic. It was shown that pharmacological inhibition of either AKT2 or CaMKII kinase in T-ALL cell lines in vitro abrogated the expression of active Notch1 intracellular domain (N1-ICD) as well as of Notch target genes. Moreover, inhibition of these kinases blocked proliferation of T-ALL cells. In the second part of the study, we analyzed the negative regulation of JAK kinases on Notch signaling using a distinct physiological context where Notch is tumor suppressive. It was shown that pharmacological inhibition of JAK kinases led to an induction of Notch receptor transcription and of Notch target genes in the human primary epidermal keratinocytes (HPEK) as well as in the skin squamous cell carcinoma (SCC) cell lines. In addition, the pharmacological inhibition of JAK kinases induced a block in proliferation, cell cycle arrest and differentiation in HPEKs and skin SCCs by increased expression of early differentiation markers. Suppression of Notch signaling in primary keratinocytes counteracted the differentiation-inducing effect of JAK inhibition. Since JAK inhibition affected Notch transcription, global gene expression profiling using RNA sequencing was done to identify transcription factors involved in an indirect regulation of JAK kinases on the Notch cascade. EGR1 and EGR2 belonging to the early growth response family of transcription factors were significantly modulated downstream of JAK inhibition. In vivo, topical inhibition of JAK kinases provided marked resistance against chemically induced cutaneous carcinogenesis.Taken together, our data reveals a key role of AKT2 and CaMKII kinases in positive regulation while of JAK kinases in the negative regulation of Notch signaling, of potential relevance for combinatory approaches for cancer therapy. Pharmacological inhibitors against these kinases could be tested for their ability to modulate Notch signaling and may prove highly beneficial in the therapy of Notch-driven cancers.

EPFL2016

Bioengineering the Human Muscle Stem-Cell Niche for Therapeutic Applications

Omid Mashinchian

In spite of decades of research, no feasible method for obtaining sufficient numbers of uncommitted muscle stem cells (MuSCs) for therapy of degenerative muscle diseases exists. One of the most fundamental problems associated with stem cell therapy of muscle is that removal of MuSCs from their tissue microenvironment and expansion in conventional culture induces their terminal commitment to myogenic differentiation. This in-vitro loss of stemness impairs the long-term engraftment potential of MuSCs and renders them unsuitable for stem cell therapy. In another disease relevant context, aging, dramatic changes in the functionality of MuSCs have been shown to depend on an altered composition of their microenvironment. Thus, muscle progenitors are fundamentally dependent on their local environment, commonly known as the âstem cell niche", and a better understanding of its role in guiding stem cell function is highly relevant for the development of therapies for aging and muscle diseases. The muscle stem cell niche is composed of diverse cellular and acellular elements, including different supportive cell types, growth factors and extracellular matrix, and as outlined above, is critical for maintaining healthy stem cell characteristics such as the capacity for self-renewal, commitment, and differentiation. Using molecular biology approaches, we decided to interrogate (I) the role of the cellular environment on stem cell commitment, (II) to test whether, in a physiological context, the systemic circulation has niche-independent effects on MuSC stemness, and (III) to study a population of MuSC-supportive cells that is affected by the aging process. In the first study of this thesis, we have successfully developed an organoid-like-approach for the scalable derivation of uncommitted MuSCs from human induced pluripotent stem cells (iPSCs) in a biologically faithful cellular 3D-environment in suspension embryoids. To this end, we employed human iPSCs and a spectrum of immortalized cell lines to screen for 3D-aggregation conditions promoting mesoderm formation and subsequent specification to the myogenic lineage without the parallel upregulation of myogenic commitment markers. Compared to myogenic cells derived from adult human skeletal muscle, this niche-mimetic embryoid derived progenitors display significantly enhanced engraftment into the muscle stem cell position peripheral to muscle fibers, and restoration of dystrophin expression when transplanted into muscles of a mouse model of Duchenne muscular dystrophy. In a second study, we present a novel method for encapsulation of human muscle progenitors in highly diffusible polyethersulfone hollow fiber capsules to identify highly specific "transcriptional-signature" induced by systemic aging in-vivo. This technique allows to study the systemic circulation in health, disease and aging at an unprecedented level in human cell types of choice. Finally, in our third study, we investigated the cellular cross-talk between muscle stem cells and non-myogenic niche-based cell type, called fibro/adipogenic progenitors (FAPs). Interestingly, the support-function and the cross-talk with stem cells are dramatically impaired in aged FAPs. We demonstrate that this mechanism can be targeted to rejuvenate myogenesis. Taken together, "mimicking" the physicochemical-interactions of MuSCs with their niche-resident cell types, represents a powerful opportunity to manipulate MuSC function in aging and disease.

EPFL2019