Functional properties of different collagen scaffolds to create a biomimetic niche for neurally committed human induced pluripotent stem cells (iPSC)

The biomimetic, standardized conditions for in vitro cultures of human neural progenitors derived from induced pluripotent stem cells (hiPSC-NPs) should meet the requirements to serve as the template and protective environment for therapeutically competent cell population. In this study, two different collagen scaffolds: bi-component consisting of collagen and chondroitin sulphate (Col-CS), and collagen modified by crosslinking agent 2,3-dialdehyde cellulose (Col-DAC) have been used for the first time to encapsulate hiPSC-NPs and compared for the ability to create permissive microenvironment enabling cell survival, growth and differentiation. In our previous report, physicochemical comparison of the scaffolds revealed different elasticity, and diverse size and distribution of the pores within the 3D structure. Binary systems of Col-CS and Col-DAC tested in the current study have the correct balance of properties to serve as a biomimetic niche: they accommodate hiPSC-NPs sustaining their ability to proliferate and differentiate into neural lineages. However, a dense, network structure and rounded in shape pores of the Col-DAC microenvironment resulted in differential cell distributions within the scaffolds, with a tendency for augmented formation of highly proliferating cell aggregates as compared to Col-CS scaffolds. In contrast, Col-CS, which exhibited formation of the network of ellipsoidal and inner interconnected parallel pore channels, promoted enhanced cell viability and neuronal differentiation

Epigenetic modulation of stem cells in neurodevelopment: The role of methylation and acetylation

The coordinated development of the nervous system requires fidelity in the expression of specific genes determining the different neural cell phenotypes. Stem cell fate decisions during neurodevelopment are strictly correlated with their epigenetic status. The epigenetic regulatory processes, such as DNA methylation and histone modifications discussed in this review article, may impact both neural stem cell (NSC) self-renewal and differentiation and thus play an important role in neurodevelopment. At the same time, stem cell decisions regarding fate commitment and differentiation are highly dependent on the temporospatial expression of specific genes contingent on the developmental stage of the nervous system. An interplay between the above, as well as basic cell processes, such as transcription regulation, DNA replication, cell cycle regulation and DNA repair therefore determine the accuracy and function of neuronal connections. This may significantly impact embryonic health and development as well as cognitive processes such as neuroplasticity and memory formation later in the adult