Abstract
In vitro cell-based assays have been fundamental in modern drug discovery and have led to the identification of novel therapeutics. We have developed complex mixed central nervous system (CNS) cultures, which recapitulate the normal process of myelination over time and allow the study of several parameters associated with CNS damage, both during development and after injury or disease. In particular, they have been used as a reliable screen to identify drug candidates that may promote (re)myelination and/or neurite outgrowth. Previously, using these cultures, we demonstrated that a panel of low sulphated heparin mimetics, with structures similar to heparan sulphates (HSs), can reduce astrogliosis, and promote myelination and neurite outgrowth. HSs reside in either the extracellular matrix or on the surface of cells and are thought to modulate cell signaling by both sequestering ligands, and acting as co-factors in the formation of ligand-receptor complexes. In this study, we have used these cultures as a screen to address the repair potential of numerous other commercially available sulphated glycomolecules, namely heparosans, ulvans, and fucoidans. These compounds are all known to have certain characteristics that mimic cellular glycosaminoglycans, similar to heparin mimetics. We show that the N-sulphated heparosans promoted myelination. However, O-sulphated heparosans did not affect myelination but promoted neurite outgrowth, indicating the importance of structure in HS function. Moreover, neither highly sulphated ulvans nor fucoidans had any effect on remyelination but CX-01, a low sulphated porcine intestinal heparin, promoted remyelination in vitro. These data illustrate the use of myelinating cultures as a screen and demonstrate the potential of heparin mimetics as CNS therapeutics.
Highlights
The repair of the central nervous system (CNS) is a complex process, which requires a multifactorial approach
We demonstrated that low sulphated heparin mimetics could prevent features of in vitro astrogliosis [11,12,13]. mHeps are glycomolecules with similar structure to heparan sulphates (HSs), which reside either in the extracellular matrix (ECM) or on the surface of cells. mHeps have a repeating subunit of uronic acid linked to glucosamine, present as an alternating co-polymer of both iduronate- and glucuronate-containing sequences bearing N-sulphate, N-acetyl, and O-sulphate substitution
The mHeps had no effect on developmental myelination (MC-Dev), we found that low sulphated (LS) mHeps could promote myelination and neurite outgrowth and act via sequestering inhibitors of repair in myelinating culture-demyelination (MC-Demy) and myelinating cultures-injured (MC-Inj) [10]
Summary
The repair of the central nervous system (CNS) is a complex process, which requires a multifactorial approach. The cultures are generated from dissociated embryonic rat spinal cords and develop over time to form many myelinated internodes separated by nodes of Ranvier [1]. They have allowed us to examine factors that regulate the process of myelination over time and we have, termed them myelinating cultures-development (MC-Dev). These cultures have been used to study the interaction between oligodendrocytes and axons during the process of myelination [2] and lead to the identification of the Biology 2019, 8, 52; doi:10.3390/biology8030052 www.mdpi.com/journal/biology
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