Toward discovering a novel family of peptides targeting neuroinflammatory states of brain microglia and astrocytes.

Microglia are immune-derived cells critical to the development and healthy function of the brain and spinal cord, yet are implicated in the active pathology of many neuropsychiatric disorders. A range of functional phenotypes associated with the healthy brain or disease states has been suggested from in vivo work and were modeled in vitro as surveying, reactive, and primed sub-types of primary rat microglia and mixed microglia/astrocytes. It was hypothesized that the biomolecular profile of these cells undergoes a phenotypical change as well, and these functional phenotypes were explored for potential novel peptide binders using a custom 7 amino acid-presenting M13 phage library (SX7) to identify unique peptides that bind differentially to these respective cell types. Surveying glia were untreated, reactive were induced with a lipopolysaccharide treatment, recovery was modeled with a potent anti-inflammatory treatment dexamethasone, and priming was determined by subsequently challenging the cells with interferon gamma. Microglial function was profiled by determining the secretion of cytokines and nitric oxide, and expression of inducible nitric oxide synthase. After incubation with the SX7 phage library, populations of SX7-positive microglia and/or astrocytes were collected using fluorescence-activated cell sorting, SX7 phage was amplified in Escherichia coli culture, and phage DNA was sequenced via next-generation sequencing. Binding validation was done with synthesized peptides via in-cell westerns. Fifty-eight unique peptides were discovered, and their potential functions were assessed using a basic local alignment search tool. Peptides potentially originated from proteins ranging in function from a variety of supportive glial roles, including synapse support and pruning, to inflammatory incitement including cytokine and interleukin activation, and potential regulation in neurodegenerative and neuropsychiatric disorders.

Neural tissue engineering: Bioresponsive nanoscaffolds using engineered self-assembling peptides.

UNLABELLED: Rescuing or repairing neural tissues is of utmost importance to the patient's quality of life after an injury. To remedy this, many novel biomaterials are being developed that are, ideally, non-invasive and directly facilitate neural wound healing. As such, this review surveys the recent approaches and applications of self-assembling peptides and peptide amphiphiles, for building multi-faceted nanoscaffolds for direct application to neural injury. Specifically, methods enabling cellular interactions with the nanoscaffold and controlling the release of bioactive molecules from the nanoscaffold for the express purpose of directing endogenous cells in damaged or diseased neural tissues is presented. An extensive overview of recently derived self-assembling peptide-based materials and their use as neural nanoscaffolds is presented. In addition, an overview of potential bioactive peptides and ligands that could be used to direct behaviour of endogenous cells are categorized with their biological effects. Finally, a number of neurotrophic and anti-inflammatory drugs are described and discussed. Smaller therapeutic molecules are emphasized, as they are thought to be able to have less potential effect on the overall peptide self-assembly mechanism. Options for potential nanoscaffolds and drug delivery systems are suggested. STATEMENT OF SIGNIFICANCE: Self-assembling nanoscaffolds have many inherent properties making them amenable to tissue engineering applications: ease of synthesis, ease of customization with bioactive moieties, and amenable for in situ nanoscaffold formation. The combination of the existing knowledge on bioactive motifs for neural engineering and the self-assembling propensity of peptides is discussed in specific reference to neural tissue engineering.

Brain biocompatibility and microglia response towards engineered self-assembling (RADA)4 nanoscaffolds.

(RADA)4-based nanoscaffolds have many inherent properties making them amenable to tissue engineering applications: ease of synthesis, ease of customization with bioactive moieties, and amenable for in situ nanoscaffold formation. There is a dearth in the literature on their biocompatibility in brain tissues; where the glia response is key to regulating the local host response. Herein, nanoscaffolds composed of (RADA)4 and (RADA)4-IKVAV mixtures were evaluated in terms of their effect on primary microglia in culture and general tissue (in vivo) biocompatibility (astrocyte and migroglia). Laminin-derived IKVAV peptide was chosen to promote beneficial cell interaction and attenuate deleterious glial responses. Microglia remained ramified when cultured with these nanoscaffolds, as observed using TNF-α and IL-1ß, NO, and proliferation assays. Evidence suggests that cultured microglia phagocytise the matrix whilst remaining ramified and viable, as shown visually and metabolically (MTT). Nanoscaffold intracerebral injection did not lead to microglia migration or proliferation, nor were glial scarring and axonal injury observed over the course of this study. IKVAV had no affect on microglia activation and astrogliosis. (RADA)4 should be advantageous for localized injection as a tuneable-platform device, which may be readily cleared without deleterious effects on tissue-resident microglia. STATEMENT OF SIGNIFICANCE: Self-assembling nanoscaffolds have many inherent properties making them amenable to tissue engineering applications: ease of synthesis, ease of customization with bioactive moieties, and amenable for in situ nanoscaffold formation. A dearth of literature exists on their biocompatibility in brain tissues; where the glia response is key to regulating the local host response. Herein, nanoscaffolds composed of the peptides (RADA)4 and (RADA)4-IKVAV mixtures were evaluated in terms of their effect on microglia cells in culture and general tissue (in vivo) biocompatibility (astrocyte and migroglia). Laminin-derived IKVAV peptide was chosen to promote beneficial cell interaction and attenuate deleterious glial responses. (RADA)4 nanoscaffolds showed no adverse effect from these cell types and should be advantageous for localized injection as a tuneable-platform device.