Eric V. Shusta

Blood-Brain Barrier Transport of Therapeutics via Receptor- Mediation

Drug delivery to the brain is hindered by the presence of the blood–brain barrier (BBB). Although the BBB restricts the passage of many substances, it is actually selectively permeable to nutrients necessary for healthy brain function. To accomplish the task of nutrient transport, the brain endothelium is endowed with a diverse collection of molecular transport systems. One such class of transport system, known as a receptor-mediated transcytosis (RMT), employs the vesicular trafficking machinery of the endothelium to transport substrates between blood and brain. If appropriately targeted, RMT systems can also be used to shuttle a wide range of therapeutics into the brain in a noninvasive manner. Over the last decade, there have been significant developments in the arena of RMT-based brain drug transport, and this review will focus on those approaches that have been validated in an in vivo setting.

Directed evolution of a stable scaffold for T-cell receptor engineering

Here we have constructed a single-chain T-cell receptor (scTCR) scaffold with high stability and soluble expression efficiency by directed evolution and yeast surface display. We evolved scTCRs in parallel for either enhanced resistance to thermal denaturation at 46°C, or improved intracellular processing at 37°C, with essentially equivalent results. This indicates that the efficiency of the consecutive kinetic processes of membrane translocation, protein folding, quality control, and vesicular transport can be well predicted by the single thermodynamic parameter of thermal stability. Selected mutations were recombined to create an scTCR scaffold that was stable for over an hour at 65°C, had solubility of over 4 mg ml−1, and shake-flask expression levels of 7.5 mg l−1, while retaining specific ligand binding to peptide–major histocompatibility complexes (pMHCs) and bacterial superantigen. These properties are comparable to those for stable single-chain antibodies, but are markedly improved over existing scTCR constructs. Availability of this scaffold allows engineering of high-affinity soluble scTCRs as antigen-specific antagonists of cell-mediated immunity. Moreover, yeast displaying the scTCR formed specific conjugates with antigen-presenting cells (APCs), which could allow development of novel cell-to-cell selection strategies for evolving scTCRs with improved binding to various pMHC ligands in situ.

Derivation of blood-brain barrier endothelial cells from human pluripotent stem cells

The blood-brain barrier (BBB) is crucial to the health of the brain and is often compromised in neurological disease. Moreover, because of its barrier properties, this endothelial interface restricts uptake of neurotherapeutics. Thus, a renewable source of human BBB endothelium could spur brain research and pharmaceutical development. Here we show that endothelial cells derived from human pluripotent stem cells (hPSCs) acquire BBB properties when co-differentiated with neural cells that provide relevant cues, including those involved in Wnt/β-catenin signaling. The resulting endothelial cells have many BBB attributes, including well-organized tight junctions, appropriate expression of nutrient transporters and polarized efflux transporter activity. Notably, they respond to astrocytes, acquiring substantial barrier properties as measured by transendothelial electrical resistance (1,450 ± 140 Ω cm2), and they possess molecular permeability that correlates well with in vivo rodent blood-brain transfer coefficients.

A Decade of Yeast Surface Display Technology: Where Are We Now?

Yeast surface display has become an increasingly popular tool for protein engineering and library screening applications. Recent advances have greatly expanded the capability of yeast surface display, and are highlighted by cell-based selections, epitope mapping, cDNA library screening, and cell adhesion engineering. In this review, we discuss the state-of-the-art yeast display methodologies and the rapidly expanding set of applications afforded by this technology.

A retinoic acid-enhanced, multicellular human blood-brain barrier model derived from stem cell sources

Blood-brain barrier (BBB) models are often used to investigate BBB function and screen brain-penetrating therapeutics, but it has been difficult to construct a human model that possesses an optimal BBB phenotype and is readily scalable. To address this challenge, we developed a human in vitro BBB model comprising brain microvascular endothelial cells (BMECs), pericytes, astrocytes and neurons derived from renewable cell sources. First, retinoic acid (RA) was used to substantially enhance BBB phenotypes in human pluripotent stem cell (hPSC)-derived BMECs, particularly through adherens junction, tight junction, and multidrug resistance protein regulation. RA-treated hPSC-derived BMECs were subsequently co-cultured with primary human brain pericytes and human astrocytes and neurons derived from human neural progenitor cells (NPCs) to yield a fully human BBB model that possessed significant tightness as measured by transendothelial electrical resistance (~5,000 Ωxcm2). Overall, this scalable human BBB model may enable a wide range of neuroscience studies.

In vitro models of the blood–brain barrier: An overview of commonly used brain endothelial cell culture models and guidelines for their use

The endothelial cells lining the brain capillaries separate the blood from the brain parenchyma. The endothelial monolayer of the brain capillaries serves both as a crucial interface for exchange of nutrients, gases, and metabolites between blood and brain, and as a barrier for neurotoxic components of plasma and xenobiotics. This “blood-brain barrier” function is a major hindrance for drug uptake into the brain parenchyma. Cell culture models, based on either primary cells or immortalized brain endothelial cell lines, have been developed, in order to facilitate in vitro studies of drug transport to the brain and studies of endothelial cell biology and pathophysiology. In this review, we aim to give an overview of established in vitro blood–brain barrier models with a focus on their validation regarding a set of well-established blood–brain barrier characteristics. As an ideal cell culture model of the blood–brain barrier is yet to be developed, we also aim to give an overview of the advantages and drawbacks of the different models described.

Efficient Differentiation of Human Pluripotent Stem Cells to Endothelial Progenitors via Small-Molecule Activation of WNT Signaling

Summary Human pluripotent stem cell (hPSC)-derived endothelial cells and their progenitors may provide the means for vascularization of tissue-engineered constructs and can serve as models to study vascular development and disease. Here, we report a method to efficiently produce endothelial cells from hPSCs via GSK3 inhibition and culture in defined media to direct hPSC differentiation to CD34+CD31+ endothelial progenitors. Exogenous vascular endothelial growth factor (VEGF) treatment was dispensable, and endothelial progenitor differentiation was β-catenin dependent. Furthermore, by clonal analysis, we showed that CD34+CD31+CD117+TIE-2+ endothelial progenitors were multipotent, capable of differentiating into calponin-expressing smooth muscle cells and CD31+CD144+vWF+I-CAM1+ endothelial cells. These endothelial cells were capable of 20 population doublings, formed tube-like structures, imported acetylated low-density lipoprotein, and maintained a dynamic barrier function. This study provides a rapid and efficient method for production of hPSC-derived endothelial progenitors and endothelial cells and identifies WNT/β-catenin signaling as a primary regulator for generating vascular cells from hPSCs.

Puromycin-purified rat brain microvascular endothelial cell cultures exhibit improved barrier properties in response to glucocorticoid induction.

In vitro blood–brain barrier (BBB) models using primary rat brain microvessel endothelial cells (BMEC) are often hampered by a lack of culture purity and poor barrier properties. To address these problems, the translation inhibitor puromycin was used to purify rat BMEC cultures. BMEC purities of 99.8% were routinely attained using puromycin treatment, and this technique proved to be far superior to other purification methods of similar difficulty. In contrast to cultures without puromycin treatment, purity of puromycin‐treated cultures was unaffected by initial seeding density. Next, rat BMEC monolayer transendothelial electrical resistance (TEER) was increased by glucocorticoid treatment with either corticosterone (CORT) or hydrocortisone (HC), and a corresponding decrease in monolayer permeability to small molecules was observed. Importantly, cultures treated with both puromycin and glucocorticoid attained significantly higher TEER values (CORT 168 ± 13 Ω × cm2; HC 218 ± 66 Ω × cm2) than those treated by the glucocorticoid alone (CORT 57 ± 5 Ω × cm2; HC 70 ± 2 Ω × cm2). Glucocorticoid induction resulted in BMEC morphological changes that accompanied the increases in TEER, and BMEC tight junctions exhibited improved integrity as visualized by the localization of tight junction proteins zonula occluden‐1, occludin and claudin‐5. The combined use of puromycin and glucocorticoid therefore provides an in vitro system that is well suited for molecular level BBB investigations.

Differentiating embryonic neural progenitor cells induce blood–brain barrier properties

The blood–brain barrier (BBB) is a multifunctional endothelial interface separating the bloodstream from the brain interior. Although the mature BBB is well characterized, the embryonic development of this complex system remains poorly understood. Embryonic neural progenitor cells (NPC) are a potential inductive cell type populating the developing brain, and their ability to influence BBB properties was therefore examined. When puromycin‐purified brain microvascular endothelial cells (BMEC) were co‐cultured with embryonic NPC in a two‐compartment Transwell system, the BMEC exhibited enhanced barrier properties in the form of increased transendothelial electrical resistance (TEER) and decreased permeability to the small molecule tracer, sodium fluorescein. These changes required the presence of NPC in the early stages of differentiation and were accompanied by alterations in the fidelity of BMEC tight junctions as indicated by occludin, claudin 5, and zonula occluden‐1 redistribution at cell–cell borders. In contrast to the findings with NPC, post‐natal astrocytes elicited a delayed, but longer duration response in BMEC TEER. BMEC co‐culture also suppressed neuronal differentiation of NPC indicating a reciprocal signaling between the two cell populations. This study demonstrates that NPC–BMEC interactions are prevalent and for the first time demonstrates that NPC are capable of inducing BBB properties.

A genomic comparison of in vivo and in vitro brain microvascular endothelial cells.

The blood—brain barrier (BBB) is composed of uniquely differentiated brain microvascular endothelial cells (BMEC). Often, it is of interest to replicate these attributes in the form of an in vitro model, and such models are widely used in the research community. However, the BMEC used to create in vitro BBB models de-differentiate in culture and lose many specialized characteristics. These changes are poorly understood at a molecular level, and little is known regarding the consequences of removing BMEC from their local in vivo microenvironment. To address these issues, suppression subtractive hybridization (SSH) was used to identify 25 gene transcripts that were differentially expressed between in vivo and in vitro BMEC. Genes affected included those involved in angiogenesis, transport and neurogenesis, and real-time quantitative polymerase chain reaction (qPCR) verified transcripts were primarily and significantly downregulated. Since this quantitative gene panel represented those BMEC characteristics lost upon culture, we used it to assess how culture manipulation, specifically BMEC purification and barrier induction by hydrocortisone, influenced the quality of in vitro models. Puromycin purification of BMEC elicited minimal differences compared with untreated BMEC, as assessed by qPCR. In contrast, qPCR-based gene panel analysis after induction with hydrocortisone indicated a modest shift of 10 of the 23 genes toward a more ‘in vivo-like’ gene expression profile, which correlated with improved barrier phenotype. Genomic analysis of BMEC de-differentiation in culture has thus yielded a functionally diverse set of genes useful for comparing the in vitro and in vivo BBB.