Microengineered systems with iPSC-derived cardiac and hepatic cells to evaluate drug adverse effects

Hepatic and cardiac drug adverse effects are among the leading causes of attrition in drug development programs, in part due to predictive failures of current animal or in vitro models. Hepatocytes and cardiomyocytes differentiated from human induced pluripotent stem cells (iPSCs) hold promise for predicting clinical drug effects, given their human-specific properties and their ability to harbor genetically determined characteristics that underlie inter-individual variations in drug response. Currently, the fetal-like properties and heterogeneity of hepatocytes and cardiomyocytes differentiated from iPSCs make them physiologically different from their counterparts isolated from primary tissues and limit their use for predicting clinical drug effects. To address this hurdle, there have been ongoing advances in differentiation and maturation protocols to improve the quality and use of iPSC-differentiated lineages. Among these are in vitro hepatic and cardiac cellular microsystems that can further enhance the physiology of cultured cells, can be used to better predict drug adverse effects, and investigate drug metabolism, pharmacokinetics, and pharmacodynamics to facilitate successful drug development. In this article, we discuss how cellular microsystems can establish microenvironments for these applications and propose how they could be used for potentially controlling the differentiation of hepatocytes or cardiomyocytes. The physiological relevance of cells is enhanced in cellular microsystems by simulating properties of tissue microenvironments, such as structural dimensionality, media flow, microfluidic control of media composition, and co-cultures with interacting cell types. Recent studies demonstrated that these properties also affect iPSC differentiations and we further elaborate on how they could control differentiation efficiency in microengineered devices. In summary, we describe recent advances in the field of cellular microsystems that can control the differentiation and maturation of hepatocytes and cardiomyocytes for drug evaluation. We also propose how future research with iPSCs within engineered microenvironments could enable their differentiation for scalable evaluations of drug effects.     

Analysis of the N-acetylneuraminic acid and N-glycolylneuraminic acid contents of glycoproteins by high-pH anion-exchange chromatography with pulsed amperometric detection

Presence or absence of N-acetylneuraminic acid (Neu5Ac) can change a sialylated glycoprotein's serum half-life and possibly its function. We evaluated the linearity, sensitivity, reproducibility, and accuracy of a HPAEC/PAD method to determine its suitability for routine simultaneous analysis of Neu5Ac and N-glycolylneuraminic acid (Neu5Gc). An effective internal standard for this analysis is 3-deoxy-d-glycero-d- galacto-2-nonulosonic acid (KDN). We investigated the effect of the Au working electrode recession and determined that linear range and sensitivity were dependent on electrode recession. Using an electrode that was 350 &mgr;m recessed from the electrode block, the minimum detection limits of Neu5Ac, KDN, and Neu5Gc were 2, 5, and 2 pmol, respectively, and were reduced to 1, 2, and 0.5 pmol using a new electrode. The response of standards was linear from 10 to 500 pmol (r2>0.99) regardless of electrode recession. When Neu5Ac, KDN, and Neu5Gc (200 pmol each) were analyzed repetitively for 48 h, area RSDs were <3%. Reproducibility was unaffected when injections of glycoprotein neuraminidase and acid digestions were interspersed with standard injections. Area RSDs of Neu5Ac and Neu5Gc improved when the internal standard was used. We determined the precision and accuracy of this method for both a recessed and a new working electrode by analyzing Neu5Ac and Neu5Gc contents of bovine fetuin and bovine and human transferrins. Results were consistent with published values and independent of the working electrode. The sensitivity, reproducibility, and accuracy of this method make it suitable for direct routine analysis of glycoprotein Neu5Ac and Neu5Gc contents.      

Axon guidance in the vertebrate central nervous system

The development of connections in the central nervous system depends on the ability of the tips of growing axons to find their appropriate, often distant, target field. Factors that regulate axon outgrowth may be distinct from those that influence direction finding. Tissue culture methods have helped to distinguish between possible in vivo mechanisms and, in some cases, have identified candidate molecules.     

Specification of distinct motor neuron identities by the singular activities of individual Hox genes.

Hox genes have been implicated in specifying positional values along the anteroposterior axis of the caudal central nervous system, but their nested and overlapping expression has complicated the understanding of how they confer specific neural identity. We have employed a direct gain-of-function approach using retroviral vectors to misexpress Hoxa2 and Hoxb1 outside of the normal Hox expression domains, thereby avoiding complications resulting from possible interactions with endogenous Hox genes. Misexpression of either Hoxa2 or Hoxb1 in the anteriormost hindbrain (rhombomere1, r1) leads to the generation of motor neurons in this territory, even though it is normally devoid of this cell type. These ectopic neurons have the specific identity of branchiomotor neurons and, in the case of Hoxb1-induced cells, their axons leave the hindbrain either by fasciculating with the resident cranial motor axons at isthmic (trochlear) or r2 (trigeminal) levels of the axis or via novel ectopic exit points in r1. Next, we have attempted to identify the precise branchiomotor subtypes that are generated after misexpression and our results suggest that the ectopic motor neurons generated following Hoxa2 misexpression are trigeminal-like, while those generated following Hoxb1 misexpression are facial-like. Our data demonstrate, therefore, that at least to a certain extent and for certain cell types, the singular activities of individual Hox genes (compared to a combinatorial mode of action, for example) are sufficient to impose on neuronal precursor cells the competence to generate distinctly specified cell types. Moreover, as these particular motor neuron subtypes are normally generated in the most anterior domains of Hoxa2 and Hoxb1 expression, respectively, our data support the idea that the main site of individual Hox gene action is in the anteriormost subdomain of their expression, consistent with the phenomenon of posterior dominance.