A small molecule that directs differentiation of human ESCs into the pancreatic lineage

Nature Chemical Biology, 2009, 5, 258

Stepwise differentiation from embryonic stem cells (ESCs) to functional insulin-secreting beta cells will identify key steps in beta-cell development and may yet prove useful for transplantation therapy for diabetics. An essential step in this schema is the generation of pancreatic progenitors—cells that express Pdx1 and produce all the cell types of the pancreas. High-content chemical screening identified a small molecule, (-)-indolactam V, that induces differentiation of a substantial number of Pdx1-expressing cells from human ESCs. The Pdx1-expressing cells express other pancreatic markers and contribute to endocrine, exocrine and duct cells, in vitro and in vivo. Further analyses showed that (-)-indolactam V works specifically at one stage of pancreatic development, inducing pancreatic progenitors from definitive endoderm. This study describes a chemical screening platform to investigate human ESC differentiation and demonstrates the generation of a cell population that is a key milepost on the path to making beta cells.

HIV-1 and microvesicles from T cells share a common glycome, arguing for a common origin

Nature Chemical Biology, 2009,

HIV-1 is a master at deceiving the immune system and usurping host biosynthetic machinery. Although HIV-1 is coated with host-derived glycoproteins, only glycosylation of viral gp120 has been described. Here we use lectin microarray technology to analyze the glycome of intact HIV-1 virions. We show that the glycan coat of human T cell line–derived HIV-1 matches that of native immunomodulatory microvesicles. The carbohydrate composition of both virus and microvesicles is cell-line dependent, which suggests a mechanism to rapidly camouflage the virus within the host. In addition, binding of both virus and microvesicles to antiviral lectins is enriched over the host cell, raising concern about targeting these glycans for therapeutics. This work also sheds light on the binding of HIV-1 to galectin-1, an important human immune lectin. Overall, our work strongly supports the theory that HIV-1 co-opts the exocytic pathway of microvesicles, thus potentially explaining why eliciting a protective antiviral immune response is difficult.