Philip S. Crosier

Insulin-Like Growth Factor-1 Reduces Postischemic White Matter Injury in Fetal Sheep

Insulin-like growth factor-1 (IGF-1) is known to be important for oligodendrocyte survival and myelination. In the current study, the authors examined the hypothesis that exogenous IGF-1 could reduce postischemic white matter injury. Bilateral brain injury was induced in near-term fetal sheep by 30 minutes of reversible carotid artery occlusion. Ninety minutes after ischemia, either vehicle (n = 8) or a single dose of 3 μg IGF-1 (n = 9) was infused intracerebroventricularly over 1 hour. White matter changes were assessed after 4 days recovery in the parasagittal intragyral white matter and underlying corona radiata. Proteolipid protein (PLP) mRNA staining was used to identify bioactive oligodendrocytes. Glial fibrillary acidic protein (GFAP) and isolectin B-4 immunoreactivity were used to label astrocytes and microglia, respectively. Myelin basic protein (MBP) density and the area of the intragyral white matter tracts were determined by image analysis. Insulin-like growth factor-1 treatment was associated with significantly reduced loss of oligodendrocytes in the intragyral white matter (P < 0.05), with improved MBP density (P < 0.05), reduced tissue swelling, and increased numbers of GFAP and isolectin B-4 positive cells compared with vehicle treatment. After ischemia there was a close association of PLP mRNA labeled cells with reactive astrocytes and macrophages/microglia. In conclusion, IGF-1 can prevent delayed, postischemic oligodendrocyte cell loss and associated demyelination.

New insights into the control of cell growth; the role of the Axl family

Summary Axl, Dtk and Mer are recently described receptors that constitute a new receptor tyrosine kinase subfamily. They bind the vitamin K‐dependent protein growth‐arrest‐specific gene 6 (Gas6) that is structurally related to the anticoagulation factor protein S. Studies suggest a role for these receptors in developmental processes, in the function of the hematopoietic and nervous systems and in tumorigenesis.

Cadherin-17 is required to maintain pronephric duct integrity during zebrafish development.

We have isolated a zebrafish cadherin that is orthologous to human LI-cadherin (CDH17). Zebrafish cdh17 is expressed exclusively in the pronephric ducts during embryogenesis, and in the mesonephros during larval development and adulthood. Like its mammalian ortholog, cdh17 is also expressed in liver and intestine in adult zebrafish. We show that cdh17-positive mesodermal cells do not contribute to the hematopoietic system. Consistent with a cell adhesion role for Cdh17, depletion of Cdh17 function using antisense morpholino oligonucleotides compromised cell cohesion during pronephric duct formation. Our results indicate that Cdh17 is necessary for maintaining the integrity of the pronephric ducts during zebrafish embryogenesis. This finding contrasts with the role of mammalian CDH17, which does not appear to be involved in nephric development.

Expression of Murine Interleukin 11 and its Receptor α-Chain in Adult and Embryonic Tissues

Interleukin 11 (IL‐11) is a multifunctional cytokine that has diverse effects on blood cells and their precursors and on a number of cell types outside of the hematopoietic system. The cDNAs encoding murine IL‐11 and its receptor α‐chain (IL‐11Rα) have recently been isolated. We have used the RNase protection assay to examine the expression of murine IL‐11 and IL‐11Rα in a range of adult mouse tissues, in embryos, and during development of embryonic stem (ES) cells into cystic embryoid bodies in vitro. The testis showed a high level of IL‐11 gene expression while a much lower level of expression was detected in the lung, stomach, small intestine, and large intestine. Expression of IL‐11 was not detected between day 10.5 and day 18.5 post coitum of embryonic development or in differentiating ES cells in vitro. In contrast, the IL‐11Rα was found to be expressed in all adult tissues examined, during embryonic development, and in totipotent and differentiating ES cells.

New rationale for large metazoan embryo manipulations on chip-based devices

The lack of technologies that combine automated manipulation, sorting, as well as immobilization of single metazoan embryos remains the key obstacle to high-throughput organism-based ecotoxicological analysis and drug screening routines. Noticeably, the major obstacle hampering the automated trapping and arraying of millimetre-sized embryos on chip-based devices is their substantial size and mass, which lead to rapid gravitational-induced sedimentation and strong inertial forces. In this work, we present a comprehensive mechanistic and design rationale for manipulation and passive trapping of individual zebrafish embryos using only hydrodynamic forces. We provide evidence that by employing innovative design features, highly efficient hydrodynamic positioning of large embryos on a chip can be achieved. We also show how computational fluid dynamics-guided design and the Lagrangian particle tracking modeling can be used to optimize the chip performance. Importantly, we show that rapid prototyping and medium scale fabrication of miniaturized devices can be greatly accelerated by combining high-speed laser prototyping with replica moulding in poly(dimethylsiloxane) instead of conventional photolithography techniques. Our work establishes a new paradigm for chip-based manipulation of large multicellular organisms with diameters well above 1 mm and masses often exceeding 1 mg. Passive docking of large embryos is an attractive alternative to provide high level of automation while alleviating potentially deleterious effects associated with the use of active chip actuation. This greatly expands the capabilities of bioanalyses performed on small model organisms and offers numerous and currently inaccessible laboratory automation advantages.

Identification of a Novel Receptor Tyrosine Kinase Expressed in Acute Myeloid Leukemic Blasts

Using the polymerase chain reaction with degenerate oligonucleotides derived from conserved motifs within the catalytic kinase domain of protein tyrosine kinases, and RNA extracted from embryonic stem cells, sequences that encode a segment of the kinase domain of several potentially novel receptor tyrosine kinases (RTKs) have been identified. One of these was selected for further study because in Northern analysis it hybridized to RNA from multipotential hematopoietic cell lines, but not from lines representative of lineage-committed cells. A cDNA for this receptor, designated developmental tyrosine kinase (DTK), was isolated and encodes a protein with structural similarities to AXL. Together these receptors form a new class of RTK. DTK is expressed in a number of human leukemic cell lines, and in the blasts of 6 of 11 patients with acute myeloid leukemia (AML) analyzed. The structure of DTK suggests that it may function as a cell adhesion molecule, and mediate cell-to-cell or cell-matrix interactions between hematopoietic cells and their respective microenvironments.

Fishing on chips: Up-and-coming technological advances in analysis of zebrafish and Xenopus embryos

Biotests performed on small vertebrate model organisms provide significant investigative advantages as compared with bioassays that employ cell lines, isolated primary cells, or tissue samples. The main advantage offered by whole‐organism approaches is that the effects under study occur in the context of intact physiological milieu, with all its intercellular and multisystem interactions. The gap between the high‐throughput cell‐based in vitro assays and low‐throughput, disproportionally expensive and ethically controversial mammal in vivo tests can be closed by small model organisms such as zebrafish or Xenopus. The optical transparency of their tissues, the ease of genetic manipulation and straightforward husbandry, explain the growing popularity of these model organisms. Nevertheless, despite the potential for miniaturization, automation and subsequent increase in throughput of experimental setups, the manipulation, dispensing and analysis of living fish and frog embryos remain labor‐intensive. Recently, a new generation of miniaturized chip‐based devices have been developed for zebrafish and Xenopus embryo on‐chip culture and experimentation. In this work, we review the critical developments in the field of Lab‐on‐a‐Chip devices designed to alleviate the limits of traditional platforms for studies on zebrafish and clawed frog embryo and larvae.

DMXAA (Vadimezan, ASA404) is a multi-kinase inhibitor targeting VEGFR2 in particular

The flavone acetic acid derivative DMXAA [5,6-dimethylXAA (xanthenone-4-acetic acid), Vadimezan, ASA404] is a drug that displayed vascular-disrupting activity and induced haemorrhagic necrosis and tumour regression in pre-clinical animal models. Both immune-mediated and non-immune-mediated effects contributed to the tumour regression. The vascular disruption was less in human tumours, with immune-mediated effects being less prominent, but nonetheless DMXAA showed promising effects in Phase II clinical trials in non-small-cell lung cancer. However, these effects were not replicated in Phase III clinical trials. It has been difficult to understand the differences between the pre-clinical findings and the later clinical trials as the molecular targets for the agent have never been clearly established. To investigate the mechanism of action, we sought to determine whether DMXAA might target protein kinases. We found that, at concentrations achieved in blood during clinical trials, DMXAA has inhibitory effects against several kinases, with most potent effects being on members of the VEGFR (vascular endothelial growth factor receptor) tyrosine kinase family. Some analogues of DMXAA were even more effective inhibitors of these kinases, in particular 2-MeXAA (2-methylXAA) and 6-MeXAA (6-methylXAA). The inhibitory effects were greatest against VEGFR2 and, consistent with this, we found that DMXAA, 2-MeXAA and 6-MeXAA were able to block angiogenesis in zebrafish embryos and also inhibit VEGFR2 signalling in HUVECs (human umbilical vein endothelial cells). Taken together, these results indicate that at least part of the effects of DMXAA are due to it acting as a multi-kinase inhibitor and that the anti-VEGFR activity in particular may contribute to the non-immune-mediated effects of DMXAA on the vasculature.

Integrated Chip-Based Physiometer for Automated Fish Embryo Toxicity Biotests in Pharmaceutical Screening and Ecotoxicology

Transgenic zebrafish (Danio rerio) models of human diseases have recently emerged as innovative experimental systems in drug discovery and molecular pathology. None of the currently available technologies, however, allow for automated immobilization and treatment of large numbers of spatially encoded transgenic embryos during real‐time developmental analysis. This work describes the proof‐of‐concept design and validation of an integrated 3D microfluidic chip‐based system fabricated directly in the poly(methyl methacrylate) transparent thermoplastic using infrared laser micromachining. At its core, the device utilizes an array of 3D micromechanical traps to actively capture and immobilize single embryos using a low‐pressure suction. It also features built‐in piezoelectric microdiaphragm pumps, embryo‐trapping suction manifold, drug delivery manifold, and optically transparent indium tin oxide heating element to provide optimal temperature during embryo development. Furthermore, we present design of the proof‐of‐concept off‐chip electronic interface equipped with robotic servo actuator driven stage, innovative servomotor‐actuated pinch valves, and embedded miniaturized fluorescent USB microscope. Our results showed that the innovative device has 100% embryo‐trapping efficiency while supporting normal embryo development for up to 72 hr in a confined microfluidic environment. We also showed data that this microfluidic system can be readily applied to kinetic analysis of a panel of investigational antiangiogenic agents in transgenic zebrafish lines. The optical transparency and embryo immobilization allow for convenient visualization of developing vasculature patterns in response to drug treatment without the need for specimen re‐positioning. The integrated electronic interfaces bring the lab‐on‐a‐chip systems a step closer to realization of complete analytical automation.

In situ hybridization screen in zebrafish for the selection of genes encoding secreted proteins

An in situ hybridization expression screen using a signal sequence trap system has been conducted in zebrafish to isolate cDNAs that encode secreted proteins. Random clones (secreted expressed sequence tags; sESTs) were sequenced from zebrafish embryonic (18–24 hr postfertilization) and adult kidney libraries. From the two RNA sources, 627 random sEST cDNAs were identified as being homologous or identical to known genes and 166 clones encode currently unidentified genes. The sESTs represent a broad range of enzymes and other regulatory molecules. Whole‐mount in situ hybridization analysis was carried out by using antisense probes generated from 244 selected sESTs, and a range of expression patterns was obtained. Genetic mapping undertaken with sEST sequences demonstrated that assignment of map position was attainable by using 5′ primers. The signal sequence trap system used in this work has yielded a range of cDNAs that encode secreted proteins and, together with analysis of patterns of expression and genetic mapping, has the potential to facilitate analysis of signaling pathways central to development and physiology.