Lesley A. Colby

VIOLIN: vaccine investigation and online information network

Vaccines are among the most efficacious and cost-effective tools for reducing morbidity and mortality caused by infectious diseases. The vaccine investigation and online information network (VIOLIN) is a web-based central resource, allowing easy curation, comparison and analysis of vaccine-related research data across various human pathogens (e.g. Haemophilus influenzae, human immunodeficiency virus (HIV) and Plasmodium falciparum) of medical importance and across humans, other natural hosts and laboratory animals. Vaccine-related peer-reviewed literature data have been downloaded into the database from PubMed and are searchable through various literature search programs. Vaccine data are also annotated, edited and submitted to the database through a web-based interactive system that integrates efficient computational literature mining and accurate manual curation. Curated information includes general microbial pathogenesis and host protective immunity, vaccine preparation and characteristics, stimulated host responses after vaccination and protection efficacy after challenge. Vaccine-related pathogen and host genes are also annotated and available for searching through customized BLAST programs. All VIOLIN data are available for download in an eXtensible Markup Language (XML)-based data exchange format. VIOLIN is expected to become a centralized source of vaccine information and to provide investigators in basic and clinical sciences with curated data and bioinformatics tools for vaccine research and development. VIOLIN is publicly available at http://www.violinet.org

Pioglitazone Induces a Proadipogenic Antitumor Response in Mice with PAX8-PPARγ Fusion Protein Thyroid Carcinoma

Approximately 35% of follicular thyroid carcinomas harbor a chromosomal translocation that results in expression of a paired box gene 8-peroxisome proliferator-activated receptor γ gene (PPARγ) fusion protein (PPFP). To better understand the oncogenic role of PPFP and its relationship to endogenous PPARγ, we generated a transgenic mouse model that combines Cre-dependent PPFP expression (PPFP;Cre) with homozygous deletion of floxed Pten (PtenFF;Cre), both thyroid specific. Although neither PPFP;Cre nor PtenFF;Cre mice develop thyroid tumors, the combined PPFP;PtenFF;Cre mice develop metastatic thyroid cancer, consistent with patient data that PPFP is occasionally found in benign thyroid adenomas and that PPFP carcinomas have increased phosphorylated AKT/protein kinase B. We then tested the effects of the PPARγ agonist pioglitazone in our mouse model. Pioglitazone had no effect on PtenFF;Cre mouse thyroids. However, the thyroids in pioglitazone-fed PPFP;PtenFF;Cre mice decreased 7-fold in size, and metastatic disease was prevented. Remarkably, pioglitazone caused an adipogenic response in the PPFP;PtenFF;Cre thyroids characterized by lipid accumulation and the induction of a broad array of adipocyte PPARγ target genes. These data indicate that, in the presence of pioglitazone, PPFP has PPARγ-like activity that results in trans-differentiation of thyroid carcinoma cells into adipocyte-like cells. Furthermore, the data predict that pioglitazone will be therapeutic in patients with PPFP-positive carcinomas.

Paired Box Gene 8-Peroxisome Proliferator-Activated Receptor-γ Fusion Protein and Loss of Phosphatase and Tensin Homolog Synergistically Cause Thyroid Hyperplasia in Transgenic Mice

Approximately 35% of follicular thyroid carcinomas and a small fraction of follicular adenomas are associated with a t(2;3)(q13;p25) chromosomal translocation that fuses paired box gene 8 (PAX8) with the peroxisome proliferator-activated receptor-gamma gene (PPARG), resulting in expression of a PAX8-PPARgamma fusion protein, PPFP. The mechanism by which PPFP contributes to follicular thyroid neoplasia is poorly understood. Therefore, we have created mice with thyroid-specific expression of PPFP. At 1 yr of age, 25% of PPFP mice demonstrate mild thyroid hyperplasia. We bred these mice to mice with thyroid-specific single-allele deletion of the tumor suppressor Pten, denoted ThyPten(+/-). In humans, PTEN deletion is associated with follicular adenomas and carcinomas, and in mice, deletion of one Pten allele causes mild thyroid hyperplasia. We found that PPFP synergizes with ThyPten(+/-) to cause marked thyroid hyperplasia, but carcinomas were not observed. AKT phosphorylation was increased as expected in the ThyPten(+/-) thyroids, and also was increased in the PPFP thyroids and in human PPFP follicular cancers. Staining for the cell cycle marker Ki-67 was increased in the PPFP, ThyPten(+/-), and PPFP;ThyPten(+/-) thyroids compared with wild-type thyroids. Several genes with increased expression in PPFP cancers also were found to be increased in the thyroids of PPFP mice. This transgenic mouse model of thyroidal PPFP expression exhibits properties similar to those of PPFP thyroid cancers. However, the mice develop thyroid hyperplasia, not carcinoma, suggesting that additional events are required to cause follicular thyroid cancer.

An indirect ELISA to detect the serologic response of elk (Cervus elaphus nelsoni) inoculated with Brucella abortus strain RB51.

An indirect enzyme-linked immunosorbent assay (ELISA) was developed to identify elk (Cervus elaphus nelsoni) with Brucella abortus strain RB51 (RB51)-specific antibodies using a mouse monoclonal antibody specific for bovine IgG1. This test was relatively easy to perform, accurate, and easily reproducible; therefore it could be standardized for use between laboratories. In addition, we attempted to compensate for inherent variabilities encountered when comparing ELISA readings from multiple samples taken from many animals over time. Optical density (OD) readings for each sample were converted into a percent positivity value for analysis. A negative cutoff value was determined above which a sample was considered to have a significantly elevated anti-RB51 antibody level. Pre- and postvaccination sera from 64 6–8 mo old elk, divided into four groups (females subcutaneously inoculated with saline (control animals), females ballistically inoculated with RB51, females subcutaneously inoculated with RB51, and males subcutaneously inoculated with RB51) were used. All serum samples were collected between 27 April and 15 November 1995. Values for all saline controls were appropriately below the negative cutoff value. All subcutaneously and ballistically inoculated elk were serologically positive to RB51 for at least two sampling periods during the study. The difference in percent positivity values for the ballistically compared to the subcutaneously inoculated groups was not statistically significant at 8, 10, 14, or 18 wk postvaccination. This suggests that processing RB51 into lactose based pellets and ballistically inoculating elk with these pellets does not alter the detectable elk antibody response. Also, inoculated and control animals can be accurately identified with ELISA at 4–8 weeks post-vaccination.

Perspectives on Curriculum Needs in Laboratory-Animal Medicine

Both the United States and Canada have projected shortages of qualified laboratory-animal veterinarians within the next 10 years. This gap is occurring because of retirement, increased regulatory requirements for research animal oversight, and insufficient numbers of veterinarians entering this field. One of the primary means of increasing student interest in nontraditional practice areas, such as laboratory animal medicine, is to ensure that they have appropriate exposure to the topic during their basic clinical training. We outline a recommended curriculum for laboratory animal medicine for North American veterinary medical colleges, which provides strategies for integrating comparative medicine material into the curriculum, incorporates flexibility for a range of delivery methods, and suggests potential resources that may be used to develop this material.

Chapter 44 – Degu

Publisher Summary This chapter studies the degu, its attributes, and uses as a laboratory animal species. Degus are mostly associated with the study of circadian rhythms due to their diurnal activities in the wild and they have also been established as valuable animal models in the study of a wide range of scientific areas including developmental biology, diabetes mellitus, cataracts, and Alzheimers disease. The organ systems and physiological processes that have made the degu a useful animal model in various areas of research have been described in detail such as external features, circulatory system, and the nervous system. Due to less established laboratory colonies, much remains to be discovered regarding optimal housing, disease control, and veterinary care of the species. The chapter describes the management, husbandry, nutrition, diseases, and behavioral patterns of the degu. The degu is chosen as an animal for experimental model due to its characteristics such as complex familial and social structure and highly developed vocal repertoire. Also degus are relatively long-lived when compared to many other laboratory rodents. The research models that have been explained are thymic research, Alzheimers disease, production of antisera, and atherosclerosis.