Introgression of Brown Norway chromosome 1 onto the fawn hooded hypertensive background rescues long-term fear memory deficits.

The isolation of genes influencing long-term memory is critical for an understanding of learning at the molecular level. Recently, chromosomal substitution rat strains, known as consomics, have been developed. Here we report the results of the first study on aversive learning and memory with these consomic rats. We compared the Fawn Hooded Hypertensive (FHH) and Brown Norway (BN) parent strains with a Brown Norway chromosome 1 substitution on the FHH background (FHH-1(BN)). Results indicated that while all strains had normal short-term memory, the FHH animals were impaired relative to BN in tests of long-term memory for a discrete auditory cue. This deficit was rescued by the introgression of the BN1 chromosome onto the FHH background. Furthermore, the FHH-1(BN) consomic showed an enhancement in long-term contextual fear memory relative to the FHH strain. These changes were not due to differences in pain sensitivity as both strains performed equally on two different pain tests. These results provide preliminary support that consomic rat strains can be a useful tool in identifying genes related to long-term fear memory formation.

Introgression of Brown Norway chromosome 13 improves visual spatial memory in the Dahl S rat.

The present study was conducted in an effort to evaluate whether chromosomal substitution can repair impaired exploration learning and memory. It has previously been observed that Dahl salt-sensitive (SS) rodents exhibit impaired cognitive function along with abnormal physiological responses to muscle stimulation. Introgression of Brown Norway chromosome (13(BN)) has been found to restore normal physiological processes in SS animals. However, the effect of chromosomal substitution on cognitive performance has not been explored. It was hypothesized that 13(BN) also rescues cognitive impairments in these animals. Visual spatial learning and cognitive flexibility were evaluated using the Morris water maze (MWM) and the T-maze. This manipulation is effective in rescuing impaired task acquisition, but not perseveration observed in the SS animal. These animals may represent a natural animal model in which to isolate genetic information responsible for learning and memory function.

Structurally similar estradiol analogs uniquely alter the regulation of intracellular signaling pathways.

Ligand structure can affect the activation of nuclear receptors, such as estrogen receptors (ERs), and their control of signaling pathways for cellular responses including death and differentiation. We hypothesized that distinct biological functions of similar estradiol (E(2)) analogs could be identified by integrating gene expression patterns obtained from human tumor cell lines with receptor binding and functional data for the purpose of developing compounds for treatment of a variety of diseases. We compared the estrogen receptor subtype selectivity and impact on signaling pathways for three distinct, but structurally similar, analogs of E(2). Modifications in the core structure of E(2) led to pronounced changes in subtype selectivity for estrogen receptors, ER-α or ER-ß, along with varying degrees of ER dimerization and activation. While all three E(2) analogs are predominantly ER-ß agonists, the cell growth inhibitory activity commonly associated with this class of compounds was detected for only two of the analogs and might be explained by a ligand-specific pattern of gene transcription. Microarray studies using three different human tumor cell lines demonstrated that the analogs distinctly affect the transcription of genes in signaling pathways for chromosome replication, cell death, and oligodendrocyte progenitor cell differentiation. That the E(2) analogs could lower tumor cell viability and stimulate neuronal differentiation confirmed that gene expression data could accurately distinguish biological activity of the E(2) analogs. The findings reported here confirm that cellular responses can be regulated by making key structural alterations to the core structure of endogenous ER ligands.

Liver transcriptomic changes associated with ritonavir-induced hyperlipidemia in sensitive and resistant strains of rats.

Ritonavir (RTV) and other protease inhibitors (PIs) used for the treatment of human immunodeficiency virus (HIV) infection are associated with elevated serum triglycerides (TG) and cholesterol in some patients. A rat strain (Sprague-Dawley or SD) commonly used in toxicology studies is not sensitive to RTV-induced hyperlipidemia, making mechanistic studies and the identification of novel, lipid-neutral PIs challenging. The objective of this study was to identify a rat strain that mirrors human PI-associated hyperlipidemia. RTV was administered at 100 mg/kg/day for 5 days to a panel of 14 rat strains estimated to cover approximately 86% of the known genetic variance in rats. Increased serum TG and cholesterol levels occurred only in two rat strains, including LEW x BN rats. Livers from LEW x BN (sensitive) and SD (resistant) rats were then evaluated using microarrays to investigate differences in the transcriptomic response to RTV. Several genes, including some involved in bile acid biosynthesis, gluconeogenesis, and carbohydrate metabolism, were differentially regulated between the two strains. In particular, cytochrome P450 7A1 (CYP7A1), a key enzyme for cholesterol metabolism, was down-regulated in the sensitive and up-regulated in resistant rats. Collectively, these results demonstrate the utility of a genetically diverse rat panel to identify strains with clinical relevance for a particular adverse effect. Furthermore, the genome-wide transcriptomic analysis suggests that RTV-induced hyperlipidemia is at least in part due to changes in hepatic lipid biosynthesis and metabolism. These findings will facilitate the discovery of novel, lipid-neutral HIV PIs and the identification of relevant biomarkers for this adverse event.