Network analysis of temporal effects of intermittent and sustained hypoxia on rat lungs.

UNLABELLED: The molecular networks underlying the lung response to hypoxia are not fully understood. We employed systems biology approaches to study temporal effects of intermittent or sustained hypoxia on gene expression in rat lungs. We obtained gene expression profiles from rats exposed to intermittent or sustained hypoxia lasting 0-30 days and identified differentially expressed genes, their patterns, biological processes, and regulatory networks critical for lung response to intermittent or sustained hypoxia. We validated selected genes with quantitative real-time PCR. Intermittent and sustained hypoxia induced two distinct sets of genes in rat lungs that displayed different temporal expression patterns. Intermittent hypoxia induced genes mostly involved in ion transport and homeostasis, neurological processes, and steroid hormone receptor activity, while sustained hypoxia induced genes principally participating in immune responses. The intermittent hypoxia-activated network suggested a role for cross talk between estrogen receptor 1 (ESR1) and other key proteins in hypoxic responses. The sustained hypoxia-activated network was indicative of vascular remodeling and pulmonary hypertension. We confirmed the temporal expression changes of 12 genes (including the Esr1 gene and 4 ESR1 target genes) in intermittent hypoxia and 8 genes in sustained hypoxia with quantitative real-time PCR. CONCLUSIONS: intermittent and sustained hypoxia induced distinct gene expression patterns in rat lungs. The functional characteristics of genes activated by these two distinct perturbations suggest their roles in the downstream physiological effects of intermittent and sustained hypoxia. Our results demonstrate the discovery potential of applying systems biology approaches to the understanding of mechanisms underlying hypoxic lung response.

Pedigreed primate embryonic stem cells express homogeneous familial gene profiles.

Human embryonic stem cells (hESCs) hold great biomedical promise, but experiments comparing them produce heterogeneous results, raising concerns regarding their reliability and utility, although these variations may result from their disparate and anonymous origins. To determine whether primate ESCs have intrinsic biological limitations compared with mouse ESCs, we examined expression profiles and pluripotency of newly established nonhuman primate ESC (nhpESCs). Ten pedigreed nhpESC lines, seven full siblings (fraternal quadruplets and fraternal triplets), and nine half siblings were derived from 41 rhesus embryos; derivation success correlated with embryo quality. Each line has been growing continuously for approximately 1 year with stable diploid karyotype (except for one stable trisomy) and expresses in vitro pluripotency markers, and eight have already formed teratomas. Unlike the heterogeneous gene expression profiles found among hESCs, these nhpESCs display remarkably homogeneous profiles (>97%), with full-sibling lines nearly identical (>98.2%). Female nhpESCs express genes distinct from their brother lines; these sensitive analyses are enabled because of the very low background differences. Experimental comparisons among these primate ESCs may prove more reliable than currently available hESCs, since they are akin to inbred mouse strains in which genetic variables are also nearly eliminated. Finally, contrasting the biological similarities among these lines with the heterogeneous hESCs might suggest that additional, more uniform hESC lines are justified. Taken together, pedigreed primate ESCs display homogeneous and reliable expression profiles. These similarities to mouse ESCs suggest that heterogeneities found among hESCs likely result from their disparate origins rather than intrinsic biological limitations with primate embryonic stem cells.