Binding of the glucocorticoid receptor complex to the nucleosomal core in the P1798 mouse lymphosarcoma

Proteomic profiling of rapid non-genomic and concomitant genomic effects of acute restraint stress on rat thymocytes

In order to investigate rapid non-genomic effects of acute stress, rats were restrained for 15 min which was sufficient to activate the hypothalamus-pituitary-adrenal (HPA) axis but too short to induce massive genomic effects of cortisol. Subcellular fractions of thymocytes (cytosol, nucleus, membrane) were investigated using quantitative 2D DIGE with MALDI-TOF/TOF mass spectrometry. In total, 108 proteins with differential subcellular localizations were identified. The specificity of the changes induced by psychological stress was reflected by the prominent modulation of proteins involved in the HPA and sympathoadrenal medullar (SAM) axis such as HMGB1 and NHERF1. Intracellular trafficking was characterized by a dominant protein exodus from the cytosol. Real translocation was observed for 9 proteins with 6 that shuttled from the cytosol to the nucleus (HYOU1, HNRPF, HNRPC, STRAP, PSA1, PPA1) and 3 from the nucleus to the cytosol (HMGB1, NHERF1, PSMA1). Proteins showing subcellular reshuffling were largely involved in transcription and translation processes (39 of 108) with a significant enrichment of RNA splicing factors. Bioinformatics analysis revealed significant enrichment for protein kinase A and 14-3-3 signaling, probably reflecting real non-genomic effects. This is the first study investigating rapid effects of stress-induced HPA activation in vivo at the proteome level.

Isolation and characterization of cortisol-sensitive and -resistant P1798 mouse lymphosarcoma cell lines

Three cell lines have been isolated and characterized from the P1798 mouse lymphosarcoma. One line, derived from a glucocorticoid-resistant tumor, was glucocorticoid-resistant in vitro. The other two cell lines, derived from glucocorticoid-sensitive and -resistant parental tumors, respectively, were shown to be glucocorticoid-sensitive in vitro. The glucocorticoid receptor from all three cell lines bound glucocorticoid with similar affinity and capacity. However, based on Sephacryl S-300 gel filtration, the glucocorticoid receptor from the resistant cell line was smaller than that of the two sensitive cell lines. Moreover, the glucocorticoid receptor from the resistant cell line accumulated to a greater extent in the nucleus. This resistant cell line thus resembles the nti variant of the S49 lymphoma cell line. All three cell lines were tumorigenic and metastatic when reimplanted into mice, contained the normal mouse diploid complement of 40 chromosomes and exhibited the same responsiveness to cortisol in vivo as they did in vitro. It is concluded that the ready passage of these cell lines in vitro or in vivo and the presence of the small receptor in the resistant line should make them excellent model systems for the study of glucocorticoid resistance.

High mobility group proteins 1 and 2 stimulate binding of a specific transcription factor to the adenovirus major late promoter

High mobility group proteins 1 and 2 (HMGs 1 and 2) are abundant chromosomal proteins which are believed to be preferentially associated with regions of active chromatin. Our previous results have shown that HMGs 1 and 2 can significantly stimulate specific transcription in vitro from the adenovirus major late promoter. This stimulation is now shown to be due, at least in part, to the influence of HMGs 1 and 2 on binding of a specific transcription factor (MLTF) upstream of the start site of the gene to a region (-66 to -51) which is required for optimal transcription both in vivo and in vitro. HMGs 1 and 2 cause both an increase in the rate of binding of the transcription factor to the DNA and alterations to the pattern of the DNaseI footprint of the factor on the DNA. Different binding states of the factor are also observed dependent on the presence of MgCl2, the factor being bound but not protecting the binding region from DNaseI in the absence of MgCl2.