Phosphorylation of activation functions AF-1 and AF-2 of RAR alpha and RAR gamma is indispensable for differentiation of F9 cells upon retinoic acid and cAMP treatment.

The role of RAR alpha 1 and RAR gamma 2 AF-1 and AF-2 activation functions and of their phosphorylation was investigated during RA-induced primitive and parietal differentiation of F9 cells. We found that: (i) primitive endodermal differentiation requires RAR gamma 2, whereas parietal endodermal differentiation requires both RAR gamma 2 and RAR alpha 1, and in all cases AF-1 and AF-2 must synergize; (ii) primitive endodermal differentiation requires the proline-directed kinase site of RAR gamma 2-AF-1, whereas parietal endodermal differentiation additionally requires that of RAR alpha 1-AF-1; (iii) the cAMP-induced parietal endodermal differentiation also requires the protein kinase A site of RAR alpha-AF-2, but not that of RAR gamma; and (iv) the AF-1-AF-2 synergism and AF-1 phosphorylation site requirements for RA-responsive gene induction are promoter context-dependent. Thus, AF-1 and AF-2 of distinct RARs exert specific cellular and molecular functions in a cell-autonomous system mimicking physiological situations, and their phosphorylation by kinases belonging to two main signalling pathways is required to enable RARs to transduce the RA signal during F9 cell differentiation.     

Differential biological activities of human interleukin-1 alpha and interleukin-1 beta

We examined the biological effects induced by both human recombinant interleukin-1 alpha (IL-1 alpha) and beta (IL-1 beta) in five different cell types of human, rat and mouse origin. IL-1 alpha and beta preparations were standardized in terms of biological activity in the EL-4/CTLL bioassay and, in parallel, employed to stimulate PGE2 secretion in human fibroblasts, mesangial cells (MC), C57B1/6 mouse MC, DBA/2 mouse macrophages and Sprague Dawley rat MC. In addition, the co-mitogenic effects of IL-1 alpha and beta were determined in freshly prepared Sprague Dawley rat thymocytes. No significant differences in IL-1 alpha and beta concentration dependent PGE2 production were detectable in the different cell types (MC, fibroblasts and macrophages) of human or mouse origin. Incubation of Sprague Dawley rat MC with both IL-1 alpha and beta resulted in a concentration dependent production of PGE2. However, in contrast to mouse or human MC the potency of IL-1 beta to induce PGE2 in Sprague Dawley rat MC was 26-fold higher compared to IL-1 alpha. In addition, the potency of IL-1 beta to enhance co-stimulated proliferation of Sprague Dawley thymocytes was 200-fold higher than that of equal biological activities of IL-1 alpha. When we tested the additive effects on Sprague Dawley cells, increasing IL-1 beta concentrations added to a fixed IL-1 alpha concentration resulted in a cumulative rise in both, PGE2 secretion by MC and thymocyte proliferation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential dependence of hypoxia-inducible factors 1 alpha and 2 alpha on mTORC1 and mTORC2

Constitutive expression of hypoxia-inducible factor (HIF) has been implicated in several proliferative disorders. Constitutive expression of HIF1 alpha and HIF2 alpha has been linked to a number of human cancers, especially renal cell carcinoma (RCC), in which HIF2 alpha expression is the more important contributor. Expression of HIF1 alpha is dependent on the mammalian target of rapamycin (mTOR) and is sensitive to rapamycin. In contrast, there have been no reports linking HIF2 alpha expression with mTOR. mTOR exists in two complexes, mTORC1 and mTORC2, which are differentially sensitive to rapamycin. We report here that although there are clear differences in the sensitivity of HIF1 alpha and HIF2 alpha to rapamycin, both HIF1 alpha and HIF2 alpha expression is dependent on mTOR. HIF1 alpha expression was dependent on both Raptor (a constituent of mTORC1) and Rictor (a constitutive of mTORC2). In contrast, HIF2 alpha was dependent only on the mTORC2 constituent Rictor. These data indicate that although HIF1 alpha is dependent on both mTORC1 and mTORC2, HIF2 alpha is dependent only on mTORC2. We also examined the dependence of HIF alpha expression on the mTORC2 substrate Akt, which exists as three different isoforms, Akt1, Akt2, and Akt3. Interestingly, the expression of HIF2 alpha was dependent on Akt2, whereas that of HIF1 alpha was dependent on Akt3. Because HIF2 alpha is apparently more critical in RCC, this study underscores the importance of targeting mTORC2 and perhaps Akt2 signaling in RCC and other proliferative disorders in which HIF2 alpha has been implicated.     

YAP1 regulates PPARG and RXR alpha expression to affect the proliferation and differentiation of ovine preadipocyte

Adipose tissue development is regulated by a serial of developmental signaling pathways. The Hippo pathway is a novel signaling cascade closely associated with adipogenesis. While most of Hippo pathway components had been verified that have a vital role in preadipocytes proliferation and differentiation, little is known about the function of Yes-associated protein 1 (YAP1) in mammalian adipose tissue development. Therefore, we investigated the role of YAP1 in ovine adipose tissue development by in vitro and in vivo experiments. We observed that the adipocyte size in subcutaneous adipose tissue increased with development. YAP1 expression increased during adipose tissue development, while decreased during the differentiation of ovine preadipocytes in vitro. YAP1 knockdown notably promoted lipid accumulation and suppressed ovine preadipocyte proliferation. In addition, we observed that YAP1 deficiency significantly upregulated peroxisome proliferator-activated receptor gamma (PPARG) and retinoid X receptor alpha (RXR alpha) expression. By contrast, overexpression of YAP1 led to the suppression of preadipocyte differentiation, lipid droplets formation, and PPARG expression. In brief, our findings demonstrated that YAP1 regulates the proliferation and differentiation of ovine preadipocyte via altering PPARG and RXR alpha expression.     

Differential binding of PGE-1 and PGF-2alpha to the human spermatozoa membrane

Using the quenching of the intrinsic fluorescence and the modifications of the ANS-dependent fluorescence of human sperm suspensions, evidence has been found that supports the presence of two different receptors for prostaglandins in human spermatozoa membrane. These receptors may bind selectively E or F type prostaglandins since: First, quenching efficiency and binding constants are different for PGE-1 (n = 0.36 nmoles/10⁶ cells, Ka = 1.69 × 10⁷ M^?1) than for PGF-2 (n = 0.14 nmoles/10⁶ cells, Ka = 0.16 × 10⁷ M^?1). Second, PGE-1 and PGF-2α show no competitions in their quenching properties. Third, PGE-1 changes the emission spectra of the sperm suspension increasing the contribution of the membrane tyrosine, while PGF-2α tends to decrease this contribution, and Fourth, PGF-2α induced a shift to the red in the emission maxima of the sperm bound ANS and decreases energy transfer from the membrane amino acids to the ANS, while PGE-1 increase this last phenomenon without modifying the normally induced ANS-fluorescence.     

Mapping of the mouse Rxr loci encoding nuclear retinoid X receptors RXR alpha, RXR beta, and RXR gamma.

Recently, a novel subgroup of nuclear hormone receptors called RXRs implicated for retinoid-mediated gene regulation have been identified. RXRs appear to interact with many other nuclear hormone receptors and modulate their functions. We have mapped genetic loci Rxra, Rxrb, and Rxrg encoding three RXR subtypes, RXR alpha, RXR beta, and RXR gamma, respectively, using interspecific backcross mice. None of the Rxr loci cosegregated with each other or with the retinoic acid receptor loci (Rar) mapped previously. Rxra mapped to Chr 2 near the centromere, Rxrb mapped to the H-2 region of Chr 17, and Rxrg was tightly linked to the Pbx gene on distal Chr 1. These results underscore that RXR genes are dispersed in the genome.     

Hepatocyte RXR alpha deletion in mice leads to inhibition of angiogenesis

To investigate the effect of RXRα deficiency in liver on angiogenesis, hepatocyte RXRα-deficient and control wild-type mice were fed either standard or high-fat diet (HF) for 7 weeks. In the 6th week of feeding, Matrigel model of in vivo angiogenesis was applied. Matrigel plug infiltrating cells were then used for visualization of vessels (CD31 staining) as well as for gene expression analysis. HF diet appeared to decrease angiogenesis in hRXRα-deficient mice. Genes related to angiogenesis (Nos3, Kdr) were down-regulated, whereas genes connected with adipogenesis (Cebpb, Srebf1), apoptosis (Gzmb, Bcl2) and proinflammatory pathway (NfκB, Tnfα) were up-regulated by HF diet in hRXRα-deficient mice in the microarray study. Our results suggest that impaired fatty acid metabolism in liver (hRXRα-deficient mice) leads to impaired angiogenesis due to lipotoxicity and promotion of adipogenesis.     

Differential unfolding of alpha1 and alpha2 chains in type I collagen and collagenolysis

Collagenolysis plays a central role in many disease processes and a detailed understanding of the mechanism of collagen degradation is of immense interest. While a considerable body of information about collagenolysis exists, the details of the underlying molecular mechanism are unclear. Therefore, to further our understanding of the precise mechanism of collagen degradation, we used molecular dynamics simulations to explore the structure of human type I collagen in the vicinity of the collagenase cleavage site. Since post-translational proline hydroxylation is an important step in the synthesis of collagen chains, we used the DNA sequence for the α1 and α2 chains of human type I collagen, and the known amino acid sequences for bovine and chicken type I collagen, to infer which prolines are hydroxylated in the vicinity of the collagenase cleavage site. Simulations of type I collagen in this region suggest that partial unfolding of the α2 chain is energetically preferred relative to unfolding of α1 chains. Localized unfolding of the α2 chain leads to the formation of a structure that has disrupted hydrogen bonds N-terminal to the collagenase cleavage site. Our data suggest that this disruption in hydrogen bonding pattern leads to increased chain flexibility, thereby enabling the α2 chain to sample different partially unfolded states. Surprisingly, our data also imply that α2 chain unfolding is mediated by the non-hydroxylation of a proline residue that is N-terminal to the cleavage site in α1 chains. These results suggest that hydroxylation on one chain (α1) can affect the structure of another chain (α2), and point to a critical role for the non-hydroxylation of proline residues near the collagenase cleavage site.     

The alpha 1 and alpha 2 polypeptides of the dihydropyridine-sensitive calcium channel differ in developmental expression and tissue distribution

The dihydropyridine (DHP) binding complex isolated from skeletal muscle contains two large proteins, alpha 1 and alpha 2, and at least two smaller polypeptides. The alpha 1 subunit has a primary structure expected for ion channels and is a functional component of a DHP-sensitive, voltage-activated calcium channel. The functions of the alpha 2 protein and the smaller polypeptides are unknown. We prepared monoclonal antibodies to the alpha 1 and alpha 2 polypeptides and studied the developmental appearance and tissue distribution of these two proteins. In rat skeletal muscle, the levels of alpha 1 are quite low during the first 10 days after birth, then rise dramatically, and, by day 20, approach those found in adult muscle. In direct contrast, alpha 2 is present in substantial amounts in rat muscle at birth and increases only slightly during this same period of development. Furthermore, alpha 1 is detected only in skeletal muscle, whereas alpha 2 is present in a variety of tissues. These results provide evidence for the segregation of these two polypeptides and suggest that the function of alpha 2 is not limited to that associated with the DHP-sensitive calcium channel.