Bacterial toxin-inducible gene expression of cathelicidin-B1 in the chicken bursal lymphoma-derived cell line DT40: functional characterization of cathelicidin-B1.

Chicken cathelicidin-B1 (chCATH-B1) is a major host defense peptide of the chicken bursa of Fabricius (BF). To investigate the mechanisms of chCATH-B1 gene expression in the BF, we focused on the DT40 cell line derived from chicken bursal lymphoma as a model for analysis. A cDNA encoding chCATH-B1 precursor was cloned from DT40 cells. The nucleotide sequence of the cDNA was identical with that of the BF chCATH-B1. A broth dilution analysis showed that the synthetic chCATH-B1 exhibited a significant defensive activity against both Escherichia coli and Staphylococcus aureus. A scanning microscopic analysis demonstrated that chCATH-B1 inhibited bacterial growth through membrane destruction with formation of blebs and spheroplasts. Limulus amoebocyte lysate assay and electromobility shift assay results revealed that chCATH-B1 bound to lipopolysaccharide (LPS) and lipoteichoic acid (LTA), which are the surface substances of the E. coli and S. aureus cell, respectively. A chemotactic assay results revealed that chCATH-B1 showed mouse-derived P-815 mastocytoma migrating activity dose-dependently but with a higher concentration, resulting in a loss of the activity. A semi-quantitative real-time RT-PCR analysis revealed that LPS stimulated chCATH-B1 gene expression in a dose-dependent manner and that the LPS-inducible chCATH-B1 gene expression was inhibited by the administration of dexamethasone. The chCATH-B1 mRNA levels in DT40 cells were also increased by the administration of bacterial LTA. The results indicate that bacterial toxins induce chCATH-B1 gene expression in the chicken BF and the peptide expressed in the organ would act against pathogenic microorganisms not only directly but also indirectly by attracting mast cells.

Regulation of urocortin I and its related peptide urocortin II by inflammatory and oxidative stresses in HL-1 cardiomyocytes.

Despite our knowledge on the regulation of urocortin (Ucn) I and its related peptides in the heart, the possible involvement of cardiovascular stress substances, such as cytokines or angiotensin II (Ang II), on this regulation remains to be fully elucidated. We therefore evaluated the potential role of cardiovascular stress substances on the regulation of the Ucn-corticotropin-releasing hormone (CRH) receptor system in HL-1 cardiomyocytes using a Ucn I-specific RIA, conventional reverse transcription-PCR (RT-PCR) and quantitative real-time RT-PCR. Ucn I mRNA levels were shown to be up-regulated by lipopolysaccarides (LPS), tumor necrosis factor-alpha (TNF-alpha), Ang II, H(2)O(2), and pyrrolidinedithiocarbamate (PDTC). The LPS- and Ang II-induced increase in Ucn I mRNA levels was abolished by tempol. In addition, the secretion of Ucn I from HL-1 cardiomyocytes was stimulated by LPS and TNF-alpha. On the contrary, Ucn II mRNA was increased by TNF-alpha alone and Ang II with tempol, and the TNF-alpha-induced increase in Ucn II mRNA was abolished by erythromycin and PDTC. These results suggested that Ucn I mRNA may be up-regulated by oxidative stress, whereas Ucn II mRNA may be up-regulated by the activated nuclear factor-kappaB, i.e. inflammatory stress. CRH-R2 mRNA may be negatively regulated by the increase in expression of Ucn I and/or Ucn II mRNA. In conclusion, the Ucn-CRH receptor system may be regulated by two major forms of cardiac stresses, i.e. oxidative and inflammatory stress, and may play a critical role in cardiac stress adaptation in heart diseases.

Azelnidipine inhibits aldosterone synthesis and secretion in human adrenocortical cell line NCI-H295R.

Blockade of a mineralocorticoid receptor is a clinically useful approach to the prevention of cardiovascular disease. The present study was designed to evaluate the effect of azelnidipine, a unique dihydropyridine Ca(2+) channel blocker, on aldosterone production in the human adrenocortical cell line NCI-H295R. Azelnidipine inhibited angiotensin II- and KCl-induced expression of steroid 11beta-hydroxylase, steroid 18-hydroxylase, and the alpha1H subunit of the T-type Ca(2+) channel, and suppressed steroid biosynthesis in H295R cells by the same amount as efonidipine. On the basis of these findings, azelnidipine appears to suppress steroid biosynthesis in H295R cells beyond the blockade of L-type calcium channels.

Possible involvement of corticotropin-releasing factor receptor signaling on vascular inflammation.

Based on the reported anti-inflammatory and anti-stress responses by corticotropin-releasing factor (CRF) receptor signaling, endogenous CRF receptor agonists, CRF, urocortin (UCN) I and its related peptides, may play protective roles against cardiovascular stresses via the CRF receptor signaling. Therefore, the present study was designed to evaluate the involvement of CRF receptor signaling against vascular inflammatory stress using human aortic endothelial cells (HAECs). In addition, due to the possible involvement of CRF receptor signaling in the effects of statin on endothelial cells, the effects of pitavastatin on the expression of UCN-related peptides in HAECs were also evaluated. HAECs expressed all UCNs, CRF type 1 receptor (CRF-R1), and CRF type 2 (CRF-R2)alpha and CRF-R2beta mRNAs. Real time PCR analysis revealed that UCN I mRNA was down-regulated, whereas UCN II mRNA was up-regulated by tumor necrosis factor (TNF)-alpha. Selective blockade of CRF-R1 resulted in significant increase in TNF-alpha-induced expression of vascular adhesion molecule-1 at mRNA level and E-selectin at mRNA and protein levels. Pitavastatin up-regulated UCN I mRNA without TNF-alpha, but co-incubation with pitavastatin and TNF-alpha resulted in decrease in UCN I mRNA. On the contrary, UCN II, CRF-R1, and CRF-R2 mRNAs were markedly increased by co-incubation of pitavastatin and TNF-alpha. These facts indicate that CRF-R1 signaling may have protective role against TNF-alpha-induced vascular inflammation. In addition, because of up-regulation of CRF-R1 mRNA by pitavastatin with or without TNF-alpha, CRF-R1 may be involved in the vasoprotective effects of pitavastatin.

Differential ubiquitination defines the functional status of the tumor suppressor Smad4.

Smad4 is an essential signal transducer of all transforming growth factor-beta (TGF-beta) superfamily pathways that regulate cell growth and differentiation, and it becomes inactivated in human cancers. Receptor-activated (R-) Smads can be poly-ubiquitinated in the cytoplasm or the nucleus, and this regulates their steady state levels or shutdown of the signaling pathway. Oncogenic mutations in Smad4 and other Smads have been linked to protein destabilization and proteasomal degradation. We analyzed a panel of missense mutants derived from human cancers that map in the N-terminal Mad homology (MH) 1 domain of Smad4 and result in protein instability. We demonstrate that all mutants exhibit enhanced poly-ubiquitination and proteasomal degradation. In contrast, wild type Smad4 is a relatively stable protein that undergoes mono- or oligo-ubiquitination, a modification not linked to protein degradation. Analysis of Smad4 deletion mutants indicated efficient mono- or oligo-ubiquitination of the C-terminal MH2 domain. Mass spectrometric analysis of mono-ubiquitinated Smad4 MH2 domain identified lysine 507 as a major target for ubiquitination. Lysine 507 resides in the conserved L3 loop of Smad4 and participates in R-Smad C-terminal phosphoserine recognition. Mono- or oligo-ubiquitinated Smad4 exhibited enhanced ability to oligomerize with R-Smads, whereas mutagenesis of lysine 507 led to inefficient Smad4/R-Smad hetero-oligomerization and defective transcriptional activity. Finally, overexpression of a mutant ubiquitin that only leads to mono-ubiquitination of Smad4 enhanced Smad transcriptional activity. These data suggest that oligo-ubiquitination positively regulates Smad4 function, whereas poly-ubiquitination primarily occurs in unstable cancer mutants and leads to protein degradation.

Two short segments of Smad3 are important for specific interaction of Smad3 with c-Ski and SnoN.

c-Ski and SnoN are transcriptional co-repressors that inhibit transforming growth factor-beta signaling through interaction with Smad proteins. Among receptor-regulated Smads, c-Ski and SnoN bind more strongly to Smad2 and Smad3 than to Smad1. Here, we show that c-Ski and SnoN bind to the "SE" sequence in the C-terminal MH2 domain of Smad3, which is exposed on the N-terminal upper side of the toroidal structure of the MH2 oligomer. The "QPSMT" sequence, located in the vicinity of SE, supports the interaction with c-Ski and SnoN. Sequences similar to SE and QPSMT are found in Smad2, but not in Smad1. The N-terminal MH1 domain and linker region of Smad3 protrude from the N-terminal upper side of the MH2 oligomer toroid. Smurf2 induces ubiquitin-dependent degradation of SnoN, since it appears to be located close to SnoN through binding to the linker region of Smad2. In contrast, transcription factors Mixer and FoxH3 (FAST1) bind to the bottom side of the Smad3 MH2 toroid; therefore, c-Ski does not affect the interaction of Smads with these transcription factors. Our findings thus demonstrate the stoichiometry of how multiple molecules can associate with the Smad oligomers and how the Smad-interacting proteins functionally interact with each other.