Interleukin-32 expression is associated with a poorer prognosis in head and neck squamous cell carcinoma.

Head and neck squamous cell carcinoma (HNSCC) represent the sixth most common malignancy diagnosed worldwide. Patient's survival is low due the high frequency of tumor recurrence. Inflammation promotes carcinogenesis as well as the formation of metastasis. Indeed, proinflammatory mediators are known to stimulate the expression of specific transcription factors such as Snai1 and to increase the ability of tumor cells to migrate into distant organs. The atypical interleukin-32 (IL32) was mainly described to exacerbate inflammatory responses in rheumatoid arthritis and inflammatory bowel diseases. IL32 is expressed in various cancers but its role in HNSCC physiology is still unexplored. Here, we analyzed the expression of IL32 and its implication on HNSCC aggressiveness. We showed that patients with tumor expressing high amounts of IL32 exhibit decreased disease-free periods (20.5 mo vs. 41 mo, P = 0.0041) and overall survival (P = 0.0359) in comparison with individuals with weak IL32 tumor expression. This overexpression was negatively correlated with gender (P = 0.0292) and p53 expression (P = 0.0307). In addition, in vitro data linked IL32 expression to metastasis formation since IL32 inhibition decreased Snai1 expression and tumor cell migration in a Boyden chamber assay. Our data provide new insight into the role of IL32 in HNSCC aggressiveness.

Maternal caffeine ingestion during gestation and lactation influences respiratory adaptation to acute alveolar hypoxia in newborn rats and adenosine A2A and GABA A receptor mRNA transcription.

Caffeine is a widely used psychostimulant freely crossing the placental barrier. At the doses usually absorbed, it acts as an antagonist of both A1 and A2A adenosine receptors. Pregnant women are generally not advised to limit their caffeine consumption and thus expose their progeny to the drug during the whole of gestation and lactation. The possibility that such caffeine exposure may have long-term consequences on brain development has led to several behavioral investigations on animal models. Despite the crucial role played by adenosine receptor systems in neonatal breathing control, few studies in vitro have been concerned with the consequences of maternal caffeine absorption on breathing, and none in the unrestrained intact animal. The present investigation analyzed the influence of caffeine exposure via placental and milk transfer on resting ventilation and on the response to moderate alveolar hypoxia of 0 to 2-day-old newborn rat (P0-P2) together with the possible underlying mechanisms. Dams absorbed caffeine (46+/-3 mg/kg/day) via drinking fluid (0.2 g/L) throughout gestation, in conditions mimicking moderate human consumption. Caffeine exposure did not significantly affect basal respiratory parameters. In contrast, it attenuated both the early increase and the secondary decrease in ventilation triggered by moderate alveolar hypoxia (11% O2 inhaled). The abolition of Fos protein expression evoked by hypoxia suggested that caffeine exposure may decrease the activity of O2-sensing peripheral chemoreceptor pathway. From real-time PCR data, those functional alterations were associated to increases in A2A adenosine receptor and alpha2 GABA(A) receptor subunit mRNAs in the medulla. This indicates that, even at moderate doses, maternal caffeine consumption may induce a series of subtle developmental alterations that may affect modulation of breathing control in the neonate in pathological situations such hypoxia.

The end of a myth: cloning and characterization of the ovine melatonin MT(2) receptor.

BACKGROUND AND PURPOSE: For many years, it was suspected that sheep expressed only one melatonin receptor (closely resembling MT(1) from other mammal species). Here we report the cloning of another melatonin receptor, MT(2), from sheep. EXPERIMENTAL APPROACH: Using a thermo-resistant reverse transcriptase and polymerase chain reaction primer set homologous to the bovine MT(2) mRNA sequence, we have cloned and characterized MT(2) receptors from sheep retina. KEY RESULTS: The ovine MT(2) receptor presents 96%, 72% and 67% identity with cattle, human and rat respectively. This MT(2) receptor stably expressed in CHO-K1 cells showed high-affinity 2[(125)I]-iodomelatonin binding (K(D)= 0.04 nM). The rank order of inhibition of 2[(125)I]-iodomelatonin binding by melatonin, 4-phenyl-2-propionamidotetralin and luzindole was similar to that exhibited by MT(2) receptors of other species (melatonin > 4-phenyl-2-propionamidotetralin > luzindole). However, its pharmacological profile was closer to that of rat, rather than human MT(2) receptors. Functionally, the ovine MT(2) receptors were coupled to G(i) proteins leading to inhibition of adenylyl cyclase, as the other melatonin receptors. In sheep brain, MT(2) mRNA was expressed in pars tuberalis, choroid plexus and retina, and moderately in mammillary bodies. Real-time polymerase chain reaction showed that in sheep pars tuberalis, premammillary hypothalamus and mammillary bodies, the temporal pattern of expression of MT(1) and MT(2) mRNA was not parallel in the three tissues. CONCLUSION AND IMPLICATIONS: Co-expression of MT(1) and MT(2) receptors in all analysed sheep brain tissues suggests that MT(2) receptors may participate in melatonin regulation of seasonal anovulatory activity in ewes by modulating MT(1) receptor action.

Structure and expression of the human histamine H4-receptor gene.

We report the characterization by genomics-based approach of the human H4-receptor gene structure. The H4-receptor gene have been mapped by radiation hybrid experiments (Gene Bridge 4) on chromosome 18q11.2, between the AFMBB11WH5 and CHLC.GATA85D10 markers. The H4-receptor gene spans more than 21 kbp and contains three exons separated by two large introns (>7 kbp). RT-PCR analysis showed that the H4-receptor gene encoded a 3.7 kb mRNA which did not seem to be alternatively spliced within its coding region. The H4-receptor transcripts were found to be highly expressed in peripheral tissues implicated in inflammatory responses such as leukocytes, spleen, lung, and liver. In addition, low expression level of the H4-receptor mRNA was also detected in several human brain regions. Analysis of the 5'-flanking region of the H4-receptor gene did not reveal the existence of canonical TATA or CAAT-box. However, several putative regulatory elements mediating TNFalpha or IL-6-stimulated transcriptional activation were detected. The uteroglobin promoter binding factor, known to mediate anti-inflammatory response of uteroglobin, in the lung, was also found in this region. Thus, the description of the H4-receptor gene promoter region will facilitate the elucidation of its transcriptional control by factors secreted during inflammatory responses.

Truncated isoforms inhibit [3H]prazosin binding and cellular trafficking of native human alpha1A-adrenoceptors.

We have identified from human liver eight alpha(1A)-adrenoceptor (alpha(1A)-AR) splice variants that were also expressed in human heart, prostate and hippocampus. Three of these alpha(1A)-AR isoforms (alpha(1A-1)-AR, alpha(1A-2a)-AR and alpha(1A-3a)-AR) gave rise to receptors with seven transmembrane domains (7TMalpha(1A)-AR). The other five (alpha(1A-2b)-AR, alpha(1A-2c)-AR, alpha(1A-3c)-AR, alpha(1A-5)-AR and alpha(1A-6)-AR) led to truncated receptors lacking transmembrane domain VII (6TMalpha(1A)-AR). The 7TMalpha(1A)-AR isoforms transiently expressed in COS-7 cells bound [(3)H]prazosin with high affinity (K(d) 0.2 nM) and mediated a noradrenaline (norepinephrine)-induced increase in cytoplasmic free Ca(2+) concentration, whereas the 6TMalpha(1A)-AR isoforms were incapable of ligand binding and signal transduction. Immunocytochemical studies with N-terminal epitope-tagged alpha(1A)-AR isoforms showed that the 7TMalpha(1A)-AR isoforms were present both at the cell surface and in intracellular compartments, whereas the 6TMalpha(1A)-AR isoforms were exclusively localized within the cell. Interestingly, in co-transfected cells, each truncated alpha(1A)-AR isoform inhibited [(3)H]prazosin binding and cell-surface trafficking of the co-expressed 'original' 7TMalpha(1A-1)-AR. However, there was no modification of either the [(3)H]prazosin-binding affinity or the pharmacological properties of alpha(1A-1)-AR. Immunoblotting experiments revealed that co-expression of the alpha(1A-1)-AR with 6TMalpha(1A)-AR isoforms did not impair alpha(1A-1)-AR expression. Therefore the expression in human tissues of many truncated isoforms constitutes a new regulation pathway of biological properties of alpha(1A)-AR.

Genomic organization and characterization of splice variants of the human histamine H3 receptor.

In the present paper we report the genomic organization of the human histamine H3-receptor gene, which consists of four exons spanning 5.5 kb on chromosome 20. Using PCR, six alternative splice variants of the H3 receptor were cloned from human thalamus. These variants were found to be coexpressed in human brain, but their relative distribution varied in a region-specific manner. These isoforms displayed either a deletion in the putative second transmembrane domain (TM), H3(DeltaTM2, 431aa) or a variable deletion in the third intracellular loop (i3), H3(Deltai3, 415aa), H3(Deltai3, 365aa), H3(Deltai3, 329aa) and H3(DeltaTM5+Deltai3, 326aa). In order to determine the biological role of the H3 receptor variants compared with the 'original' H3(445aa) receptor, three isoforms, namely H3(445aa), H3(DeltaTM2, 431aa) and H3(Deltai3, 365aa), were expressed in CHO cells and their pharmacological properties were investigated. Binding studies showed that H3(DeltaTM2, 431aa) transiently expressed in CHO cells was unable to bind [125I]iodoproxyfan, whereas both the H3(445aa) and H3(Deltai3, 365aa) receptors displayed a high affinity for [125I]iodoproxyfan [K(d)=28+/-5 pM (n=4) and 8+/-1 pM (n=5) respectively]. In addition, H3(Deltai3, 365aa) possessed the same pharmacological profile as the H3(445aa) receptor. However, in CHO cells expressing H3(Deltai3, 365aa), H3 agonists did not inhibit forskolin-induced cAMP production, stimulate [35S]guanosine 5'-[gamma-thio]triphosphate ([35S]GTP[S]) binding or stimulate intracellular Ca(2+) mobilization. Therefore the 80-amino-acid sequence located at the C-terminal portion of i3 plays an essential role in H3 agonist-mediated signal transduction. The existence of multiple H3 isoforms with different signal transduction capabilities suggests that H3-mediated biological functions might be tightly regulated through alternative splicing mechanisms.