A commentary on gestational programming and functions of HLA-G in pregnancy.

HLA-G is an HLA class Ib gene that is highly expressed in human trophoblast cells. The single HLA-G mRNA is alternatively spliced to generate at least seven transcripts, three of which encode soluble isoforms. Many studies have shown that high levels of soluble antigens are associated with successful implantation and graft acceptance. To study expression, regulation and functions of two of the soluble isoforms, HLA-G5 and HLA-G6, we generated recombinant proteins in eukaryotic cells and developed monoclonal antibodies specific for each of the two proteins. In addition, we investigated the olive baboon Paan-AG gene as a potential functional correlate of HLA-G. Here, we present summaries of the studies that have been conducted in our laboratory using these tools and discuss the results within the context of the research on this topic that is ongoing in ours and other laboratories worldwide. Collectively, the data indicate that soluble HLA-G is a critical contributor to immune privilege in pregnancy and imply that this placenta-derived substance may impact other pathways leading to successful reproduction.

The olive baboon (Papio anubis): a potential animal model to study the function of human leukocyte antigen-G (HLA-G).

The human class Ib major histocompatibility complex (MHC) molecule, HLA-G, is unique in its limited polymorphism, high expression in the placenta and generation of multiple transcripts by alternative splicing. The proteins encoded by these transcripts are believed to modulate maternal-fetal immunological relationships during pregnancy. The baboon placenta expresses Paan-AG, a novel MHC molecule that is evolutionarily related to the MHC-A locus but shares unique characteristics with HLA-G. In this brief review, we present evidence suggesting that Paan-AG may be the functional homologue of HLA-G, and propose that the baboon would compromise an excellent animal model for functional studies of HLA-G proteins in human pregnancy.

Immunogenicity of the soluble isoforms of HLA-G.

Soluble class Ib HLA-G glycoproteins synthesized in the placenta are abundant in the pregnant uterus and circulate in maternal blood throughout pregnancy. To establish immunogenicity of these proteins, we tested sera from 64 women with at least one successful pregnancy (multigravid), 21 women who had never been pregnant, and 54 males for antibodies to epitopes present on recombinant sHLA-G isoforms (sHLA-G1, sHLA-G2) derived from HLA 6.0 cDNA (HLA-G*0101 allele). By indirect enzyme-linked immunosorbent assay, antibodies to sHLA-G isoforms were identified in six sera, all from multigravid women; all other sera were negative (P = 0.0083). Immunoblots showed that two of the positive sera reacted exclusively with sHLA-G1 and -G2 whereas four reacted to both sHLA-G and pooled HLA class I antigens. To establish potential relationships between anti-sHLA-G and exposure to foreign paternal alleles (*0101, *0103, *0104, *0106), all multigravid women and their partners were genotyped. No relationship between allelic disparity and antibody production was identified. Taken together, these results indicate that (i) tolerance to HLA-G is the usual condition as antibodies to HLA-G were not detected in 91% (58/64) multigravid women, and (ii) pregnancy stimulates loss of tolerance in 9% (6/64) of multigravid women. All six women delivered healthy babies, demonstrating that maternal antibodies to epitopes on sHLA-G do not abrogate pregnancy.

Rapid recovery and identification of anthrax bacteria from the environment.

Bacillus anthracis has been recognized as a highly likely biological warfare or terrorist agent. We have designed culture techniques to rapidly isolate and identify "live" anthrax from suspected environmental release. A special medium (3AT medium) allows for discrimination between closely related bacilli and non-pathogenic strains. Nitrate was found to be a primary factor influencing spore formation in Bacillus anthracis. Nitrate reduction in anthrax is not an adaptation to saprophytic environmental existence, but it is a signal to enhance environmental survival upon the death of the anthrax host, which can be mimicked in culture.

Role for copper in transient oxidation and nuclear translocation of MTF-1, but not of NF-kappa B, by the heme-hemopexin transport system.

Heme-hemopexin (2-10 microM) is used as a model for intravenous heme released in trauma, stroke, and ischemia-reperfusion. A transient increase in cellular protein oxidation occurs during receptor-mediated heme transport from hemopexin which is inhibited by the nonpermeable Cu(I) chelator, bathocuproinedisulfonate. Thus, participation of surface redox process involving Cu(I) generation are proposed to be linked to the induction of the protective proteins heme oxygenase-1 (HO-1) and metallothionein-1 (MT-1) by heme-hemopexin. The region (-153 to -42) in the proximal promoter of the mouse MT-1 gene responds to heme- and CoPP-hemopexin in transient transfection assays and contains metal-responsive elements for MTF-1 and an antioxidant-responsive element (ARE) overlapping a GC-rich E-box to which USF-1 and -2 bind. No decreases in DNA binding of the diamide-oxidation sensitive USF-1 and -2 occur upon exposure of cells to heme-hemopexin. MTF-1 and the ARE-binding proteins are relatively resistant to diamide oxidation and are induced approximately eight- and two-fold, respectively, by heme-hemopexin. BCDS prevents the nuclear translocation of MTF-1 by both heme- and CoPP-hemopexin complexes as well as MT-1 mRNA induction by CoPP-hemopexin. Thus, copper is needed for the surface oxidation events and yet the nuclear translocation of MTF-1 in response to hemopexin occurs via copper, probably Cu(I),-dependent signaling cascades from the hemopexin receptor rather than the oxidation per se.

Cell-surface events for metallothionein-1 and heme oxygenase-1 regulation by the hemopexin-heme transport system.

A model has been developed for the hemopexin receptor-mediated heme transport system based on iron uptake in yeast. Two steps are required: reduction followed by oxidation by a multi-copper-oxidase. Furthermore, in the hemopexin system, the surface redox events have been linked with gene regulation. The impermeable Cu(I) chelator bathocuproinedisulfonate (BCDS) is shown here to abrogate heme oxygenase-1 (HO-1) mRNA induction by heme-hemopexin. A role for Cu(I) in the regulation of HO-1 and MT-1 (Sung et al., 1999) by hemopexin supports the participation of electron transport processes at the cell surface as does competition by the reductase activator, ferric citrate, which inhibits the induction of MT-1 and HO-1 mRNA by heme-hemopexin. There is a key role for the hemopexin receptor because neither ferric citrate nor iron-transferrin alone regulates MT-1 or HO-1. Cell-surface copper is the first molecule to link the concomitant regulation of HO-1 and MT-1 by the hemopexin receptor. In addition, cytochrome b5 and cytochrome b5 reductase are implicated here in the response of cells to heme-hemopexin. Reduction of one or more electron donors of the reductase and oxidation of the electron acceptor, b5 heme, leads to gene regulation, but only when heme-hemopexin is bound to its receptor. Protein kinase cascades, including JNK, are activated by the hemopexin receptor itself upon ligand binding but are modulated by a Cu(I)-dependent process likely to be heme uptake.

Pulsed microwave induced light, sound, and electrical discharge enhanced by a biopolymer.

Intense flashes of light were observed in sodium bicarbonate and hydrogen peroxide solutions when they were exposed to pulsed microwave radiation, and the response was greatly enhanced by a microwave-absorbing, biosynthesized polymer, diazoluminomelanin. A FPS-7B radar transmitter, operating at 1.25 GHz provided pulses of 5.73 +/- 0.09 micros in duration at 10.00 +/- 0.03 pulses/s with 2.07 +/- 0.08 MW forward power (mean +/- standard deviation), induced the effect but only when the appropriate chemical interaction was present. This phenomenon involves acoustic wave generation, bubble formation, pulsed luminescence, ionized gas ejection, and electrical discharge. The use of pulsed microwave radiation to generate highly focused energy deposition opens up the possibility of a variety of biomedical applications, including targeting killing of microbes or eukaryotic cells. The full range of microwave intensities and frequencies that induce these effects has yet to be explored and, therefore, the health and safety implications of generating the phenomena in living tissues remain an open question.

Cellular protection mechanisms against extracellular heme. heme-hemopexin, but not free heme, activates the N-terminal c-jun kinase.

Hemopexin protects cells lacking hemopexin receptors by tightly binding heme abrogating its deleterious effects and preventing nonspecific heme uptake, whereas cells with hemopexin receptors undergo a series of cellular events upon encountering heme-hemopexin. The biochemical responses to heme-hemopexin depend on its extracellular concentration and range from stimulation of cell growth at low levels to cell survival at otherwise toxic levels of heme. High (2-10 microM) but not low (0.01-1 microM) concentrations of heme-hemopexin increase, albeit transiently, the protein carbonyl content of mouse hepatoma (Hepa) cells. This is due to events associated with heme transport since cobalt-protoporphyrin IX-hemopexin, which binds to the receptor and activates signaling pathways without tetrapyrrole transport, does not increase carbonyl content. The N-terminal c-Jun kinase (JNK) is rapidly activated by 2-10 microM heme-hemopexin, yet the increased intracellular heme levels are neither toxic nor apoptotic. After 24 h exposure to 10 microM heme-hemopexin, Hepa cells become refractory to the growth stimulation seen with 0.1-0.75 microM heme-hemopexin but HO-1 remains responsive to induction by heme-hemopexin. Since free heme does not induce JNK, the signaling events, like phosphorylation of c-Jun via activation of JNK as well as the nuclear translocation of NFkappaB, G2/M arrest, and increased expression of p53 and of the cell cycle inhibitor p21(WAF1/CIP1/SDI1) generated by heme-hemopexin appear to be of paramount importance in cellular protection by heme-hemopexin.

Inhibition of G protein in human sperm and its influence on acrosome reaction and zona pellucida binding.

OBJECTIVE: To evaluate human sperm acrosomal status, zona pellucida (ZP)-binding capacity, and sperm motion characteristics after treatment with pertussis toxin followed by exposure to increasing concentrations of solubilized human ZP. DESIGN: Prospective analytical study. SETTING: Normal human sperm donors in an academic research environment. INTERVENTION: Sperm were prepared with a wash and swim-up method and treated with a final concentration of 100 ng/mL pertussis toxin. Acrosomal status were determined using a Pisum sativum agglutinin-fluorescien-isothiocyanate method after exposure of sperm to 0.25, 0.5, 0.75, and 1.00 ZP/microL solutions of human ZP. Zona binding potential was recorded using intact zona-binding assays. Motion characteristics were recorded with a semen analyzer. MAIN OUTCOME MEASURE: Percentage acrosome-reacted sperm, number of zona-bound sperm, and sperm motion parameters. RESULTS: Spermatozoa treated with 100 ng/mL pertussis toxin, followed by ZP-mediated acrosome reaction induction, showed a significant decrease in the percentage of acrosome-reacted sperm compared with untreated controls. Motion characteristics of 3-hour capacitated sperm after treatment with either phosphate-buffered saline (PBS) or pertussis toxin were not different. Pertussis toxin-treated sperm populations bound significantly more sperm to the ZP after 4 hours incubation compared with the PBS-control groups: 137.1 +/- 8.0 compared with 96.3 +/- 7.0 (mean +/- SEM). CONCLUSIONS: The data support the concept of the controlling mechanism and importance of G proteins during the ZP-mediated acrosome reaction. Intact acrosome correlate with and are needed to ensure tight zona binding.

Identification of a Renibacterium salmoninarum DNA fragment associated with bacterial internalization into CHSE-cultured cells.

We report here the isolation of a Renibacterium salmoninarum DNA sequence capable of transforming a non-invasive Escherichia coli strain into a microorganism able to enter the fish cell line, CHSE-214. Immunofluorescence and electron microscopy techniques were used to assess the acquired invasive phenotype by HB101 E. coli cells, upon transformation with pPMV-189. This plasmid carries a 2282-bp R. salmoninarum DNA segment. The invasive phenotype is conserved upon deletion of approximately 1000 bp at the 3' end of the insert. The remaining segment contains an ORF region encoding a putative protein of about 30 kDa.