B D Nelson

Sp1 Activates and Inhibits Transcription from Separate Elements in the Proximal Promoter of the Human Adenine Nucleotide Translocase 2 (ANT2) Gene

Expression of the adenine nucleotide translocator 2 (ANT2) gene is growth regulated. We report a feature of the ANT2 promoter that involves a novel regulatory function for the Sp1 transfactor. We show that expression from the ANT2 proximal promoter is modulated through three Sp1 elements, two of which activate and one of which partially inhibits transcription. The inhibitor site, box C, is juxtaposed to transcription start (nucleotides −7 to −2). Sp1 bound to box C decreases transcription initiation. This was demonstrated by introducing mutations in box C which (a) increased chloramphenicol acetyltransferase expression in the transient transfection assay and (b) inhibited binding of both purified Sp1 and Sp1 in crude nuclear extracts. The activating elements (A and B boxes) are located at adjacent sites in the distal region of the proximal promoter. Mutation of either box inhibits transfection by 90%, indicating that they act in a synergistic manner. Supershift experiments with crude nuclear extracts showed that only Sp1 was bound to the three GC boxes. The finding that Sp1 acts as an activator/inhibitor within the same promoter region was verified in NIH3T3, HeLa, JEG3, and COS-1, indicating that this dual effect of Sp1 is widely preserved. These data suggest a unique role for Sp1 and raise the possibility that growth activation of the ANT2 gene is regulated by the interaction of Sp1 on the A, B, and C boxes.

Tissue distribution of 35S-labelled perfluorooctane sulfonate in adult mice after oral exposure to a low environmentally relevant dose or a high experimental dose

The widespread environmental pollutant perfluorooctane sulfonate (PFOS), detected in most animal species including the general human population, exerts several effects on experimental animals, e.g., hepatotoxicity, immunotoxicity and developmental toxicity. However, detailed information on the tissue distribution of PFOS in mammals is scarce and, in particular, the lack of available information regarding environmentally relevant exposure levels limits our understanding of how mammals (including humans) may be affected. Accordingly, we characterized the tissue distribution of this compound in mice, an important experimental animal for studying PFOS toxicity. Following dietary exposure of adult male C57/BL6 mice for 1-5 days to an environmentally relevant (0.031 mg/kg/day) or a 750-fold higher experimentally relevant dose (23 mg/kg/day) of ³⁵S-PFOS, most of the radioactivity administered was recovered in liver, bone (bone marrow), blood, skin and muscle, with the highest levels detected in liver, lung, blood, kidney and bone (bone marrow). Following high daily dose exposure, PFOS exhibited a different distribution profile than with low daily dose exposure, which indicated a shift in distribution from the blood to the tissues with increasing dose. Both scintillation counting (with correction for the blood present in the tissues) and whole-body autoradiography revealed the presence of PFOS in all 19 tissues examined, with identification of thymus as a novel site for localization for PFOS and bone (bone marrow), skin and muscle as significant body compartments for PFOS. These findings demonstrate that PFOS leaves the bloodstream and enters most tissues in a dose-dependent manner.

Isolation of murine intrahepatic immune cells employing a modified procedure for mechanical disruption and functional characterization of the B, T and natural killer T cells obtained

Intrahepatic immune cells (IHIC) are known to play central roles in immunological responses mediated by the liver, and isolation and phenotypic characterization of these cells is therefore of considerable importance. In the present investigation, we developed a simple procedure for the mechanical disruption of mouse liver that allows efficient isolation and phenotypic characterization of IHIC. These cells are compared with the corresponding cells purified from the liver after enzymatic digestion with different concentrations of collagenase and DNase. The mechanical disruption yielded viable IHIC in considerably greater numbers than those obtained following enzymatic digestion. The IHIC isolated employing the mechanical disruption were heterogeneous in composition, consisting of both innate and adaptive immune cells, of which B, T, natural killer (NK), NK T cells, granulocytes and macrophages were the major populations (constituting 37·5%, 16·5%, 12·1%, 7·9%, 7·9% and 7·5% of the total number of cells recovered respectively). The IHIC obtained following enzymatic digestion contained markedly lower numbers of NK T cells (1·8%). The B, T and NK T cells among IHIC isolated employing mechanical disruption were found to be immunocompetent, i.e. they proliferated in vitro in response to their specific stimuli (lipopolysaccharide, concanavalin A and α‐galactosylceramide respectively) and produced immunoglobulin M and interferon‐γ. Thus, the simple procedure for the mechanical disruption of mouse liver described here results in more efficient isolation of functionally competent IHIC for various types of investigation.

Characterization of a Silencer Element and Purification of a Silencer Protein That Negatively Regulates the Human Adenine Nucleotide Translocator 2 Promoter

Expression of adenine nucleotide translocator isoform 2 (ANT2) is growth regulated. In the present study, we report the presence of a silencer region in the human ANT2 promoter and the purification of a two-component factor that recognizes a specific hexanucleotide element, GTCCTG, of the silencer. Transfection of deletion constructs shows that ANT2 silencer activity extends over a region of at least 310 nts. However, mutating the GTCCTG element completely relieves silencing activity in the context of the human ANT2 promoter. The data suggest that the GTCCTG element might be required for maintaining silencer activity of the extended silencer region. The ANT2 silencer region cloned in front of the herpes simplex virus thymidine kinase promoter confers nearly complete inhibition to the heterologous promoter. However, unlike the ANT2 promoter, mutating the GTCCTG element restores only partial activity to the herpes simplex virus thymidine kinase promoter. A protein complex consisting of two major polypeptides of 37 and 49 kDa was isolated from HeLa nuclear extracts by affinity chromatography using the GTCCTG element as the affinity resin. Cross-linking studies and Southwestern analysis indicate that p37 binds DNA. p49 appears to be loosely associated with the p37/DNA complex but is necessary for strong binding of p37. Our data implicating the GTCCTG element directly in silencing of the ANT2 promoter, together with data from the literature reporting the presence of this element within the silencer region of several additional promoters, suggest a general role of the GTCCTG element in transcriptional silencing.

TGF-β/NF1/Smad4-mediated suppression of ANT2 contributes to oxidative stress in cellular senescence

Oxidative stress and persistent activation of DNA damage response (DDR) are causally involved in the development of cellular senescence, a phenomenon implicated in fundamental (patho)physiological processes such as aging, fetal development and tumorigenesis. Here, we report that adenine nucleotide translocase-2 (ANT2) is consistently down-regulated in all three major forms of cellular senescence: replicative, oncogene-induced and drug-induced, in both normal and cancerous human cells. We previously reported formation of novel NF1/Smad transcription repressor complexes in growth-arrested fibroblasts. Here we show that such complexes form in senescent cells. Mechanistically, binding of the NF1/Smad complexes to the NF1-dependent repressor elements in the ANT2 gene promoter repressed ANT2 expression. Etoposide-induced formation of these complexes and repression of ANT2 were relatively late events co-incident with production and secretion of, and dependent on, TGF-β. siRNA-mediated knock-down of ANT2 in proliferating cells resulted in increased levels of reactive oxygen species (ROS) and activation of the DDR. Knock-down of ANT2, together with etoposide treatment, further intensified ROS production and DNA damage signaling, leading to enhanced apoptosis. Together, our data show that TGF-β-mediated suppression of ANT2 through NF1/Smad4 complexes contributes to oxidative stress and DNA damage during induction of cellular senescence.

In vivo mapping of the human adenine nucleotide translocator-2 (ANT2) promoter provides support for regulation by a pair of proximal Sp1-activating sites and an upstream silencer element.

Regulatory factors bound to the human adenine nucleotide translocator-2 (ANT2) promoter have been mapped in HeLa cells by in vivo DNase I protection and ligation-mediated PCR amplification. Protein binding was detected at only three sites within the extended promoter region (to nt -703). One, starting at nt -61 and covering the TATA box and transcription start, most probably represents occupation by the transcription-initiation machinery. A repeated Sp1 element determined by in vitro studies to be the major activation element for the promoter was also protected in vivo on nucleotides responsible for strong binding to the zinc fingers. Occupation of two additional upstream Sp1 elements was not observed. The third site occupied in vivo was identified previously by in vitro studies as a unique silencer element. Treatment of cells with trichostatin A to induce hyperacetylation released the silencer-binding protein after 1 h, but had no effect on the Sp1-activating elements. Prolonged treatment (24 h) displaced Sp1 from the activating elements. These findings confirm and extend in vitro studies indicating that regulation of the ANT2 promoter is most probably exerted through a single pair of proximal Sp1-activating elements and an upstream silencer, and that chromatin organization plays a role in the interaction between the two.

Activity of the human cytochrome c1 promoter is modulated by E2F

The human cytochrome c(1) promoter is strongly activated in transfected Drosophila SL2 cells expressing exogenous human E2F1. Transfection-deletion experiments, DNase I protection by E2F1 and gel mobility-shift experiments locate E2F1 activation sites to two regions on either side of the transcription start site. Deletion of either region prevents E2F1 activation in transfected SL2 cells, suggesting a co-operative interaction between them. E2F6, a member of the E2F family that lacks transactivation domains but contains specific suppressor domains, inhibits cytochrome c(1) promoter activity when co-transfected into HeLa cells, indicating that the E2F proteins modulate the cytochrome c(1) promoter in mammalian cells. However, E2F is not a general regulator of oxidative phosphorylation genes since three additional nuclear-encoded mitochondrial genes were unaffected by E2F1 or E2F6.

Primary Biliary Cirrhosis: Indication for a Single Mitochondrial Antigenic Epitope Detected by Patient Autoantibodies and a Novel Monoclonal Antibody

A monoclonal antibody specific for the major primary biliary cirrhosis (PBC)‐associated mitochondrial antigen (subunit I of NADH‐ubiquinone reductase) was produced and used to study the binding sites recognized by anti‐mitochondrial autoantibodies (AMA) in PBC sera. Immunization of mice with purified beef heart mitochondrial inner membranes resulted in one monoclonal antibody which reacted with mitochondrial proteins. This antibody (PBC‐MoAb), which was of the IgG2b subclass with kappa light chains, exhibited a pattern of immunofluorescence reactivity with rat kidney, human thyroid, and cultured human epithelial cells (Hep‐2) similar to that obtained with sera from PBC patients. Similar binding patterns between PBC‐MoAb and AMA were also found in western blot analysis using mitochondria as antigen. Both types of antibodies revealed a major antigen of 75 kDa, a minor antigen of 60 kDa, and a third antigen (70 kDa), which was detected only in samples that had not been boiled prior to electrophoresis. Furthermore, optimal binding of the PBC‐MoAb and AMA to the 75 and 70 kDa antigens required reduction of the antigen with mercaptoethanol prior to electrophoresis. Competition ELISA experiments were conducted to compare the epitopes recognized by PBC‐MoAb and AMA. Of 28 PBC sera tested, 27 inhibited the binding of PBC‐MoAb to mitochondrial inner membranes by almost 100% and one serum inhibited binding by 50%, indicating that most PBC sera contain autoantibodies reactive with the same or a closely related antibody binding site as the PBC‐MoAb. PBC‐MoAb inhibited AMA binding to the inner membrane by more than 80% in 10 sera, 60–80% in 11 sera, and 40–59% in seven sera, with an average inhibition of 71%. Our observations strongly indicate that anti‐mitochondrial autoantibody binding sites are restricted to a highly immunogenic epitope on the major PBC‐specific antigen (NADH‐ubiquinone reductase subunit I), and that the anti‐mitochondrial monoclonal antibody obtained has a specificity identical with the human PBC‐specific M2 type anti‐mitochondrial autoantibody.

Primary Biliary Cirrhosis (PBC): Characterization of a Monoclonal Antibody (PBC‐MoAb) having Specificity Identical with Disease‐Associated Auto‐antibodies

We have raised a monoclonal antibody (PBC‐MoAb) directed against mitochondria which resembles patent anti‐mitochondrial autoantibodies (AMA) (M2 type) in several respects.

Characterization of the hepatic and splenic immune status and immunoglobulin synthesis in aged male mice lacking the peroxisome proliferator-activated receptor-alpha (PPARα).

It is now well established that the nuclear receptor peroxisome proliferator‐activated receptor‐alpha (PPARα) is expressed in different types of immune cells and plays a pivotal role in the regulation of age‐related production of inflammatory cytokines. However, the role(s) of this receptor in the regulation of immune cell homoeostasis in ageing non‐lymphoid and lymphoid organs has not yet been resolved. We examine this issue here by evaluating the hepatic and splenic immune status and immunoglobulin (Ig) production in male PPARα‐null mice and their wild‐type littermates at one and 2 years of age. In comparison with the age‐matched control animals, PPARα‐null mice exhibited age‐related elevations in the numbers of total, as well as of phenotypically distinct subpopulations of intrahepatic immune cells (IHIC) and splenocytes. Moreover, at 2 years of age, these alterations in hepatic immune cells were accompanied by significant increases in hepatic levels of the pro‐inflammatory cytokines tumour necrosis factor‐alpha (TNF‐α), interleukin‐6 (IL‐6) and interferon‐gamma (IFN‐γ), in combination with the development of hepatic inflammatory loci containing mixtures of leucocytes. Alterations in splenocytes of old PPARα‐null mice were also accompanied by increases in cellularity of both white and red pulps of the spleen. Furthermore, these same animals exhibited pronounced increases in the numbers of splenic plasma cells and enhanced production of Ig of different isotypes, including IgG1, IgG2a and IgE. Thus, our findings indicate that upon ageing, PPARα plays a crucial role in regulating the total numbers, compositions and functions of immune cells in both lymphoid and non‐lymphoid immune organs of mice.