Central depletion of brain-derived neurotrophic factor in mice results in high bone mass and metabolic phenotype.

Brain-derived neurotrophic factor (BDNF) plays important roles in neuronal differentiation/survival, the regulation of food intake, and the pathobiology of obesity and type 2 diabetes mellitus. BDNF and its receptor are expressed in osteoblasts and chondrocyte. BDNF in vitro has a positive effect on bone; whether central BDNF affects bone mass in vivo is not known. We therefore examined bone mass and energy use in brain-targeted BDNF conditional knockout mice (Bdnf(2lox/2lox)/93). The deletion of BDNF in the brain led to a metabolic phenotype characterized by hyperphagia, obesity, and increased abdominal white adipose tissue. Central BDNF deletion produces a marked skeletal phenotype characterized by increased femur length, elevated whole bone mineral density, and bone mineral content. The skeletal changes are developmentally regulated and appear concurrently with the metabolic phenotype, suggesting that the metabolic and skeletal actions of BDNF are linked. The increased bone development is evident in both the cortical and trabecular regions. Compared with control, Bdnf(2lox/2lox)/93 mice show greater trabecular bone volume (+50% for distal femur, P < 0.001; +35% for vertebral body, P < 0.001) and midfemoral cortical thickness (+11 to 17%, P < 0.05), measured at 3 and 6 months of age. The skeletal and metabolic phenotypes were gender dependent, with female being more affected than male mice. However, uncoupling protein-1 expression in brown fat, a marker of sympathetic tone, was not different between genotypes. We show that deletion of central BDNF expression in mice results in increased bone mass and white adipose tissue, with no significant changes in sympathetic signaling or peripheral serotonin, associated with hyperphagia, obesity, and leptin resistance.

Intravascular and endobronchial DNA delivery to murine lung tissue using a novel, nonviral vector.

Gene transfer to the lung can be achieved via either the airway or the pulmonary vasculature. We evaluated gene transfer and expression by intravascular and endobronchial routes, using DNA complexed with G9 PAMAM dendrimer or naked plasmid DNA. Intravascular tail vein delivery of dendrimer-complexed pCF1CAT plasmid resulted in high levels of transgene expression in the lung at 12 and 24 hr, followed by a second peak of expression 3 to 5 days after administration. After intravenous administration of the complexes, CAT expression was never observed in organs other than the lung. There were only minimal levels of CAT protein expressed in the lung after intravenous administration of naked plasmid DNA. Repeated intravascular doses of the dendrimer-complexed plasmid, administered four times at 4-day intervals, maintained expression at 15-25% of peak concentrations achieved after the initial dose. Endobronchial delivery of naked pCF1CAT plasmid produced significant amounts of CAT protein in the lung. Comparison of intratracheal and intranasal routes resulted in similar expression levels of CAT in the lung and trachea. However, in juxtaposition to vascular delivery, intranasal delivery of dendrimer-complexed plasmid DNA gave lower levels of CAT expression than that observed with naked plasmid DNA. In situ localization of CAT enzymatic activity suggested that vascular administration seemed to achieve expression in the lung parenchyma, mainly within the alveoli, while endobronchial administration primarily targeted bronchial epithelium. Our results show that intravenously administered G9 dendrimer is an effective vector for pulmonary gene transfer and that transgene expression can be prolonged by repeated administration of dendrimer-complexed DNA.

Evidence for interference in estradiol-17beta inactivation to estrone by oxidized low-density lipoprotein and selected lipid peroxidation products.

An elevation in plasma estrogen levels is believed to play a key role in the pathogenesis of breast cancer. The conversion of estradiol-17beta (E2) to estrone (E1) by 17beta-hydroxy steroid dehydrogenase type 4 (17-HSD4) represents a major pathway of its inactivation in cells. In this study the potential relationship between lipoprotein peroxidation products and E2 metabolism was examined. It was noted that oxidized low-density lipoprotein (OX-LDL), not native LDL, caused a time- and concentration-dependent inhibition of the conversion of labeled E2 to E1 in THP-1 macrophage cells. Further studies noted that among the lipoprotein peroxidation products examined, malondialdehyde (MDA) caused a marked decrease in this reaction, whereas hexanal and a variety of oxysterols had no effect. This inhibition of E1 formation from E2 in THP-1 cells was confirmed by the quantitation of estrone formed with high-pressure liquid chromatography and by the expression of 17-HSD4 by reverse transcriptase-polymerase chain reaction. MDA added to Hep G2 cells showed a similar trend in E1 formation. These results suggest that increased oxidative stress and lipid peroxidation might result in decreased inactivation of biologically active estrogen. This might be important in postmenopausal women undergoing estrogen replacement therapy.

TRAIL death pathway expression and induction in thyroid follicular cells.

To determine whether programmed cell death in thyroid follicular cells can be related to activation of the tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) pathway, we examined the expression and function of this pathway in primary thyroid follicular cells and a papillary thyroid carcinoma cell line in vitro. Despite the expression of TRAIL receptors death receptor 4 and death receptor 5, purified TRAIL could not induce programmed cell death (PCD) in any of the thyroid follicular cells examined. However, pre-incubation with cycloheximide before TRAIL facilitated the induction of rapid and massive PCD. This suggested that despite the presence of a labile inhibitor of the TRAIL pathway, TRAIL could mediate PCD under appropriate conditions. To determine whether there were sources of TRAIL in the thyroid that could interact with thyroid follicular cell TRAIL receptors, RNase protection assays were used to determine TRAIL mRNA expression. TRAIL message was expressed in intrathyroidal lymphocytes isolated from a patient with thyroiditis, and unexpectedly, thyroid follicular cells themselves could be induced to express abundant TRAIL message in the presence of the inflammatory cytokines interferon gamma, tumor necrosis factor alpha, and interleukin 1beta. Furthermore, the papillary thyroid carcinoma cell line could be induced to kill the TRAIL-sensitive lymphoma cell line BJAB through a TRAIL-dependent mechanism.

The effect of synthetic surfactant Exosurf on gene transfer in mouse lung in vivo.

Gene transfer in the lung holds promise for the treatment of diseases such as pulmonary fibrosis, cystic fibrosis and asthma. Pulmonary surfactant has been reported to enhance expression from endobronchial, adenovirus-mediated gene transfer in experimental animals. This study examines the effect of exogenous synthetic surfactant (Exosurf) on gene expression from naked plasmid DNA administered endobronchially to adult mice. Transfection efficiency was evaluated by quantifying the expression of chloramphenicol acetyltransferase (CAT) and luciferase (Luc) genes in the lung. Endobronchial administration of either CAT or Luc expression plasmid DNA resulted in detectable concentrations of each reporter protein. CAT expression from plasmid DNA was monitored after endobronchial administration with the maximal expression observed at 3-5 days after administration and decreasing for 5 days thereafter. When DNA was delivered in a 50% suspension of Exosurf, the expression of either CAT or Luc was significantly reduced by 89.6 +/- 1.4% and 82.7 +/- 10.5%, respectively. The decrease in Luc expression was closely correlated (r = 0.99, P < 0.001) to log concentration of surfactant in the plasmid buffer solution (IC50 = 8.6%). CAT expression was not altered when surfactant was administered either 2 h before or after plasmid DNA instillation. Examination of the components of Exosurf revealed that two compounds, DPPC and tyloxapol, showed inhibitory effects on CAT expression. However, the inhibition caused by Exosurf appeared greater than that of either component. Our results suggest that the lung surfactant is a barrier to transfection of the endobronchial airway and may be partly responsible for the low expression of exogenous DNA in vivo in the bronchial tree.

Fas (APO-1, CD95)-mediated apoptosis in thyroid cells is regulated by a labile protein inhibitor.

To determine whether thyroid cell apoptosis observed in autoimmune thyroid disease could be related to activation of the Fas pathway, we examined the expression and function of Fas on thyroid follicular cells in vitro. Fas messenger RNA was found to be present using two different techniques and was expressed at equal levels in thyrocytes cultured either in the presence or absence of TSH. Fas antigen protein expression was demonstrated by Western blot of thyroid cell lysates and by immunohistochemical staining of thyrocytes, and the amount of Fas protein present did not appear to vary regardless of culture conditions. Despite expressing substantial amounts of Fas protein, thyrocytes treated with anti-Fas monoclonal antibody failed to undergo apoptosis. The addition of either interferon-gamma or interleukin-1beta to the anti-Fas-treated cell cultures also did not promote apoptotic signaling through this pathway. In contrast, the concomitant administration of cycloheximide allowed the induction of apoptosis through the activation of Fas in thyrocytes. These results suggest that Fas is constitutively expressed in thyrocytes, but that the induction of apoptosis through the Fas pathway is blocked by a labile protein inhibitor.

Trp64----nonsense mutation in the lipoprotein lipase gene.

A lipoprotein lipase (LpL) gene defect has been identified, a G----A transition at nucleotide position 446 of exon 3, resulting in a premature termination codon (Trp----stop) at amino acid residue 64. This defect was identified in a Type I hyperlipoproteinemic subject with an amino acid residue 194 defect in the other allele. Plasma lipoprotein values as well as LpL mass and activity in postheparin plasma were determined in the subjects with the residue 64 defect and in other LpL-deficient heterozygotes. LpL mass levels in both the Type I and the other subject with a 64 LpL defect were markedly reduced. This may be explained by rapid degradation of LpL protein or decreased secretion from the 64 defective allele. Alternatively, the marked reduction or absence of mass associated with the 64 defect may be due to synthesis of a severely truncated protein which escapes immunologic detection.

Chylomicron-retinyl palmitate clearance in type I hyperlipidemic families.

Our primary aim was to determine the extent to which intraplasmic retinyl palmitate (RP) transfers to other lipoprotein particles when chylomicron remnants are not produced and/or the plasma RP residence time is increased. The study was conducted on three familial type I hyperlipoproteinemic patients, four lipoprotein lipase (LpL)-deficient heterozygotes, and three controls on a metabolic research unit. To each subject, a fat load was administered containing 16% of total daily calories in type I patients, 40% in heterozygotes and controls, plus 60,000 U/m2 vitamin A. Triglyceride (TG) and RP levels were evaluated in chylomicron and nonchylomicron fractions. Delay in the clearance of chylomicron fraction RP and the marked deficiency in nonchylomicron-RP (presumed lack of remnant production) in all three type I patients suggests that RP does not demonstrate significant intraplasmic transfer from chylomicrons to existent apolipoprotein B100 particles. In contrast to noncoincident TG and RP peaking in the normal subject, heterozygotes were found to demonstrate coincident plasma TG and RP curves, which is consistent with a common catabolic pathway for both TG and RP and inconsistent with intraplasmic RP transfer. This corroborates reports on compromised chylomicron clearance in heterozygotes. We conclude that RP is an appropriate representative marker for intestinally derived particles in LpL-deficient or partially deficient individuals.