Multiple-mouse magnetic resonance imaging with cryogenic radiofrequency probes for evaluation of brain development.

Multiple-mouse magnetic resonance imaging (MRI) increases scan throughput by imaging several mice simultaneously in the same magnet bore, enabling multiple images to be obtained in the same time as a single scan. This increase in throughput enables larger studies than otherwise feasible and is particularly advantageous in longitudinal study designs where frequent imaging time points result in high demand for MRI resources. Cryogenically-cooled radiofrequency probes (CryoProbes) have been demonstrated to have significant signal-to-noise ratio benefits over comparable room temperature coils for in vivo mouse imaging. In this work, we demonstrate implementation of a multiple-mouse MRI system using CryoProbes, achieved by mounting four such coils in a 30-cm, 7-Tesla magnet bore. The approach is demonstrated for longitudinal quantification of brain structure from infancy to early adulthood in a mouse model of Sanfilippo syndrome (mucopolysaccharidosis type III), generated by knockout of the Hgsnat gene. We find that Hgsnat-/- mice have regionally increased growth rates compared to Hgsnat+/+ mice in a number of brain regions, notably including the ventricles, amygdala and superior colliculus. A strong sex dependence was also noted, with the lateral ventricle volume growing at an accelerated rate in males, but several structures in the brain parenchyma growing faster in females. This approach is broadly applicable to other mouse models of human disease and the increased throughput may be particularly beneficial in studying mouse models of neurodevelopmental disorders.

Importing genetically altered animals: ensuring quality.

The reproducibility of research using laboratory animals requires reliable management of their quality, in particular of their genetics, health and environment, all of which contribute to their phenotypes. The point at which these biological materials are transferred between researchers is particularly sensitive, as it may result in a loss of integrity of the animals and/or their documentation. Here, we describe the various aspects of laboratory animal quality that should be confirmed when sharing rodent research models. We also discuss how repositories of biological materials support the scientific community to ensure the continuity of the quality of laboratory animals. Both the concept of quality and the role of repositories themselves extend to all exchanges of biological materials and all networks that support the sharing of these reagents.

Neuroanatomy and behavior in mice with a haploinsufficiency of AT-rich interactive domain 1B (ARID1B) throughout development.

BACKGROUND: One of the causal mechanisms underlying neurodevelopmental disorders (NDDs) is chromatin modification and the genes that regulate chromatin. AT-rich interactive domain 1B (ARID1B), a chromatin modifier, has been linked to autism spectrum disorder and to affect rare and inherited genetic variation in a broad set of NDDs. METHODS: A novel preclinical mouse model of Arid1b deficiency was created and validated to characterize and define neuroanatomical, behavioral and transcriptional phenotypes. Neuroanatomy was assessed ex vivo in adult animals and in vivo longitudinally from birth to adulthood. Behavioral testing was also performed throughout development and tested all aspects of motor, learning, sociability, repetitive behaviors, seizure susceptibility, and general milestones delays. RESULTS: We validated decreased Arid1b mRNA and protein in Arid1b+/- mice, with signatures of increased axonal and synaptic gene expression, decreased transcriptional regulator and RNA processing expression in adult Arid1b+/- cerebellum. During neonatal development, Arid1b+/- mice exhibited robust impairments in ultrasonic vocalizations (USVs) and metrics of developmental growth. In addition, a striking sex effect was observed neuroanatomically throughout development. Behaviorally, as adults, Arid1b+/- mice showed low motor skills in open field exploration and normal three-chambered approach. Arid1b+/- mice had learning and memory deficits in novel object recognition but not in visual discrimination and reversal touchscreen tasks. Social interactions in the male-female social dyad with USVs revealed social deficits on some but not all parameters. No repetitive behaviors were observed. Brains of adult Arid1b+/- mice had a smaller cerebellum and a larger hippocampus and corpus callosum. The corpus callosum increase seen here contrasts previous reports which highlight losses in corpus callosum volume in mice and humans. LIMITATIONS: The behavior and neuroimaging analyses were done on separate cohorts of mice, which did not allow a direct correlation between the imaging and behavioral findings, and the transcriptomic analysis was exploratory, with no validation of altered expression beyond Arid1b. CONCLUSIONS: This study represents a full validation and investigation of a novel model of Arid1b+/- haploinsufficiency throughout development and highlights the importance of examining both sexes throughout development in NDDs.

Thought Field Therapy clinical applications: utilization in an HMO in behavioral medicine and behavioral health services.

Thought Field Therapy (TFT) is a self-administered treatment developed by psychologist Roger Callahan. TFT uses energy meridian treatment points and bilateral optical-cortical stimulation while focusing on the targeted symptoms or problem being addressed. The clinical applications of TFT summarized included anxiety, adjustment disorder with anxiety and depression, anxiety due to medical condition, anger, acute stress, bereavement, chronic pain, cravings, depression, fatigue, nausea, neurodermatitis, obsessive traits, panic disorder without agoraphobia, parent-child stress, phobia, posttraumatic stress disorder, relationship stress, trichotillomania, tremor, and work stress. This uncontrolled study reports on changes in self-reported Subjective Units of Distress (SUD; Wolpe, 1969) in 1,594 applications of TFT, treating 714 patients. Paired t-tests of pre- and posttreatment SUD were statistically significant in 31 categories reviewed. These within-session decreases of SUD are preliminary data that call for controlled studies to examine validity, reliability, and maintenance of effects over time. Illustrative case and heart rate variability data are presented.

Antimicrobial activity of the semisynthetic compound, hexahydrocolupulone.

In this study we demonstrate that hexahydrocolupulone (HHC) more effectively inhibits the growth in vitro of Gram-positive organisms than Mycobacterium tuberculosis or Escherichia coli. Vancomycin-resistant Enterococcus faecium, methicillin-resistant Staphylococcus aureus, and coagulase-negative staphylococci were inhibited by HHC at concentrations < or = 4.06 mg/L. Growth inhibition profiles varied according to the microorganism evaluated (static for S. aureus and bactericidal for Bacillus subtilis).

Absence of pyridoxine-5'-phosphate oxidase (PNPO) activity in neoplastic cells: isolation, characterization, and expression of PNPO cDNA.

Major differences in the metabolism of vitamin B6 in various cancers compared to their normal cellular counterparts have been documented. In particular, pyridoxine- 5'-phosphate oxidase (PNPO), the rate-limiting enzyme in pyridoxal 5'-phosphate (PLP) biosynthesis, is absent in liver and neurally-derived tumors. We show that the expression of PNPO is developmentally regulated not only in liver but also in brain. Specifically, PNPO activity in fetal brain tissue is 7.5-fold lower than that found in adult brain tissue. Furthermore, the isolation and characterization of a PNPO cDNA are described. The isolated cDNA was verified to be the authentic PNPO cDNA on the basis of two criteria. First, the translated product from the PNPO cDNA is immunologically reactive to a polyclonal PNPO antibody. Second, PNPO negative hepatoma cell lines stably transfected with the PNPO cDNA express enzymatically active PNPO protein. The availability of these biological reagents will not only facilitate in depth investigations of the reasons for the absence of PNPO in liver and brain malignancies but also aid in an understanding of the biochemical regulation of B6 metabolism in development.

Induction of p53 by the concerted actions of aziridine and quinone moieties of diaziquone.

The biologic functions attributed to the nucleophosphoprotein p53 have been increasing in recent years. Some studies suggested that wild type p53 is responsible for cell cycle arrest brought about as a response to exposure of mammalian cells to DNA-damaging agents. This cell cycle arrest occurs in order for cells to repair the damaged macromolecules. Extensively damaged cells are also thought to undergo apoptosis via the p53-dependent or -independent signal transduction pathways. In this study, we investigated the ability of diaziridinylbenzoquinones to increase p53 levels in the human breast cancer cell line MCF-7. Diaziquone (AZQ), an anticancer agent, and its derivatives, diaziridinequinone (DZQ) and methyldiaziridinequinone (MeDZQ), induced p53 in a dose- and time-dependent manner as measured by the electrophoretic mobility shift assay. Wild type p53 induction by AZQ was suppressed when DT-diaphorase activity was inhibited by pretreating the cells with dicumarol. Aside from their potent alkylating activity, these agents also undergo redox cycling as evidenced by oxygen consumption and the production of reactive oxygen species (ROS). Inhibition of ROS production by the antioxidant enzyme catalase reduced AZQ- and DZQ-mediated p53 induction by about 45%. Thiotepa, a non-quinone aziridine-containing agent, and 1,4-benzoquinone (p-BQ), a redox cycling quinone, increased p53 levels. The nonalkylator oxygen-radical-generating agent menadione (MD) caused p53 induction only when MCF-7 cells were allowed to recover in drug-free media. On the basis of these data, we propose that the bioreductive activation of AZQ is a prerequisite for p53 induction. Moreover, the induction of p53 by AZQ requires both the quinone and the aziridine moieties of the AZQ molecule. Although AZQ and its analogues increased p53 levels in MCF-7 cells, p53 induction in these cells may not be responsible for the apoptosis seen upon treatment of MCF-7 cells with these agents. The uncoupling of p53 induction and apoptosis is evidenced by the generation of nucleosomal DNA laddering in aziridinequinone-treated T47D cells, a breast cancer cell line bearing a p53 mutation.

Hexahydrocolupulone and its antitumor cell proliferation activity in vitro.

The purpose of this study was to evaluate the ability of hexahydrocolupulone (HHC) to inhibit the growth of tumor cells in vitro and to investigate the potential mechanism(s) involved. HHC was demonstrated to have a wide spectrum of activity against a number of established human tumor cell lines, including some exhibiting drug resistance. Culturing human breast adenocarcinoma (MCF-7) cells in the presence of HHC for 18 hr resulted in a significant decrease in the incorporation of [3H]uridine and [3H]leucine into RNA and protein, respectively. MCF-7 cells cultured in the presence of 1.5 microM HHC for 48 hr demonstrated an increase in the amount of cells detected in G0/G1 and a decrease in the amount of cells detected in S phase. In contrast, treatment with 25 microM HHC decreased the amount of cells detected in G0/G1 and increased the amount of cells detected in S phase. HHC did not cause single-stranded or double-stranded DNA breaks, interfere with topoisomerase function, or generate free radicals. Mice injected intraperitoneally for 5 consecutive days with HHC to a final in vivo blood concentration of 200 microM survived and showed no obvious signs of toxicity. Mass spectroscopy analysis, crystal generation, and structure elucidation confirmed HHC purity. Consequently, all activity observed can be attributed to HHC, a metabolite, and/or a combination thereof. These data suggest that HHC inhibits tumor cell proliferation in vitro via a mechanism(s) that may involve effects on macromolecular synthesis, precursor metabolism/transport, and/or the cell cycle or cell cycle-dependent pathway(s).

Insensitivity of cultured rat cortical neurons to mitochondrial DNA synthesis inhibitors: evidence for a slow turnover of mitochondrial DNA.

Mitochondrial dysfunction is a major contributor to aging and neurodegeneration. Defects in mitochondrial DNA (mtDNA) have been identified in several neuromuscular diseases. Even though there is a high rate of phenotypic expression of mtDNA mutations in the central nervous system and replication of DNA introduces errors, little is known about the replicative activity of mtDNA in the brain. In this study, we investigated the sensitivity of cultured rat cortical neurons to mtDNA synthesis inhibitors as a means to assess the turnover rate of mtDNA. Four-day treatment with dideoxycytidine (ddC) (0.2 microM) or ethidium bromide (EtB) (0.25 microg/mL) reduced the mtDNA content approximately 80% in the human lymphoblastoid cell line, CEM. Concentrations of ddC ranging from 0.2 to 10 microM did not reduce mtDNA content in primary cultures of rat cortical neurons. Similarly, treatment with EtB (0.1, 0.25, and 0.5 microg/mL) did not affect significantly neuronal mtDNA. EtB (0.25 microg/mL) was effective in reducing mtDNA content in the undifferentiated embryonic carcinoma cell line, P 19. However, once P 19 cells were differentiated into a neuronal phenotype, they became insensitive to inhibition of mtDNA synthesis by EtB. Thus, cultured rat cortical neurons were less sensitive to mtDNA synthesis inhibitors than cell lines, suggesting that the turnover of mtDNA in central neurons is very slow. This may protect central neurons from accumulating mutations during the replication of mtDNA.

alpha-Ketoacids scavenge H2O2 in vitro and in vivo and reduce menadione-induced DNA injury and cytotoxicity.

We demonstrate that alpha-ketoacids reduce and, in some instances, abrogate menadione-induced DNA damage and cytotoxicity in the human breast cancer cell line, MCF7. We confirm that alpha-ketoacids quench the copious amounts of H2O2 generated by menadione while these alpha-ketoacids undergo nonenzymatic oxidative decarboxylation; our data thus support enhanced H2O2 production as an important pathway for menadione-induced DNA damage and cytotoxicity. We also demonstrate that alpha-ketoacids scavenge H2O2 generated by mitochondria and microsomes when these organelles are exposed to menadione; additionally, alpha-ketoacids protect oxidant-vulnerable enzymes against functional impairment induced by H2O2. Finally, we provide the first in vivo demonstration that acute elevations in concentrations of alpha-ketoacids in rat tissues and urine scavenge H2O2. We conclude that enhanced H2O2 production is a major pathway for menadione-induced DNA damage and cytotoxicity and that the diverse alpha-ketoacids present within the cell must be considered, along with glutathione peroxidase and catalase, as part of the intracellular antioxidant defense mechanisms that regulate the ambient levels of H2O2.

Cellular biochemical determinants modulating the metabolism of estrone 3,4-quinone.

The metabolism of the o-quinone derivative of estrone, 3,4-estrone quinone (3,4-EQ), has been investigated in human breast cancer cells. Unlike the p-quinone, diethylstilbestrol 4',4"-quinone, 3,4-EQ was not a substrate for the two-electron reduction catalyzed by the putative detoxifying enzyme, NAD(P)H:quinone reductase (DT diaphorase; DT D). Accordingly, the DNA damage induced by 3,4-EQ in human MCF-7 cells was not affected by an inhibitor of DT D. Although 3,4-EQ was not an apparent substrate for the two-electron reduction catalyzed by DT D, this o-quinone was a substrate for the one-electron reduction catalyzed by cytochrome P450 reductase. The one-electron reduction of 3,4-EQ catalyzed by cytochrome P450 reductase occurred in the face of a significant and potentially physiologically relevant spontaneous reduction of 3,4-EQ by NADPH. The impact of purified superoxide dismutase (SOD) upon the production of hydrogen peroxide produced as a consequence of 3,4-EQ metabolism was evaluated; surprisingly, SOD inhibited the hydrogen peroxide produced by this o-quinone. Possible reasons for the SOD-mediated inhibition of redox cycling of 3,4-EQ are discussed. In summary, important differences in the metabolism of 3,4-EQ vis-a-vis o- and p- quinones have been observed, and the implications of these differences are discussed.

2',3'-Dideoxycytidine alters calcium buffering in cultured dorsal root ganglion neurons.

Mitochondria play a prominent role in shaping intracellular calcium concentration ([Ca2+]i) transients in dorsal root ganglion neurons. Mitochondrial DNA polymerase is inhibited by antiviral compounds such as 2',3'-dideoxycytidine (ddC). Here, we test the hypothesis that ddC can alter mitochondrially mediated Ca2+ buffering in neurons. Chronic treatment of dorsal root ganglion cultures with ddC (1 microM) lowered mitochondrial DNA levels and decreased the mitochondrially mediated component of depolarization-induced [Ca2+]i transients. The inhibition increased in a time-dependent manner, reaching a maximum at 6 days. ddC did not affect small, action potential-evoked, [Ca2+]i transients that are predominantly buffered by Ca(2+)-ATPases, suggesting that ATP levels were not depleted. The drug did not inhibit whole-cell Ca2+ currents, indicating that the Ca2+ load was not affected. Thus, ddC produces a graded, time-dependent inhibition of mitochondrial function that is reflected, in part, by a decrease in the direct buffering of Ca2+ by mitochondria. This effect may contribute to the peripheral neuropathy that results from ddC treatment. Furthermore, ddC promises to be a useful tool to study the role of mitochondria in [Ca2+]i homeostasis and neurodegenerative processes.

Heme oxygenase does not protect human cells against oxidant stress.

The induction of heme oxygenase in cells under conditions of oxidative stress has been hypothesized to represent a cellular antioxidant defense mechanism. The objectives of this study were to characterize the induction of heme oxygenase by the oxidant stress-inducing quinone agent menadione (2-methyl-1,4-naphthoquinone) and to elucidate the roles of basal and induced heme oxygenase enzyme activities in menadione-induced DNA damage and growth inhibition in human MCF-7 cells. Time- and dose-dependent inductions of heme oxygenase messenger RNA and enzyme activity in menadione-treated MCF-7 cells were demonstrated. Intracellular and extracellular bilirubin concentrations were less than 100 nmol/L and were not altered when heme oxygenase was induced. The roles of the basal and induced heme oxygenase enzyme activities in menadione-mediated DNA damage were evaluated by means of the heme oxygenase competitive inhibitor tin protoporphyrin. Inhibition of the basal heme oxygenase enzyme activity by tin protoporphyrin resulted in a decrease in the number of menadione-induced DNA breaks and an attenuation of the cellular growth inhibition caused by menadione. Induced heme oxygenase did not protect MCF-7 cells from menadione-induced DNA breaks. Basal heme oxygenase enzyme activities in two cloned menadione-resistant cell lines were significantly less than that measured in a menadione-sensitive parental MCF-7 cell line. Collectively, these data do not support a protective role for basal or induced heme oxygenase enzyme activities against oxidant stress-related DNA strand breakage or cytotoxic effects engendered by menadione in human cells.

Status of glutathione and glutathione-metabolizing enzymes in menadione-resistant human cancer cells.

Cloned menadione (MD)-resistant human breast cancer cell lines have been developed and characterized with respect to glutathione (GSH) content and GSH-metabolizing enzymes. Increases in the activities of gamma-glutamyltranspeptidase and glutathione-S-transferase were demonstrated in the absence of alterations in the GSH content of two cloned MD-resistant cell lines. The MD-resistant cells also displayed alterations in their growth kinetics, possessing longer doubling times and increased fractions in the G1/O phase of the cell cycle as compared to parental MD-sensitive cells. The possible mechanisms for the resistance to MD, including an increase in repair of MD-induced DNA damage, are discussed.

An o-quinone form of estrogen produces free radicals in human breast cancer cells: correlation with DNA damage.

The o-quinone forms of 2,3- and 3,4-catechol estrogens have been implicated in the carcinogenicity of these hormones. The concomitant production of reactive oxygen species during reduction of the o-quinone estrogens has been inferred to play a mechanistic role in their mutagenic potential. Conclusive evidence documenting the production of hydrogen peroxide, the hydroxyl radical, and the estrone 3,4-semiquinone in estrone 3,4-quinone (3,4-EQ)-treated human breast cancer subcellular fractions was demonstrated in the absence of exogenously added catalysts. Subcellular fractions of MCF-7 cells treated with 3,4-EQ and NADPH, including nuclei, mitochondria, and microsomes, were shown to support significant amounts of hydrogen peroxide production. Hydrogen peroxide production in 3,4-EQ-treated cellular fractions and the chromosomal DNA damage induced in 3,4-EQ-treated MCF-7 cells were abolished by the addition of catalase. A significant and potentially physiologically relevant spontaneous reduction of 3,4-EQ by NADPH resulting in hydrogen peroxide production was demonstrated. The results unequivocally demonstrate that free radicals are produced during the metabolism of estrone 3,4-quinone in human cells.

Effect of pyruvate on oxidant injury to isolated and cellular DNA.

Drawing upon the capacity of pyruvate to detoxify H2O2, we demonstrate that pyruvate (i) protects against H2O2-dependent, hydroxyl radical-mediated degradation of isolated DNA; (ii) reduces the amount of 8-hydroxy-2-deoxyguanosine detected following oxidative injury to isolated DNA and (iii) diminishes the amounts of detectable hydroxyl radical generated by a H2O2-dependent system. Compared to mannitol, pyruvate protects weakly against oxidative degradation of DNA induced by a H2O2-independent, hydroxyl radical-generating system. The protective effects of pyruvate against H2O2-instigated DNA damage were also evinced in cells in culture exposed to H2O2. In contrast to its protective effects against H2O2-dependent injury to DNA, pyruvate failed to offer convincing protection to another intracellular, H2O2-vulnerable target, glyceraldehyde-3-phosphate dehydrogenase. The protection conferred by pyruvate to intracellular H2O2-vulnerable targets is thus influenced by the nature of the target exposed to H2O2. Pyruvate was markedly protective in a model of cytotoxicity induced by the concomitant depletion of cellular glutathione and inhibition of catalase activity; pyruvate can thus function as an intracellular antioxidant and in this latter model, no evidence of DNA damage was observed. Pyruvate, in contrast to catalase, is a potent protector against cytotoxicity induced by organic peroxides, a finding that cannot be explained by the scavenging of organic peroxides, differences in glutathione content or attenuation in oxidative injury to DNA. We conclude that while DNA damage is a key pathogenetic event in oxidative stress induced by H2O2, such nuclear changes may not universally subserve a critical role in models of H2O2-dependent cell death. We also conclude that the antioxidant capabilities of pyruvate extend beyond scavenging of H2O2 to include potent protection against cytotoxicity induced by organic peroxides.

DNA strand scission and free radical production in menadione-treated cells. Correlation with cytotoxicity and role of NADPH quinone acceptor oxidoreductase.

Menadione (MD; 2-methyl-1,4-naphthoquinone), a redox cycling quinone was shown to induce single (ss)- and double (ds)-strand DNA breaks in human MCF-7 cells. This DNA damage was mediated via the hydroxyl radical as evidenced by electron spin resonance spectroscopy (ESR) studies utilizing the spin trap, 5,5-dimethyl-1-pyrroline-1-oxide. The free radical production and DNA damage were shown to play a role in MD cytotoxicity as revealed by the reversal of MD toxicity and inhibition of hydroxyl radical production by exogenously added catalase. The role of NADPH quinone acceptor oxidoreductase in the metabolism of MD was evaluated. Purified quinone acceptor oxidoreductase in combination with MD resulted in the production of significant levels of the hydroxyl radical as measured by ESR. Dicumarol, an inhibitor of quinone acceptor oxidoreductase, decreased the production of the hydroxyl radical and attenuated DNA strand breaks in MCF-7 cells treated with MD.

A microassay for heme oxygenase activity using thin-layer chromatography.

A sensitive and facile assay for heme oxygenase (HO) has been developed. The basis of the assay is the detection of [14C]bilirubin formation in a coupled enzyme assay involving HO and biliverdin reductase actions, respectively. Separation of substrate from product is accomplished by thin-layer chromatography with subsequent quantitation by liquid scintillation counting of radioactive material present on chromatograms. As little as 20 micrograms of total cellular protein derived from cells growing in a standard 25-cm2 culture flask is sufficient for detection of HO enzyme activity using this assay. The reaction is inhibited by tin-protoporphyrin (10 microM final concentration), a specific inhibitor of HO. The linearity of the enzyme reaction with respect to incubation time and amount of protein used was established. Comparison of the new HO assay with a spectrophotometric assay was made, and good agreement of the results from both methods was found. The assay described here should facilitate measurements of this important heme-degrading enzyme in tissue culture studies and cases where limited amounts of material are available.

Menadione-induced DNA damage in a human tumor cell line.

The nature and extent of menadione (MD)-induced DNA damage were explored using the human breast cancer cell line MCF-7. Concentration-dependent single-strand (ss) and double-strand (ds) DNA breaks were detected in MD-treated MCF-7 cells using the alkaline- and neutral-elution techniques, respectively. The repair of ss and ds DNA breaks was extensive but not complete after a 6-hr incubation in drug-free medium. Evidence was found for the production of DNA interstrand cross-links in MCF-7 cells treated with the bifunctional alkylating agent, mitomycin C, but not for cells treated with MD. Exposure of MCF-7 cells to etoposide (VP-16), mitoxantrone and camptothecin resulted in the detection of significant amounts of protein-linked DNA breaks, whereas none were found in MD-treated cells. These results support the proposition that MD-induced DNA damage is not likely to be mediated via topoisomerases, nor do significant amounts of protein-linked DNA form in MD-treated cells. Thus, MD serves as a good model for examination of the role of the quinone moiety in DNA damage in relation to redox cycling. Future studies directed at elucidation of the biochemical determinants mediating formation of reactive oxygen species effecting the MD-induced DNA damage are necessary and underway.