Orphan nuclear receptor pregnane X receptor sensitizes oxidative stress responses in transgenic mice and cancerous cells

Efficient handling of oxidative stress is critical for the survival of organisms. The orphan nuclear receptor pregnane X receptor (PXR) is important in xenobiotic detoxification through its regulation of phase I and phase II drug-metabolizing/detoxifying enzymes and transporters. In this study we unexpectedly found that the expression of an activated human PXR in transgenic female mice resulted in a heightened sensitivity to paraquat, an oxidative xenobiotic toxicant. Heightened paraquat sensitivity was also seen in wild-type mice treated with the mouse PXR agonist pregnenolone-16alpha-carbonitrile. The PXR-induced paraquat sensitivity was associated with decreased activities of superoxide dismutase and catalase, enzymes that scavenge superoxide and hydrogen peroxide, respectively. Paradoxically, the general expression and activity of glutathione S-transferases, a family of phase II enzymes that detoxify electrophilic and cytotoxic substrates, was also induced in the transgenic mice. PXR regulates glutathione S-transferase expression in an isozyme-, tissue-, and sex-specific manner, and this regulation is independent of the nuclear factor-erythroid 2 p45-related factor 2/Kelch-like Ech-associated protein 1 pathway. In cell cultures, expression of activated human PXR sensitizes the cancerous colon and liver cells to the cytotoxic effect of paraquat, which is associated with an increased production of the reactive oxygen species. The current study reveals a novel function of PXR in the mammalian oxidative stress response, and this regulatory pathway may be implicated in carcinogenesis by sensitizing normal and cancerous tissues to oxidative cellular damage.     

Effects of heavy metal (Pb) on arbuscular mycorrhizal fungi in vitro

The responses of Ri-TDNA-transformed roots and arbuscular mycorrhizal fungi established on Ri-TDNA-transformed roots to lead-amended media was investigated in vitro. At exposure to increasing concentrations of lead (2–10 mg/l[ppm]), three Ri-TDNA-transformed root clones viz., Swa, Swb and Swc, exhibited profuse growth. At exposure to increasing concentrations of lead (0.1–5 ppm), the dual cultures of Ri-TDNA-transformed roots and arbuscular mycorrhizal fungi., Glomus lamellosum/Swa, Glomus intraradices/Swb and Glomus proliferum/Swc, exhibited tolerance to 5 ppm of lead. When subjected to one physiological stress, either exposure to Pb or inoculation with AM fungi, Ri-TDNA-transformed root clones exuded more phenols in the growth medium than retained in the roots. When subjected to dual physiological stress, mycorrhizal Ri-TDNA-transformed roots growing on Pb-enriched medium, the total phenol content increased in the roots and exudation into the medium decreased.     

Effects of daily iron supplementation in primary-school–aged children: systematic review and meta-analysis of randomized controlled trials

Background:

Anemia is an important public health and clinical problem. Observational studies have linked iron deficiency and anemia in children with many poor outcomes, including impaired cognitive development; however, iron supplementation, a widely used preventive and therapeutic strategy, is associated with adverse effects. Primary-school–aged children are at a critical stage in intellectual development, and optimization of their cognitive performance could have long-lasting individual and population benefits. In this study, we summarize the evidence for the benefits and safety of daily iron supplementation in primary-school–aged children.

Methods:

We searched electronic databases (including MEDLINE and Embase) and other sources (July 2013) for randomized and quasi-randomized controlled trials involving daily iron supplementation in children aged 5–12 years. We combined the data using random effects meta-analysis.

Results:

We identified 16 501 studies; of these, we evaluated 76 full-text papers and included 32 studies including 7089 children. Of the included studies, 31 were conducted in low- or middle-income settings. Iron supplementation improved global cognitive scores (standardized mean difference 0.50, 95% confidence interval [CI] 0.11 to 0.90, p = 0.01), intelligence quotient among anemic children (mean difference 4.55, 95% CI 0.16 to 8.94, p = 0.04) and measures of attention and concentration. Iron supplementation also improved age-adjusted height among all children and age-adjusted weight among anemic children. Iron supplementation reduced the risk of anemia by 50% and the risk of iron deficiency by 79%. Adherence in the trial settings was generally high. Safety data were limited.

Interpretation:

Our analysis suggests that iron supplementation safely improves hematologic and nonhematologic outcomes among primary-school–aged children in low- or middle-income settings and is well-tolerated.An estimated 25% of school-aged children worldwide are anemic.¹ Iron deficiency is thought to account for about half of the global cases of anemia² and is associated with inadequate dietary iron and, in developing settings, hookworm and schistosomiasis.³ In developed settings, anemia is prevalent among disadvantaged populations, including newly arrived refugees, indigenous people⁴ and some ethnic groups (e.g., Hispanic people in the United States).^5,6 About 3% of primary-school–aged children in Canada are anemic.⁷ Programs to address anemia are constrained by concerns that iron supplements cause adverse effects, including an increased risk of infections such as malaria in endemic areas.⁸In observational studies, iron deficiency has been associated with impaired cognitive and physical development. It has been estimated that each 10 g/L decrement in hemoglobin reduces future intelligence quotient (IQ) by 1.73 points.⁹ However, observational data are susceptible to confounding,¹⁰ and a causal relation between iron deficiency and cognitive impairment has not been confirmed.¹¹ Randomized controlled trials should overcome confounding, but results of trials examining this question have not agreed.Optimizing cognitive and physical development in primary-school–aged children could have life-long benefits.¹² However, anemia-control recommendations must balance safety and efficacy. We performed a systematic review of the effects of daily iron supplementation, a commonly used strategy to combat anemia,² in primary-school–aged children. We examined cognitive, growth and hematologic outcomes and adverse effects across all settings.     

Novel bifunctional alkylating agents, 5,10-dihydropyrrolo[1,2-b]isoquinoline derivatives, synthesis and biological activity

A series of linear pyrrolo[1,2-b]isoquinoline derivatives was synthesized for antitumor evaluation. The preliminary antitumor studies reveal that both bis(hydroxymethyl) and their bis(alkylcarbamate) derivatives show significant antitumor activity in inhibiting various human tumor cell growth in vitro. 1,2-Bis(hydroxymethyl)-3-methyl-5,10-dihydropyrrolo[1,2-b]isoquinoline (20a) was selected for antitumor studies in animal models. The results show that this agent can induce complete tumor remission or significant suppression in nude mice bearing human breast (MX-1) xenograft and ovarian (SK-OV-3) xenografts, respectively. Alkaline agarose gel shifting assay showed that 20a is able to cross-link with DNA. Studies on the cell cycle inhibition revealed that this agent induces cell arrest at G2/M phase. The results warrant further antitumor investigation against other human tumor growth in animal models.     

Homologous expression of a bacterial phytochrome. The cyanobacterium Fremyella diplosiphon incorporates biliverdin as a genuine, functional chromophore

Bacteriophytochromes constitute a light-sensing subgroup of sensory kinases with a chromophore-binding motif in the N-terminal half and a C-terminally located histidine kinase activity. The cyanobacterium Fremyella diplosiphon (also designated Calothrix sp.) expresses two sequentially very similar bacteriophytochromes, cyanobacterial phytochrome A (CphA) and cyanobacterial phytochrome B (CphB). Cyanobacterial phytochrome A has the canonical cysteine residue, by which covalent chromophore attachment is accomplished in the same manner as in plant phytochromes; however, its paralog cyanobacterial phytochrome B carries a leucine residue at that position. On the basis of in vitro experiments that showed, for both cyanobacterial phytochrome A and cyanobacterial phytochrome B, light-induced autophosphorylation and phosphate transfer to their cognate response regulator proteins RcpA and RcpB [Hübschmann T, Jorissen HJMM, B?rner T, G?rtner W & deMarsac NT (2001) Eur J Biochem268, 3383-3389], we aimed at the identification of a chromophore that is incorporated in vivo into cyanobacterial phytochrome B within the cyanobacterial cell. The approach was based on the introduction of a copy of cphB into the cyanobacterium via triparental conjugation. The His-tagged purified, recombinant protein (CphBcy) showed photoreversible absorption bands similar to those of plant and bacterial phytochromes, but with remarkably red-shifted maxima [lambda(max) 700 and 748 nm, red-absorbing (P(r)) and far red-absorbing (P(fr)) forms of phytochrome, respectively]. A comparison of the absorption maxima with those of the heterologously generated apoprotein, assembled with phycocyanobilin (lambda(max) 686 and 734 nm) or with biliverdin IXalpha (lambda(max) 700 and 750 +/- 2 nm), shows biliverdin IXalpha to be a genuine chromophore. The kinase activity of CphBcy and phosphotransfer to its cognate response regulator was found to be strictly P(r)-dependent. As an N-terminally located cysteine was found as an alternative covalent binding site for several bacteriophytochrome photoreceptors that bind biliverdin and lack the canonical cysteine residue (e.g. Agrobacterium tumefaciens and Deinococcus radiodurans), this corresponding residue in heterologously expressed cyanobacterial phytochrome B was mutated into a serine (C24S); however, there was no change in its spectral properties. On the other hand, the mutation of His267, which is located directly after the canonical cysteine, into alanine (H267A), caused complete loss of the capability of cyanobacterial phytochrome B to form a chromoprotein.     

Sirtuin Inhibition Induces Apoptosis-like Changes in Platelets and Thrombocytopenia

Sirtuins are evolutionarily conserved NAD⁺-dependent acetyl-lysine deacetylases that belong to class III type histone deacetylases. In humans, seven sirtuin isoforms (Sirt1 to Sirt7) have been identified. Sirtinol, a cell-permeable lactone ring derived from naphthol, is a dual Sirt1/Sirt2 inhibitor of low potency, whereas EX-527 is a potent and selective Sirt1 inhibitor. Here we demonstrate that Sirt1, Sirt2, and Sirt3 are expressed in enucleate platelets. Both sirtinol and EX-527 induced apoptosis-like changes in platelets, as revealed by enhanced annexin V binding, reactive oxygen species production, and drop in mitochondrial transmembrane potential. These changes were associated with increased phagocytic clearance of the platelets by macrophages. Expression of acetylated p53 and the conformationally active form of Bax were found to be significantly higher in both sirtinol- and EX-527-treated platelets, implicating the p53-Bax axis in apoptosis induced by sirtuin inhibitors. Administration of either sirtinol or EX-527 in mice led to a reduction in both platelet count and the number of reticulated platelets. Our results, for the first time, implicate sirtuins as a central player in the determination of platelet aging. Because sirtuin inhibitors are being evaluated for their antitumor activity, this study refocuses attention on the potential side effect of sirtuin inhibition in delimiting platelet life span and management of thrombosis.     

The dual-specificity phosphatase hYVH1 interacts with Hsp70 and prevents heat-shock-induced cell death

hYVH1 [human orthologue of YVH1 (yeast VH1-related phosphatase)] is an atypical dual-specificity phosphatase that is widely conserved throughout evolution. Deletion studies in yeast have suggested a role for this phosphatase in regulating cell growth. However, the role of the human orthologue is unknown. The present study used MS to identify Hsp70 (heat-shock protein 70) as a novel hYVH1-binding partner. The interaction was confirmed using endogenous co-immunoprecipitation experiments and direct binding of purified proteins. Endogenous Hsp70 and hYVH1 proteins were also found to co-localize specifically to the perinuclear region in response to heat stress. Domain deletion studies revealed that the ATPase effector domain of Hsp70 and the zinc-binding domain of hYVH1 are required for the interaction, indicating that this association is not simply a chaperone-substrate complex. Thermal phosphatase assays revealed hYVH1 activity to be unaffected by heat and only marginally affected by non-reducing conditions, in contrast with the archetypical dual-specificity phosphatase VHR (VH1-related protein). In addition, Hsp70 is capable of increasing the phosphatase activity of hYVH1 towards an exogenous substrate under non-reducing conditions. Furthermore, the expression of hYVH1 repressed cell death induced by heat shock, H2O2 and Fas receptor activation but not cisplatin. Co-expression of hYVH1 with Hsp70 further enhanced cell survival. Meanwhile, expression of a catalytically inactive hYVH1 or a hYVH1 variant that is unable to interact with Hsp70 failed to protect cells from the various stress conditions. The results suggest that hYVH1 is a novel cell survival phosphatase that co-operates with Hsp70 to positively affect cell viability in response to cellular insults.     

3-D illustration of network orientations of interstitial cells of Cajal subgroups in human colon as revealed by deep-tissue imaging with optical clearing

Morphological changes of interstitial cells of Cajal (ICC) have been proposed to characterize motility disorders. However, a global view of the network orientations of ICC subgroups has not been established to illustrate their three-dimensional (3-D) architectures in the human colon. In this research, we integrate c-kit immunostaining, 3-D microscopy with optical clearing, and image rendering to present the location-dependent network orientations with high definition. Full-depth colonic tissues were obtained from colectomies performed for nonobstructing carcinoma. Specimens of colon wall were prepared away from the tumor site. C-kit and nuclear fluorescent staining were used to identify the ICC processes and cell body. Optical clearing was used to generate transparent colon specimens, which led to panoramic visualization of the fluorescence-labeled ICC networks at the myenteric plexus (ICC-MY), longitudinal (ICC-LM) and circular (ICC-CM) muscles, and submucosal boundary (ICC-SM) up to 300 μm in depth via confocal microscopy with subcellular level resolution. We observed four distinct network patterns: 1) periganglionic ICC-MY that connect with ICC-LM and ICC-CM, 2) plexuses of ICC-LM within the longitudinal muscle and extending toward the serosa, 3) repetitive and organized ICC-CM layers running parallel to the circular muscle axis and extending toward the submucosa, and 4) a condensed ICC-SM layer lining the submucosal border. Among the four patterns, the orderly aligned ICC-CM layers provide an appropriate target for quantitation. Our results demonstrate the location-dependent network orientations of ICC subgroups and suggest a practical approach for in-depth imaging and quantitative analysis of ICC in the human colon specimen.