Diane Baus scite author profile

Oxidative modification of cytoplasmic RNA in vulnerable neurons is an important, well documented feature of the pathophysiology of Alzheimer disease. Here we report that RNA-bound iron plays a pivotal role for RNA oxidation in vulnerable neurons in Alzheimer disease brain. The cytoplasm of hippocampal neurons showed significantly higher redox activity and iron(II) staining than age-matched controls. Notably, both were susceptible to RNase, suggesting a physical association of iron(II) with RNA. Ultrastructural analysis further suggested an endoplasmic reticulum association. Both rRNA and mRNA showed twice the iron binding as tRNA. rRNA, extremely abundant in neurons, was considered to provide the greatest number of iron binding sites among cytoplasmic RNA species. Interestingly, the difference of iron binding capacity disappeared after denaturation of RNA, suggesting that the higher order structure may contribute to the greater iron binding of rRNA. Reflecting the difference of iron binding capacity, oxidation of rRNA by the Fenton reaction formed 13 times more 8-hydroxyguanosine than tRNA. Consistent with in situ findings, ribosomes purified from Alzheimer hippocampus contained significantly higher levels of RNase-sensitive iron(II) and redox activity than control. Furthermore, only Alzheimer rRNA contains 8-hydroxyguanosine in reverse transcriptase-PCR. Addressing the biological significance of ribosome oxidation by redox-active iron, in vitro translation with oxidized ribosomes from rabbit reticulocyte showed a significant reduction of protein synthesis. In conclusion these results suggest that rRNA provides a binding site for redoxactive iron and serves as a redox center within the cytoplasm of vulnerable neurons in Alzheimer disease in advance of the appearance of morphological change indicating neurodegeneration.

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Genetics and Diet Regulate Vitamin A Production via the Homeobox Transcription Factor ISX

Lobo

Amengual

Baus

et al. 2013

Journal of Biological Chemistry

115

111

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Background: Dietary ␤-carotene is the natural precursor of vitamin A. Results: The retinoic acid-inducible homeobox transcription factor ISX controls intestinal expression of the vitamin A producing enzyme BCMO1. Conclusion: Vitamin A production is under negative feedback regulation. Significance: Large individual variability in intestinal ␤-carotene conversion is associated with this diet-responsive regulatory network.

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L13a Blocks 48S Assembly: Role of a General Initiation Factor in mRNA-Specific Translational Control

et al. 2007

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Transcript-specific translational control restricts macrophage inflammatory gene expression. The proinflammatory cytokine interferon-gamma induces phosphorylation of ribosomal protein L13a and translocation from the 60S ribosomal subunit to the interferon-gamma-activated inhibitor of translation (GAIT) complex. This complex binds the 3'UTR of ceruloplasmin mRNA and blocks its translation. Here, we elucidate the molecular mechanism underlying repression by L13a. Translation of the GAIT element-containing reporter mRNA is sensitive to L13a-mediated silencing when driven by internal ribosome entry sites (IRESs) that require initiation factor eIF4G, but is resistant to silencing when driven by eIF4F-independent IRESs, demonstrating a critical role for eIF4G. Interaction of L13a with eIF4G blocks 43S recruitment without suppressing eIF4F complex formation. eIF4G attack, e.g., by virus, stress, or caspases, is a well-known mechanism of global inhibition of protein synthesis. However, our studies reveal a unique mechanism in which targeting of eIF4G by mRNA-bound L13a elicits transcript-specific translational repression.

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Diane Baus

Ribosomal RNA in Alzheimer Disease Is Oxidized by Bound Redox-active Iron

Genetics and Diet Regulate Vitamin A Production via the Homeobox Transcription Factor ISX

L13a Blocks 48S Assembly: Role of a General Initiation Factor in mRNA-Specific Translational Control

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