Viktoriya Pastukh

Perinuclear mitochondrial clustering creates an oxidant-rich nuclear domain required for hypoxia-induced transcription.

Reactive oxygen species generated by mitochondria that redistribute near the nucleus promote transcriptional responses to hypoxia. Mitochondria for Transcription A key response to reduced oxygen tension, a condition referred to as hypoxia, involves the hypoxia-inducible factor (HIF) family of transcription factors. During hypoxia, HIF-1α translocates to the nucleus to activate genes involved in adapting to oxygen deprivation. Al-Mehdi et al. showed that the transcriptional response to hypoxia was accompanied by the subcellular redistribution of mitochondria around the nucleus. Reactive oxygen species produced by the redistributed mitochondria caused oxidative modification of the promoter regions of HIF-1 target genes, such as that encoding vascular endothelial growth factor (VEGF). The introduction of oxidative modifications in these promoters enhanced HIF-1α association and gene expression. Because the presence of hypoxia in solid tumors is an indicator of poor prognosis, understanding the details of the transcriptional response to hypoxia may provide new targets for the therapeutic treatment of solid tumors. Mitochondria can govern local concentrations of second messengers, such as reactive oxygen species (ROS), and mitochondrial translocation to discrete subcellular regions may contribute to this signaling function. Here, we report that exposure of pulmonary artery endothelial cells to hypoxia triggered a retrograde mitochondrial movement that required microtubules and the microtubule motor protein dynein and resulted in the perinuclear clustering of mitochondria. This subcellular redistribution of mitochondria was accompanied by the accumulation of ROS in the nucleus, which was attenuated by suppressing perinuclear clustering of mitochondria with nocodazole to destabilize microtubules or with small interfering RNA–mediated knockdown of dynein. Although suppression of perinuclear mitochondrial clustering did not affect the hypoxia-induced increase in the nuclear abundance of hypoxia-inducible factor 1α (HIF-1α) or the binding of HIF-1α to an oligonucleotide corresponding to a hypoxia response element (HRE), it eliminated oxidative modifications of the VEGF (vascular endothelial growth factor) promoter. Furthermore, suppression of perinuclear mitochondrial clustering reduced HIF-1α binding to the VEGF promoter and decreased VEGF mRNA accumulation. These findings support a model for hypoxia-induced transcriptional regulation in which perinuclear mitochondrial clustering results in ROS accumulation in the nucleus and causes oxidative base modifications in the VEGF HRE that are important for transcriptional complex assembly and VEGF mRNA expression.

Pseudomonas aeruginosa exotoxin Y is a promiscuous cyclase that increases endothelial Tau phosphorylation and permeability

Background: ExoY induces inter-endothelial gaps, although the mechanisms by which this occurs are poorly understood. Results: ExoY synthesized cAMP and cGMP, which caused endothelial Tau hyperphosphorylation, accumulation of insoluble Tau, inter-endothelial cell gaps, and increased permeability. Conclusion: ExoY is a promiscuous cyclase and an edema factor. Significance: Acute Pseudomonas infections cause a pathophysiological sequela in endothelium previously recognized only in chronic neurodegenerative diseases. Exotoxin Y (ExoY) is a type III secretion system effector found in ∼ 90% of the Pseudomonas aeruginosa isolates. Although it is known that ExoY causes inter-endothelial gaps and vascular leak, the mechanisms by which this occurs are poorly understood. Using both a bacteria-delivered and a codon-optimized conditionally expressed ExoY, we report that this toxin is a dual soluble adenylyl and guanylyl cyclase that results in intracellular cAMP and cGMP accumulation. The enzymatic activity of ExoY caused phosphorylation of endothelial Tau serine 214, accumulation of insoluble Tau, inter-endothelial cell gap formation, and increased macromolecular permeability. To discern whether the cAMP or cGMP signal was responsible for Tau phosphorylation and barrier disruption, pulmonary microvascular endothelial cells were engineered for the conditional expression of either wild-type guanylyl cyclase, which synthesizes cGMP, or a mutated guanylyl cyclase, which synthesizes cAMP. Sodium nitroprusside stimulation of the cGMP-generating cyclase resulted in transient Tau serine 214 phosphorylation and gap formation, whereas stimulation of the cAMP-generating cyclase induced a robust increase in Tau serine 214 phosphorylation, gap formation, and macromolecular permeability. These results indicate that the cAMP signal is the dominant stimulus for Tau phosphorylation. Hence, ExoY is a promiscuous cyclase and edema factor that uses cAMP and, to some extent, cGMP to induce the hyperphosphorylation and insolubility of endothelial Tau. Because hyperphosphorylated and insoluble Tau are hallmarks in neurodegenerative tauopathies such as Alzheimer disease, acute Pseudomonas infections cause a pathophysiological sequela in endothelium previously recognized only in chronic neurodegenerative diseases.

Human mitochondrial transcription factor A possesses multiple subcellular targeting signals

The mitochondrial transcription factor A (TFAM) is a member of a high‐mobility group (HMG) family represented mostly by nuclear proteins. Although nuclear localization of TFAM has been demonstrated in some tumors and after treatment of tumor cells with anticancer drugs, the significance of these observations has not been fully elucidated. Here we report that both TFAM overexpression and impairment of its mitochondrial targeting can result in nuclear accumulation of the protein. Both M1 and M7 methionines of human TFAM (hTFAM) can be used for translation initiation with almost equal efficiency resulting in two polypeptides. The shorter polypeptide, however, is not located in the nucleus, despite truncation in the mitochondrial targeting sequence, and both isoforms are targeted to mitochondria with similar efficiency. We further demonstrate that nuclear TFAM confers significant cytoprotection against the chemotherapeutic drugs etoposide, camptothecin, and cisplatin. Three regions of hTFAM [HMG‐like domain 1 (HMG1) and HMG‐like domain 2 (HMG2), as well as the tail region] can effect nuclear accumulation of enhanced green fluorescent protein (EGFP) fusions. The HMG1 domain contains a bipartite nuclear localization sequence whose identity is supported by site‐directed mutagenesis. However, this bipartite nuclear localization sequence is weak, and both N‐terminal and C‐terminal flanking sequences enhance the nuclear targeting of EGFP. Finally, several mutations in the HMG1 domain increased the mitochondrial targeting of the EGFP fusions, suggesting that the mitochondrial targeting sequence of hTFAM may extend beyond the cleavable presequence.

A retro-lentiviral system for doxycycline-inducible gene expression and gene knockdown in cells with limited proliferative capacity

Currently, there is no reliable system for regulated gene expression and regulated gene knockdown in cells with finite lifespan. In this manuscript, we describe a vector system, consisting of a retrovirus for the delivery of rtTA, and a lentivirus for the delivery of either a transgene or a miR-shRNA for the modification of primary cells. Primary rat pulmonary microvascular endothelial cells (PMVEC) modified by these vectors for the inducible expression of Gaussia luciferase or DsRed Express demonstrated greater than 100-fold induction of the transgene expression with doxycycline. The system works reliably in both sequential and simultaneous infection modes, with about 95% of the sells selected with two antibiotics being inducible in each mode. The lentiviral vector for gene knockdown allows for the direct cloning of shRNA oligos using alpha-complementation, and for the monitoring of induction of RNA interference with fluorescent reporter, mCherry. The gene knockdown vector was validated by knocking down β-actin expression in PMVECs, with two of the four constructs showing 59 and 75% knockdown, respectively, compared to uninduced controls. The vectors described here were successfully used for the modification of various primary and established cell lines for regulated gene expression and regulated knockdown.

Mutations in the passenger polypeptide can affect its partitioning between mitochondria and cytoplasm

In this study, we report that the partitioning between mitochondria and cytoplasm of two variants, mCherry and DsRed Express (DRE), of the red fluorescent protein, DsRed, fused to one of the six matrix targeting sequences (MTSs) can be affected by both MTS and amino acid substitutions in DsRed. Of the six MTSs tested, MTSs from superoxide dismutase and DNA polymerase gamma failed to direct mCherry, but not DRE to mitochondria. By evaluating a series of chimeras between mCherry and DRE fused to the MTS of superoxide dismutase, we attribute the differences in the mitochondrial partitioning to differences in the primary amino acid sequence of the passenger polypeptide. The impairment of mitochondrial partitioning closely parallels the number of mCherry-specific mutations, and is not specific to mutations located in any particular region of the polypeptide. These observations suggest that both MTS and the passenger polypeptide affect the efficiency of mitochondrial import and provide a rationale for the observed diversity in the primary amino acid sequences of natural MTSs.

α-Complementation-Enabled T7 Expression Vectors and Their Use for the Expression of Recombinant Polypeptides for Protein Transduction Experiments

Over the past few years protein transduction has emerged as a powerful means for the delivery of proteins into cultured cells and into whole mice. This method is based on the ability of proteins containing protein transduction domains (PTDs), short stretches of 9-16 predominantly basic amino acids, to traverse the cytoplasmic membrane and accumulate inside cells in a time- and dose-dependent fashion. The number of PTDs, both natural and synthetic, is constantly expanding, as is the need to test newly discovered PTDs for their ability to mediate the internalization of the corresponding fusion proteins. Here we describe a strategy and methodology that can be used for the construction of vectors for the T7 RNA polymerase-driven expression of PTD fusions. The cloning in these vectors is facilitated by alpha-complementation. Also, these vectors are small in size (less than 3 kbp) and express influenza virus hemagglutinin tag as well as His tag as part of the fusion for immunological identification and purification respectively of expressed proteins.

Carbonic anhydrase IX is a critical determinant of pulmonary microvascular endothelial cell pH regulation and angiogenesis during acidosis

Carbonic anhydrase IX (CA IX) is highly expressed in rapidly proliferating and highly glycolytic cells, where it serves to enhance acid-regulatory capacity. Pulmonary microvascular endothelial cells (PMVECs) actively utilize aerobic glycolysis and acidify media, whereas pulmonary arterial endothelial cells (PAECs) primarily rely on oxidative phosphorylation and minimally change media pH. Therefore, we hypothesized that CA IX is critical to PMVEC angiogenesis because of its important role in regulating pH. To test this hypothesis, PMVECs and PAECs were isolated from Sprague-Dawley rats. CA IX knockout PMVECs were generated using the CRISPR-Cas9 technique. During serum-stimulated growth, mild acidosis (pH 6.8) did not affect cell counts of PMVECs, but it decreased PAEC cell number. Severe acidosis (pH 6.2) decreased cell counts of PMVECs and elicited an even more pronounced reduction of PAECs. PMVECs had a higher CA IX expression compared with PAECs. CA activity was higher in PMVECs compared with PAECs, and enzyme activity was dependent on the type IX isoform. Pharmacological inhibition and genetic ablation of CA IX caused profound dysregulation of extra- and intracellular pH in PMVECs. Matrigel assays revealed impaired angiogenesis of CA IX knockout PMVECs in acidosis. Lastly, pharmacological CA IX inhibition caused profound cell death in PMVECs, whereas genetic CA IX ablation had little effect on PMVEC cell death in acidosis. Thus CA IX controls PMVEC pH necessary for angiogenesis during acidosis. CA IX may contribute to lung vascular repair during acute lung injury that is accompanied by acidosis within the microenvironment.