Erratum: Integrin-FAK Signaling Rapidly and Potently Promotes Mitochondrial Function Through STAT3 (Cell Communication and Signaling (2016) 14 (32) DOI: 10.1186/s12964-016-0157-7)

Reference. Unfortunately, after publication of this article [1], it was noticed that the Acknowledgements and Funding sections were incomplete. The Acknowledgements section currently reads, “We are grateful for the technical support by Aruna Visavadiya, Ying Li, and Rhesa Dykes” and the Funding section currently reads, “This work was supported by NIH grant NS45734 and ETSU medical school funds”. The full, corrected sections can be seen below. Acknowledgements We are grateful for the technical support by Aruna Visavadiya, Ying Li, and Rhesa Dykes. Dr. Britta Engelhardt (Theodor Kocher institute) is thanked for providing the bEnd5 cells. Funding This work was supported by NIH grant NS45734 and in part by NIH grant C06RR0306551 and the ETSU College of Medicine. Further to this, a duplicate image in Fig. 4e was reported. The correct image is presented in this correction article. (Figure Presented)

MicroRNAs in Cerebral Ischemia

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Inhibition of strocyte FAK–JNK Signaling Promotes Subventricular Zone Neurogenesis Through CNTF

Astrocyte-derived ciliary neurotrophic factor (CNTF) promotes adult subventricular zone (SVZ) neurogenesis. We found that focal adhesion kinase (FAK) and JNK, but not ERK or P38, repress CNTF in vitro. Here, we defined the FAK–JNK pathway and its regulation of CNTF in mice, and the related leukemia inhibitory factor (LIF) and interleukin-6 (IL-6), which promote stem cell renewal at the expense of neurogenesis. Intrastriatal injection of FAK inhibitor, FAK14, in adult male C57BL/6 mice reduced pJNK and increased CNTF expression in the SVZ-containing periventricular region. Injection of a JNK inhibitor increased CNTF without affecting LIF and IL-6, and increased SVZ proliferation and neuroblast formation. The JNK inhibitor had no effect in CNTF−/− mice, suggesting that JNK inhibits SVZ neurogenesis by repressing CNTF. Inducible deletion of FAK in astrocytes increased SVZ CNTF and neurogenesis, but not LIF and IL-6. Intrastriatal injection of inhibitors suggested that P38 reduces LIF and IL-6 expression, whereas ERK induces CNTF and LIF. Intrastriatal FAK inhibition increased LIF, possibly through ERK, and IL-6 through another pathway that does not involve P38. Systemic injection of FAK14 also inhibited JNK while increasing CNTF, but did not affect P38 and ERK activation, or LIF and IL-6 expression. Importantly, systemic FAK14 increased SVZ neurogenesis in wild-type C57BL/6 and CNTF+/+ mice, but not in CNTF−/− littermates, indicating that it acts by upregulating CNTF. These data show a surprising differential regulation of related cytokines and identify the FAK–JNK–CNTF pathway as a specific target in astrocytes to promote neurogenesis and possibly neuroprotection in neurological disorders

Liver Vitronectin Release Into the Bloodstream Increases Due to Reduced Vagal Muscarinic Signaling After Cerebral Stroke in Female Mice

Vitronectin (VTN) is a glycoprotein enriched in the blood and activates integrin receptors. VTN blood levels increase only in female mice 24 h after an ischemic stroke and exacerbate brain injury through IL-6-driven inflammation, but the VTN induction mechanism is unknown. Here, a 30 min middle cerebral artery occlusion (MCAO) in female mice induced VTN protein in the liver (normally the main source) in concert with plasma VTN. Male mice were excluded as VTN is not induced after stroke. MCAO also increased plasma VTN levels after de novo expression of VTN in the liver of VTN female mice, using a hepatocyte-specific (SERPINA1) promoter. MCAO did not affect SERPINA1 or VTN mRNA in the liver, brain, or several peripheral organs, or platelet VTN, compared to sham mice. Thus, hepatocytes are the source of stroke-induced increases in plasma VTN, which is independent of transcription. The cholinergic innervation by the parasympathetic vagus nerve is a potential source of brain-liver signaling after stroke. Right-sided vagotomy at the cervical level led to increased plasma VTN levels, suggesting that VTN release is inhibited by vagal tone. Co-culture of hepatocytes with cholinergic neurons or treatment with acetylcholine, but not noradrenaline (sympathetic transmitter), suppressed VTN expression. Hepatocytes have muscarinic receptors and the M1/M3 agonist bethanechol decreased VTN mRNA and protein release in vitro via M1 receptors. Finally, systemic bethanechol treatment blocked stroke-induced plasma VTN. Thus, VTN translation and release are inhibited by muscarinic signaling from the vagus nerve and presents a novel target for lessening detrimental VTN expression

Vitronectin Mitigates Stroke-Increased Neurogenesis Only in Female Mice and Through FAK-Regulated IL-6

Vitronectin (VTN) is a blood protein produced mainly by the liver. We show that VTN leaks from the bloodstream into the injury site and neighboring subventricular zone (SVZ) following ischemic stroke (middle cerebral artery occlusion, MCAO) in adult mice. MCAO is known to increase neurogenesis after stroke. VTN inhibits this response in females, but not in males, as shown by ~70% more stroke-induced SVZ neurogenesis in female VTN−/− mice at 14 d. In female VTN−/− mice, stroke-induced expression of interleukin-6 (IL-6) at 24 h was reduced in the SVZ. The closely related leukemia inhibitory factor (LIF) or pro-neurogenic ciliary neurotrophic factor (CNTF) were not affected. The female-specific effect of VTN on IL-6 expression was not due to sex hormones, as shown by ovariectomy and castration. IL-6 injection next to the SVZ reversed the MCAO-induced increase in neurogenesis seen in VTN−/− mice. Our in vitro and vivo data suggest that plasma VTN activates focal adhesion kinase (FAK) in the SVZ following MCAO, which reduces IL-6 expression in astrocytes but increases it in other cells such as microglia/macrophages. Inducible conditional astrocytic FAK deletion increased MCAO-induced IL-6 expression in females at 24 h and blocked MCAO-induced neurogenesis at 14 d, confirming a key detrimental role of IL-6. Collectively, these data suggest that leakage of VTN into the SVZ reduces the neurogenic response to stroke in female mice by promoting IL-6 expression. Reducing VTN or VTN signaling may be an approach to promote neurogenesis for neuroprotection and cell replacement after stroke in females