Transcellular degradation of axonal mitochondria

Davis, Chung Ha O.; Kim, Keun Young; Bushong, Eric A.; Mills, Elizabeth; Boassa, Daniela; Shih, Tiffany; Kinebuchi, Mira; Phan, Sébastien; Zhou, Yi; Bihlmeyer, Nathan A.; Nguyen, Judy V.; Jin, Yingxue; Ellisman, Mark H.; Marsh-Armstrong, Nicholas

doi:10.1073/pnas.1404651111

Cited by 519 publications

(474 citation statements)

References 27 publications

(16 reference statements)

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“…Both phagocytosis and cell infiltration are implicated in glaucoma (5,41,64,65). Given the physiological function of ONH astrocytes in phagocytosing myelin and mitochondria, an early effect of high IOP may be to alter astrogliosis and disrupt phagocytosis (41,66). These functions are carried out when C3 effector fragments bind various receptors, including C3AR1 for C3a and CR1, CR2, CR3, and CR4 for C3b (67).…”

Section: Discussionmentioning

confidence: 99%

Early immune responses are independent of RGC dysfunction in glaucoma with complement component C3 being protective

Harder

Braine

Williams

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

103

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Various immune response pathways are altered during early, predegenerative stages of glaucoma; however, whether the early immune responses occur secondarily to or independently of neuronal dysfunction is unclear. To investigate this relationship, we used the Wld s allele, which protects from axon dysfunction. We demonstrate that DBA/2J.Wld s mice develop high intraocular pressure (IOP) but are protected from retinal ganglion cell (RGC) dysfunction and neuroglial changes that otherwise occur early in DBA/2J glaucoma. Despite this, immune pathways are still altered in DBA/2J.Wld s mice. This suggests that immune changes are not secondary to RGC dysfunction or altered neuroglial interactions, but may be directly induced by the increased strain imposed by high IOP. One early immune response following IOP elevation is up-regulation of complement C3 in astrocytes of DBA/2J and DBA/ 2J.Wld s mice. Unexpectedly, because the disruption of other complement components, such as C1Q, is protective in glaucoma, C3 deficiency significantly increased the number of DBA/2J eyes with nerve damage and RGC loss at an early time point after IOP elevation. Transcriptional profiling of C3-deficient cultured astrocytes implicated EGFR signaling as a hub in C3-dependent responses. Treatment with AG1478, an EGFR inhibitor, also significantly increased the number of DBA/2J eyes with glaucoma at the same early time point. These findings suggest that C3 protects from early glaucomatous damage, a process that may involve EGFR signaling and other immune responses in the optic nerve head. Therefore, therapies that target specific components of the complement cascade, rather than global inhibition, may be more applicable for treating human glaucoma.G laucoma is a common disorder characterized by the loss of retinal ganglion cells (RGCs) and degeneration of the optic nerve (1-3). Intraocular pressure (IOP) elevation is a major risk factor for developing glaucoma (4). Harmful IOP leads to changes in immune response pathways in nonneuronal cells, such as astrocytes and microglia/monocytes (5-9). Similar changes occur in many neurodegenerative diseases, including Parkinson's disease (10), Alzheimer's disease (11), and Huntington's disease (12). In glaucoma, immune responses are known to occur at predegenerative stages (5, 8), but key questions remain unanswered (2, 13-15). It is not known whether the earliest immune responses are protective or damaging, or which events irreversibly damage the optic nerve. Moreover, it is not known whether the immune responses are secondary to RGC dysfunction or occur independently, possibly as a more direct result of IOP elevation.In glaucoma, an early insult to RGC axons occurs where they exit the eye in the optic nerve head (ONH) (16)(17)(18)(19)(20). Modeling shows that an increase in IOP inside the eye leads to increased strain in this critical region (21,22). To understand the molecular responses occurring during glaucoma, gene expression profiles of human lamina astrocytes and ONH tissue from animal models hav...

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Section: Discussionmentioning

confidence: 99%

Early immune responses are independent of RGC dysfunction in glaucoma with complement component C3 being protective

Harder

Braine

Williams

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

103

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“…Also, the removal and degradation of mitochondria are tightly regulated [9,12,13], because dysfunctional mitochondria are a source of reactive oxygen species, which can damage the cell [14]. Deficits in mitochondrial trafficking have been proposed to contribute to the pathogenesis of Parkinson's disease, schizophrenia, amyotrophic lateral sclerosis, optic atrophy, and Alzheimer's disease [13,[15][16][17][18][19].…”

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confidence: 99%

Mitochondrial Dynamics in Visual Cortex Are Limited In Vivo and Not Affected by Axonal Structural Plasticity

et al. 2016

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[5] are often localized far away from the soma, mitochondria are actively transported to these sites [6][7][8][9][10][11]. Also, the removal and degradation of mitochondria are tightly regulated [9,12,13], because dysfunctional mitochondria are a source of reactive oxygen species, which can damage the cell [14]. Deficits in mitochondrial trafficking have been proposed to contribute to the pathogenesis of Parkinson's disease, schizophrenia, amyotrophic lateral sclerosis, optic atrophy, and Alzheimer's disease [13,[15][16][17][18][19]. In neuronal cultures, about a third of mitochondria are motile, whereas the majority remains stationary for several days [8,20]. Activity-dependent mechanisms cause mitochondria to stop at synaptic sites [7,8,20,21], which affects synapse function and maintenance. Reducing mitochondrial content in dendrites decreases spine density [22,23], whereas increasing mitochondrial content or activity increases it [7]. These bidirectional interactions between synaptic activity and mitochondrial trafficking suggest that mitochondria may regulate synaptic plasticity. Here we investigated the dynamics of mitochondria in relation to axonal boutons of neocortical pyramidal neurons for the first time in vivo. We find that under these circumstances practically all mitochondria are stationary, both during development and in adulthood. In adult visual cortex, mitochondria are preferentially localized at putative boutons, where they remain for several days. Retinal-lesion-induced cortical plasticity increases turnover of putative boutons but leaves mitochondrial turnover unaffected. We conclude that in visual cortex in vivo, mitochondria are less dynamic than in vitro, and that structural plasticity does not affect mitochondrial dynamics. RESULTS AND DISCUSSION Few Motile Mitochondria in Axons of Pyramidal Neurons in Visual Cortex In VivoTo fluorescently label mitochondria and the neuronal structures in which they are localized, we performed in utero electroporation with two DNA constructs driving expression of mitomTurquoise2 and membrane-associated YFP. A cranial window was implanted once mice had reached the age of 8-10 weeks. This allowed us to visualize mitochondria in axonal arbors of layer 2/3 pyramidal neurons in V1 in vivo using two-photon microscopy (Figures 1A-1C; Movie S1). Two to three weeks after cranial window implantation, optical imaging of intrinsic imaging was performed to localize monocular V1. One week later, axonal branches in layer 1 and upper layer 2 were imaged using in vivo two-photon microscopy. We found that the density of mitochondria was 0.09 per mm ( Figure 1D). Surprisingly, the fraction of axonal mitochondria that were motile was only 0.83% ( Figure 1E), much lower than the 10%-30% previously observed in neuronal cultures [6][7][8][9][10]. We therefore asked whether the difference in mitochondrial motility was caused by the different experimental condition (in vivo versus in vitro) or by the difference in the age of the imaged neurons. We assessed mitochondrial motilit...

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“…This raises questions about intercellular mitochondrial transfer being involved in both replacement of defective organelles and recycling damaged organelles. In this context, a recent study showed that mitochondria from the optic nerve head are packaged into exosomes that are taken up and processed by surrounding astrocytes (35).…”

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confidence: 99%

Mitochondrial DNA in Tumor Initiation, Progression, and Metastasis: Role of Horizontal mtDNA Transfer

2015

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Mitochondrial DNA (mtDNA), encoding 13 out of more than 1,000 proteins of the mitochondrial proteome, is of paramount importance for the bioenergetic machinery of oxidative phosphorylation that is required for tumor initiation, propagation, and metastasis. In stark contrast to the widely held view that mitochondria and mtDNA are retained and propagated within somatic cells of higher organisms, recent in vitro and in vivo evidence demonstrates that mitochondria move between mammalian cells. This is particularly evident in cancer where defective mitochondrial respiration can be restored and tumor-forming ability regained by mitochondrial acquisition. This paradigm shift in cancer cell biology and mitochondrial genetics, concerning mitochondrial movement between cells to meet bioenergetic needs, not only adds another layer of plasticity to the armory of cancer cells to correct damaged mitochondria, but also points to potentially new therapeutic approaches. Cancer Res; 75(16); 3203-8. Ó2015AACR.

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Transcellular degradation of axonal mitochondria

Cited by 519 publications

References 27 publications

Early immune responses are independent of RGC dysfunction in glaucoma with complement component C3 being protective

Early immune responses are independent of RGC dysfunction in glaucoma with complement component C3 being protective

Mitochondrial Dynamics in Visual Cortex Are Limited In Vivo and Not Affected by Axonal Structural Plasticity

Mitochondrial DNA in Tumor Initiation, Progression, and Metastasis: Role of Horizontal mtDNA Transfer

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