ミトコンドリアの融合は、時間をかけてネットワークを介してミトコンドリアのマトリックスphotoconvertedをターゲットとしたGFPの平衡を追跡することによって測定した。これまでのところ、1つだけのセルが同時に時間の長い運動解析に供することができます。我々はこれにより、データ収集プロセスをスピードアップ、同時に複数のセルを測定する手法を提案する。
Mitochondrial fusion plays an essential role in mitochondrial calcium homeostasis, bioenergetics, autophagy and quality control. Fusion is quantified in living cells by photo-conversion of matrix targeted photoactivatable GFP (mtPAGFP) in a subset of mitochondria. The rate at which the photoconverted molecules equilibrate across the entire mitochondrial population is used as a measure of fusion activity. Thus far measurements were performed using a single cell time lapse approach, quantifying the equilibration in one cell over an hour. Here, we scale up and automate a previously published live cell method based on using mtPAGFP and a low concentration of TMRE (15 nm). This method involves photoactivating a small portion of the mitochondrial network, collecting highly resolved stacks of confocal sections every 15 min for 1 hour, and quantifying the change in signal intensity. Depending on several factors such as ease of finding PAGFP expressing cells, and the signal of the photoactivated regions, it is possible to collect around 10 cells within the 15 min intervals. This provides a significant improvement in the time efficiency of this assay while maintaining the highly resolved subcellular quantification as well as the kinetic parameters necessary to capture the detail of mitochondrial behavior in its native cytoarchitectural environment.
Mitochondrial dynamics play a role in many cellular processes including respiration, calcium regulation, and apoptosis1,2,3,13. The structure of the mitochondrial network affects the function of mitochondria, and the way they interact with the rest of the cell. Undergoing constant division and fusion, mitochondrial networks attain various shapes ranging from highly fused networks, to being more fragmented. Interestingly, Alzheimer’s disease, Parkinson’s disease, Charcot Marie Tooth 2A, and dominant optic atrophy have been correlated with altered mitochondrial morphology, namely fragmented networks4,10,13. Often times, upon fragmentation, mitochondria become depolarized, and upon accumulation this leads to impaired cell function18. Mitochondrial fission has been shown to signal a cell to progress toward apoptosis. It can also provide a mechanism by which to separate depolarized and inactive mitochondria to keep the bulk of the network robust14. Fusion of mitochondria, on the other hand, leads to sharing of matrix proteins, solutes, mtDNA and the electrochemical gradient, and also seems to prevent progression to apoptosis9. How fission and fusion of mitochondria affects cell homeostasis and ultimately the functioning of the organism needs further understanding, and therefore the continuous development and optimization of how to gather information on these phenomena is necessary.
Existing mitochondrial fusion assays have revealed various insights into mitochondrial physiology, each having its own advantages. The hybrid PEG fusion assay7, mixes two populations of differently labeled cells (mtRFP and mtYFP), and analyzes the amount of mixing and colocalization of fluorophores in fused, multinucleated, cells. Although this method has yielded valuable information, not all cell types can fuse, and the conditions under which fusion is stimulated involves the use of toxic drugs that likely affect the normal fusion process. More recently, a cell free technique has been devised, using isolated mitochondria to observe fusion events based on a luciferase assay1,5. Two human cell lines are targeted with either the amino or a carboxy terminal part of Renilla luciferase along with a leucine zipper to ensure dimerization upon mixing. Mitochondria are isolated from each cell line, and fused. The fusion reaction can occur without the cytosol under physiological conditions in the presence of energy, appropriate temperature and inner mitochondrial membrane potential. Interestingly, the cytosol was found to modulate the extent of fusion, demonstrating that cell signaling regulates the fusion process 4,5. This assay will be very useful for high throughput screening to identify components of the fusion machinery and also pharmacological compounds that may affect mitochondrial dynamics. However, more detailed whole cell mitochondrial assays will be needed to complement this in vitro assay to observe these events within a cellular environment.
A technique for monitoring whole-cell mitochondrial dynamics has been in use for some time and is based on a mitochondrially-targeted photoactivatable GFP (mtPAGFP)6,11. Upon expression of the mtPAGFP, a small portion of the mitochondrial network is photoactivated (10-20%), and the spread of the signal to the rest of the mitochondrial network is recorded every 15 minutes for 1 hour using time lapse confocal imaging. Each fusion event leads to a dilution of signal intensity, enabling quantification of the fusion rate. Although fusion and fission are continuously occurring in cells, this technique only monitors fusion as fission does not lead to a dilution of the PAGFP signal6. Co-labeling with low levels of TMRE (7-15 nM in INS1 cells) allows quantification of the membrane potential of mitochondria. When mitochondria are hyperpolarized they uptake more TMRE, and when they depolarize they lose the TMRE dye. Mitochondria that depolarize no longer have a sufficient membrane potential and tend not to fuse as efficiently if at all. Therefore, active fusing mitochondria can be tracked with these low levels of TMRE9,15. Accumulation of depolarized mitochondria that lack a TMRE signal may be a sign of phototoxicity or cell death. Higher concentrations of TMRE render mitochondria very sensitive to laser light, and therefore great care must be taken to avoid overlabeling with TMRE. If the effect of depolarization of mitochondria is the topic of interest, a technique using slightly higher levels of TMRE and more intense laser light can be used to depolarize mitochondria in a controlled fashion (Mitra and Lippincott-Schwartz, 2010). To ensure that toxicity due to TMRE is not an issue, we suggest exposing loaded cells (3-15 nM TMRE) to the imaging parameters that will be used in the assay (perhaps 7 stacks of 6 optical sections in a row), and assessing cell health after 2 hours. If the mitochondria appear too fragmented and cells are dying, other mitochondrial markers, such as dsRED or Mitotracker red could be used instead of TMRE.
The mtPAGFP method has revealed details about mitochondrial network behavior that could not be visualized using other methods. For example, we now know that mitochondrial fusion can be full or transient, where matrix content can mix without changing the overall network morphology. Additionally, we know that the probability of fusion is independent of contact duration and organelle dimension, is influenced by organelle motility, membrane potential and history of previous fusion activity8,15,16,17.
In this manuscript, we describe a methodology for scaling up the previously published protocol using mtPAGFP and 15nM TMRE8 in order to examine multiple cells at a time and improve the time efficiency of data collection without sacrificing the subcellular resolution. This has been made possible by the use of an automated microscope stage, and programmable image acquisition software. Zen software from Zeiss allows the user to mark and track several designated cells expressing mtPAGFP. Each of these cells can be photoactivated in a particular region of interest, and stacks of confocal slices can be monitored for mtPAGFP signal as well as TMRE at specified intervals. Other confocal systems could be used to perform this protocol provided there is an automated stage that is programmable, an incubator with CO2, and a means by which to photoactivate the PAGFP; either a multiphoton laser, or a 405 nm diode laser.
買収は、光活性化後、15分ごとに発生した場合、このメソッドは、一度におよそ10細胞のイメージングを可能にします。細胞の正確な数は1つがどのように迅速に培養皿内でmtPAGFP発現する細胞を見つけて、マークすることができ、どのように迅速に1つのすべてのソフトウェアのパラメータを設定することができますによって異なります。指定されたZ-スタックマージンはすべてのセルに対して適用されるので自動化がスムーズに実行できるように細胞の均一な層を使用する必要があります。
この初期の光活性化領域のサイズは、平衡時間を制御します。ミトコンドリアの融合を測定することができるようにするには、それが残りのネットワークへの信号の広がりは経時的にモニターすることができるようなネットワークの唯一の10-20%、光活性化することが重要である。ネットワークのあまりに多くが光活性化されている場合は、それは完全な融合が速すぎると発生する可能性があり、イベントがキャプチャされません。
細心の注意を払う必要があり二光子レーザーのレーザパワーだけでなく、ミトコンドリアの脱分極を引き起こす毒性を避けるためにTMRE濃度を調整します。 mtPAGFP信号はTMRE信号と共局在することを保証することは、毒性と一般的な細胞の健康8,15を評価するのに役立ちます。 epifluoerescent光照射は避けるべきである。 mtPAGFPを発現する細胞を捜している間、低消費電力488nmの励起でスキャンしながら、ピンホールを最大限に開いている必要があります。 PA-GFPは1時間かけて信号を測定することではなく、セルのいずれかが8トリッキーなことができoversaturateないように十分な光活性化するために2つの光子レーザパワーを調整します。一度自動化されたプログラムが開始されたしかし、時間は、この最適化のステップに費やさなければならない、それは複数のセルを選択するには、それを停止し、再開するのは面倒です。
品質管理のため、微分干渉コントラスト(DIC)の買収は、セルにフォーカスを監視するための画像(または透過光)は非常にすることができます親切にも、スキャン中に浸油に形成された気泡を検出するための良い方法、これは時々ステージの動きから発生します。
このmtPAGFPメソッドを使用すると、ラベルが付いていないされているものに光活性化ミトコンドリアからのミトコンドリアのマトリックスタンパク質の単方向の動きにデータを収集しますが、それは他のプロセスを研究するためにこのテクニックを利用することが考えられる。の融合は、可溶性マトリックスタンパク質15の混合とは異なる時間スケールで発生し、ABC-私のために示されているようにたとえば、特定の蛍光色素は、核融合イベント時に、その特定の動きを観察し、膜タンパク質に結合することができます。
The authors have nothing to disclose.
我々は、神経科学研究のためのタフツセンター、P30 NS047243(ジャクソン)、ボストン大学メディカルキャンパス、リンク医学Corporationの学際的医学研究のためのエヴァンスセンターでサポートされているミトコンドリアアフィニティ研究協力(mtARC)と、この作業を支援するためのツァイスに感謝します。
Name of the reagent | Company | Catalogue number |
COXIII-adenoviral PA-GFP | Dr. Lippincott-Schwartz | |
TMRE | Invitrogen | T669 |
Zeiss LSM 710 confocal | Zeiss |