key: cord-308461-4lhh3du0
authors: Ueki, Hiroshi; Wang, I-Hsuan; Zhao, Dongming; Gunzer, Matthias; Kawaoka, Yoshihiro
title: Multicolor two-photon imaging of in vivo cellular pathophysiology upon influenza virus infection using the two-photon IMPRESS
date: 2020-01-29
journal: Nat Protoc
DOI: 10.1038/s41596-019-0275-y
sha: 
doc_id: 308461
cord_uid: 4lhh3du0

In vivo two-photon imaging is a valuable technique for studies of viral pathogenesis and host responses to infection in vivo. In this protocol, we describe a methodology for analyzing influenza virus–infected lung in vivo by two-photon imaging microscopy. We describe the surgical procedure, how to stabilize the lung, and an approach to analyzing the data. Further, we provide a database of fluorescent dyes, antibodies, and reporter mouse lines that can be used in combination with a reporter influenza virus (Color-flu) for multicolor analysis. Setup of this model typically takes ~30 min and enables the observation of influenza virus–infected lungs for >4 h during the acute phase of the inflammation and at least 1 h in the lethal phase. This imaging system, which we termed two-photon IMPRESS (imaging pathophysiology research system), is broadly applicable to analyses of other respiratory pathogens and reveals disease progression at the cellular level in vivo.

In vivo two-photon imaging is an analytical approach that can be used to visualize cell dynamics and hemodynamics in organs or tissues of live animals. Information in real time obtained by using this approach, such as changes in cell behavior and morphology, tissue localization, and blood flow, has revealed highly sophisticated and dynamic systems of living organisms. During in vivo imaging, the blood circulation in the tissue being observed is maintained; therefore, this technique is also effective for analyzing the migration and invasion of immune cells in the inflammatory environment. Observations in physiological environments deepen our understanding of host response mechanisms under both steady-state and disease conditions. Computed tomography, X-ray, and IVIS Spectrum (an in vivo imaging system) imaging methods have been used as non-invasive approaches; however, these techniques have low spatiotemporal resolution and have been able to estimate only the site of inflammation in an organ 1, 2 . Therefore, it is impossible to observe cellular responses of the immune system using these approaches. By contrast, a two-photon excitation laser microscope, the light source of which is a near-infrared laser that produces low damage to cells but has long-reaching depth in tissue, enables us to capture the movement of cells in living animals at high resolution. Two-photon imaging has been in use in biological science since the 1990s; it has progressed at a remarkable rate, and observation methods for various organs, including brain, liver, and lymph nodes, have been reported 3, 4 . In this protocol, we describe how to use it to image virus-infected lungs. We have previously demonstrated that this protocol works by using mice infected with mouse-adapted seasonal influenza virus (H1N1) or highly pathogenic avian influenza virus (H5N1) 5 .

The lung, which is a respiratory organ, has contact with the outside environment and is an important organ for research on immunity to infectious diseases. In the seventeenth century, Marcello Malpighi discovered pulmonary capillaries and alveoli in the frog lung by using optical microscopy 6 ; now fluorescent reporter mice facilitate the study of disease models in conjunction with two-photon excitation microscopy (Table 1) . However, a challenge encountered when imaging the lung is that it is constantly moving during respiration. The lung has been stabilized in several ways during in vivo observation by microscopy, including bronchus clamping, prolonged apnea, gluing, and suction 7, 8 ; however, it is difficult to reduce motion artifacts due to lung respiratory movement under physiological conditions and hence to obtain high-quality images. Bronchus clamping can suppress respiratory motion artifacts of the lung lobe 9, 10 ; however, it is not suitable for long-term observation because it causes severe hypoxia. Although prolonging apnea is less invasive [11] [12] [13] , it does not allow researchers sufficient time to observe the lung for image acquisition by two-photon excitation microscopy, and the quality of the images tends to deteriorate over time. Gluing addresses the above limitations 14, 15 ; however, it can induce shear force injury and inflammation, which affect the interpretation of results. A suction window, which is currently the most commonly used stabilizing system during lung imaging, achieves moderate immobilization of the lung and high-quality images [16] [17] [18] [19] ; however, the observation period is limited to ≤12 h. Ex vivo imaging of lungs and in vivo imaging of trachea have also been performed as complementary methods 8 . Each of these methods has its advantages and disadvantages, and it is important to select and optimize the method best suited to the goal of the experiments and disease model.

In vivo observation of lungs has been performed using various lung disease and experimental models, including bacterial infection, allergen inoculation, tumor metastasis, and lipopolysaccharide (LPS)-induced sepsis (Table 1) . However, for viral respiratory diseases, such as influenza, other than an observation in a methodology report 20 , only analyses of the trachea in vivo [21] [22] [23] and isolated lungs had been performed 24 , with no analysis of the lung in vivo, until our recent publication 5 (Table 1) . Unlike ex vivo methods, which involve isolated or sliced lungs, in vivo imaging using two-photon excitation microscopy of live animals enables researchers to observe hemodynamics, migration and extravasation of immune cells, as well as interactions among immune cells during influenza virus infection. However, it is technically demanding to perform two-photon excitation microscopy of live influenza virus-infected lung, which exhibits severe inflammation, requiring the development of highly sophisticated, less invasive instruments and surgical techniques. In addition, when observing animals infected with pathogenic viruses, specialized facilities and instruments are frequently required to avoid the spread of the virus. Furthermore, because many types of immune cells infiltrate the infected lung in an inflammatory environment, it is necessary to distinguish the target immune cells from the infected cells by using fluorescent labels in the infected microenvironment. To detect multiple fluorescent signals excited simultaneously by a two-photon excitation laser, fluorochromes with different spectra and equal brightness must be selected; however, there is currently no comprehensive database of fluorescent reagents, fluorescent reporter viruses, and reporter mouse lines available for lung in vivo imaging. We therefore also provide a database of fluorescent dyes, antibodies, and reporter mouse lines that can be used in combination with a reporter influenza virus (Color-flu) [25] [26] [27] for multicolor analysis under pathological conditions in this protocol.

Our system uses suction-based lung stabilization 16, 28 to improve an existing in vivo two-photon imaging system for influenza virus-infected lung as a model of an acute inflammatory respiratory disease 5 . We have successfully used C57BL/6 mice and transgenic mice of the C57BL/6 background (6-to 10-week-old males and females). By using our method, described in detail here, it is possible to visualize and analyze the behavior of immune cells and their interactions with infected cells during an influenza virus infection, which creates an acute inflammatory environment.

A limitation of two-photon excitation microscopy is that the observation depth that can be achieved is a maximum of~70 μm. Therefore, we cannot observe the bronchial region. This limitation is linked to the wavelength of the infrared laser and detector capability of the microscope. However, as laser technology develops, the observation depth achievable using this method will improve.

In this protocol, we describe the application of this methodology to influenza virus infection of the lungs because this is what we have used it for previously. This protocol could be applied not only to studies of the early stages of inflammation due to infection or other causes, but also to analyses of tissue regeneration mechanisms in lungs that are in the process of recovering from infection or other PROTOCOL NATURE PROTOCOLS injuries. The information provided will also be useful to those using two-photon imaging analysis for the evaluation of the effects of drugs and vaccines, as well as biological events in the lungs and other organs (e.g., liver, spleen) 5 . Moreover, with minor modifications, the approach could be applied to analyses of other respiratory diseases, including other infectious models (e.g., severe acute respiratory syndrome (SARS) and Middle East respiratory syndrome (MERS)), pulmonary fibrosis, and tumor metastasis. . DNA fingerprinting showed that this cell line has the same origin as one obtained from ATCC (cat. no. CCL-34, RRID:CVCL_0422) ! CAUTION All viruses and infected animals should be handled in accordance with your institution's biosafety regulations. All work on highly pathogenic avian influenza viruses must be performed under biosafety level 3 (BSL3) regulations. Accordingly, all our in vivo imaging studies were performed in the BSL3 facility at the University of Tokyo (Tokyo, Japan), which is approved for such use by the Ministry of Agriculture, Forestry, and Fisheries of Japan c CRITICAL The cells should be regularly checked to ensure that they are not contaminated with mycoplasma. • Isoflurane (MSD Animal Health) ! CAUTION Isoflurane is an anesthetic gas associated with adverse health outcomes. It should be used in a well-ventilated room or with another appropriate removal system. Store it in a locked drawer at room temperature (18-25°C). • Sevoflurane (Maruishi Pharmaceutical) ! CAUTION Sevoflurane is an anesthetic gas associated with adverse health outcomes. It should be used in a well-ventilated room or with another appropriate removal system. Store it in a locked drawer at room temperature. 

c CRITICAL All reagents should be prepared under sterile conditions. Fluorescent reagents should be protecting from light during the setup procedure because they are light sensitive.

To prepare 10 mg/ml of tamoxifen solution in sunflower seed oil, dissolve 100 mg of tamoxifen in 1 ml of ethanol (99.5%) and add 9 ml of sunflower seed oil. After adding the ethanol and sunflower seed oil, mix well by vortexing and sonication. This solution can be stored in a refrigerator (2-8°C) for a week. ! CAUTION Tamoxifen powder should be handled in a hood. To avoid inhalation and contact with skin, wear rubber gloves and a surgical mask.

Prepare a solution at a concentration of 2 mg/ml in sterile 1× PBS or saline, make aliquots in 1.5-ml microtubes, and store them in a refrigerator (2-8°C) for up to 2 weeks. Inject 50 μl (100 μg) of fluorescent dextran i.v. per mouse.

Qtracker 655 vascular labels Immediately before use, add 5 μl of the stock solution to 95 μl of sterile 1× PBS or saline to make 100 μl total and inject 50 μl i.v. at a concentration of 0.1 μM.

Prepare a solution at a concentration of 1 × 10 8 beads/ml in sterile 1× PBS or saline, make aliquots of the solution in dark 1.5-ml microtubes, and store them in a refrigerator (2-8°C) for long periods (~3 months). Immediately before use, mix well and inject 50 μl i.v. per mouse.

Qdot 655 WGA Immediately before use, add 5 μl of the stock solution to 95 μl of sterile 1× PBS or saline to make 100 μl total and i.v. inject 50 μl.

Prepare a solution at a concentration of 100 μM in sterile 1× PBS or saline, dispense the solution into dark 1.5-ml microtubes, and store them in a refrigerator (2-8°C) for up to 2 weeks. Inject 50 μl of fluorescent dextran i.v. per mouse.

Divide the 5 mM DMSO stock solution into dark 1.5-ml microtubes and store them at −20°C for up to 3 months. Immediately before use, prepare a solution at a concentration of 50 μM in sterile 1× PBS or saline and i.v. inject 50 μl per mouse.

Prepare a solution at a concentration of 100 mM in sterile 1× PBS or saline, dispense the solution in dark 1.5-ml microtubes, and store them at −20°C for up to 3 months. Immediately before use, prepare a solution at a concentration of 1 mM in sterile 1× PBS or saline and inject 50 μl i.v. per mouse.

Prepare a solution at a concentration of 10 mM in sterile 1× PBS or saline, make aliquots of the solution in dark 1.5-ml microtubes, and store them in a refrigerator (2-8°C) for up to 2 weeks. Inject 50 μl of the solution i.v. per mouse.

Prepare a working solution according to the vendor's manual, dissolve pan caspase in vivo probe in 5 μl of DMSO, and add 55 μl of 1× injection buffer (from the kit). Inject 60 μl of the solution i.v. per mouse within 1 h of preparation.

Prepare a working solution according to the vendor's manual, dissolve 100 μl of PKH26PCL in 900 μl of ethanol and store at room temperature for up to 3 months. Immediately before use, prepare a solution at a concentration of 10 μM in sterile Dilution Buffer (from the kit) and inject 50 μl intranasally per mouse.

CellROX Green, Orange, and Deep Red Immediately before use, add 50 μl of the stock solution to 450 μl of sterile 1× PBS or saline to make 500 μl total and inject 50 μl i.v. at a concentration of 250 μM.

LysoTracker Blue, Green, Red, and Deep Red Immediately before use, add 50 μl of the stock solution to 450 μl of sterile 1× PBS or saline to make 500 μl total and inject 50 μl i.v. at a concentration of 100 μM.

MitoTracker Orange CMTMRos, Red CM-H2Xros, and Red FM Immediately before use, dilute 50 μg of MitoTracker in 1 ml of DMSO and inject 50 μl i.v. at a concentration of 100 μM.

c CRITICAL The MitoTracker solution should be prepared fresh each time immediately before use.

Prepare the solution at a concentration of 10 mM in sterile 1× PBS or saline, make aliquots in dark 1.5-ml microtubes, and store them in a refrigerator (2-8°C) for up to 2 weeks. Immediately before use, prepare a solution at a concentration of 10 μM in sterile 1× PBS or saline and inject 50 μl i.v. per mouse.

Prepare the solution at a concentration of 10 mM in DMSO, make aliquots in dark 1.5-ml microtubes, and store them in a refrigerator (2-8°C) for up to 2 weeks. Immediately before use, prepare a working solution at a concentration of 1 mM in sterile 1× PBS or saline and inject 50 μl i.v. per mouse.

Prepare each solution at a concentration of 1 mM in DMSO, make aliquots in dark 1.5-ml microtubes, and store them in a refrigerator (2-8°C) for up to 1 week. Immediately before use, prepare solutions at a concentration of 100 μM in sterile 1× PBS or saline and inject 50 μl i.v. per mouse.

Dilute fluorescent antibodies to a concentration of 1 µg per 10 μl with sterile 1× PBS or saline and inject 50 μl i.v. per mouse. ! CAUTION It should be noted that antibody staining may affect the target cell behavior; for example, at a high dose (~200 μg), antibodies may neutralize cell activities and/or cause antibody-dependent cytotoxic activity [35] [36] [37] . In our studies, we use 5 µg of antibody for brightness screening because inoculation of fluorochrome-conjugated anti-Ly-6G antibody at low doses (1-40 µg) into mice does not affect neutrophil recruitment 38 . The contribution of Ly-6G, which is expressed predominantly on murine neutrophils, to recruitment during inflammation remains a matter of debate. It has been reported that low-dose antibody treatment inhibited Ly-6G ligation and the recruitment of neutrophils to the site of inflammation 39 ; however, a more recent study indicated that Ly-6G knockout did not affect either neutrophil differentiation or recruitment to the site of inflammation in Catchup mice 32 . Therefore, a low dose of anti-Ly-6G antibody is used in our protocol.

Laser path adjustment system An overview of the laser path adjustment system is shown in Fig. 1 . Our two-photon excitation laser (Chameleon Vision II) unit is placed on an anti-vibration table outside the BSL3 facility. The laser beam enters the BSL3 room, where the two-photon excitation scanning microscope is located, through a window (composed of a small glass window (WG12012-B) and a planar window (RS seal)) connecting the inside and the outside of the BSL3 facility (Fig. 1c,d) . The laser path connecting the laser source unit and the two-photon excitation microscope is adjusted by automated laser beam alignment and the Aligna 4D stabilization system is adjusted with two active mirrors. ! CAUTION This system adjusts the laser path passing from the outside to the inside of the BSL3 facility for maintenance purposes, so there is no need for this setup unless you are using pathogens that require BSL3 containment. Heat is generated when the laser source unit is running, so keep the temperature and humidity constant by using air conditioning equipment. ! CAUTION The system should be operated only by users trained to deal with unenclosed high-power invisible beams and should be placed in an appropriate enclosure with interlocking doors.

Two-photon excitation laser scanning microscopy system for in vivo imaging of virus-infected mouse lungs in a BSL3 facility A schematic of the arrangement of the in vivo lung imaging system for virus-infected mouse is shown in Fig. 2a, and layout examples are shown in Fig. 2b -g. This in vivo lung imaging system is based on the upright microscope LSM 780 NLO system, which is equipped with four different lasers (excitation at 405, 488, 543, and 633 nm) for confocal imaging and a two-photon excitation laser (excitation at 630-1,050 nm). To be able to perform the surgical procedure on the mouse, we replaced the sample stage with a large, flat one (microscope stage for in vivo experiment) as shown in Fig. 2b ,c. To efficiently excite multiple fluorescent proteins and fluorescent dyes simultaneously, the wavelength of the infrared laser should be set at 910 nm. All fluorescent spectra between the 410-and 695-nm wavelengths can be detected using a 20× water immersion lens, and we record signals in lambda image stacks (0.13 frames per s, 1,024 × 1,024 pixels) and acquire z-stack images with z-depths of 5 μm (total of 10-μm z-depth). We perform spectral separation of the acquired lambda stacks by using the linear unmixing function of the ZEN software. Although the LSM 780 microscope system is controlled by a primary personal computer, we recommended adding >64 GB of RAM for appropriate imaging analysis.

We keep the mice on a heated stage on the sample stage and record their vital signs using a LabOx-1 pulse oximeter. To observe the lungs of the mice with a thoracotomy, we place the ventilator with an airway pressure monitor and anesthesia machine for rodents in appropriate positions on the stage. We installed high-efficiency particulate air (HEPA) filters in the exhalation duct of the ventilation system (Fig. 2b,d) , and the operator wore a positive pressure mask (Versaflo Faceshields) and a Tyvek suit (Fig. 2e-g) to avoid exposure to the viruses. ! CAUTION The wavelength and power of the excitation laser should be adjusted appropriately according to the experimental conditions. Increasing the laser power enhances target signals and enables detection of second-harmonic generation (SHG), in which structures with repeating patterns lead to the formation of a signal. SHG is a useful phenomenon for visualizing collagen fibers in the lung without staining; however, it should be noted that the autofluorescence of lung tissue is also enhanced under excessive excitation conditions ( Supplementary  Fig. 1 ). When using this protocol, we did not perform experiments under which SHG occurs, in order to minimize autofluorescence; it is better to adjust the laser power according to the experimental purpose. When the wavelength of the excitation laser is too short, the autofluorescence signal becomes very strong and it is difficult to observe properly. By contrast, when the laser wavelength is too long, it becomes difficult to obtain a signal because of the short excitation energy (Supplementary Fig. 2 ). ! CAUTION Although color separation of emission using a conventional optical band-pass filter is also available for this protocol, multispectral imaging is a useful approach for simultaneously analyzing multiple targets by eliminating tissue autofluorescence and identifying fluorescent labels with overlapping spectra 40, 41 . In vivo two-photon imaging is performed under conditions of single stimulation with a two-photon excitation laser; limitations exist regarding available fluorescent reagents/proteins for multiple labeling of target cells and lung architecture. Therefore, we recommend using a multispectral approach to produce crosstalk-free images of fluorescence with overlapping spectra that cannot be separated by using band-pass filters. Before starting experiments, it is necessary to collect spectral signatures of the emission signal of each fluorescent reagent and protein as reference spectra under the same excitation condition as will be used in the experiment.

To observe the mouse lung using an upright microscope, it is necessary to prepare a thoracic suction window to immobilize the lung. In the BSL3 facility, animal experiments must be performed while wearing two or three layers of latex gloves; therefore, the thoracic suction window was designed for easy handling, even in the BSL3 facility, and to be minimally invasive for the infected animals (Fig. 3a-c and Supplementary Fig. 3 ). To position a cover glass for each observation, flatten the upper surface of the thoracic suction window so that a commercially available cover glass will fit. This device is also designed to reduce concavity and convexity as much as possible so that blood containing virus cannot accumulate. Connect the thoracic suction window to an aspirator through a waste tank and a suction regulator. To prevent the spread of virus-containing aerosols, install HEPA filters between the waste tank and the suction regulator as shown in Fig. 3d . Starting up the imaging system equipment • Timing 20-30 min 2 On the day of analysis, turn on the two-photon excitation laser and the Aligna 4D control unit placed outside the BSL3 facility, and verify that they are working. c CRITICAL The Aligna 4D control unit needs to be kept ON. 3 Wearing a Tyvek suit, positive pressure mask, and gloves according to the guidelines for the BSL3 facility, enter the BSL3 facility where the imaging system is housed. ? TROUBLESHOOTING 4 Turn on the microscope controllers, confocal lasers, and the computer for the two-photon excitation microscope and the Aligna 4D system. 5 Launch the microscope control software ZEN and turn on the lasers, including the two-photon excitation laser. 6 Launch the Aligna 4D control software Kangoo and adjust the laser path connecting the laser source unit and the microscope (Supplementary Fig. 4) . ? TROUBLESHOOTING 7 Wrap the hot plate with aluminum foil, turn it on, and keep it at 35°C. Sterilize the surgical area and tools with 70% ethanol and place all instruments within easy reach.

Animal anesthesia • Timing 2-3 min 8 Turn on the gas anesthesia vaporizer and supply 5% isoflurane to a mouse anesthesia induction chamber. 9 Anesthetize the influenza virus-infected mouse with 5% isoflurane in a mouse anesthesia induction chamber. Subsequently, transfer the mouse to the hot plate while supplying 2% isoflurane via an anesthetic mask.

? TROUBLESHOOTING

10 Inject the chosen fluorescent dyes and antibodies via the retro-orbital plexus (as shown in Supplementary Video 1) using an insulin syringe. Tables 4 and 5 show the brightness levels of antibodies and fluorescence of dyes, respectively, in vivo. ! CAUTION When working with viruses in a BSL3 containment, it is not safe to use needles, so we avoid them as much as possible, which is a standard precaution in high-containment laboratories. In addition, in the BSL3 facility, animal experiments must be performed wearing two or three layers of latex gloves. Tail-vein administration is a common method; however, it is not easy to perform these procedures with so many layers of gloves. Use tweezers to hold down the mouse to make the administration route. When an infected animal is not used, an administration route can be created via the tail vein or the jugular vein. ? TROUBLESHOOTING Surgical procedure • Timing 10-15 min c CRITICAL Before experimenting with infected animals, practice the surgical procedures with euthanized animals. 11 Place the mouse on its back and tape the anterior limbs with adhesive tape (Fig. 4a) . 12 Using straight scissors, cut the skin beneath the chin in the middle and expose the trachea (Fig. 4b) .

Insert a tracheal cannula and intubate the mouse to facilitate mechanical ventilation with a ventilator (Fig. 4c) . Turn on the ventilator, ventilate the mouse at a respiratory rate of 120 breaths per min, and apply positive-end expiratory pressure (PEEP;~6 cm H 2 O) and a tidal volume of 0.5 mL. Deliver isoflurane continuously at 2% to maintain anesthesia. ! CAUTION Perform the surgery with care so as not to cut the blood vessels. If bleeding occurs, stop the bleeding with fine bulldog forceps for microsurgery. 13 Place the mouse in the right lateral decubitus position and re-fix its anterior limbs with the tape (Fig. 4d) . Make an incision in the skin at the left axilla using straight scissors, straight iris scissors, and hooked forceps (Fig. 4e) . ! CAUTION Carefully change the mouse's position in order to avoid cannula drop off. 14 Expose the left lung lobe by surgical intercostal incision between ribs 3 and 4, and keep it exposed by using retractors (Fig. 4f) . The brightness of each fluorescent protein during in vivo lung imaging was scored as relative fluorescence intensity compared with FluoSpheres fluorescent microspheres as an internal standard. For relative intensities of 0-0.2, 0.2-0.6, 0.6-0.9, and >0.9, the brightness scores are represented as +, ++, +++, and ++++, respectively. The brightness of each fluorochrome during in vivo lung imaging was scored as relative fluorescence intensity compared with FluoSpheres fluorescent microspheres as an internal standard. For relative intensities of 0-0.2, 0.2-0.6, 0.6-0.9, and >0.9, the brightness scores are represented as +, ++, +++, and ++++, respectively. AF, Alexa Fluor; ND, not detected. ! CAUTION Perform the surgery with care so as not to cut the blood vessels. If bleeding occurs, stop the bleeding with fine bulldog forceps for microsurgery. c CRITICAL Because lungs infected with viruses often shrink, secure a large field of surgical view so that the suction window can reach it. 15 Place the mouse beneath the objective lens and connect a device to monitor the heart rate of the mouse (we use a LabOx-1 pulse oximeter).

Starting up the thoracic vacuum window system • Timing 2-3 min 16 Turn on the aspirator connected to the thoracic suction window. 17 Fix the thoracic suction window to the holding block at a 90°angle and put a round cover glass on the tip of the suction device.

? TROUBLESHOOTING 18 Turn on the suction pressure regulator and adjust the suction pressure to 25-30 mmHg.

19 Lower the thoracic suction window gently to immobilize the mouse lungs (Fig. 4g,h) . The thoracic suction window should cause the lung to stick to the cover glass because of negative pressure. ! CAUTION Carefully move the suction window so as not to scratch the objective. 20 Position the objective lens above the thoracic window. 21 Put water drops on the cover glass by using a pasteur pipette and lower the objective lens to the thoracic suction window (Fig. 4i) . Unmixing of spectrum data and analyzing the images • Timing 1-2 h per sample 24 To unmix the spectrum data, prepare a reference image of each spectrum in advance. To make a reference image, acquire each fluorescent dye or protein separately without any co-staining and analyze the single fluorescent spectrum. We use the linear unmixing module of the ZEN software for separating spectrum data; however, other commercial or open-source software is available (Table 6 ). 25 Subject unmixed time-series stacks to image registration to correct for tissue drifts and respiratory artifacts. This step is critical to certain analyses, such as long-term tracking of individual cells or subcellular structures. In some cases, a reference channel is required for determining the shift and distortion of the objects. In our studies, we use time-series stacks of blood vessels or collagens for such use, because their localizations are constant over time without substantial changes in shape or structure during the observation. ! CAUTION Some image registration algorithms may cause spatial distortion. Choose algorithms that generate corrected data suitable for your subsequent analyses, especially when examination of the shape and structure of cells and tissues is required. 26 Analyze the movies as required for your experiment.

Troubleshooting advice can be found in Table 7 .

Step 1, infection: 10-20 min Anticipated results

The imaging system described in this protocol enables the observation of the behavior of virusinfected cells and immune cells in infected lungs in real time. Typical images of influenza virus-infected lung are shown in Fig. 5a and Supplementary Video 2. When observing while using a multicolor fluorescent label, it is easier to analyze the detected images if the brightness level of each fluorophore is adjusted to make them similar. It is better to choose fluorescent dyes or proteins that possess high fluorescence stability for long-term observations (Tables 2, 4 and 5). We have found that use of MA-Cerulean-viruses or MA-Venus-viruses for infection produces influenza virus-infected cells with sufficient brightness (Table 3) . For labeling immune cells and alveolar cells, we have achieved good results by using the fluorochrome phycoerythrin (PE) for antibody staining and Rosa-tdTomato 42 or -mTFP1 33 mice that were crossed with cell-specific Cre-expressing mice. If using reporter mice expressing a fluorescent protein such as GFP, which is regulated by an endogenous promoter, the expression level of the fluorescent protein should be confirmed. To visualize the lung structure, we use Texas-Red dextran or Qtracker 655 Vascular Labels for the red to far-infrared channel. Mice die during anesthesia The level of anesthesia is too high Decrease the concentration of anesthesia as soon as the mouse shows loss of righting reflex 10

Mice regain consciousness during anesthesia

The level of anesthesia is too low Confirm the concentration of anesthesia; administer the reagents again after a brief pause 15 No heart rate is measured The monitoring probe is mispositioned Make sure that the monitoring probe is in the appropriate place 17

The cover glass falls off The cover glass does not hold on the suction device Put water droplets on the tip of the suction device and then place the cover glass on it Influenza virus-infected lungs are infiltrated by numerous immune cells, including neutrophils and monocytes [43] [44] [45] . An immune cell-specific reporter mouse line can be used to visualize cells infiltrating the alveoli and cells in blood vessels, whereas it is preferable to label intravascular cells by intravenous administration of fluorochrome-conjugated antibodies 5, 46, 47 . Consistent with previous reports, intravenously injected antibodies will label only the cells in contact with the blood flow and not those in extravascular regions under our experimental conditions 5 . By administering a fluorescently labeled antibody against neutrophils into neutrophil reporter mice, we can observe the behavior of both the neutrophils infiltrating the influenza-infected lungs and the neutrophils in blood vessels separately (Fig. 5b) . To observe the interaction between different kinds of infiltrating immune cells, such as neutrophils and monocytes, double-reporter mice expressing fluorescent proteins with different spectra but similar brightness have a major advantage (Fig. 5c and Supplementary Video 3) .

Co-infection of the host with different strains of influenza virus can lead to the emergence of reassortant viruses. By infecting mice with Color-flu viruses that produce different fluorescence spectra, we detected alveolar epithelial cells that simultaneously expressed two fluorescent proteins in vivo (Fig. 6) . Visualization of co-infected cells might enable us to better understand the reassortment process of influenza viruses in vivo.

In summary, the use of this in vivo imaging system for infected animal and multicolor imaging enables us to analyze pathology and immune cell dynamics at the cellular level, which would not be possible by using conventional histopathology methods. This imaging system thus provides a novel and useful approach for investigating viral pathogenicity.

Further information on research design is available in the Nature Research Reporting Summary linked to this article.

The data that support this study are available from the corresponding author upon reasonable request.

The MATLAB scripts are available at https://github.com/KawaokaLab/Ueki_PNAS_2018. 

For all statistical analyses, confirm that the following items are present in the figure legend, table legend, main text, or Methods section.

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For null hypothesis testing, the test statistic (e.g. F, t, r) with confidence intervals, effect sizes, degrees of freedom and P value noted

Give P values as exact values whenever suitable.

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Policy information about availability of computer code

To efficiently excite multiple fluorescent proteins and fluorescent dyes simultaneously, the wavelength of the infrared laser was set at 910 nm. All fluorescent spectra between 410 and 695 nm wavelengths were detected using a 20x water immersion lens (Carl Zeiss AG, Germany) and the signals were recorded in lambda image stacks.

We use the linear unmixing module of ZEN software for separating spectrum data. Unmixed time-series stacks are subjected to image registration to correct for tissue drifts and respiratory artefacts. A reference channel is required for determining the shift and distortion of the objects. In our studies, we employ time-series stacks of blood vessels or collagens for such use, as their localizations are constant over time without significant changes in shapes or structures during the observation.

For manuscripts utilizing custom algorithms or software that are central to the research but not yet described in published literature, software must be made available to editors/reviewers. We strongly encourage code deposition in a community repository (e.g. GitHub). See the Nature Research guidelines for submitting code & software for further information.

Policy information about availability of data All manuscripts must include a data availability statement. This statement should provide the following information, where applicable:

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The data that support this study are available from the corresponding author upon reasonable request.

October 2018

Field-specific reporting Please select the one below that is the best fit for your research. If you are not sure, read the appropriate sections before making your selection.

For a reference copy of the document with all sections, see nature.com/documents/nr-reporting-summary-flat.pdf

All studies must disclose on these points even when the disclosure is negative.

Only one sample was shown as a representative example that can be obtained by using the imaging protocol.

Data exclusions No data was excluded since one representative image was shown.

No repeated measurements were performed in this paper since one image has been shown as a representative image by using the imaging protocol.

• Microsurgery straight scissors (13.5 cm

• Microsurgery bulldog forceps (BRC, cat. no. 70052-30CII/R)

• Insulin syringes (0.5 ml, 100 U, 30 gauge × 10 mm; Nipro, cat. no. 08277) • Pasteur pipettes (BD Falcon, cat. no. 357575) • Customized surgical retractor

• Thoracic suction window (Sakura Seiki, custom made)

Stage for mounting a thoracic suction window (Sakura Seiki, custom made) • Suction regulator (Iwaki, cat. no. 1450050) • Cover glass (Matsunami Glass, cat. no. C013001) • Hot plate (Hipet, cat

• Confocal microscope system (Zeiss, model no. LSM 780 NLO)

• Infrared laser (Coherent, model no. Chameleon Vision II)

• 20× water immersion lens (Zeiss, Plan-Apochromat model)

• Beam-pointing stabilizer (TEM Messtechnik, model no. Aligna 4D system

High-efficiency particulate air (HEPA) filters (Vacushield; Pall, cat. no. 4402) • Artificial ventilator (Shinano, cat

• Airway pressure monitor (Shinano)

• Gas anesthesia vaporizer

• Mouse anesthesia induction chamber

• Mouse anesthesia mask

• Positive pressure mask (Versaflo Faceshields

SoftWear III) • Surgical gloves

RS seal (Roxtec, cat

LabOx-1)

Highly sensitive real-time in vivo imaging of an influenza reporter virus reveals dynamics of replication and spread

Consecutive CT in vivo lung imaging as quantitative parameter of influenza vaccine efficacy in the ferret model

Calcium imaging of single stereocilia in hair cells: localization of transduction channels at both ends of tip links

In vivo fluorescence microscopy: lessons from observing cell behavior in their native environment

In vivo imaging of the pathophysiological changes and neutrophil dynamics in influenza virus-infected mouse lungs

Marcello Malpighi and the discovery of the pulmonary capillaries and alveoli

Live imaging of the lung

Live imaging of the pulmonary immune environment

Examination of the pulmonary circulation with the microscope

Color-coded real-time cellular imaging of lung T-lymphocyte accumulation and focus formation in a mouse asthma model

Pathophysiological role of endothelins in pulmonary microcirculatory disorders due to intestinal ischemia and reperfusion

Intravital microscopy of the murine pulmonary microcirculation

Surfactant protein A mediates pulmonary clearance of Staphylococcus aureus

In vivo two-photon imaging reveals monocyte-dependent neutrophil extravasation during pulmonary inflammation

DAP12 expression in lung macrophages mediates ischemia/reperfusion injury by promoting neutrophil extravasation

Stabilized imaging of immune surveillance in the mouse lung

Two-photon imaging within the murine thorax without respiratory and cardiac motion artifact

Visualization of immediate immune responses to pioneer metastatic cells in the lung

The lung is a site of platelet biogenesis and a reservoir for haematopoietic progenitors

T cell response in the lung following influenza virus infection

Neutrophil trails guide influenza-specific CD8 + T cells in the airways

Live imaging of influenza infection of the trachea reveals dynamic regulation of CD8 + T cell motility by antigen

Imaging cell interaction in tracheal mucosa during influenza virus infection using two-photon intravital microscopy

Three phases of CD8 T cell response in the lung following H1N1 influenza infection and sphingosine 1 phosphate agonist therapy

Multi-spectral fluorescent reporter influenza viruses (Color-flu) as powerful tools for in vivo studies

Molecular determinants of virulence and stability of a reporter-expressing H5N1 influenza A virus

Amino acid changes in PB2 and HA affect the growth of a recombinant influenza virus expressing a fluorescent reporter protein

Live imaging of the lung

A transgenic mouse line that retains Cre recombinase activity in mature oocytes irrespective of the cre ransgene transmission

Insertion of enhanced green fluorescent protein into the lysozyme gene creates mice with green fluorescent granulocytes and macrophages

Multiple stromal populations contribute to pulmonary fibrosis without evidence for epithelial to mesenchymal transition

Catchup: a mouse model for imaging-based tracking and modulation of neutrophil granulocytes

A multifunctional teal-fluorescent Rosa26 reporter mouse line for Cre-and Flp-mediated recombination

TrackMate: an open and extensible platform for single-particle tracking

The role of neutrophils during mild and severe influenza virus infections of mice

Excessive neutrophils and neutrophil extracellular traps contribute to acute lung injury of influenza pneumonitis

The effects of acute neutrophil depletion on resolution of acute influenza infection, establishment of tissue resident memory (TRM), and heterosubtypic immunity

Antibodies against neutrophil LY6G do not inhibit leukocyte recruitment in mice in vivo

Ly6G ligation blocks recruitment of neutrophils via a β2-integrin-dependent mechanism

Spectral imaging: principles and applications

Multispectral imaging in biology and medicine: slices of life

A robust and high-throughput Cre reporting and characterization system for the whole mouse brain

Regulating the adaptive immune response to respiratory virus infection

A systems analysis identifies a feedforward inflammatory circuit leading to lethal influenza infection

Innate immunity to influenza virus infection

Intravascular staining for discrimination of vascular and tissue leukocytes

In vivo compartmental analysis of leukocytes in mouse lungs

A study of the pulmonary circulation by the transillumination method

Pulmonary capillary recruitment during airway hypoxia in the dog

The behavior of the arterioles and capillaries of the lung

Capillary recruitment during airway hypoxia: role of pulmonary artery pressure

Capillaroscopic appearance of the pulmonary alveoli in the living dog

Diffusing capacity of the lung during hypoxia: role of capillary recruitment

Intrapulmonary blood flow redistribution during hypoxia increases gas exchange surface area

The normal behavior of the pulmonary blood vessels with observations on the intermittence of the flow of blood in the arterioles and capillaries

An experimental model for simultaneous quantitative analysis of pulmonary micro-and macrocirculation during unilateral hypoxia in vivo

A thoracic window for observation of the lung in a living animal

Microscopic observation of the lung in vivo

Precapillary oxygenation contributes relevantly to gas exchange in the intact lung

Pulmonary microcirculatory observations in vivo under physiological conditions

Direct measurement of pulmonary capillary transit times

Intravital laser confocal microscopy of pulmonary edema resulting from intestinal ischemia-reperfusion injury in the rat

Physiological neutrophil sequestration in the lung: visual evidence for localization in capillaries

Measurement of lung microvascular pressure in the intact anesthetized rabbit by the micropuncture technique

Emergency granulopoiesis promotes neutrophil-dendritic cell encounters that prevent mouse lung allograft acceptance

Capillary perfusion patterns in single alveolar walls

Measurement of microhemodynamics in the ventilated rabbit lung by intravital fluorescence microscopy

Donor pulmonary intravascular nonclassical monocytes recruit recipient neutrophils and mediate primary lung allograft dysfunction

Leukocyte kinetics in pulmonary microcirculation: intravital fluorescence microscopic study

The pulmonary endothelial glycocalyx regulates neutrophil adhesion and lung injury during experimental sepsis

Temporal capillary perfusion patterns in single alveolar walls of intact dogs

Aspirin-triggered 15-epi-lipoxin A4 regulates neutrophil-platelet aggregation and attenuates acute lung injury in mice

Sites of leukocyte sequestration in the pulmonary microcirculation

CXCR4 identifies transitional bone marrow premonocytes that replenish the mature monocyte pool for peripheral responses

Contribution of selectins to leucocyte sequestration in pulmonary microvessels by intravital microscopy in rabbits

Lung vaso-occlusion in sickle cell disease mediated by arteriolar neutrophil-platelet microemboli

Leukocyte margination in alveolar capillaries: interrelationship with functional capillary geometry and microhemodynamics

Neutrophils disturb pulmonary microcirculation in sepsis-induced acute lung injury

Platelet kinetics in the pulmonary microcirculation in vivo assessed by intravital microscopy

Pulmonary microvascular changes during sepsis: evaluation using intravital videomicroscopy

Intravital microscopic observations of 15-microm microspheres lodging in the pulmonary microcirculation

Intravital imaging of a pulmonary endothelial surface layer in a murine sepsis model

In vivo measurement of the mouse pulmonary endothelial surface layer

Real-time assessment of inflammation and treatment response in a mouse model of allergic airway inflammation

Direct visualisation of microparticles in the living lung

Spatiotemporally separated antigen uptake by alveolar dendritic cells and airway presentation to T cells in the lung

Two-photon intravital imaging of lungs during anthrax infection reveals long-lasting macrophage-dendritic cell contacts

Intravital imaging allows real-time characterization of tissue resident eosinophils

Quantitative intravital two-photon excitation microscopy reveals absence of pulmonary vaso-occlusion in unchallenged sickle cell disease mice

Initial host response to bacteria in the murine lung differs between Pseudomonas aeruginosa, Staphylococcus aureus and Streptococcus pneumoniae

iNKT cell emigration out of the lung vasculature requires neutrophils and monocyte-derived dendritic cells in inflammation

A new model for the study of pulmonary microcirculation: determination of pulmonary edema in rats

The lung is a host defense niche for immediate neutrophil-mediated vascular protection

An experimental rat model for studying pulmonary microcirculation by in vivo videomicroscopy

Bispecific antibody targets multiple Pseudomonas aeruginosa evasion mechanisms in the lung vasculature

Alveolar dynamics in acute lung injury: heterogeneous distension rather than cyclic opening and collapse

Maladaptive role of neutrophil extracellular traps in pathogen-induced lung injury

Leukotriene B4-mediated neutrophil recruitment causes pulmonary capillaritis during lethal fungal sepsis

α-Toxin induces platelet aggregation and liver injury during Staphylococcus aureus sepsis

Neutrophil mobilization via plerixafor-mediated CXCR4 inhibition arises from lung demargination and blockade of neutrophil homing to the bone marrow

Transfusion of human platelets treated with mirasol pathogen reduction technology does not induce acute lung injury in mice

A new model of lung metastasis for intravital studies

Visualizing the function and fate of neutrophils in sterile injury and repair

In vivo subcellular resolution optical imaging in the lung reveals early metastatic proliferation and motility

Two distinct interstitial macrophage populations coexist across tissues in specific subtissular niches

Patrolling monocytes control tumor metastasis to the lung

Pulmonary environmental cues drive group 2 innate lymphoid cell dynamics in mice and humans

Long-term high-resolution intravital microscopy in the lung with a vacuum stabilized imaging window

Cancer cells induce metastasis-supporting neutrophil extracellular DNA traps

A permanent window for the murine lung enables high-resolution imaging of cancer metastasis

Embryonic stem cells and mice expressing different GFP variants for multiple non-invasive reporter usage within a single animal

Cre reporter strains produced by targeted insertion of EYFP and ECFP into the ROSA26 locus

A global double-fluorescent Cre reporter mouse

In vivo depletion of CD11c + dendritic cells abrogates priming of CD8 + T cells by exogenous cell-associated antigens

Notch-RBP-J signaling controls the homeostasis of CD8 -dendritic cells in the spleen

Zbtb46 expression distinguishes classical dendritic cells and their committed progenitors from other immune lineages

Absence of MHC class II on cDCs results in microbial-dependent intestinal inflammation

Identification of a dendritic cell receptor that couples sensing of necrosis to immunity

A macrophage colony-stimulating factor receptor-green fluorescent protein transgene is expressed throughout the mononuclear phagocyte system of the mouse

Analysis of fractalkine receptor CX(3)CR1 function by targeted deletion and green fluorescent protein reporter gene insertion

Fate mapping reveals origins and dynamics of monocytes and tissue macrophages under homeostasis

Generation of CD4CreER(T(2)) transgenic mice to study development of peripheral CD4-T-cells

Notch2 integrates signaling by the transcription factors RBP-J and CREB1 to promote T cell cytotoxicity

B lymphocyte-specific, Cre-mediated mutagenesis in mice

Genetic analysis of basophil function in vivo

Lethal influenza infection in the absence of the natural killer cell receptor gene Ncr1

High-efficiency type II cell-enhanced green fluorescent protein expression facilitates cellular identification, tracking, and isolation

Hyperspectral phasor analysis enables multiplexed 5D in vivo imaging

The Orfeo Toolbox remote sensing image processing software

Optimizing imaging parameters for the separation of multiple labels in a fluorescence image

Spectral imaging and linear un-mixing enables improved FRET efficiency with a novel GFP2-YFP FRET pair

Blind source separation techniques for the decomposition of multiply labeled fluorescence images

Image matching as a diffusion process: an analogy with Maxwell's demons

Diffeomorphic demons: efficient non-parametric image registration

Automated motion artifact removal for intravital microscopy, without a priori information

Nonrigid registration using free-form deformations: application to breast MR images

IMART software for correction of motion artifacts in images collected in intravital microscopy

Automated filtering of intrinsic movement artifacts during twophoton intravital microscopy

Removing physiological motion from intravital and clinical functional imaging data

Software tools for single-cell tracking and quantification of cellular and molecular properties

CellProfiler: image analysis software for identifying and quantifying cell phenotypes

Icy: an open bioimage informatics platform for extended reproducible research

Additional information Supplementary information is available for this

Peer review information Nature Protocols thanks Megan MacLeod and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Reprints and permissions information is available at www.nature.com/reprints. Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations

We thank S. Watson for editing the manuscript. We thank K. Iwatsuki-Horimoto, L. Wu, S. Fukuyama, Y. Matsuzawa, and K. Miyake Randomization No randomization is included in this paper since one image has been shown as a representative image by using the imaging protocol.

Blinding was not relevant to this study which is describing a imaging protocol and anticipated results.

We require information from authors about some types of materials, experimental systems and methods used in many studies. Here, indicate whether each material, system or method listed is relevant to your study. If you are not sure if a list item applies to your research, read the appropriate section before selecting a response. 

All antibodies used are commercialized and the fluorescence has been tested in this study. The Information is included in Table 4 . Animals and other organisms Policy information about studies involving animals; ARRIVE guidelines recommended for reporting animal research Laboratory animals Six-ten-week-old C57BL/6 mice (Japan SLC, Inc.) and transgenic mouse lines were used in this study. All animal care and experiments conformed to the guidelines for animal experiments of the University of Tokyo, and were approved by the animal research committee of the University of Tokyo (PA17-31 and PA17-17). All in vivo imaging studies were performed in the biosafety level 3 facility at the University of Tokyo (Tokyo, Japan), which is approved for such use by the Ministry of Agriculture, Forestry, and Fisheries of Japan.

Field-collected samples Not applicable.

All experiments with mice were performed in accordance with the University of Tokyo's Regulations for Animal Care and Use and were approved by the Animal Experiment Committee of the Institute of Medical Science, the University of Tokyo.Note that full information on the approval of the study protocol must also be provided in the manuscript.