실시간으로 개발을 시각화 하기 위해 다중 광자 시간 경과 영상: 마이그레이션 Zebrafish 태아 신경 크레스트 셀의 시각화

요약

레이저 스캐닝 현미경 검사 법 긴 파장 다중 광자 형광 여기의 고급 광학 기술의 조합 안내 (sox10:EGFP)에 안내 (foxd3:GFP) zebrafish 태아 신경 크레스트 마이그레이션의 고해상도, 3 차원, 실시간 영상 캡처 구현 되었습니다.

초록

선 천 성 눈 craniofacial 변칙 중단 신경 크레스트, 몸 전체에 수많은 세포 유형을 철새 줄기 세포의 일시적인 인구에에서 반영 합니다. 신경 크레스트의 생물학 이해 제한, 공부 vivo에서 될 수 있는 유전자 세공 모델의 부족과 실시간으로 반영 되었습니다. Zebrafish는 신경 크레스트 등 철새 세포 인구를 공부에 대 한 특히 중요 한 개발 모델입니다. 개발 눈에 신경 크레스트 마이그레이션 검사, 레이저 스캔 현미경 긴 파장 다중 광자 형광 여기의 고급 광학 기술의 조합 같이 sox10 와 foxd3 가 되어 초기 신경 크레스트 차별화 규제 가능성이 신경 크레스트 셀에 대 한 마커를 대표 하는 수많은 동물 모델에서 유전자 변형 zebrafish 태아, 즉 Tg (sox10:EGFP) 및 안내 (foxd3:GFP)에 개발 눈의 고해상도, 3 차원, 실시간 동영상 캡처 구현 되었습니다. 다중 광자 시간 경과 영상 동작 및 초기 눈 개발에 기여 두 신경 크레스트 세포 인구의 철새 패턴 분별 하 사용 되었다. 이 프로토콜 예를 들어, zebrafish 신경 크레스트 마이그레이션 중 시간 경과 비디오를 생성 하기 위한 정보를 제공 하 고 많은 구조는 제 브라와 다른 모델 유기 체에서의 초기 개발을 시각화에 추가 적용할 수 있습니다.

서문

선 천 성 눈 질환 아동 실명을 일으킬 수 있으며 종종 두개골 신경 크레스트의 이상 때문. 신경 크레스트 세포는 신경 관에서 발생 하 고 몸 통하여 수많은 직물을 형성 하는 일시적인 줄기 세포. ^{1 , 2 , 3 , 4 , 5} 신경 크레스트 셀, prosencephalon 및 mesencephalon에서 파생 된 게 상승 뼈와 연골은 midface 정면 지역, 그리고 홍 채, 각 막, 배수 채널 및 sclera 눈의 앞쪽 세그먼트에서. ^{4 , 6 , 7 ,} Rhombencephalon 형태는 인 두 아치, 턱, 그리고 심장 유출 관에서 ⁸ 신경 크레스트 셀. ^{1 , 3 , 4 , 9 , 10} 연구 강조 했습니다 눈을 신경 크레스트의 기여 및 periocular 개발, 척 추가 있는 눈 개발에 이러한 세포의 중요성을 강조. 실제로, Axenfeld Rieger 증후군과 피터 스 플러스 증후군에서 관찰 신경 크레스트 셀 마이그레이션 및 분화의 방해는 craniofacial 눈 변칙와 이어질. ^{11 , 12 , 13 , 14 , 15 , 16 , 17} 따라서, 마이그레이션, 확산 및이 신경 크레스트 세포의 분화에 대 한 포괄적인 이해 선 천 성 눈 질환을 기본 복잡성에 대 한 통찰력을 제공할 것입니다.

Zebrafish는 zebrafish 눈의 구조는과 유사 하 포유류 들 그리고 많은 유전자는 제 브라와 포유류 사이의 보존 진화론으로 눈 개발 공부에 대 한 강력한 모델 생물 이다. ^{18 , 19 , 20} 또한, zebrafish 태아는 투명 하 고 oviparous, 실시간으로 눈 개발의 시각화를 촉진.

이전에 게시 작업에 확대,^6,,720 신경 크레스트 셀의 철새 패턴 사용 하 여 다중 광자 형광 이미징 SRY (섹스 결정 지역 Y)의 transcriptional 통제 녹색 형광 단백질 (GFP)으로 표시 하는 유전자 변형 zebrafish 선에 시간 경과 설명 했다-상자 10 (sox10) 또는 Forkhead 상자 D3 (foxd3) 유전자 규제 지역. ^{21 , 22 , 23 , 24}. 다중 광자 형광 시간 경과 영상 레이저 스캐닝 현미경 표본 fluorophores 태그로의 고해상도, 3 차원 이미지를 긴 파장 다중 광자 형광 여기의 고급 광학 기술을 결합 하는 강력한 기술입니다. ^{25 , 26 , 27} 다중 광자 레이저를 사용 하 여 표준 confocal 현미경 검사 법, 증가 조직의 침투 및 감소 fluorophore 표백 등 뚜렷한 장점이 있다.

이 메서드를 사용 하 여 마이그레이션 및 철새 통로의 타이밍에 다양 한 신경 크레스트 세포의 두 가지 인구 periocular mesenchyme 개발 눈에 차별, 즉 foxd3 양성 신경 크레스트 세포와 craniofacial mesenchyme sox10 양성 신경 크레스트 셀을 했다. 이 방법으로 zebrafish에 눈와 craniofacial 신경 크레스트 마이그레이션 마이그레이션 시각화 하는 방법을 도입, 개발 하는 동안 실시간으로 레 귤 레이트 된 신경 크레스트 마이그레이션 관찰 하기 쉽게.

이 프로토콜 Tg (sox10:EGFP)에 안내 (foxd3:GFP) 유전자 변형 zebrafish, 예를 들어 초기 눈 개발 하는 동안 시간 경과 비디오를 생성 하기 위한 정보를 제공 합니다. 이 프로토콜 zebrafish에 신경 크레스트 셀에서 파생 된 어떤 눈와 craniofacial 구조의 초기 개발의 고해상도, 3 차원, 실시간 시각화를 위한 추가로 적용할 수 있습니다. 또한,이 방법은 다른 조직 및 장기 제 브라와 다른 동물 모델의 개발의 시각화에 대 한 추가 적용할 수 있습니다.

프로토콜

The protocol described here was performed in accordance with the guidelines for the humane treatment of laboratory animals established by the University of Michigan Committee on the Use and Care of Animals (UCUCA).

1. Embryo Collection for Time-lapse Imaging

1. Between 3 and 9 pm, set up male and female adult Tg(sox10:EGFP) or Tg(foxd3:GFP) transgenic zebrafish in a divided breeding tank for pairwise mating.
   NOTE: The Tg(sox10:EGFP) and Tg(foxd3:GFP) fish, kind gifts from Thomas Schilling and Mary Halloran, respectively, were crossed into the Casper (roy -/-, nacre -/-) background to decrease auto-fluorescence and interference with pigmentation.
   1. Assemble the breeding tank (slotted inner tank + solid outer tank) and fill it with reverse osmosis (RO) system water.
   2. Transfer up to 3 females and 3 males into opposing sides of the tank separated by a divider; up to 6 fish can be bred pairwise in a single breeding tank.
   3. The next morning, remove the divider shortly after the lights turn on in the vivarium.
      NOTE: In the present study, the lights are on a 14-hour light (on at 9 am) and 10-hour dark (off at 11 pm) cycle.
   4. Allow undisturbed mating for 20 min or until sufficient numbers of embryos are produced; the embryos will be at the bottom of the breeding tank. When eggs are observed, lift the slotted inner tank out along with the fish and quickly place them (fish and inner tank) into a clean solid outer tank filled with RO water.
2. Prepare standard 1X embryo medium by adding the following per 1 L of RO water: 0.287 g (4.9 mM) NaCl, 0.127 g (0.17 mM) KCl, 0.048 g (0.33 mM) CaCl₂.2H₂O, 0.04 g (0.33 mM) MgSO₄ (anhydrous). Stir solution until the salts are completely dissolved.
   1. Add 100 µL of 0.1% methylene blue as a fungicide. Add 0.25 g of sodium bicarbonate to adjust the pH to 7.75. Store medium at room temperature.
3. Collect eggs from the outer tank using an egg-collecting screen, and transfer the eggs to Petri dishes (~50 embryos per dish) containing 30 mL of 1X embryo medium. Incubate the collected eggs at 28.5 °C.
4. Embryo preparation
   1. Tg(sox10:EGFP) embryos.
      1. For Tg(sox10:EGFP) embryos, at 12 h post-fertilization (hpf), remove the dead eggs and assess the developmental stage of the embryos. Screen for GFP-positive embryos using a dissecting fluorescent stereomicroscope with a standard 460-490 nm band-pass excitation filter. Using forceps, remove the chorions from 3-4 embryos that express GFP, and transfer these embryos to a separate Petri dish containing 30 mL of fresh 1X embryo medium.
   2. Tg(foxd3:GFP) embryos.
      1. For Tg(foxd3:GFP) embryos, at 22-24 hpf, remove the dead eggs and assess the developmental stage of the embryos. Screen for positive embryos using a dissecting fluorescent stereomicroscope with a standard 460-490 nm band-pass excitation filter. Using forceps, remove the chorions from 3-4 embryos that express GFP.
      2. Prepare 1000X Phenylthiourea (PTU) stock solution by dissolving 0.75 g (3%) of PTU in 25 mL of Dimethylsulfoxide (DMSO). Aliquot and store the stock solution at 4 °C. Add 30 µL of 1000X PTU (3%) stock solution to 30 mL of 1X embryo medium to generate 0.003% PTU solution.
      3. Place the screened and dechorionated GFP-positive embryos in 0.003% PTU solution to inhibit pigmentation. Do not initiate treatment of the embryos with PTU prior to 20 hpf, as early treatment (at <20 hpf) can have adverse effects on neural crest and neuroepithelial development.²⁸
   3. Prior to conducting the time-lapse experiment, monitor the embryos through live imaging using a standard stereomicroscope at 12-24 h intervals in age-matched comparisons as a control for temperature drift.

2. Mounting of Embryo for Time-lapse Imaging

1. Preparation of time-lapse embryo media
   1. Prepare standard 0.4% tricaine stock solution by adding 0.004 g of tricaine to 100 mL of RO water. Aliquot (~1 mL) the stock solution into fresh 1.5-mL centrifuge tubes and store at -20 °C.
   2. Prepare time-lapse embryo medium (50 mL of 1X embryo medium, 0.016% tricaine) by adding 2 mL of 0.4% tricaine solution to 48 mL of 1X embryo medium. If using embryos >22 hpf, then also add 50 µL of 3% PTU stock solution (final concentration.003% PTU) to the embryo medium.
2. Preparation of 2% low-melt agarose
   1. Add 0.4 g of low-melt agarose powder to 20 mL of 1X embryo medium. Heat for 1-2 min or until the solution is clear and all particles are dissolved.
      NOTE: Increasing the percentage of the agarose gel decreases the porosity of the matrix, which may physically impede the growth and development of the embryo. Therefore, the agarose solution can be lowered to 1.5% to minimize these effects. However, when the excitation beam is held stationary during laser-scanning microscopy, greater heating can occur, increasing rapidly in a logarithmic relationship with time. In this protocol, heating due to fluorophore absorption is highly localized to the focal region. Thus, in the region of interest, the temperature could increase to a value high enough (≥ 30 °C) to melt agarose solutions made at percentages lower than 1.5, thereby directly exposing the embryo to the laser or enabling conditions in which the embryo floats out of the focal plane. For this reason, the use of agarose solutions lower than 1.5% is not recommended.
   2. Aliquot (~1 mL) the agarose solution into fresh 1.5-mL centrifuge tubes for storage. Store excess agarose solution in liquid form on a heat block (60-70 °C) for 2-3 weeks.
3. Mounting the Embryo
   1. To set up the open bath chamber, place a small amount of high vacuum grease on the base of the open bath chamber. Place a circular glass coverslip onto the base and screw the top of the open bath chamber onto the base until tight ( Figure 1A, B).
   2. Pipet (~500-700 µL) of 2% agarose solution (60-70 °C) into the open bath chamber until the base is ~3/4 filled ( Figure 1C). Note that once the agarose solution is in the open bath chamber on the lab bench, the temperature of the solution decreases approximately 1 °C/s.
   3. Wait 30 s to allow the agarose to cool slightly (~30-40 °C), without completely polymerizing, and subsequently transfer a single embryo to the center of the base ( Figure 1D, E).
   4. Under a fluorescent stereomicroscope, position the embryo using a 1-10 µL micropipette tip, making sure that the embryo is placed near the bottom of the agarose, as the embryo may float away when covered with embryo media if it is placed too near the surface of the agarose.
      NOTE: In the presented videos (Videos 1-3), the embryos are oriented laterally, but depending on the area of interest, the embryos can be oriented ventrally or dorsally.
   5. Monitor and reposition the embryo until the agarose has set. Once the agarose has set, use a transfer pipet to fill the assembled open chamber entirely with time-lapse embryo media ( Figure 1F).
   6. Place the open bath chamber in the quick exchange platform, which fits onto the stage adapter ( Figure 1G). Place the entire setup (embryo, open bath chamber, quick exchange platform and stage adaptor) onto the stage of the microscope immediately above the condenser ( Figure 1H).

3. Microscope Set-up for Time-lapse Imaging

1. Determining laser settings
   1. Determining laser wavelength to use. Use a wavelength that is twice the excitation wavelength of the fluorophore of interest (e.g. wavelength between 880 and 940 nm for GFP).
      NOTE: In the present study, the wavelength setting for GFP was between 880 and 940 nm. The higher the wavelength, the lower the output power of the laser.
   2. Determine laser transmission. A high percent of laser transmission will kill the embryo, use the lowest level of transmission (recommended). For 24 to 48 h time-lapse studies, as presented herein, keep transmission below 5%.
   3. Determine microscope detection systems and ensure that the correct filters for the fluorophore are in place.
      NOTE: For multi-photon microscopes, there are multiple detection systems with various sensitivities for the emitted fluorescence. In general, an internal detection system has less sensitivity than an external detection system. For transgenic lines with high levels of GFP expression, the internal detection system is adequate. For transgenic lines with low levels of GFP expression or with other fluorophores (e.g., red fluorescent protein), an external detection system may be required to maintain the percent of laser transmission at a reasonable level. Regardless the detection system used, the correct filters for the fluorophore must be in place.
2. Adjusting software settings on the multi-photon microscope
   1. Using the 5X objective, locate the embryo. Manually raise the stage to the highest position, and use the fine focus to position the embryo in the middle of the microscope range.
   2. Manually lower the stage, and change the 5X objective to the 25X water immersion objective (numerical aperture NA, 0.95). Carefully raise the stage to bring the embryo back into focus.
   3. In the software, click on the "xyzt" mode for obtaining multiple images at time intervals (t) in the x-y plane over a depth of "z". Use the epifluorescence or brightfield view to find the depth of focus in the area of interest, which will demarcate the Z-stack.
      1. In the software, click on "begin" button; for these experiments, the lateral edge of the eye was the beginning of the Z-stack. Click on "end" button; the midline of the embryo was the end of the Z-stack.
         NOTE: The step size was 0.3-0.6 µm and there was a total of ~200 steps for a z-stack size of 60 to 120 µm).
   4. Click on the menu for adjusting acquisition time and imaging frequency. For the present system, ~200 steps requires approximately 5 min for each z-stack acquisition. For adequate recovery of the fluorophore and survival of the embryo, allow for a ratio of at least 1:3 between z-stack acquisition (laser power on) and recovery time (laser power off).
      NOTE: For example, z-stacks are acquired every 20 min with 5 min of z-stack acquisition and 15 min of recovery. For this protocol, larger z-stacks can be obtained, but would appropriately increase the time between z-stack acquisitions, resulting in fewer images over the time-lapse course.
      1. With appropriate time for embryo recovery, set the time between z-stacks in the designated window. Set the total length of time for the experiment in the appropriate window.
   5. Final software, laser, and embryo adjustments.
      1. Turn on the live image setting to make final adjustments to the laser settings. Adjust laser transmission (see 3.1.2), gain and offset slider bars within the software to optimize the fluorescent image. Also, adjust the orientation of the embryo, as needed, depending on the length of the experiment, anticipated growth of the embryo, etc. Make sure that the area of interest remains within the frame through the duration of the experiment.
      2. Turn off the epifluorescent light source as it is no longer needed during time-lapse acquisition. Cover the stage with the laser safety box ( Figure 1I). When using the internal detection system, the laser safety box is adequate for protection against background light. Press "start".
         NOTE: However, with more sensitive external detection systems, the laser safety box does not block enough background light, and additional covers are required to prevent the disruption of image acquisition.

4. During Time-lapse Acquisition

1. Refill the open bath chamber with time-lapse embryo media every 8-12 h (at least 2 times per day) during time-lapse acquisition through the sliding doors on the laser safety box ( Figure 1I).
2. Before opening the doors of the laser safety box, ensure that the microscope is not actively acquiring an image.
   NOTE: The use of heaters and circulating media systems is not necessary for time-lapse imaging experiments lasting 24 to 48 h. Indeed, the temperatures of both stage and in-line heaters are difficult to control, and during image acquisition the embryo exhibits an adequate development rate at a temperature range from 25-28 °C. Moreover, circulating media systems tend to overflow and potentially damage the equipment. Thus, all embryos are routinely staged post-acquisition.

5. Post-acquisition processing

1. In the software, click on the "file" menu and choose "save".
2. Open the file in image processing software (see the Table of Materials). Highlight the correct image series. In the software, choose the "Process" menu. Click on 3D Deconvolution and "Apply" to deconvolve each z-stack.
   NOTE: The file is large; therefore, this step may take many hours.
3. In the software, under the "Process" menu, click on "maximum projection." Click on "Apply" to initiate maximum projection to generate 1 image per z-stack. Export each maximum projected file (1 image per z-stack) as a tiff.
4. Import individual tiff files into video processing software. Select all tiff files and drag them into the video editor. Adjust length of each image within the video to 0.1s. Export video as mov or mp4 file.

결과

다중 광자 형광 시간 경과 영상 생성을 야기할 craniofacial 구조 및 안내 (sox10:EGFP)에 안내 (foxd3:GFP) 눈의 앞쪽 세그먼트 zebrafish 라인 두개골 신경 크레스트 셀의 마이그레이션 패턴을 공개 동영상 일련의. 예를 들어, sox10-긍정적인 신경 크레스트 셀 12와 30 hpf 사이 craniofacial 지역 (비디오 1, 그림 2)에 신경 튜브의 가장자?...

토론

다중 광자 시간 경과 영상 과도 하 고 철새 세포 인구의 비보에 추적을 수 있습니다. 이 강력한 기술은 실시간으로 미 발달 과정을 공부 하 사용할 수 있습니다 그리고 현재 연구에이 방법의 결과 신경 크레스트 셀 마이그레이션 및 개발의 현재 지식 향상. 이전 시간 경과 이미징 연구는 일반적으로 confocal 레이저 스캐닝 현미경 검사 법을 이용 한다. ^{29 ,}

자료

Name	Company	Catalog Number	Comments
Breeding Tanks with Dividers	Aquaneering	ZHCT100	Crossing Tank Set (1.0-liter) Clear Polycarbonate with Lid and Insert
M205 FA Combi-Scope	Leica Microsystems CMS GmbH		Stereofluorescence Microscope - FusionOptics and TripleBeam
Sodium Chloride	Millipore (EMD)	7760-5KG	Double PE sack. CAS No. 7647-14-5, EC Number 231-598-3
Potassium Chloride	Millipore (EMD)	1049380500	Potassium chloride 99.999 Suprapur. CAS No. 7447-40-7, EC Number 231-211-8.
Calcium Chloride Dihydrate	Fisher Scientific	C79-500	Poly bottle; 500 g. CAS No. 10035-04-8
Magnesium Sulfate (Anhydrous)	Millipore (EMD)	MX0075-1	Poly bottle; 500 g. CAS No. 7487-88-9, EC Number 231-298-2
Methylene Blue	Millipore (EMD)	284-12	Glass bottle; 25 g. Powder, Certified Biological Stain
Sodium Bicarbonate	Millipore (EMD)	SX0320-1	Poly bottle; 500 g. Powder, GR ACS. CAS No. 144-55-8, EC Number 205-633-8
N-Phenylthiourea	Sigma	P7629-25G	>98%. CAS Number 103-85-5, EC Number 203-151-2
Dimethylsulfoxide	Sigma	D8418-500ML	Molecular Biology grade. CAS Number 67-68-5, EC Number 200-664-3
Tricaine Methanesulfonate	Western Chemical Inc.	MS222	Tricaine-S
Low-Melt Agarose	ISC Bioexpress	E-3112-25	GeneMate Sieve GQA Low Melt Agarose, 25 g
Open Bath Chamber	Warner Instruments	RC-40HP	High Profile
Glass Coverslips	Fisher Scientific	12-545-102	Circle cover glass. 25 mm diameter
High Vacuum Grease	Fisher Scientific	14-635-5C	2.0-lb. tube. DOW CORNING CORPORATION 1658832
Quick Exchange Platform	Warner Instruments	QE-1	35 mm
Stage Adapter	Warner Instruments	SA-20LZ-AL	16.5 x 10 cm
TC SP5 MP multi-photon microscope	Leica Microsystems CMS GmbH
Mai Tai DeepSee Ti-Sapphire Laser	SpectraPhysics
Laser Safety Box	Leica Microsystems CMS GmbH
Leica Application Suite X (LAS X)  Software	Leica Microsystems CMS GmbH
Photoshop CS 6 Version 13.0 x64 Software	Adobe
iMovie Version 10.1.4 Software	Apple