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临界条件在免疫染色豌豆蚜虫胚胎鉴定:增加组织通透性和降低背景染色

Published: February 02, 2016
doi:

Özet

A protocol of whole-mount immunostaining on aphid embryos is presented, in which critical conditions for decreasing background staining and increasing tissue permeability are addressed. These conditions are specifically developed for effective detection of protein expression in the embryonic tissues of aphids.

Abstract

在豌豆蚜蚜豌豆 ,用基因组测序和丰富的可塑性,已成为一个新兴的模式,基因组和发育研究。像其他蚜虫,A。通过豌豆孤雌胎生繁殖,其中的胚胎在流水作业的方式,在卵巢管内的卵商会发展迅速传播。此前我们已经建立了全安装了一个强大的平台, 原位杂交技术 ,允许在蚜虫胚胎检测mRNA的表达。分析蛋白质的表达,但是,建立的方案进行免疫染色的无性胎生蚜虫的卵巢管没有产生令人满意的结果。这里,我们报告用于增加组织渗透性和减少的背景染色,这两者都施加既定方法时一些问题的优化条件。优化包括:(1)温育的蛋白酶K(1微克/毫升,10分钟),发现其中必不可少˚F在中期和后期蚜虫胚胎或抗体的渗透; (2)替代正常山羊血清/牛血清白蛋白与由地高辛(DIG)供给的封闭试剂的基于缓冲设置和(3)应用的甲醇,而过氧化氢​​(H 2 O 2)的漂白内源性过氧化物酶;其中显著减少了背景染色的蚜虫组织。对于免疫优化这些关键条件,将允许有效的检测基因产物中一个, 豌豆等蚜虫胚胎。

Introduction

蚜虫是半翅目昆虫的小(1-10毫米)的软组织。它们以植物为食吸吮韧皮部汁液用口器刺入。此外,他们依靠专性共生细菌,Buchnera aphidicola,合成的必需氨基酸有缺陷的韧皮部汁液饮食。蚜虫有一个复杂的生活史包括春季和夏季长日照光周期和性卵生复制由短日照的光周期期间,他们躺在越冬卵1,2-有限数量的触发期间孤雌胎生再现。春天,这些卵孵化,生产的第一代全女性蚜虫(fundatrices),继多轮孤雌生殖,直到秋天。周期性孤雌生殖蚜虫,凡在每年的生命周期的无性和有性阶段的交替,已被视为一种进化新奇1,2。在孤雌胎生蚜,胚胎发生在卵巢小管(卵巢管)蛋室的地方。相比之下,性卵生胚胎发育的受精卵。除了生殖可塑性,蚜虫可以显示跨代翼多型:针对拥挤信号和捕食者的威胁,在unwinged无性女性可以viviparously产生翼的后代进行远距离迁移。出版豌豆蚜虫的基因组序列的豌豆蚜 -the的第一基因组序列基底hemimetabolous昆虫可以进一步探索生殖可塑性,翼多型,以及其他功能,包括昆虫与植物相互作用,病毒引导和共生的蚜虫在分子的依据3。

除了 ​​基因组测序,需要用于促进豌豆蚜作为一个成熟的模式生物4用于表征基因表达和功能的工具。我们已经描述了整个底座的可靠的协议<em>在用于蚜虫胚胎5-7检测mRNA的表达原位杂交。通过双链RNA注射和摄食RNA干扰(RNAi)已被用于在蚜虫若虫和成虫的基因沉默,但对于基因抑制在胚胎稳定的条件还没有被报道8-10。免疫染色,可以检测蛋白表达的样品和RNAi敲低后,已对豌豆蚜胚胎11月13日被执行之前的抗体为基础的方法。然而,组织渗透性和消除背景染色增加是因为效果不够理想使用标准协议的免疫染色豌豆蚜虫的无性胎生胚胎。例如,我们发现,组织该抗体的渗透在gastrulating胚胎降低(阶段8-10)和胚胎形态学识别肢芽(阶段13-14)是勉强可渗透抗体。此外,背景染色是可视化的无性viviparo我们豌豆蚜胚胎使用抗体对种系标记分子Vasa以及,对表示在胚胎段12,13的ENGRAILED / Invected蛋白染色。实际上背景染色还在胚胎染色单独用二抗清晰可见。

为了提高导磁率,而不会损坏蚜组织完整性,我们仔细滴定蛋白酶K的浓度,并确定为对蚜虫的胚胎组织消化的最佳条件。为了避免在豌豆蚜非特异性染色,我们搜​​寻了的化合物,可以有效地阻止胚胎和抑制内源过氧化物酶(POD)的活性,用于免疫染色过程中放大信号的酶。通过地高辛(DIG)系缓冲器集提供的,而在传统上使用的正常山羊血清(NGS)甲封闭试剂/牛血清白蛋白(BSA),显著降低背景染色。此外,甲醇,发现INHI更有效地咬了内源性过氧化物酶活性比过氧化氢 ​​(H 2 O 2)。关于这些蚜虫特定条件免疫染色对胚胎的细节将在下面的章节进行说明。

Protocol

蚜虫1.文化注:孤雌胎生豌豆蚜A的实验室株豌豆最初收集在中央台和在长日照的光周期已经饲养的寄主植物(花园豌豆豌豆或蚕豆蚕豆 )超过300代(一代:〜10天)。 种子发芽浸泡寄主植物的种子在自来水中3-5天在RT。加注新水,每天一次。 注:另外,把寄主植物的种子直接进入潮湿的土壤中可诱发发芽为好。 增长10发芽的种子在小火锅?…

Representative Results

在这项研究中,我们进行的无性豌豆蚜虫( 图1A)的胚胎全安装免疫。这些女性产生后代孤雌及viviparously。这些女性胚胎内的卵巢小管(卵巢管)( 图1B和 图2A)的蛋商会发展。显微镜之前,​​解剖卵巢管是染色的目标;然而,需要用显微镜(图2B – D)的下观察胚胎的卵腔室分离。 <p class="jove_content" fo:kee…

Discussion

我们确定了最佳条件,以成功的免疫染色豌豆蚜虫的一个关键豌豆 ,一个新兴的模式生物基因组和发育研究3,15。用于增加组织渗透性和减少的背景染色优化条件下增强的强度和信号的特异性。他们从标准协议有所不同免疫染色在其他动物模型中的步骤创建于细胞膜毛孔和阻断非特异性抗体结合。

用于免疫染色原位杂交,蛋白酶K(PK)消化?…

Açıklamalar

The authors have nothing to disclose.

Acknowledgements

We are grateful to Chau-Ti Ting (Fly Core in Taiwan) for providing the monoclonal 4D9 antibody, Technology Commons (TechComm) of the College of Life Science NTU for confocal microscopy, Hsiao-Ling Lu for proofreading the manuscript, and Chen-yo Chung for helping filming. CC particularly thanks Charles E. Cook for providing strategic suggestions and for critical editing of the manuscript. This work was supported by the Ministry of Science and Technology (101-2313-B-002-059-MY3 and 104-2313-B-002-022-MY3 for GWL and CC), and the National Taiwan University (NTU-CESRP 101R4602D3 for CC; 103R4000 for GWL).

Materials

30% hydrogen perxidase (H₂O₂) Sigma-Aldrich 18304 For bleaching endogenous peroxidase of embryos.
4’6-diamidino-2-phenyl-indole dihydrochloride (DAPI) Sigma-Aldrich D9542 For labeling the double-strand DNA. TOXIC. Wear gloves, dispense into small aliquots and feeze to minimize exposure
4D9 anti-engrailed/invected mouse monoclonal antibody Developmental studies hybridoma bank AB_528224 For labeling the developing segments of embryo.
ApVas1 rabbit polyclonal antibody Our laboratory N/A For labeling the aphid germline specific Vas1 protein in embryos. This antibody was made by our laboratory. 
Austerlitz Insect pins ENTOMORAVIA N/A For seperating each egg chambers from an ovariole. Size 000, BLACK ENAMELLED. 
Bovine serum albumin (BSA) Sigma-Aldrich 9048-46-8 For blocking the non-specific binding of antibodies.
Camera connted to compound microscope Canon EOS 5D For photographing of aphid embryos.
Colorimetric 8 cell tray Kartell Labware 357 For developing the staining signal of aphid embryos. Diameter 95 x 57 mm, cell depth 2 mm.
Compound microscope with DIC optics Leica Microsystems DMR For photographing of aphid embryo mounted on the slides.
DIG Wash and Block Buffer Set Sigma-Aldrich (Roche) 1.1586E+10 For blocking the non-specific binding of antibodies. We diluted the 10X Blocking solution into 1X as blocking reagent.
Forceps Ideal-tek N/A For dissection of ovaries from aphids. Manufacturer part No 5: 5 SA. 
Glass dropper N/A N/A For transfering ovaries of aphids from the splot plate to tubes. 150 mm of total length and 5 3/4" of tip length.
Glycerol Sigma-Aldrich G5516 For clearing of aphid embryos and mounting.
Glycine Bioshop N/A For blocking the enzyme activity of proteinase K (PK).
Goat anti-mouse IgG conjugated Alexa Fluor 488 Invitrogen A11017 For detection of primary antibody from mouse.
Goat anti-rabbit IgG conjugated Alexa Fluor 633 Invitrogen A21072 For detection of primary antibody from rabbit.
Intelli mixer ELMI laboratory equipment RM-2M For improving the thorughly reaction of reagents with ovaries.
Laser-scanning confocal microscopy Leica Microsystems SP5 For photographing of aphid embryo mounted on the slides with florecent tag.
methanol  Burdick and Jackson AH2304 For bleaching endogenous peroxidase of embryos.
Microscope slides  Thermo scientific 10143560 For mounting of embryos. SUPERFROST ground edges, ca./env. 76 x 26 mm.
Microscope Cover glasses Marienfeld 0101030 For mounting embryos on the slides. Size 18 x 18 mm. Thickness No. 1 (0.13 to 0.16 mm)
Microscope Cover glasses Marienfeld 0101050 For mounting embryos on the slides. Size 22 x 22 mm. Thickness No. 1 (0.13 to 0.16 mm)
mouse monoclonal anti-alphaTubulin antibody (DM1A) Santa Cruz Biotechnology sc-32293 For labeling the distrbution of alpha-tubulin of cells.
Nail polish N/A N/A For sealing the coverslips on the slides.
Normal goat serum (NGS) Sigma-Aldrich G9023 For blocking the non-specific binding of antibodies.
Paraformaldehyde (PFA) VWR MK262159 For fixation of aphid ovaries.
Phalloidin-TRITC Sigma-Aldrich P1951 For labeling the distrbution of F-actin on embryos.
Phosphate-buffered saline (PBS) N/A N/A As isotonic solution for aphid ovaries.
Plastic dropper N/A N/A For transfering ovaries of aphids from tube to cell tray. Size 3 ml. 
Proteinase K Merck 124678 For creating pores (punching) on the cell membrane and facilitating the access of antibodies. 
Pyrex spot plate N/A N/A For dissection and color reactions of aphid ovaries under microscopy. Each cavity with diameter 22 mm and  depth 7 mm.
SIGMAFAST 3,3’-diaminobenzidine (DAB) tablets  Sigma-Aldrich D4168 For developing of substrated signals. Also called DAB peroxidase substrate tablet set.
Stereo microscope Leica Microsystems EZ4 For dissection and observation of aphid ovaries.
Triton-X 100 Sigma-Aldrich T8787 For creating pores (punching) on the cell membrane. 
VECTASHIELD Elite ABC Kit (Rabbit IgG) Vector laboratories PK-6101 For enhancement of the signal. Including of biotinylated goat anti-rabbit IgG secondary antibody, A and B reagents.
VECTASHIELD mounting medium Vector laboratories H1000 For clearing of aphid embryos and mounting.

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Lin, G., Chang, C. Identification of Critical Conditions for Immunostaining in the Pea Aphid Embryos: Increasing Tissue Permeability and Decreasing Background Staining. J. Vis. Exp. (108), e53883, doi:10.3791/53883 (2016).

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