What s left in asymmetry Michael Levin Research Paper Summary

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Introduction (What is this Protocol About?)

This protocol explains how to reduce or “knockdown” a gene’s activity in planarians using RNA interference (RNAi).

Planarians are flatworms commonly used to study regeneration (the process of regrowing lost body parts) and tissue maintenance.

By injecting lab-made double-stranded RNA (dsRNA) into the planarian, scientists can lower the expression of a specific gene and observe resulting changes, called phenotypes.

This method helps researchers understand the role of different genes during regeneration.

Related Background Information

The technique was originally described by Sánchez Alvarado and Newmark in 1999.

Planarians serve as a powerful model system for studies on regeneration, adult stem cell regulation, aging, and behavior.

Other protocols related to planarians include methods for maintaining colonies and imaging their membrane potential.

Key Terms and Concepts

RNA interference (RNAi): A method used to reduce or silence the expression of a specific gene.

Double-stranded RNA (dsRNA): Two complementary strands of RNA that, when introduced into an organism, trigger RNAi.

Phenotype: The observable traits or changes in an organism that result from a change in gene activity.

Microinjection: A technique for delivering small volumes of liquid into an organism using a very fine needle.

In vitro: Procedures performed in a controlled laboratory environment outside a living organism.

Step-by-Step Method: RNA Synthesis

Prepare two separate transcription reactions using enzymes:

One reaction uses T3 polymerase and the other uses T7 polymerase.

Each reaction includes: DNA template (1 μg), DTT (10 mM), ribonucleotides (1%), RNA transcription buffer (20%), RNasin (60 units), and the respective polymerase (17 units).

If using a vector with two T7 promoters, a single T7 reaction may be used after linearizing the DNA.

Incubate both reactions at 37°C for 2 hours to synthesize RNA.

Add DNase I (1 unit) to each reaction and incubate at 37°C for 15 minutes to remove the DNA template.

Reserve 1 μL from each reaction in separate tubes and store at -20°C for later comparison.

Combine the remaining 19 μL from each reaction into one tube.

Add 360 μL of RNAi Solution A to the combined reaction and let it sit at room temperature for 10 minutes.

Add 200 μL of a phenol:chloroform mixture and vortex vigorously to mix.

Centrifuge at 14,000 rpm for 2 minutes at room temperature and transfer the clear aqueous phase to a new tube.

Add 200 μL of chloroform, vortex again, and centrifuge at 14,000 rpm for 2 minutes; transfer the new aqueous phase to another fresh tube.

Heat the tube in a water bath at 68°C for 10 minutes to denature (unfold) the RNA, then incubate at 37°C for 30 minutes to allow the RNA strands to reanneal and form dsRNA.

Add 1 mL of cold 100% ethanol and centrifuge at 14,000 rpm for 15 minutes at 4°C to precipitate the RNA.

Discard the supernatant and wash the RNA pellet with 1 mL of cold 80% ethanol; centrifuge at 14,000 rpm for 10 minutes at 4°C.

Discard the wash solution and resuspend the RNA pellet in 10 μL of nuclease-free water; keep the sample on ice.

Verify RNA quality and confirm dsRNA formation by running a small amount on a 1% agarose gel under non-denaturing conditions.

Step-by-Step Method: Microinjection of dsRNA

Prepare the microinjection needle:

Use a micropipette puller to form a long, thin needle.

Break the tip slightly under a dissecting microscope so that about 10%-25% of the tip is removed; the opening should be small enough to prevent unwanted leakage.

Fill the needle with mineral oil, ensuring that no air bubbles are present.

Attach the needle to the microinjector and adjust its position under a dissecting microscope:

Set the microinjector to deliver 32 nanoliters (nL) per pulse.

Aspirate 1–2 μL of the dsRNA solution into the needle.

Place the planarian on cold, wet tissue (placing ice underneath helps keep it cool and still).

Carefully insert the needle into the planarian, typically near the prepharyngeal area (just in front of the mouth), to ensure the needle tip enters the body.

Press the injection key to dispense 32 nL; repeat this 3 to 5 times so that the worm’s gastrovascular system fills with the dsRNA solution, confirming successful injection.

Transfer the injected planarian to a Petri dish containing fresh planarian water at room temperature.

For a stronger gene knockdown effect, repeat the injection process over consecutive days or weeks.

Troubleshooting Common Problems

If RNA (ssRNA or dsRNA) is not visible on the agarose gel:

Check that all reagents are fresh and have not been repeatedly frozen and thawed.

Ensure the DNA template includes both T3 and T7 promoter regions.

Work on clean surfaces free from RNase and DNase contamination.

If no liquid is dispensed from the needle during injection:

Examine the needle for air bubbles.

Ensure the needle is securely attached to the microinjector.

If you are uncertain whether the injected liquid is entering the planarian:

Practice the injection technique; adding a small amount of food coloring to the injection solution can help visualize the process.

If no observable phenotype is produced:

Check the gene knockdown by methods such as in situ hybridization or RT-PCR to confirm reduced gene expression.

Consider adjusting the injection schedule or targeting two genes that may compensate for each other.

Materials and Equipment

Reagents:

1% agarose gel, DNA template (with T3 and T7 promoters), DNase I, DTT, ribonucleotides, RNA transcription buffer, RNasin, T3 and T7 polymerases, nuclease-free water, phenol:chloroform mix, chloroform, 100% and 80% ethanol, and RNAi Solution A.

Equipment:

Microcentrifuge (with both room temperature and 4°C capability), water baths, vortex mixer, micropipette puller, microinjector, dissecting microscope, Petri dishes, and apparatus for agarose gel electrophoresis.

Planarians (the flatworms) and planarian water for maintaining them.

Acknowledgments and References

The authors acknowledge contributions and funding from organizations such as the NIH, NSF, and others.

For more detailed information, refer to the publications by Oviedo et al. (2008) and Sánchez Alvarado and Newmark (1999).

PRINT CHINESE BIOELECTRICITY GUIDE

Chinese Version: 简介 (研究背景)

本协议描述了如何利用RNA干扰（RNAi）在平片虫中实现基因敲低，即降低某个基因的活性。

平片虫是一种常用于研究再生（失去的部位重新生长）和组织维持的扁形动物。

通过向平片虫注射体外合成的双链RNA（dsRNA），科学家可以降低目标基因的表达，从而观察到由此产生的表型变化。

这种方法有助于研究者理解不同基因在再生过程中的作用。

相关背景信息

该技术最早由 Sánchez Alvarado 和 Newmark (1999) 描述。

平片虫被认为是研究再生、干细胞调控、衰老及行为的重要模型系统。

其他相关协议包括建立平片虫种群及平片虫细胞膜电位的成像方法。

关键术语和概念

RNA干扰 (RNAi)：一种降低或沉默特定基因表达的方法。

双链RNA (dsRNA)：由两条互补RNA链组成的分子，用于触发RNAi反应。

表型：基因活性改变后在生物体上表现出的可观察特征。

微注射：使用极细针头向生物体内注入极少量液体的技术。

体外：在实验室内控制环境中进行的实验操作，而非在生物体内进行。

分步方法：RNA合成

准备两个独立的转录反应体系，分别使用T3和T7聚合酶：

每个反应中加入：DNA模板 (1 μg)、DTT (10 mM)、核糖核苷酸 (1%)、RNA转录缓冲液 (20%)、RNasin (60单位)和相应的聚合酶 (17单位)。

如果使用双T7启动子的载体，可在酶切后只用T7聚合酶分别进行反应。

在37°C水浴中孵育2小时以进行RNA合成。

向每个反应中加入1单位DNase I，并在37°C下孵育15分钟以去除DNA模板。

从每个反应中取出1μL样品，另存备用并置于-20°C。

将剩余的反应混合物合并到一个管中。

加入360μL RNAi专用溶液A，在室温下静置10分钟。

加入200μL酚:氯仿混合物，剧烈震荡混合以提取RNA。

在室温下以14000 rpm离心2分钟，将上层水相转移到新管中。

加入200μL氯仿，震荡混合后以14000 rpm离心2分钟，再次转移上层水相到新管中。

在68°C水浴中加热10分钟使RNA变性，再于37°C水浴中孵育30分钟使RNA重新配对形成双链RNA。

加入1 mL冷却的100%乙醇，在4°C下以14000 rpm离心15分钟以沉淀RNA。

弃去上清液，用1 mL冷80%乙醇洗涤RNA沉淀，再以14000 rpm在4°C离心10分钟。

弃去洗涤液，将RNA沉淀重悬于10μL无RNA酶水中，并置于冰上保存。

通过在1%琼脂糖凝胶上检测1μL ssRNA样品和0.5μL dsRNA样品，确认双链RNA的形成。

分步方法：dsRNA的微注射

准备微注射针：

使用微吸管拉针仪制作细长针头。

在解剖显微镜下观察，轻轻敲碎针尖，去除大约10%-25%的针尖，确保开口足够小以防止液体泄漏。

用矿物油填充针头，确保无气泡。

将针头安装到微注射器上，并在解剖显微镜下调整好位置：

设定每次注射量为32纳升 (nL)。

吸取1-2μL dsRNA溶液（来自RNA合成步骤）。

将平片虫放在冷湿纸巾上（在下面放冰可保持其凉爽和湿润）。

小心将针头插入平片虫，通常选择口前区域，确保针头进入体内。

按下注射键释放32纳升液体，重复3至5次，使平片虫的胃血管系统充满dsRNA溶液，以确认注射成功。

将注射后的平片虫转移到含有新鲜平片虫水的培养皿中，并保持室温。

为增强表型效果，可在连续几天或几周内重复注射。

常见问题及解决方案

若在琼脂糖凝胶上未检测到RNA（ssRNA或dsRNA）：

检查所有试剂是否新鲜，且未反复冻融。

确认DNA模板包含T3和T7启动子区域。

确保在无RNase和DNase污染的环境下操作。

若注射时针头无液体流出：

检查针头内是否存在气泡。

确认针头是否正确安装在微注射器上。

若不确定液体是否进入平片虫体内：

多加练习，可在注射液中加入少量食用色素以便观察。

若未观察到任何表型变化：

通过原位杂交或RT-PCR检测目标基因表达是否降低。

考虑调整注射时间表，或同时靶向两个可能互补的基因。

材料与设备

试剂：

1%琼脂糖凝胶、含T3和T7启动子的DNA、DNase I、DTT、核糖核苷酸、RNA转录缓冲液、RNasin、T3和T7聚合酶、无RNA酶水、酚:氯仿混合物、氯仿、100%及80%乙醇、RNAi专用溶液A。

设备：

微量离心机（水浴室温和4°C均可）、水浴、震荡器、微吸管拉针仪、微注射器、解剖显微镜、培养皿及琼脂糖凝胶电泳仪器。

平片虫及用于维持平片虫生长的平片虫水。

致谢与参考文献

作者感谢各资助机构（如NIH、NSF等）及相关人员的支持。

更多详情请参阅 Oviedo 等人 (2008) 以及 Sánchez Alvarado 与 Newmark (1999) 的相关文献。

Introduction (What is this Protocol About?)

This protocol explains how to reduce or “knockdown” a gene’s activity in planarians using RNA interference (RNAi).
Planarians are flatworms commonly used to study regeneration (the process of regrowing lost body parts) and tissue maintenance.
By injecting lab-made double-stranded RNA (dsRNA) into the planarian, scientists can lower the expression of a specific gene and observe resulting changes, called phenotypes.
This method helps researchers understand the role of different genes during regeneration.

Related Background Information

The technique was originally described by Sánchez Alvarado and Newmark in 1999.
Planarians serve as a powerful model system for studies on regeneration, adult stem cell regulation, aging, and behavior.
Other protocols related to planarians include methods for maintaining colonies and imaging their membrane potential.

Key Terms and Concepts

RNA interference (RNAi): A method used to reduce or silence the expression of a specific gene.
Double-stranded RNA (dsRNA): Two complementary strands of RNA that, when introduced into an organism, trigger RNAi.
Phenotype: The observable traits or changes in an organism that result from a change in gene activity.
Microinjection: A technique for delivering small volumes of liquid into an organism using a very fine needle.
In vitro: Procedures performed in a controlled laboratory environment outside a living organism.

Step-by-Step Method: RNA Synthesis

Prepare two separate transcription reactions using enzymes:
- One reaction uses T3 polymerase and the other uses T7 polymerase.
- Each reaction includes: DNA template (1 μg), DTT (10 mM), ribonucleotides (1%), RNA transcription buffer (20%), RNasin (60 units), and the respective polymerase (17 units).
- If using a vector with two T7 promoters, a single T7 reaction may be used after linearizing the DNA.
Incubate both reactions at 37°C for 2 hours to synthesize RNA.
Add DNase I (1 unit) to each reaction and incubate at 37°C for 15 minutes to remove the DNA template.
Reserve 1 μL from each reaction in separate tubes and store at -20°C for later comparison.
Combine the remaining 19 μL from each reaction into one tube.
Add 360 μL of RNAi Solution A to the combined reaction and let it sit at room temperature for 10 minutes.
Add 200 μL of a phenol:chloroform mixture and vortex vigorously to mix.
Centrifuge at 14,000 rpm for 2 minutes at room temperature and transfer the clear aqueous phase to a new tube.
Add 200 μL of chloroform, vortex again, and centrifuge at 14,000 rpm for 2 minutes; transfer the new aqueous phase to another fresh tube.
Heat the tube in a water bath at 68°C for 10 minutes to denature (unfold) the RNA, then incubate at 37°C for 30 minutes to allow the RNA strands to reanneal and form dsRNA.
Add 1 mL of cold 100% ethanol and centrifuge at 14,000 rpm for 15 minutes at 4°C to precipitate the RNA.
Discard the supernatant and wash the RNA pellet with 1 mL of cold 80% ethanol; centrifuge at 14,000 rpm for 10 minutes at 4°C.
Discard the wash solution and resuspend the RNA pellet in 10 μL of nuclease-free water; keep the sample on ice.
Verify RNA quality and confirm dsRNA formation by running a small amount on a 1% agarose gel under non-denaturing conditions.

Step-by-Step Method: Microinjection of dsRNA

Prepare the microinjection needle:
- Use a micropipette puller to form a long, thin needle.
- Break the tip slightly under a dissecting microscope so that about 10%-25% of the tip is removed; the opening should be small enough to prevent unwanted leakage.
Fill the needle with mineral oil, ensuring that no air bubbles are present.
Attach the needle to the microinjector and adjust its position under a dissecting microscope:
- Set the microinjector to deliver 32 nanoliters (nL) per pulse.
Aspirate 1–2 μL of the dsRNA solution into the needle.
Place the planarian on cold, wet tissue (placing ice underneath helps keep it cool and still).
Carefully insert the needle into the planarian, typically near the prepharyngeal area (just in front of the mouth), to ensure the needle tip enters the body.
Press the injection key to dispense 32 nL; repeat this 3 to 5 times so that the worm’s gastrovascular system fills with the dsRNA solution, confirming successful injection.
Transfer the injected planarian to a Petri dish containing fresh planarian water at room temperature.
For a stronger gene knockdown effect, repeat the injection process over consecutive days or weeks.

Troubleshooting Common Problems

If RNA (ssRNA or dsRNA) is not visible on the agarose gel:
- Check that all reagents are fresh and have not been repeatedly frozen and thawed.
- Ensure the DNA template includes both T3 and T7 promoter regions.
- Work on clean surfaces free from RNase and DNase contamination.
If no liquid is dispensed from the needle during injection:
- Examine the needle for air bubbles.
- Ensure the needle is securely attached to the microinjector.
If you are uncertain whether the injected liquid is entering the planarian:
- Practice the injection technique; adding a small amount of food coloring to the injection solution can help visualize the process.
If no observable phenotype is produced:
- Check the gene knockdown by methods such as in situ hybridization or RT-PCR to confirm reduced gene expression.
- Consider adjusting the injection schedule or targeting two genes that may compensate for each other.

Materials and Equipment

Reagents:
- 1% agarose gel, DNA template (with T3 and T7 promoters), DNase I, DTT, ribonucleotides, RNA transcription buffer, RNasin, T3 and T7 polymerases, nuclease-free water, phenol:chloroform mix, chloroform, 100% and 80% ethanol, and RNAi Solution A.
Equipment:
- Microcentrifuge (with both room temperature and 4°C capability), water baths, vortex mixer, micropipette puller, microinjector, dissecting microscope, Petri dishes, and apparatus for agarose gel electrophoresis.
Planarians (the flatworms) and planarian water for maintaining them.

Acknowledgments and References

The authors acknowledge contributions and funding from organizations such as the NIH, NSF, and others.
For more detailed information, refer to the publications by Oviedo et al. (2008) and Sánchez Alvarado and Newmark (1999).

Chinese Version: 简介 (研究背景)

本协议描述了如何利用RNA干扰（RNAi）在平片虫中实现基因敲低，即降低某个基因的活性。
平片虫是一种常用于研究再生（失去的部位重新生长）和组织维持的扁形动物。
通过向平片虫注射体外合成的双链RNA（dsRNA），科学家可以降低目标基因的表达，从而观察到由此产生的表型变化。
这种方法有助于研究者理解不同基因在再生过程中的作用。

关键术语和概念

RNA干扰 (RNAi)：一种降低或沉默特定基因表达的方法。
双链RNA (dsRNA)：由两条互补RNA链组成的分子，用于触发RNAi反应。
表型：基因活性改变后在生物体上表现出的可观察特征。
微注射：使用极细针头向生物体内注入极少量液体的技术。
体外：在实验室内控制环境中进行的实验操作，而非在生物体内进行。

分步方法：RNA合成

准备两个独立的转录反应体系，分别使用T3和T7聚合酶：
- 每个反应中加入：DNA模板 (1 μg)、DTT (10 mM)、核糖核苷酸 (1%)、RNA转录缓冲液 (20%)、RNasin (60单位)和相应的聚合酶 (17单位)。
- 如果使用双T7启动子的载体，可在酶切后只用T7聚合酶分别进行反应。
在37°C水浴中孵育2小时以进行RNA合成。
向每个反应中加入1单位DNase I，并在37°C下孵育15分钟以去除DNA模板。
从每个反应中取出1μL样品，另存备用并置于-20°C。
将剩余的反应混合物合并到一个管中。
加入360μL RNAi专用溶液A，在室温下静置10分钟。
加入200μL酚:氯仿混合物，剧烈震荡混合以提取RNA。
在室温下以14000 rpm离心2分钟，将上层水相转移到新管中。
加入200μL氯仿，震荡混合后以14000 rpm离心2分钟，再次转移上层水相到新管中。
在68°C水浴中加热10分钟使RNA变性，再于37°C水浴中孵育30分钟使RNA重新配对形成双链RNA。
加入1 mL冷却的100%乙醇，在4°C下以14000 rpm离心15分钟以沉淀RNA。
弃去上清液，用1 mL冷80%乙醇洗涤RNA沉淀，再以14000 rpm在4°C离心10分钟。
弃去洗涤液，将RNA沉淀重悬于10μL无RNA酶水中，并置于冰上保存。
通过在1%琼脂糖凝胶上检测1μL ssRNA样品和0.5μL dsRNA样品，确认双链RNA的形成。

分步方法：dsRNA的微注射

准备微注射针：
- 使用微吸管拉针仪制作细长针头。
- 在解剖显微镜下观察，轻轻敲碎针尖，去除大约10%-25%的针尖，确保开口足够小以防止液体泄漏。
用矿物油填充针头，确保无气泡。
将针头安装到微注射器上，并在解剖显微镜下调整好位置：
- 设定每次注射量为32纳升 (nL)。
吸取1-2μL dsRNA溶液（来自RNA合成步骤）。
将平片虫放在冷湿纸巾上（在下面放冰可保持其凉爽和湿润）。
小心将针头插入平片虫，通常选择口前区域，确保针头进入体内。
按下注射键释放32纳升液体，重复3至5次，使平片虫的胃血管系统充满dsRNA溶液，以确认注射成功。
将注射后的平片虫转移到含有新鲜平片虫水的培养皿中，并保持室温。
为增强表型效果，可在连续几天或几周内重复注射。

常见问题及解决方案

若在琼脂糖凝胶上未检测到RNA（ssRNA或dsRNA）：
- 检查所有试剂是否新鲜，且未反复冻融。
- 确认DNA模板包含T3和T7启动子区域。
- 确保在无RNase和DNase污染的环境下操作。
若注射时针头无液体流出：
- 检查针头内是否存在气泡。
- 确认针头是否正确安装在微注射器上。
若不确定液体是否进入平片虫体内：
- 多加练习，可在注射液中加入少量食用色素以便观察。
若未观察到任何表型变化：
- 通过原位杂交或RT-PCR检测目标基因表达是否降低。
- 考虑调整注射时间表，或同时靶向两个可能互补的基因。

材料与设备

试剂：
- 1%琼脂糖凝胶、含T3和T7启动子的DNA、DNase I、DTT、核糖核苷酸、RNA转录缓冲液、RNasin、T3和T7聚合酶、无RNA酶水、酚:氯仿混合物、氯仿、100%及80%乙醇、RNAi专用溶液A。
设备：
- 微量离心机（水浴室温和4°C均可）、水浴、震荡器、微吸管拉针仪、微注射器、解剖显微镜、培养皿及琼脂糖凝胶电泳仪器。
平片虫及用于维持平片虫生长的平片虫水。

致谢与参考文献

作者感谢各资助机构（如NIH、NSF等）及相关人员的支持。
更多详情请参阅 Oviedo 等人 (2008) 以及 Sánchez Alvarado 与 Newmark (1999) 的相关文献。

BioPunk Ambience

What s left in asymmetry Michael Levin Research Paper Summary

Introduction (What is this Protocol About?)

Related Background Information

Key Terms and Concepts

Step-by-Step Method: RNA Synthesis

Step-by-Step Method: Microinjection of dsRNA

Troubleshooting Common Problems

Materials and Equipment

Acknowledgments and References

Chinese Version: 简介 (研究背景)

相关背景信息

关键术语和概念

分步方法：RNA合成

分步方法：dsRNA的微注射

常见问题及解决方案

材料与设备

致谢与参考文献

Introduction (What is this Protocol About?)

Related Background Information

Key Terms and Concepts

Step-by-Step Method: RNA Synthesis

Step-by-Step Method: Microinjection of dsRNA

Troubleshooting Common Problems

Materials and Equipment

Acknowledgments and References

Chinese Version: 简介 (研究背景)

相关背景信息

关键术语和概念

分步方法：RNA合成

分步方法：dsRNA的微注射

常见问题及解决方案

材料与设备

致谢与参考文献

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