日韩中文日韩欧美在线观看,亚洲人成网站999久久久综合,精品无码三级在线观看视频,亚洲一区爱区精品无码,亚洲第一AV无码专区,亚洲s久久久久一区二区,国产免费丝袜调教视频,国产在线视频一区二区三区,亚洲免费毛片,国产三级裸体视频无码

熱門搜索:A549    293T 金黃色葡萄球菌 大腸桿菌 AKK菌
購物車 1 種商品 - 共0元
當前位置: 首頁 > 行業(yè)資訊 > SABER tech gives DNA and RNA visualization a boost

SABER tech gives DNA and RNA visualization a boost

 

SABER tech gives DNA and RNA visualization a boost

Date:May 20,

Source:Wyss Institute for Biologically Inspired Engineering at Harvar

Summary:A collaborative research team has now developed 'Signal Amplification by Exchange Reaction' (SABER), a highly programmable and practical method that significantly enhances the sensitivity as well as customization and multiplexing capabilities of FISH analysis.

Researchers have been using "Fluorescence in situ hybridization" (FISH) analysis for decades to literally fish for specific DNA and RNA sequences in intact cells and tissues within their vast seas of nucleic acid molecules. Because of its ability to light specific sequences up under the microscope at the exact locations at which they reside, FISH has come to be a go-to method in the diagnosis of chromosomal abnormalities, investigation of the 3D organization of genomes in cells' nuclei, analysis of the immediate products of gene expression known as messenger RNAs and more.

However, it remains challenging to pick up sequences with FISH that are rare, especially in thick tissues that emit unspecific background fluorescence, and to detect many targets at the same time in multiplexed analysis. Several methods have been developed that can amplify weaker FISH signals but these cannot be easily customized, are unable to simultaneously visualize a large number of DNA or RNA target molecules, and they are expensive and difficult to use.

A collaborative research team from Harvard's Wyss Institute for Biologically Inspired Engineering and Harvard Medical School (HMS) has now developed "Signal Amplification by Exchange Reaction" (SABER), a highly programmable and practical method that significantly enhances the sensitivity as well as customization and multiplexing capabilities of FISH analysis. The team demonstrated SABER to amplify FISH signals at distinct RNA and DNA targets in the different layers of the mouse retina, and visualize up to 17 different target regions on the human X chromosome simultaneously. In addition, they used SABER as an effective tool to identify a genomic element that controls the transcription of a specific gene expressed in a particular type of retinal neuron. Their study is published in Nature Methods.

"With SABER-amplified FISH analysis and its sensitivity, multiplexing potential, practicality and cost-efficiency, we created a way to overcome key limitations of existing methods and provide researchers with a more powerful handle on a broad spectrum of analyses, ranging from fundamental research, to biomarker discovery and the development of therapeutics," said Wyss Institute Core faculty member Peng Yin, Ph.D., who corresponded the study together with Constance Cepko, Ph.D., the Bullard Professor of Genetics and Neuroscience in the Blavatnik Institute at HMS, and Brian Beliveau, Ph.D., a former Damon Runyon Postdoctoral Fellow in Yin's group and now Assistant Professor at the University of Washington's Department of Genome Sciences in Seattle.

Yin also is co-leader of the Wyss Institute's Molecular Robotics Initiative, and Professor of Systems Biology at Harvard Medical School; and Cepko also is an Investigator of the Howard Hughes Medical Institute and a member of the Harvard Stem Cell Institute.

In SABER, the researchers first programmed the "Primer Exchange Reaction" (PER) method previously reported by Yin's group to synthesize a longer concatemer of identical shorter sequences with the help of a catalytic self-folding DNA hairpin structure. This engineered mechanism shares similarity with the naturally occurring enzymatic mechanism that extends "telomeres" at the ends of chromosomes with identical DNA repeats to protect them from degradation but can be executed in a test tube.

The PER-generated concatemers are then hybridized via short complementary handle sequences to their target DNA or RNA sequences in fixed cells and tissues where they provide a scaffold with multiple binding sites for short fluorescent oligonucleotides ('imagers') added next. "In contrast to conventional FISH analysis, SABER allows us to not only bind one but many fluorescent dye molecules to a single nucleic acid target, which can considerably boost the strength of the signal coming from its location inside the cell, and we can even further amplify it by creating branched structures in extra hybridization steps, with additional concatemers grown from internal branch points of already existing concatemers," said Jocelyn Kishi, Ph.D., a co-first author on the study and Postdoctoral Fellow working with Yin who developed SABER with Beliveau. "This opens a wealth of new opportunities."

"SABER enables us to tune the signal strength to the abundance and localizations of specific RNA and DNA targets in FISH analysis, and, because concatemers for multiple targets can be synthesized in bulk ahead of time, SABER provides us with standardized probe sets that can be easily generated and re-used in different studies," said Beliveau. "In addition, by repeatedly washing imagers complementary to one set of targets out of a sample and substituting them for imagers that bind to other targets in a process we call DNA-Exchange, we were able to further multiplex our approach."

The spectral features of distinguishable fluorescent dyes allow researchers to only analyze up to four targets at the same time by conventional fluorescence microscopy. With DNA-Exchange, a set of imagers can be washed out of a sample and replaced by a different one binding to PER-generated concatemers at different target sites, and the process can be repeated multiple times. Using the multiplexing potential of 'Exchange-SABER', the team visualized 17 distinct regions of the human X chromosome in one fell swoop using the same type of microscopic equipment.

Applying SABER to thick tissues, Constance Cepko's group at HMS demonstrated the performance and utility of the method in the retina, which is organized into layers with a high diversity of neural cell types. "We previously applied single-cell sequencing to dissociated retinal tissue, but were unable to use the resulting markers to identify many cell types simultaneously in intact tissue," said co-first author Sylvain Lapan, Ph.D., a Postdoctoral Fellow in Cepko's group. "By providing multiplexed detection of marker transcripts, SABER is allowing us to close this loop and add a spatial dimension to our analyses."

Key to their analysis was a method developed for the study by co-first author Emma West that, based on cell surface fluorescence stainings, can computationally map all cells contained in a cross-section of the retina to specific positions. This enabled the team to assign individual signals obtained by SABER-enhanced FISH analysis to exact 3D spaces occupied by cells. "By modeling cellular coordinates and transcript positions, we can create a digital representation of our tissue that is quantitative at the single cell level. This is not only useful for identifying cell types, but also for analyzing phenotypes and the activity of introduced genetic elements," said co-first author Emma West, who is a Graduate Student in Cepko's group.

In addition, the team used SABER-FISH as an effective tool to identify genomic elements known as enhancers that drive gene expression in specific retinal cell types. "We introduced recombinant DNA constructs into the retina in which those elements were individually coupled to a reporter, and by performing SABER-FISH analysis to quantify the copy numbers of constructs in single cells, as well as the expression of the reporter, we were able to correlate activity of one specific enhancer with cell type-specific expression," said Lapan.

"The sensitivity and simpler, cheaper workflow of SABER-FISH allow us to gather much more information from experiments in which we manipulate the retina in order to understand the regulatory networks that govern its development, and to assess the efficacy of our gene therapy approaches to eye diseases," said Cepko. "Importantly, this approach has the potential to similarly enhance research in many other tissue types and organs."


Story Source:

Materials provided by Wyss Institute for Biologically Inspired Engineering at Harvard. Original written by Benjamin Boettner. Note: Content may be edited for style and length.


Journal Reference:

1.    Jocelyn Y. Kishi, Sylvain W. Lapan, Brian J. Beliveau, Emma R. West, Allen Zhu, Hiroshi M. Sasaki, Sinem K. Saka, Yu Wang, Constance L. Cepko, Peng Yin. SABER amplifies FISH: enhanced multiplexed imaging of RNA and DNA in cells and tissuesNature Methods, 2019; DOI: 10.1038/s41592-019-0404-0

 

 

临沭县| 犍为县| 平罗县| 天津市| 巴青县| 新竹县| 黑山县| 马龙县| 博乐市| 防城港市| 通许县| 城口县| 纳雍县| 凤庆县| 建宁县| 武汉市| 抚远县| 临安市| 盖州市| 茶陵县| 会宁县| 三门峡市| 德令哈市| 神池县| 新竹市| 临泽县| 财经| 金寨县| 涿鹿县| 类乌齐县| 丰台区| 颍上县| 平塘县| 吴忠市| 斗六市| 栾川县| 安顺市| 承德县| 新巴尔虎左旗| 广安市| 尚志市|