{"id":1156,"date":"2018-07-18T06:02:21","date_gmt":"2018-07-18T06:02:21","guid":{"rendered":"http:\/\/163.180.4.222\/lab\/?p=1156"},"modified":"2019-10-14T15:01:02","modified_gmt":"2019-10-14T06:01:02","slug":"crispr-gene-editing-produces-unwanted-dna-deletions","status":"publish","type":"post","link":"https:\/\/biochemistry.khu.ac.kr\/lab\/?p=1156","title":{"rendered":"CRISPR gene editing produces unwanted DNA deletions"},"content":{"rendered":"

 <\/p>\n

 <\/p>\n

(\uc6d0\ubb38<\/a>)<\/p>\n

 <\/p>\n

 <\/p>\n

DNA-cutting enzyme used for genetic modification can create large deletions and shuffle genes.<\/i><\/h6>\n

 <\/p>\n

 <\/p>\n

 <\/p>\n

\n
\n
\n
\"SEM<\/div>\n<\/div>
\n

Gene-editing experiments with human embryonic stem cells revealed the imprecision of the CRISPR-Cas9 system.<\/span>Credit: Annie Cavanagh via Wellcome\/CC BY NC<\/a><\/p>\n<\/figcaption><\/figure>\n

 <\/p>\n

 <\/p>\n

Researchers have embraced CRISPR gene-editing as a method for altering genomes, but some are cautioning that unwanted DNA changes may slip by undetected.<\/p>\n

The tool can cause large DNA deletions and rearrangements near its target site on the genome, according to a paper published on 16 July in\u00a0Nature Biotechnology<\/i>1<\/a><\/sup>. Such alterations can muddle the interpretation of experimental results and could complicate efforts to design therapies based on CRISPR.<\/p>\n

The finding is in line with previous results from not only CRISPR but also other gene-editing systems2<\/a><\/sup>. Such unwanted edits are a problem that warrants more attention from researchers says Patrick Hsu, a bioengineer at the Salk Institute in La Jolla, California. \u201cI do think this has been underappreciated by the field,\u201d he notes.<\/p>\n

CRISPR -Cas9 gene editing relies on the Cas9 enzyme to cut DNA at a particular target site. The cell then attempts to reseal this break using DNA repair mechanisms. These mechanisms do not always work perfectly, and sometimes segments of DNA will be deleted or rearranged, or unrelated bits of DNA will become incorporated into the chromosome.<\/p>\n

\u201cThe cell will try to stitch things back together,\u201d says mouse geneticist Allan Bradley of the Wellcome Sanger Institute in Hinxton, UK, who led the study. \u201cBut it doesn\u2019t really know what bits of DNA lie adjacent to each other.\u201d<\/p>\n

Researchers often use CRISPR to generate small deletions in the hope of knocking out a gene\u2019s function. But when examining CRISPR edits, Bradley and his colleagues found large deletions \u2014 often several thousand DNA letters long \u2014 and complicated rearrangements of DNA sequences in which previously distant DNA sequences were stitched together. The phenomenon was prevalent in all three of the cell types they tested, including a kind of human cell grown in the laboratory.<\/p>\n

 <\/p>\n

Quality control<\/b><\/p>\n

Many researchers use a method for amplifying short snippets of DNA to test whether their edits have been made. But this approach might miss larger deletions and rearrangements, says James Haber, a molecular biologist at Brandeis University in Waltham, Massachusetts.<\/p>\n

The deletions and rearrangements should occur only with gene-editing techniques that rely on DNA cutting, not with some other types of CRISPR modifications that avoid cutting DNA, notes Hsu. A method called base editing, for example,\u00a0uses a\u00a0<\/a>modified CRISPR system to switch one DNA letter for another without cutting DNA<\/a>. And other systems use inactivated Cas9 fused to other enzymes\u00a0to turn genes on or off, or to target RNA<\/a>.<\/p>\n

Some scientists are already on the lookout for large deletions. At eGenesis, a company in Cambridge, Massachusetts that is using gene editing to engineer pig organs for transplant, researchers routinely look for both large and small deletions using a number of methods, says Luhan Yang, the company’s co-founder and chief scientific officer.<\/p>\n

Similarly, at Intellia, another firm in Cambridge that is developing CRISPR\u2013based therapies, scientists have looked for large deletions in gene-editing studies in mouse livers. So far they have found no evidence of such deletions, says senior vice president Thomas Barnes. This, he says, may be because the cells his team works with do not divide often. Bradley and colleagues’ study, by contrast, used actively dividing cells.<\/p>\n

Overall, these unwanted edits are a problem that deserves more attention, but this should not stop anyone from using CRISPR, says Haber. \u201cIt means that when people use it, they need to do a more thorough analysis,\u201d he says. \u201cIt\u2019s generally important to know whether your mutations are as you think they are.\u201d<\/p>\n

 <\/p>\n

 <\/p>\n<\/div>\n

doi: 10.1038\/d41586-018-05736-3<\/div>\n

 <\/p>\n

 <\/p>\n

 <\/p>\n

 <\/p>\n

 <\/p>\n

http:\/\/www.yonhapnews.co.kr\/bulletin\/2018\/07\/16\/0200000000AKR20180716142400017.HTML?input=1195m<\/p>\n

 <\/p>\n

\u82f1 \uc5f0\uad6c\uc9c4 “\ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704, \uc608\uc0c1 \ubabb\ud55c \ubcc0\uc774 \uc720\ubc1c \uac00\ub2a5\uc131”<\/h5>\n

 <\/p>\n

 <\/p>\n

\uae40\uc9c4\uc218\u00a0IBS<\/span>\u00a0\ub2e8\uc7a5 “\ubcc0\uc774 \ubc1c\uc0dd \uacfc\uc815 \ubd88\uba85\ud655\ud558\uc9c0\ub9cc \uc8fc\uc758 \uae4a\uc740 \uad00\ucc30 \ud544\uc694”<\/p>\n

\uc720\uc804\uccb4 \ub0b4 \ud2b9\uc815 \uc720\uc804\uc790\ub97c \uc815\ud655\ud558\uac8c \uc81c\uac70 \ub610\ub294 \uad50\uc815\ud560 \uc218 \uc788\uc5b4 \uc554 \ub4f1 \ub09c\uce58\ubcd1 \uce58\ub8cc\uc5d0 \ud070 \uae30\ub300\ub97c \ubaa8\uc73c\uace0 \uc788\ub294 \ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704(CRISPR<\/span>–Cas<\/span>9)\uac00 \uc608\uc0c1\uce58 \ubabb\ud55c \ubcc0\uc774\ub97c \uc720\ubc1c\ud560 \uac00\ub2a5\uc131\uc774 \uc788\ub2e4\ub294 \uc5f0\uad6c\uacb0\uacfc\uac00 \ub098\uc654\ub2e4.<\/p>\n

\uc601\uad6d \uc6f0\ucef4 \uc0dd\uc5b4 \uc5f0\uad6c\uc18c \uc568\ub7f0 \ube0c\ub798\ub4e4\ub9ac \ubc15\uc0ac\ud300\uc740 17\uc77c \uad6d\uc81c\ud559\uc220\uc9c0 ‘\ub124\uc774\ucc98 \ubc14\uc774\uc624\ud14c\ud06c\ub180\ub85c\uc9c0'(Nature<\/span>\u00a0Biotechnology<\/span>)\uc5d0\uc11c \ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704\ub97c \uc774\uc6a9\ud55c \uc950 \uc904\uae30\uc138\ud3ec\uc640 \uc778\uac04 \ub9dd\ub9c9\uc0c1\ud53c\uc138\ud3ec \uc2e4\ud5d8\uc744 \ud1b5\ud574 \ud45c\uc801 \uc720\uc804\uc790 \uc8fc\ubcc0\uc758 \uc5fc\uae30\uac00 \uc218\ucc9c\uac1c \ub2e8\uc704\ub85c \uacb0\uc2e4\ub418\uac70\ub098 \uc7ac\ubc30\uc5f4\ub418\ub294 \uc624\ub958\uac00 \ub0ae\uc740 \ube48\ub3c4\ub85c \uc77c\uc5b4\ub09c\ub2e4\ub294 \uc0ac\uc2e4\uc744 \ud655\uc778\ud588\ub2e4\uace0 \ubc1d\ud614\ub2e4.<\/p>\n

\ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704\ub294 \uad50\uc815\ud558\uac70\ub098 \uc81c\uac70\ud558\uace0\uc790 \ud558\ub294 \uc720\uc804\uc790\uc758\u00a0DNA<\/span>\ub97c \uc778\uc2dd\ud560 \uc218 \uc788\ub294 \ud2b9\uc815 \uc5fc\uae30\uc11c\uc5f4\uc758\u00a0RNA<\/span>\u00a0\uc870\uac01\uc744 ‘\uac00\uc774\ub4dc’\ub85c \uc0ac\uc6a9\ud574 \uc720\uc804\uccb4 \ub0b4 \ud45c\uc801 \uc704\uce58\ub97c \uc815\ud655\ud558\uac8c \ucc3e\uc544\u00a0DNA<\/span>\ub97c \uc5fc\uae30 \uac00\ub2e5\uc744 \uc798\ub77c\ub0bc \uc218 \uc788\ub2e4.<\/p>\n

\uc774\ub97c \uc9c8\ubcd1 \uce58\ub8cc\uc5d0 \ud65c\uc6a9\ud558\uba74 \uc774\ub860\uc801\uc73c\ub85c \uc720\uc804\uc9c8\ud658\uc744 \uc77c\uc73c\ud0a4\ub294 \uc720\uc804\uc790\ub098 \ub3cc\uc5f0\ubcc0\uc774\ub97c \ud558\ub098\ub9cc \uc815\ud655\ud788 \uc798\ub77c\ub0b4\uac70\ub098 \uad50\uc815\ud558\ub294 \uac83\uc774 \uac00\ub2a5\ud558\ub2e4\ub294 \uc758\ubbf8\ub2e4. \uc2e4\uc81c\ub85c \ud604\uc7ac \ubbf8\uad6d\uacfc \uc911\uad6d\uc5d0\uc11c\ub294 \uc554\uacfc \uc778\uac04\uba74\uc5ed\uacb0\ud54d\ubc14\uc774\ub7ec\uc2a4(HIV<\/span>) \uac10\uc5fc, \uc720\uc804\uc9c8\ud658 \ub4f1 \ub2e4\uc591\ud55c \uc9c8\ubcd1\uc5d0 \ub300\ud55c \uc784\uc0c1\uc2dc\ud5d8\uc774 \uc9c4\ud589\ub418\uace0 \uc788\ub2e4.<\/p>\n

\ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704\uc758 \uc7a5\uc810\uc740 \uc2e4\ud5d8 \uacb0\uacfc \ubaa9\ud45c\ud558\uc9c0 \uc54a\uc740 \uc704\uce58\uc758 \uc5fc\uae30\ub97c \uc798\ub77c\ub0b4\ub294 \uac83\uacfc \uac19\uc740 \uc624\ub958\uac00 \ube44\uad50\uc801 \uc801\uc5b4 \uc548\uc815\uc131\uc774 \ub192\ub2e4\ub294 \uc810\uc774\ub2e4. \ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704\ub294 \ub300\uccb4\ub85c \ud45c\uc801 \ubc16\uc5d0 \uc788\ub294 \uc791\uc740 \ud06c\uae30\uc758 \uc5fc\uae30\ub97c \uc81c\uac70\ud558\uac70\ub098 \uc0bd\uc785\ud558\ub294 \uc815\ub3c4\uc758 \uc624\ub958\ub97c \uc77c\uc73c\ud0a4\ub294 \uac83\uc73c\ub85c \uc54c\ub824\uc838 \uc788\ub2e4.<\/p>\n

\ube0c\ub798\ub4e4\ub9ac \ubc15\uc0ac\ud300\uc740 \uadf8\ub7ec\ub098 \uc950 \ubc30\uc544\uc904\uae30\uc138\ud3ec\uc640 \uc778\uac04 \ub9dd\ub9c9\uc0c1\ud53c\uc138\ud3ec\uc5d0 \ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704\ub97c \uc801\uc6a9\ud55c \uc774\ubc88 \uc5f0\uad6c\uc5d0\uc11c \uc9c0\uae08\uae4c\uc9c0 \uc54c\ub824\uc9c4 \uac83\uacfc \ub2ec\ub9ac \ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790 \uac00\uc704\uac00 \ud45c\uc801 \uc8fc\ubcc0\uc758 \uc5fc\uae30 \uc218\ucc9c\uac1c\ub97c \uc798\ub77c\ub0b4\uac70\ub098 \uc7ac\ubc30\uce58\ud558\ub294 \uc624\ub958\ub97c \uc77c\uc73c\ud0a8\ub2e4\ub294 \uc0ac\uc2e4\uc744 \ud655\uc778\ud588\ub2e4.<\/p>\n

\uc5f0\uad6c\uc9c4\uc740 \uc774\ub294 \ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704\uac00 \uad50\uc815\ud558\uace0\uc790 \ud558\ub294 \ud45c\uc801 \uc720\uc804\uc790\ubfd0\ub9cc \uc544\ub2c8\ub77c \uc8fc\ubcc0\uc758 \ub2e4\ub978 \uc720\uc804\uc790\ub4e4\uc774\ub098 \uc720\uc804\uc790 \ubc1c\ud604 \ub4f1\uc744 \uc870\uc808\ud558\ub294 \uc870\uc808 \uc5fc\uae30\uc11c\uc5f4\uc5d0\ub3c4 \uc601\ud5a5\uc744 \ubbf8\uccd0 \uc138\ud3ec \uae30\ub2a5 \ubcc0\ud654\ub97c \ucd08\ub798\ud560 \uac00\ub2a5\uc131\uc774 \uc788\uc74c\uc744 \ubcf4\uc5ec\uc900\ub2e4\uace0 \uc9c0\uc801\ud588\ub2e4.<\/p>\n

\uae30\ucd08\uacfc\ud559\uc5f0\uad6c\uc6d0(IBS<\/span>) \uc720\uc804\uccb4 \uad50\uc815\uc5f0\uad6c\ub2e8 \uae40\uc9c4\uc218 \ub2e8\uc7a5(\uc11c\uc6b8\ub300 \ud654\ud559\ubd80 \uacb8\uc784\uad50\uc218)\uc740 \uc774 \uc5f0\uad6c\uacb0\uacfc\uc5d0 \ub300\ud574 “\uc5f0\uad6c\uc9c4\uc774 \ud45c\uc801 \uc8fc\ubcc0\uc5d0\uc11c \ub300\uaddc\ubaa8 \uc5fc\uae30 \uacb0\uc2e4 \ub4f1\uc774 \uc77c\uc5b4\ub0a0 \uc218 \uc788\uc74c\uc744 \ud655\uc778\ud588\uc73c\ub098 \uc5b4\ub5bb\uac8c \uc774\ub7f0 \ubcc0\uc774\uac00 \ubc1c\uc0dd\ud558\ub294\uc9c0\ub294 \ubd88\uba85\ud655\ud558\ub2e4”\uba70 “\uc720\uc804\uc790 \ub179\uc544\uc6c3 \ubc29\uc2dd\uc73c\ub85c \uc9c8\ubcd1\uc744 \uce58\ub8cc\ud558\ub294 \uacbd\uc6b0\uc5d0\ub294 \uc774\ub7f0 \uc624\ub958\uac00 \ud06c\uac8c \ubb38\uc81c \ub418\uc9c0\ub294 \uc54a\uc744 \uac83 \uac19\uc9c0\ub9cc, \uc8fc\uc758 \uae4a\uac8c \uad00\ucc30\ud560 \ud544\uc694\ub294 \uc788\ub2e4”\uace0 \ub9d0\ud588\ub2e4.<\/p>\n

\uadf8\ub294 \ub610 \ub124\uc774\ucc98 \ubc14\uc774\uc62c\ub85c\uc9c0 \ub17c\ud3c9\uc5d0\uc11c “\uc5f0\uad6c\uc9c4\uc774 \ud06c\ub9ac\uc2a4\ud37c \uc720\uc804\uc790\uac00\uc704 \ub4f1\uc744 \uccb4\uc138\ud3ec\u00b7\uc0dd\uc2dd\uc138\ud3ec \uc720\uc804\uc790 \uce58\ub8cc\ubc95\uc5d0 \uc801\uc6a9\ud558\uae30 \uc704\ud55c \uc548\uc804 \uae30\uc900\uc744 \ub192\uc600\ub2e4”\uba70 “\ud5a5\ud6c4 \uc784\uc0c1\uc2dc\ud5d8\uc5d0\uc11c \uc774\ub7f0 \ubc29\ubc95\uc774 \ud45c\uc801 \uc678 \uc5fc\uae30\uc5d0 \ubbf8\uce58\ub294 \uc601\ud5a5\uc740 \ubb3c\ub860 \ud45c\uc801 \ub0b4 \uc5fc\uae30\uc5d0 \ubbf8\uce58\ub294 \uc601\ud5a5\ub3c4 \uc8fc\uc758\ud574 \uc0b4\ud53c\uace0 \uc81c\uc5b4\ud574\uc57c \ud55c\ub2e4”\uace0 \uac15\uc870\ud588\ub2e4.<\/p>\n

 <\/p>\n

 <\/p>\n

 <\/p>\n

 <\/p>\n","protected":false},"excerpt":{"rendered":"

    (\uc6d0\ubb38)     DNA-cutting enzyme used for genetic modification can create large deletions and shuffle genes.       Gene-editing experiments with human(more…)<\/a><\/p>\n","protected":false},"author":1,"featured_media":0,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"_monsterinsights_skip_tracking":false,"_monsterinsights_sitenote_active":false,"_monsterinsights_sitenote_note":"","_monsterinsights_sitenote_category":0,"jetpack_post_was_ever_published":false,"_jetpack_newsletter_access":"","_jetpack_dont_email_post_to_subs":false,"_jetpack_newsletter_tier_id":0,"_jetpack_memberships_contains_paywalled_content":false,"_jetpack_memberships_contains_paid_content":false,"footnotes":"","jetpack_publicize_message":"","jetpack_publicize_feature_enabled":true,"jetpack_social_post_already_shared":true,"jetpack_social_options":{"image_generator_settings":{"template":"highway","default_image_id":0,"font":"","enabled":false},"version":2}},"categories":[33,34,29,30],"tags":[7,8,3,4],"class_list":["post-1156","post","type-post","status-publish","format-standard","hentry","category-do-biology","category-lets-do-chemistry","category-lets-do-science","category-recent-science-news","tag-do-biology","tag-lets-do-chemistry","tag-lets-do-science","tag-recent-science-news"],"aioseo_notices":[],"jetpack_publicize_connections":[],"jetpack_featured_media_url":"","jetpack-related-posts":[{"id":976,"url":"https:\/\/biochemistry.khu.ac.kr\/lab\/?p=976","url_meta":{"origin":1156,"position":0},"title":"CRISPR with a heart of gold helps ailing mice","author":"biochemistry","date":"June 28, 2018","format":false,"excerpt":"\u00a0 \u00a0 (\uc6d0\ubb38) \u00a0 \u00a0 \u00a0 Gene-editing molecules ride gold nanoparticles into the brain. \u00a0 Expression of a protein (blue-green, left) associated with fragile X syndrome is suppressed (right) in the brains of mice treated with CRISPR gene-editing molecules. Credit: B. Lee\u00a0et al.\/Nature\u00a0Biomed. Eng. \u00a0 \u00a0 Scientists are mining gold\u2026","rel":"","context":"In "Let's Do Biology!"","block_context":{"text":"Let's Do Biology!","link":"https:\/\/biochemistry.khu.ac.kr\/lab\/?cat=33"},"img":{"alt_text":"","src":"","width":0,"height":0},"classes":[]},{"id":2952,"url":"https:\/\/biochemistry.khu.ac.kr\/lab\/?p=2952","url_meta":{"origin":1156,"position":1},"title":"The CRISPR \ufefffix that could combat inherited blood disorders","author":"biochemistry","date":"March 27, 2019","format":false,"excerpt":"\u00a0 Researchers have finally identified a reliable way to edit the genes of blood stem cells. \u00a0 The elongated red blood cells of people with sickle-cell disease can block small blood vessels, reducing the flow of oxygen to nearby tissues. Credit: Eye of Science\/SPL \u00a0 \u00a0 \u00a0 An enhanced version\u2026","rel":"","context":"In "Let's Do Biology!"","block_context":{"text":"Let's Do Biology!","link":"https:\/\/biochemistry.khu.ac.kr\/lab\/?cat=33"},"img":{"alt_text":"","src":"","width":0,"height":0},"classes":[]},{"id":1535,"url":"https:\/\/biochemistry.khu.ac.kr\/lab\/?p=1535","url_meta":{"origin":1156,"position":2},"title":"Canine CRISPR trial raises \ufeffhopes for humans with deadly disease","author":"biochemistry","date":"September 2, 2018","format":false,"excerpt":"\u00a0 \u00a0 (\uc6d0\ubb38) \u00a0 \u00a0 Dogs with a disorder similar to Duchenne muscular dystrophy improve after gene-editing treatment. \u00a0 \u00a0 A powerful gene-editing technique can stimulate dogs\u2019 production of an important muscle protein, a finding that takes researchers a step closer to trying the technology in humans who have a\u2026","rel":"","context":"In "Let's Do Biology!"","block_context":{"text":"Let's Do Biology!","link":"https:\/\/biochemistry.khu.ac.kr\/lab\/?cat=33"},"img":{"alt_text":"","src":"","width":0,"height":0},"classes":[]},{"id":3891,"url":"https:\/\/biochemistry.khu.ac.kr\/lab\/?p=3891","url_meta":{"origin":1156,"position":3},"title":"Inserting DNA with CRISPR","author":"biochemistry","date":"July 16, 2019","format":false,"excerpt":"\u00a0 \u00a0 Most prokaryotes rely on the CRISPR-Cas system for adaptive immunity against viruses and mobile elements (1,\u00a02). Small RNAs produced from CRISPR direct Cas effector proteins to seek and destroy nucleic acids from invaders that have complementary target sites (3). There are multiple types of CRISPR, which are defined\u2026","rel":"","context":"In "Let's Do Biology!"","block_context":{"text":"Let's Do Biology!","link":"https:\/\/biochemistry.khu.ac.kr\/lab\/?cat=33"},"img":{"alt_text":"","src":"","width":0,"height":0},"classes":[]},{"id":2247,"url":"https:\/\/biochemistry.khu.ac.kr\/lab\/?p=2247","url_meta":{"origin":1156,"position":4},"title":"Precision genome engineering","author":"biochemistry","date":"December 3, 2018","format":false,"excerpt":"\u00a0 \u00a0 Genome editing through CRISPR-Cas systems has the potential to correct genetic mutations that occur in diseased cells, such as cancer cells. However, the ability to selectively activate CRISPR-Cas systems in diseased cells is important to ensure that gene editing only occurs where it is wanted. Zhu\u00a0et al.\u00a0developed a\u2026","rel":"","context":"In "Let's Do Biology!"","block_context":{"text":"Let's Do Biology!","link":"https:\/\/biochemistry.khu.ac.kr\/lab\/?cat=33"},"img":{"alt_text":"","src":"","width":0,"height":0},"classes":[]},{"id":3984,"url":"https:\/\/biochemistry.khu.ac.kr\/lab\/?p=3984","url_meta":{"origin":1156,"position":5},"title":"Enriching stem cells for gene editing","author":"biochemistry","date":"August 3, 2019","format":false,"excerpt":"\u00a0 \u00a0 Gene editing using CRISPR-Cas9 may allow targeted treatment for a variety of genetic diseases. These include inherited abnormalities of \u03b2 hemoglobin, which can be indirectly targeted by increasing the amount of healthy fetal hemoglobin without fully correcting the disease-causing mutation. Humbert\u00a0et al.\u00a0used CRISPR-based gene editing to modify hematopoietic\u2026","rel":"","context":"In "Let's Do Biology!"","block_context":{"text":"Let's Do Biology!","link":"https:\/\/biochemistry.khu.ac.kr\/lab\/?cat=33"},"img":{"alt_text":"","src":"","width":0,"height":0},"classes":[]}],"jetpack_sharing_enabled":false,"jetpack_shortlink":"https:\/\/wp.me\/p9Xo1j-iE","_links":{"self":[{"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=\/wp\/v2\/posts\/1156","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=%2Fwp%2Fv2%2Fcomments&post=1156"}],"version-history":[{"count":1,"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=\/wp\/v2\/posts\/1156\/revisions"}],"predecessor-version":[{"id":4270,"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=\/wp\/v2\/posts\/1156\/revisions\/4270"}],"wp:attachment":[{"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=%2Fwp%2Fv2%2Fmedia&parent=1156"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=%2Fwp%2Fv2%2Fcategories&post=1156"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/biochemistry.khu.ac.kr\/lab\/index.php?rest_route=%2Fwp%2Fv2%2Ftags&post=1156"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}