KAIST 생명과학과동창회
  • News & Events
  • News

News

Antibiotic tolerance study paves way for new treatments


A new study identifies a mechanism that makes bacteria tolerant to penicillin and related antibiotics, findings that could lead to new therapies that boost the effectiveness of these treatments.


Antibiotic tolerance is the ability of bacteria to survive exposure to antibiotics, in contrast to antibiotic resistance, when bacteria actually grow in the presence of antibiotics. Tolerant bacteria can lead to infections that persist after treatment and may develop into resistance over time.

The study in mice, “A Multifaceted Cellular Damage Repair and Prevention Pathway Promotes High Level Tolerance to Beta-lactam Antibiotics,” published Feb. 3 in the journal EMBO Reports, reveals how tolerance occurs, thanks to a system that mitigates iron toxicity in bacteria that have been exposed to penicillin.


“We’re hoping we can design a drug or develop antibiotic adjuvants that would then basically kill off these tolerant cells,” said senior author Tobias Dörr, assistant professor of microbiology in the Weill Institute for Cell and Molecular Biology in the College of Agriculture and Life Sciences.


Co-authors included Ilana Brito, the Mong Family Sesquicentennial Faculty Scholar and assistant professor in the Meinig School of Biomedical Engineering in the College of Engineering, and Lars Westblade, associate professor of pathology and laboratory medicine at Weill Cornell Medicine.


Some bacteria, including the model bacterium used in the study, Vibrio cholerae, which causes cholera in humans, are remarkably tolerant to penicillin and related antibiotics, known as beta lactam antibiotics. It has been known for a long time that beta-lactam antibiotics break down bacterial cell walls, but how bacteria survive loss of their cell walls was poorly understood.


In the study, the researchers developed a V. cholerae mutant that lacked a two-component damage repair response system that controls a gene network encoding diverse functions. Without the system, known as VxrAB, when the cell wall is damaged by antibiotics, the transfer of electrons across the cell membrane goes awry, leading to electrons ending up on the wrong molecules. This misdirection causes hydrogen peroxide to accumulate in the cell, which changes the oxidation state of cellular iron and disrupts signals for the cell to tell how much iron it has.   


In the presence of hydrogen peroxide, the mutant bacteria cannot sense how much iron has been acquired, and it behaves as if it is iron-starved and seeks to acquire more iron. Left unchecked, these circumstances cause iron toxicity, which will kill the cell, according to the experiments the researchers conducted. In further tests with mutant V. cholerae bacteria, both in test tubes and in mice, the researchers showed that reducing the influx of iron increased the bacteria’s tolerance to beta lactams.


Fortunately for normal V. cholerae, exposure to antibiotics and the breakdown of the cell’s walls activate the VxrAB system, which works to repair cell walls and downregulates iron uptake systems, and thereby creates antibiotic tolerance. More study is needed to understand what triggers the VxrAB system in the presence of beta-lactam antibiotics.


The research opens the door for developing new drugs that could be combined with antibiotics to exploit oxidative damage and iron influx in tolerant bacteria. In future work, the researchers will search for parallel mechanisms of tolerance in other bacterial pathogens.


Jung-Ho Shin, a postdoctoral researcher in Dörr’s lab, is the paper’s first author. Co-authors include researchers from the Korea Advanced Institute of Science and Technology, the Korea Advanced Institute of Science and Technology, and the Intelligent Synthetic Biology Center in Korea.

The study was funded by the National Research Foundation of Korea and the National Institutes of Health.


https://news.cornell.edu/stories/2021/02/antibiotic-tolerance-study-paves-way-new-treatments

https://www.miragenews.com/antibiotic-tolerance-study-paves-way-for-new-516267/



List of Articles
번호 제목 글쓴이 날짜 조회 수
383 서성배 교수님_동물의 식습관을 조절하는 원리 규명해 네이처 게재​ 생명과학과 2021.05.11 1101
382 [이승재 교수님 연구실] 과기정통부, ‘2022년도 건강한 연구실’ 10개 선정 생명과학과 2022.12.12 1101
381 [전상용, 조병관 교수님] 나노입자로 염증부터 면역치료까지 가능 생명과학과 2023.06.21 1103
380 [한진희 교수님] 카이스트, 뉴런(신경 세포) 교체에 의한 기억저장 규명 생명과학과 2021.11.24 1106
379 [한용만, 허원도 교수님] 광유전학적으로 인슐린 분비 조절성공…인간 전분화능 줄기세포 유래 췌도 오가노이드 개발 생명과학과 2023.03.24 1115
378 [최길주, 김상규 교수님] 카오스재단 2022 봄 카오스강연 ‘식물행성 (Plant Planet)’ 에서 강연(4/6) 생명과학과 2022.02.22 1118
377 2021 대성해강미생물포럼_좌장 조병관 교수, 연사 김대수 교수_21.09.28(화) 13:00~ file 생명과학과 2021.09.13 1120
376 한진희 교수님_ 치매 치료에 열 올리는 KAIST·연구기관 생명과학과 2021.08.18 1123
375 [이주형 학부생] 포스텍SF 어워드에서 생명과학과 학부생 이주형, 단편 부문 가작 선정 생명과학과 2022.02.10 1124
374 [김상규 교수님] 단일세포 RNA 시퀀싱을 통한 꽃향기 합성 유전자 발굴​ 생명과학과 2022.02.15 1129
373 2021 Agrwal Award 시상식이 9월 9일(목) 오후 4시_이준혁 학생(정원석 교수) file 생명과학과 2021.09.06 1140
372 [정인경 교수님] 파킨슨병 발병 3차원 게놈 지도 최초 제시​ 생명과학과 2023.05.08 1143
371 양한슬 교수님_ 서경배과학재단 2021년 신진과학자 선정 file 생명과학과 2021.08.31 1154
370 [강석조 교수님] 이행 호염구, 알레르기 매개 세포에 대한 새로운 이해 생명과학과 2023.11.08 1169
369 [김대수 교수님] “뇌는 무언가 실패하는 순간 발달...‘메타인지’로 창의성 키워야” [이노베이트코리아 2022] 생명과학과 2022.07.18 1174
368 [허원도, 윤기준 교수님] 제51주년 개교기념식 개교기념 우수교원 포상 및 특별포상에서 학술상, 우수강의상 수상 생명과학과 2022.02.16 1178
367 [이승재 교수님] 국내 연구팀, 예쁜꼬마선충을 이용 새로운 항노화 단백질 찾아 생명과학과 2021.12.13 1182
366 김은준 교수님_시냅스 뇌질환 연구 김은준 IBS단장 “치료약 없는 자폐 연구 도전” 생명과학과 2021.08.23 1204
365 [정원석 교수님] 카이스트, 노화된 뇌에서 생겨난 비정상적 별아교세포 ‘아프다(APDA)’발견 생명과학과 2022.08.08 1213
364 [김찬혁, 정원석 교수님] 심각한 염증 부작용 없앤 새로운 알츠하이머병 치료제 개발​ 생명과학과 2022.08.22 1217
Board Pagination Prev 1 2 3 4 5 6 7 8 9 10 ... 23 Next
/ 23