The demand for Erigeron breviscapus,a medicinal Compositae plant with cardiovascular therapeutic properties,has been increasing by 15%annually,exceeding production capacity and necessitating improvements in yield and ...The demand for Erigeron breviscapus,a medicinal Compositae plant with cardiovascular therapeutic properties,has been increasing by 15%annually,exceeding production capacity and necessitating improvements in yield and bioactive compound content.Genetic transformation remains essential for functional genomics,yet current Agrobacterium and biolistic methods are inefficient and expensive.In this study,we cloned the full-length sequences of the BABY BOOM,WUSCHEL and GROWTH-REGULATING FACTOR(GRF)genes of E.breviscapus and then transformed them into E.breviscapus explants.The transformation efficiency for the GRF gene reached 45%,and all the transgenic E.breviscapus plants were fertile without obvious developmental defects.Furthermore,we inserted EbGRF4 and Cas9-EbPDS-sgRNA into the same vector for Agrobacterium-mediated transformation to effectively knock out the PDS gene,resulting in albino seedlings,with a gene editing efficiency of 33.3%.These findings provide a solid foundation for functional genomic research and the genetic improvement of E.breviscapus,as well as an important reference for establishing high-efficiency genetic transformation systems for other medicinal plants.展开更多
As we welcome the spring of 2026,we extend our sincere greetings and best wishes to colleagues worldwide in the field of crop science,our partners,and all those committed to sustainable agricultural development!The Ye...As we welcome the spring of 2026,we extend our sincere greetings and best wishes to colleagues worldwide in the field of crop science,our partners,and all those committed to sustainable agricultural development!The Year of the Horse symbolizes endeavor and far-reaching journeys,reflecting our own spirit of continuous exploration and breakthrough innovation on the path of crop science.Here,I extendmysincere appreciation to all our authors and reviewers for their invaluable time,expertise,and dedication,which are instrumental in the success of The Crop Journal,establishing it as a premier platform for the global crop science research community.The Crop Journal publishes its 2026 first issue as a special issue themed“Synthetic Biology for Crop Improvement”,ably vip-edited by four young scientists.The issue provides a comprehensive overview of major advances in the field.In the past few years,crop science has made long strides in metabolic engineering of important pathways in secondary metabolism.The achievements expedite the emergence of synthetic biology as a potent methodology for crop breeding and represent a fundamental paradigm shift from“deciphering crops”to“designing crops”,which is further empowered by artificial intelligence(AI).At this turning point of the New Year,I would like to take this opportunity to provide a brief retrospective and future perspective.展开更多
The 2025 edition of the Chinese Pharmacopoeia has been officially promulgated by the National Medical Products Administration(NMPA)and the National Health Commission(NHC).As the core of the traditional Chinese medicin...The 2025 edition of the Chinese Pharmacopoeia has been officially promulgated by the National Medical Products Administration(NMPA)and the National Health Commission(NHC).As the core of the traditional Chinese medicine(TCM)standards system,Volume Ⅰ of the Chinese Pharmacopoeia further refines the standards for crude drugs and decoction pieces,strengthens the TCM safety risk prevention and control system,and actively advances the improvement of the TCM standards system.This edition will play a significant role in ensuring the quality of TCM products,safeguarding public health,and fostering high-quality development of the TCM industry.展开更多
Brain organoids are artificial neural tissues derived in vitro,containing a variety of cell types,as well as structural and/or functional brain regions.They can partially mimic brain physiological activities and disea...Brain organoids are artificial neural tissues derived in vitro,containing a variety of cell types,as well as structural and/or functional brain regions.They can partially mimic brain physiological activities and diseased processes.Owing to their operability and sample accessibility,brain organoids serve as a bridge between in vitro monolayer cell culture models and in vivo animal models.An increasing number of induction protocols for brain organoids have been developed over the preceding decade.A key future research direction will focus on ensuring the complexity and quality of brain organoids.The integration of powerful technologies,such as the CRISP R/Cas9 genome editing and lineage tra cing systems,shall precipitate practical and broad applications of brain organoids.In this review,we discuss the generation and application of brain organoids,as well as their integration with genome editing technologies,in the study of neural development,disease modeling,and mechanistic investigations.The innovative combination of these two technologies may offer a fresh perspective for exploring the fundamental aspects of the human nervous system and related diseases.展开更多
Emerging and powerful genome editing tools,particularly CRISPR/Cas9,are facilitating functional genomics research and accelerating crop improvement(Jiang et al.2021;Cao et al.2023;Chen C et al.2023;Liu et al.2023a).Ho...Emerging and powerful genome editing tools,particularly CRISPR/Cas9,are facilitating functional genomics research and accelerating crop improvement(Jiang et al.2021;Cao et al.2023;Chen C et al.2023;Liu et al.2023a).However,the detection and screening of transgenic lines remain major bottlenecks,being time-consuming,labor-intensive,and inefficient during transformation and subsequent mutation identification.A simple and efficient visual marker system plays a critical role in addressing these challenges.Recent studies demonstrated that the GmW1 and RUBY reporter systems were used to obtain visual transgenic soybean(Glycine max) plants(Chen L et al.2023;Chen et al.2024).展开更多
Superconducting diodes,which enable dissipationless supercurrent flow in one direction while blocking it in the reverse direction,are emerging as pivotal components for superconducting electronics.The development of e...Superconducting diodes,which enable dissipationless supercurrent flow in one direction while blocking it in the reverse direction,are emerging as pivotal components for superconducting electronics.The development of editable superconducting diodes could unlock transformative applications,including dynamically reconfigurable quantum circuits that adapt to operational requirements.Here,we report the first observation of the superconducting diode effect(SDE)in LaAlO_(3)/KTaO_(3) heterostructures—a two-dimensional oxide interface superconductor with exceptional tunability.We observe a strong SDE in Hall-bar(or strip-shaped)devices under perpendicular magnetic fields(<15 Oe),with efficiencies above 40%and rectification signals exceeding 10 mV.Through conductive atomic force microscope lithography,we demonstrate reversible nanoscale editing of the SDE’s polarity and efficiency by locally modifying the superconducting channel edges.This approach enables multiple nonvolatile configurations within a single device,realizing an editable superconducting diode.Our work establishes LaAlO_(3)/KTaO_(3) as a platform for vortex-based nonreciprocal transport and provides a pathway toward designer quantum circuits with on-demand functionalities.展开更多
Genomic disorders affecting the central nervous system(CNS)are among the most complex and devastating conditions in human health.Moreover,these disorders,such as Rett syndrome,spinal muscular atrophy,and Fragile X syn...Genomic disorders affecting the central nervous system(CNS)are among the most complex and devastating conditions in human health.Moreover,these disorders,such as Rett syndrome,spinal muscular atrophy,and Fragile X syndrome,are typically caused by mutations in genes essential for neural development,synaptic function,or cellular homeostasis.Despite the genetic diversity involved,these diseases share key pathological features,including progressive neurodegeneration,disruption of neural circuits,and loss of cognitive or motor function.Meanwhile,one of the significant clinical challenges in treating CNS disorders is the limited regenerative capacity of the adult nervous system,which makes reversing disease progression extremely difficult once symptoms appear.In addition,the blood-brain barrier(BBB)restricts the passage of most systemically administered therapeutics,further complicating effective intervention.Consequently,current treatment options remain largely palliative,and effective cures remain elusive.展开更多
Wolfram syndrome(WS)is a rare autosomal rece s s i ve disease characte r i zed by the development of diabetes insipidus,diabetes mellitus,optic atrophy,and deafness(often referred to as DIDMOAD),and overall severe neu...Wolfram syndrome(WS)is a rare autosomal rece s s i ve disease characte r i zed by the development of diabetes insipidus,diabetes mellitus,optic atrophy,and deafness(often referred to as DIDMOAD),and overall severe neurodegenerative fallback.The global prevalence of this disease is estimated at 1 in 770,000(Lee et al.,2023).It is most commonly caused by biallelic(point)mutations in the Wolframin endoplasmic reticulum(ER)transmembrane glycoprotein(WFS1)gene(in case of WS type 1),but mutations in the CDGSH Iron Sulfur Domain 2(CISD2)are also linked to WS(type 2).The latter,however,often present with less severe pathological manifestations(Lee et al.,2023).WFS1 is located on chromosome 4p16.1 and spans over 33 kilobases.Many mutation variants have been identified in WFS1,encompassing missense,nonsense,and frameshift mutations.These mutations are spread across the coding region of WFS1,but certain regions,such as exon 8,the largest exon,appear particularly mutation-prone and associated with the classical WS type 1 phenotype(Lee et al.,2023).展开更多
Base editors are essential tools for precise genome editing in plants.However,achieving high efficiency in C-to-G editing while minimizing byproduct and offtarget mutations remains challenging.In this study,we present...Base editors are essential tools for precise genome editing in plants.However,achieving high efficiency in C-to-G editing while minimizing byproduct and offtarget mutations remains challenging.In this study,we present the development and evaluation of a novel glycosylase-based cytosine base editor(gCBE)for efficient C-to-G editing in rice.Unlike traditional cytosine base editors,which rely on cytosine deamination,gCBE directly excises cytosine to generate an apurinic/apyrimidinic(AP)site,thus circumventing the deamination step and reducing the production of C-to-T byproducts.We constructed several gCBE variants,including N-gCBE,M-gCBE,and C-gCBE,by fusing engineered human UDG2(UNG*)to SpCas9 nickase(nSpCas9,D10A)and tested their editing efficiency and specificity in rice.Our results demonstrate that M-gCBE achieved efficient C-to-G editing(6.3%to 37.5%)similar to OsCGBE(9.4%to 28.1%)at most targets,though with site-dependent variations.Notably,gCBE tools showed a marked reduction in C-to-T byproducts,with average C-to-T mutation rates of 12.5%for N-gCBE and 16.7%for M-gCBE,compared to 53.1%for OsCGBE.Notably,both N-gCBE and M-gCBE were capable of generating homozygous C-to-G mutations in the T_(0)generation,a key advantage over OsCGBE,which predominantly generated C-to-T mutations.Off-target analysis revealed minimal off-target effects with M-gCBE,highlighting its potential for high-precision genome editing.These findings suggest that gCBE tools,particularly M-gCBE,are highly efficient and precise,providing an advanced solution for C-to-G editing in plants and offering promising applications for crop improvement.展开更多
Bacterial blight(BB),caused by Xanthomonas oryzae pathovar oryzae(Xoo),poses a significant threat to rice production,particularly in Asia and West Africa.Breeding resistance against BB in elite rice varieties is cruci...Bacterial blight(BB),caused by Xanthomonas oryzae pathovar oryzae(Xoo),poses a significant threat to rice production,particularly in Asia and West Africa.Breeding resistance against BB in elite rice varieties is crucial to advancing rice breeding program and supporting smallholder farmers.Transcription Activator-Like effectors(TALes)are key virulence factors in Xoo,with some targeting the susceptibility(S)genes such as the sugar transporter SWEET genes in rice.Among these,SWEET14 is an important S gene,with its promoter bound by the TALe TalC which exists across all sequenced African Xoo isolates.In the present study,we utilized CRISPR/Cas9-based cytidine and adenine base editors to alter the effector binding element(EBE)of TalC in the promoter of SWEET14 in rice cultivars Kitaake,IR24,and Zhonghua 11.Mutations with C to T changes in EBE led to reduced SWEET14 induction by TalC-containing Xoo strains,resulting in resistance to African Xoo isolates reliant on TalC for virulence.Conversely,A to G changes retained SWEET14 inducibility and susceptibility to Xoo in edited lines.Importantly,no off-target mutations were detected at predicted sites,and the edited lines exhibited no obvious defects in major agronomic traits in Kitaake.These results underscore the effectiveness of base editing systems for both molecular biology research and crop improvement endeavors.展开更多
“Journal of Jilin University(Science Edition)” is a comprehensive academic journal in the fields of science sponsored by Jilin University and administrated by the Ministry of Education of the People's Republic o...“Journal of Jilin University(Science Edition)” is a comprehensive academic journal in the fields of science sponsored by Jilin University and administrated by the Ministry of Education of the People's Republic of China.The journal started publication in 1955.The original name at starting publication was “Journal of Natural Science of Northeast People University”,which was changed into “Acta Scientiarum Naturalium Universitatis Jilinensis” in 1958owing to the name change of the university.展开更多
Incorporating a low density of ester units into the backbone of polyethylene materials enhances their sustainability and recyclability while maintaining the main material properties of polyethylenes.Here we report a n...Incorporating a low density of ester units into the backbone of polyethylene materials enhances their sustainability and recyclability while maintaining the main material properties of polyethylenes.Here we report a new way to access degradable polyethylene materials with a low content of in-chain ester units via mechanochemical backbone editing.Initially,ester groups are incorporated as side groups through catalytic copolymerization of ethylene with a cyclobutene-fused lactone monomer(CBL),yielding polyethylene materials with high molecular weights and adjustable thermomechanical properties.Subsequent solid-state ball-milling treatment selectively introduces side-chain ester groups into the main chain of the polyethylene materials via force-induced cycloreversion of the cyclobutane units.Under acidic conditions,hydrolysis of the resultant polyethylene materials with in-chain ester units facilitates further degradation into oligomers.展开更多
On the morning of January 15,the China-Laos Cultural Road Dialogue took place in Vientiane,Laos.A ceremony was held during the event to release the January 2025 special editions of China Report ASEAN(an English journa...On the morning of January 15,the China-Laos Cultural Road Dialogue took place in Vientiane,Laos.A ceremony was held during the event to release the January 2025 special editions of China Report ASEAN(an English journal)and Champa(a Chinese-Lao bilingual journal named after the national flower of Laos which is considered a symbol of sincerity and joy).Part of the 2025“One River,One Family”Spring Festival cultural series in Laos,the event was supervised by China International Communications Group(CICG),the Chinese Embassy in Laos,and China State Railway Group Company,hosted by the Publicity Department of the CPC Yunnan Provincial Committee and the Publicity Department of the Central Committee of the Lao People’s Revolutionary Party(LPRP),and organized by CICG Asia-Pacific,Yunnan Daily,Yunnan International Communication Center for South and Southeast Asia,Pasaxon(“The People”newspaper in Laos),and China Railway Kunming Group.展开更多
Nonobstructive azoospermia(NOA)affects about 60%of men with azoospermia,representing a severe form of male infertility.The current approach to manage NOA primarily involves testicular sperm retrieval methods such as c...Nonobstructive azoospermia(NOA)affects about 60%of men with azoospermia,representing a severe form of male infertility.The current approach to manage NOA primarily involves testicular sperm retrieval methods such as conventional testicular sperm extraction(c-TESE)and microdissection testicular sperm extraction(micro-TESE).While combining testicular sperm retrieval with intracytoplasmic sperm injection(ICSI)offers hope for patients,the overall sperm retrieval rate(SRR)stands at around 50%.In cases where micro-TESE fails to retrieve sperm,limited options,like donor sperm or adoption,can be problematic in certain cultural contexts.This paper delves into prospective treatments for NOA management.Gene editing technologies,particularly clustered regularly interspaced short palindromic repeats(CRISPR)/CRISPR-associated(Cas)protein 9(CRISPR/Cas9),hold potential for correcting genetic mutations underlying testicular dysfunction.However,these technologies face challenges due to their complexity,potential off-target effects,ethical concerns,and affordability.This calls for research to address key challenges associated with NOA management within the clinical settings.This also necessitate ongoing research essential for developing more sensitive diagnostic tests,validating novel treatments,and customizing current treatment strategies for individual patients.This review concluded that the future of NOA management may entail a combination of these treatment options,tailored to each patient’s unique circumstances,providing a comprehensive approach to address NOA challenges.展开更多
The monumental second edition Petroleum Geology of China has been published by the Petroleum Industry Press.This definitive work was compiled under the leadership of Academician Zhai Guangming,a preeminent authority i...The monumental second edition Petroleum Geology of China has been published by the Petroleum Industry Press.This definitive work was compiled under the leadership of Academician Zhai Guangming,a preeminent authority in petroleum exploration.As the culmination of eight years of dedicated effort by over a thousand experts and scholars,this monumental publication comprises 25 volumes(bound in 32 books).展开更多
Ectothermic organisms may expand their thermal tolerance by producing multiple protein isoforms with differing thermal sensitivities.While such isoforms commonly originate from allelic variation at a single locus(allo...Ectothermic organisms may expand their thermal tolerance by producing multiple protein isoforms with differing thermal sensitivities.While such isoforms commonly originate from allelic variation at a single locus(allozymes)or from gene duplication that gives rise to paralogs with distinct thermal responses,this study investigated mRNA editing as an alternative,post-transcriptional mechanism for generating mRNA variants.Cytosolic malate dehydrogenase(cMDH)was examined in foot tissue of two congeners of the marine mussel genus Mytilus,which occupy different thermal environments.Multiple editing events were detected within the mRNA coding region in both species.Editing sites were species-specific,with no shared positions identified.In M.coruscus,editing occurred at 117,123,135,190,195,204,279,and 444,while in M.galloprovincialis,editing was detected at 216 and 597.Each species exhibited multiple edited mRNA variants,and these isoforms were associated with differential protein expression.These findings suggest that mRNA editing may contribute an additional layer of molecular variation.The generation of diverse mRNA isoforms from a single DNA coding sequence may enhance enzymatic flexibility across temperature ranges,supporting eurythermal physiological performance and mitigating thermal stress.Moreover,the presence of multiple edited transcripts within individual organisms raises important caveats about the limitations of approaches that deduce amino acid sequences or estimate adaptive variation solely from genomic data.展开更多
基金supported by the National Natural Science Foundation of China(82160727)the Major Science and Technique Programs in Yunnan Province(202304BT090021-ML05)Yunnan Agricultural University research start-up Fund(KY2022-02).
文摘The demand for Erigeron breviscapus,a medicinal Compositae plant with cardiovascular therapeutic properties,has been increasing by 15%annually,exceeding production capacity and necessitating improvements in yield and bioactive compound content.Genetic transformation remains essential for functional genomics,yet current Agrobacterium and biolistic methods are inefficient and expensive.In this study,we cloned the full-length sequences of the BABY BOOM,WUSCHEL and GROWTH-REGULATING FACTOR(GRF)genes of E.breviscapus and then transformed them into E.breviscapus explants.The transformation efficiency for the GRF gene reached 45%,and all the transgenic E.breviscapus plants were fertile without obvious developmental defects.Furthermore,we inserted EbGRF4 and Cas9-EbPDS-sgRNA into the same vector for Agrobacterium-mediated transformation to effectively knock out the PDS gene,resulting in albino seedlings,with a gene editing efficiency of 33.3%.These findings provide a solid foundation for functional genomic research and the genetic improvement of E.breviscapus,as well as an important reference for establishing high-efficiency genetic transformation systems for other medicinal plants.
文摘As we welcome the spring of 2026,we extend our sincere greetings and best wishes to colleagues worldwide in the field of crop science,our partners,and all those committed to sustainable agricultural development!The Year of the Horse symbolizes endeavor and far-reaching journeys,reflecting our own spirit of continuous exploration and breakthrough innovation on the path of crop science.Here,I extendmysincere appreciation to all our authors and reviewers for their invaluable time,expertise,and dedication,which are instrumental in the success of The Crop Journal,establishing it as a premier platform for the global crop science research community.The Crop Journal publishes its 2026 first issue as a special issue themed“Synthetic Biology for Crop Improvement”,ably vip-edited by four young scientists.The issue provides a comprehensive overview of major advances in the field.In the past few years,crop science has made long strides in metabolic engineering of important pathways in secondary metabolism.The achievements expedite the emergence of synthetic biology as a potent methodology for crop breeding and represent a fundamental paradigm shift from“deciphering crops”to“designing crops”,which is further empowered by artificial intelligence(AI).At this turning point of the New Year,I would like to take this opportunity to provide a brief retrospective and future perspective.
文摘The 2025 edition of the Chinese Pharmacopoeia has been officially promulgated by the National Medical Products Administration(NMPA)and the National Health Commission(NHC).As the core of the traditional Chinese medicine(TCM)standards system,Volume Ⅰ of the Chinese Pharmacopoeia further refines the standards for crude drugs and decoction pieces,strengthens the TCM safety risk prevention and control system,and actively advances the improvement of the TCM standards system.This edition will play a significant role in ensuring the quality of TCM products,safeguarding public health,and fostering high-quality development of the TCM industry.
基金Special Projectfor Clinical Research of Shanghai Municipal Health Commission,No.202140403Key Disciplines Group Construction Project of Pudong Health Bureau of Shanghai,No.PWZxq2022-05+2 种基金Natural Science Foundation of Ningxia Hui Autonomous Region,No.2024AAC05084Ningxia Hui Autonomous Region Key Research and Development Program,No.2021BEG03084National Natural Science Foundation of China,Nos.32370895,32070862。
文摘Brain organoids are artificial neural tissues derived in vitro,containing a variety of cell types,as well as structural and/or functional brain regions.They can partially mimic brain physiological activities and diseased processes.Owing to their operability and sample accessibility,brain organoids serve as a bridge between in vitro monolayer cell culture models and in vivo animal models.An increasing number of induction protocols for brain organoids have been developed over the preceding decade.A key future research direction will focus on ensuring the complexity and quality of brain organoids.The integration of powerful technologies,such as the CRISP R/Cas9 genome editing and lineage tra cing systems,shall precipitate practical and broad applications of brain organoids.In this review,we discuss the generation and application of brain organoids,as well as their integration with genome editing technologies,in the study of neural development,disease modeling,and mechanistic investigations.The innovative combination of these two technologies may offer a fresh perspective for exploring the fundamental aspects of the human nervous system and related diseases.
基金supported by the Jilin Science and Technology Development Program,China (20240602032RC)the Jilin Agricultural Science and Technology Innovation Project,China (CXGC2024ZD001)+1 种基金the Jilin Agricultural Science and Technology Innovation Project,China (CXGC2024ZY012)the Jilin Province Development and Reform Commission-Project for Improving the Independent Innovation Capacity of Major Grain Crops,China (2024C002)。
文摘Emerging and powerful genome editing tools,particularly CRISPR/Cas9,are facilitating functional genomics research and accelerating crop improvement(Jiang et al.2021;Cao et al.2023;Chen C et al.2023;Liu et al.2023a).However,the detection and screening of transgenic lines remain major bottlenecks,being time-consuming,labor-intensive,and inefficient during transformation and subsequent mutation identification.A simple and efficient visual marker system plays a critical role in addressing these challenges.Recent studies demonstrated that the GmW1 and RUBY reporter systems were used to obtain visual transgenic soybean(Glycine max) plants(Chen L et al.2023;Chen et al.2024).
基金supported by the National Key R&D Program of China (Grant No.2023YFA1406400)the National Natural Science Foundation of China (Grant Nos.12534005 and 12325402)。
文摘Superconducting diodes,which enable dissipationless supercurrent flow in one direction while blocking it in the reverse direction,are emerging as pivotal components for superconducting electronics.The development of editable superconducting diodes could unlock transformative applications,including dynamically reconfigurable quantum circuits that adapt to operational requirements.Here,we report the first observation of the superconducting diode effect(SDE)in LaAlO_(3)/KTaO_(3) heterostructures—a two-dimensional oxide interface superconductor with exceptional tunability.We observe a strong SDE in Hall-bar(or strip-shaped)devices under perpendicular magnetic fields(<15 Oe),with efficiencies above 40%and rectification signals exceeding 10 mV.Through conductive atomic force microscope lithography,we demonstrate reversible nanoscale editing of the SDE’s polarity and efficiency by locally modifying the superconducting channel edges.This approach enables multiple nonvolatile configurations within a single device,realizing an editable superconducting diode.Our work establishes LaAlO_(3)/KTaO_(3) as a platform for vortex-based nonreciprocal transport and provides a pathway toward designer quantum circuits with on-demand functionalities.
基金the National Research Foundation of Korea(NRF)grant funded by the Korea government(MSIT)(RS-2024-00344633)HYC acknowledges the financial support from the National Research Foundation of Korea(NRF)grant funded by the Korea government(MSIT)(RS-2023-00211360)Biomaterials Specialized Graduate Program through the Korea Environmental Industry&Technology Institute(KEITI)funded by the Ministry of Environment(MOE).
文摘Genomic disorders affecting the central nervous system(CNS)are among the most complex and devastating conditions in human health.Moreover,these disorders,such as Rett syndrome,spinal muscular atrophy,and Fragile X syndrome,are typically caused by mutations in genes essential for neural development,synaptic function,or cellular homeostasis.Despite the genetic diversity involved,these diseases share key pathological features,including progressive neurodegeneration,disruption of neural circuits,and loss of cognitive or motor function.Meanwhile,one of the significant clinical challenges in treating CNS disorders is the limited regenerative capacity of the adult nervous system,which makes reversing disease progression extremely difficult once symptoms appear.In addition,the blood-brain barrier(BBB)restricts the passage of most systemically administered therapeutics,further complicating effective intervention.Consequently,current treatment options remain largely palliative,and effective cures remain elusive.
基金Research into Wolfram syndrome in the De Groef team has been supported by the Eye Hope Foundation(Belgium),Wolfram UK(UK)and The Snow Foundation(USA).
文摘Wolfram syndrome(WS)is a rare autosomal rece s s i ve disease characte r i zed by the development of diabetes insipidus,diabetes mellitus,optic atrophy,and deafness(often referred to as DIDMOAD),and overall severe neurodegenerative fallback.The global prevalence of this disease is estimated at 1 in 770,000(Lee et al.,2023).It is most commonly caused by biallelic(point)mutations in the Wolframin endoplasmic reticulum(ER)transmembrane glycoprotein(WFS1)gene(in case of WS type 1),but mutations in the CDGSH Iron Sulfur Domain 2(CISD2)are also linked to WS(type 2).The latter,however,often present with less severe pathological manifestations(Lee et al.,2023).WFS1 is located on chromosome 4p16.1 and spans over 33 kilobases.Many mutation variants have been identified in WFS1,encompassing missense,nonsense,and frameshift mutations.These mutations are spread across the coding region of WFS1,but certain regions,such as exon 8,the largest exon,appear particularly mutation-prone and associated with the classical WS type 1 phenotype(Lee et al.,2023).
基金supported by the National Natural Science Foundation of China(82404798)the Natural Science Foundation of Sichuan Province(2024NSFSC1831)+1 种基金the National Key Laboratory for Tropical Crop Breeding(NKLTCB-RC202403,NKLTCBZRJJ4)the Hainan Seed Industrial Laboratory(B22C1000P).
文摘Base editors are essential tools for precise genome editing in plants.However,achieving high efficiency in C-to-G editing while minimizing byproduct and offtarget mutations remains challenging.In this study,we present the development and evaluation of a novel glycosylase-based cytosine base editor(gCBE)for efficient C-to-G editing in rice.Unlike traditional cytosine base editors,which rely on cytosine deamination,gCBE directly excises cytosine to generate an apurinic/apyrimidinic(AP)site,thus circumventing the deamination step and reducing the production of C-to-T byproducts.We constructed several gCBE variants,including N-gCBE,M-gCBE,and C-gCBE,by fusing engineered human UDG2(UNG*)to SpCas9 nickase(nSpCas9,D10A)and tested their editing efficiency and specificity in rice.Our results demonstrate that M-gCBE achieved efficient C-to-G editing(6.3%to 37.5%)similar to OsCGBE(9.4%to 28.1%)at most targets,though with site-dependent variations.Notably,gCBE tools showed a marked reduction in C-to-T byproducts,with average C-to-T mutation rates of 12.5%for N-gCBE and 16.7%for M-gCBE,compared to 53.1%for OsCGBE.Notably,both N-gCBE and M-gCBE were capable of generating homozygous C-to-G mutations in the T_(0)generation,a key advantage over OsCGBE,which predominantly generated C-to-T mutations.Off-target analysis revealed minimal off-target effects with M-gCBE,highlighting its potential for high-precision genome editing.These findings suggest that gCBE tools,particularly M-gCBE,are highly efficient and precise,providing an advanced solution for C-to-G editing in plants and offering promising applications for crop improvement.
基金supported by a sub-award to the University of Missouri from the Heinrich Heine University of Dusseldorf funded by the Bill&Melinda Gates Foundation(OPP1155704)(Bing Yang)and the China Scholar Council(Chenhao Li,as a joint Ph.D.student).
文摘Bacterial blight(BB),caused by Xanthomonas oryzae pathovar oryzae(Xoo),poses a significant threat to rice production,particularly in Asia and West Africa.Breeding resistance against BB in elite rice varieties is crucial to advancing rice breeding program and supporting smallholder farmers.Transcription Activator-Like effectors(TALes)are key virulence factors in Xoo,with some targeting the susceptibility(S)genes such as the sugar transporter SWEET genes in rice.Among these,SWEET14 is an important S gene,with its promoter bound by the TALe TalC which exists across all sequenced African Xoo isolates.In the present study,we utilized CRISPR/Cas9-based cytidine and adenine base editors to alter the effector binding element(EBE)of TalC in the promoter of SWEET14 in rice cultivars Kitaake,IR24,and Zhonghua 11.Mutations with C to T changes in EBE led to reduced SWEET14 induction by TalC-containing Xoo strains,resulting in resistance to African Xoo isolates reliant on TalC for virulence.Conversely,A to G changes retained SWEET14 inducibility and susceptibility to Xoo in edited lines.Importantly,no off-target mutations were detected at predicted sites,and the edited lines exhibited no obvious defects in major agronomic traits in Kitaake.These results underscore the effectiveness of base editing systems for both molecular biology research and crop improvement endeavors.
文摘“Journal of Jilin University(Science Edition)” is a comprehensive academic journal in the fields of science sponsored by Jilin University and administrated by the Ministry of Education of the People's Republic of China.The journal started publication in 1955.The original name at starting publication was “Journal of Natural Science of Northeast People University”,which was changed into “Acta Scientiarum Naturalium Universitatis Jilinensis” in 1958owing to the name change of the university.
基金financially supported by the National Natural Science Foundation of China(No.52473097)the Fundamental Research Funds for the Central Universities(No.24X010301678)Shanghai Jiao Tong University 2030 Initiative(No.WH510363002/002)。
文摘Incorporating a low density of ester units into the backbone of polyethylene materials enhances their sustainability and recyclability while maintaining the main material properties of polyethylenes.Here we report a new way to access degradable polyethylene materials with a low content of in-chain ester units via mechanochemical backbone editing.Initially,ester groups are incorporated as side groups through catalytic copolymerization of ethylene with a cyclobutene-fused lactone monomer(CBL),yielding polyethylene materials with high molecular weights and adjustable thermomechanical properties.Subsequent solid-state ball-milling treatment selectively introduces side-chain ester groups into the main chain of the polyethylene materials via force-induced cycloreversion of the cyclobutane units.Under acidic conditions,hydrolysis of the resultant polyethylene materials with in-chain ester units facilitates further degradation into oligomers.
文摘On the morning of January 15,the China-Laos Cultural Road Dialogue took place in Vientiane,Laos.A ceremony was held during the event to release the January 2025 special editions of China Report ASEAN(an English journal)and Champa(a Chinese-Lao bilingual journal named after the national flower of Laos which is considered a symbol of sincerity and joy).Part of the 2025“One River,One Family”Spring Festival cultural series in Laos,the event was supervised by China International Communications Group(CICG),the Chinese Embassy in Laos,and China State Railway Group Company,hosted by the Publicity Department of the CPC Yunnan Provincial Committee and the Publicity Department of the Central Committee of the Lao People’s Revolutionary Party(LPRP),and organized by CICG Asia-Pacific,Yunnan Daily,Yunnan International Communication Center for South and Southeast Asia,Pasaxon(“The People”newspaper in Laos),and China Railway Kunming Group.
文摘Nonobstructive azoospermia(NOA)affects about 60%of men with azoospermia,representing a severe form of male infertility.The current approach to manage NOA primarily involves testicular sperm retrieval methods such as conventional testicular sperm extraction(c-TESE)and microdissection testicular sperm extraction(micro-TESE).While combining testicular sperm retrieval with intracytoplasmic sperm injection(ICSI)offers hope for patients,the overall sperm retrieval rate(SRR)stands at around 50%.In cases where micro-TESE fails to retrieve sperm,limited options,like donor sperm or adoption,can be problematic in certain cultural contexts.This paper delves into prospective treatments for NOA management.Gene editing technologies,particularly clustered regularly interspaced short palindromic repeats(CRISPR)/CRISPR-associated(Cas)protein 9(CRISPR/Cas9),hold potential for correcting genetic mutations underlying testicular dysfunction.However,these technologies face challenges due to their complexity,potential off-target effects,ethical concerns,and affordability.This calls for research to address key challenges associated with NOA management within the clinical settings.This also necessitate ongoing research essential for developing more sensitive diagnostic tests,validating novel treatments,and customizing current treatment strategies for individual patients.This review concluded that the future of NOA management may entail a combination of these treatment options,tailored to each patient’s unique circumstances,providing a comprehensive approach to address NOA challenges.
基金supported by Funding was provided by grants from the Changsha Chinese Medicine Foundation(Grant No.B202314)the Natural Science Foundation of Hunan Province,China(Grant No.2024JJ8224)+1 种基金Changsha Municipal Natural Science Foundation(Grant No.kq2403187)Hunan Province Children’s Safe Medication Clinical Medical Technology Demonstration Base(Grant No.2023SK4083).
文摘Pediatric congenital heart disease(CHD)pharmacotherapy faces three fundamental barriers:developmental pharmacokinetic complexity,anatomic-genetic heterogeneity,and evidence chain gaps.Traditional agents exhibit critical limitations:digoxin’s narrow therapeutic index(0.5–0.9 ng/mL)is exacerbated by ABCB1 mutations(toxicity risk increases 4.1-fold),furosemide efficacy declines by 35%in neonates due to NKCC2 immaturity,andβ-blocker responses vary by CYP2D6 polymorphisms(poor metabolizers require 50–75%dose reduction).Novel strategies demonstrate transformative potential—CRISPR editing achieves 81%reversal of BMPR2-associated pulmonary vascular remodeling,metabolically matured cardiac organoids replicate adult myocardial energy metabolism for drug screening,and SGLT2 inhibitors activate triple mechanisms(calcium overload mitigation,mitophagy,fibrosis reversal).However,clinical translation requires overcoming developmental barriers:age-dependent enzyme expression(infant CYP2D6=30–60%adult activity),post-Fontan hepatotoxicity(bosentan trough concentrations elevates 1.8-fold),and AI model limitations(32%error in complex CHD).Future integration of placental transfer models,disease-specific organoids,and multi-omics mapping of FOXO/CRIM1 pathways will shift paradigms from symptom control to curative repair.
文摘The monumental second edition Petroleum Geology of China has been published by the Petroleum Industry Press.This definitive work was compiled under the leadership of Academician Zhai Guangming,a preeminent authority in petroleum exploration.As the culmination of eight years of dedicated effort by over a thousand experts and scholars,this monumental publication comprises 25 volumes(bound in 32 books).
基金supported by the National Key Research and Development Program of China(2022-24)National Natural Science Foundation of China(42025604,42376102)Fundamental Research Funds for the Central Universities。
文摘Ectothermic organisms may expand their thermal tolerance by producing multiple protein isoforms with differing thermal sensitivities.While such isoforms commonly originate from allelic variation at a single locus(allozymes)or from gene duplication that gives rise to paralogs with distinct thermal responses,this study investigated mRNA editing as an alternative,post-transcriptional mechanism for generating mRNA variants.Cytosolic malate dehydrogenase(cMDH)was examined in foot tissue of two congeners of the marine mussel genus Mytilus,which occupy different thermal environments.Multiple editing events were detected within the mRNA coding region in both species.Editing sites were species-specific,with no shared positions identified.In M.coruscus,editing occurred at 117,123,135,190,195,204,279,and 444,while in M.galloprovincialis,editing was detected at 216 and 597.Each species exhibited multiple edited mRNA variants,and these isoforms were associated with differential protein expression.These findings suggest that mRNA editing may contribute an additional layer of molecular variation.The generation of diverse mRNA isoforms from a single DNA coding sequence may enhance enzymatic flexibility across temperature ranges,supporting eurythermal physiological performance and mitigating thermal stress.Moreover,the presence of multiple edited transcripts within individual organisms raises important caveats about the limitations of approaches that deduce amino acid sequences or estimate adaptive variation solely from genomic data.
