The efficient conversion of lignin into mono-cycloalkanes via both C–O and C–C bonds cleavage are attractive,but challenging due to the high C–C bond dissociation energy.Previous studies have demonstrated that NbO_...The efficient conversion of lignin into mono-cycloalkanes via both C–O and C–C bonds cleavage are attractive,but challenging due to the high C–C bond dissociation energy.Previous studies have demonstrated that NbO_(x)-based catalysts exhibited exceptional capabilities for C_(Ar)–C bond cleavage and broken the limitation of lignin monomers.In this work,we presented an economical multifunctional Pt-Nb/MOR catalyst that achieved an impressive monomer yield of 147%during the depolymerization and hydrodeoxygenation of lignin into mono-cycloalkanes.Reaction pathway studies showed that unlike traditional NbO_(x)-based catalytic system,bicyclohexane was an important intermediate in this system and followed the C_(sp3)–C_(sp3)cleavage pathway after complete cyclic-hydrogenation.Deep investigations demonstrated that the doping of Nb in Pt/MOR not only enhanced the activation of hydrogen by Pt,but also increased the acidity of MOR,both of these are favor for the hydrogenolytic cleavage of C_(sp3)–C_(sp3)bonds.This work provides a low-cost catalyst to obtain high-yield monomers from lignin under relatively mild conditions and would help to design catalysts with higher activity for the valorization of lignin.展开更多
The oxidation of lignin model compounds to esters via C-C bond cleavage has attracted considerable attention,as esters could be used as important polymer precursors and pharmaceutical intermediates.However,most studie...The oxidation of lignin model compounds to esters via C-C bond cleavage has attracted considerable attention,as esters could be used as important polymer precursors and pharmaceutical intermediates.However,most studies focus on designing homogeneous or noble metal catalysts and conducting the reactions under basic conditions.Here,we report an efficient process for the C-C bond cleavage of lignin model compounds and selectively producing esters over different shaped CeO_(2)(i.e.,nanospheres(S),nanorods(R),nanoparticles(P),and nanocubes(C))under base-free conditions.Specifically,the yield of methyl anisate from the aerobic oxidation of l-(4-methoxyphenyl)ethanol reaches 77.6%over CeO_(2)-S in one hour(91%in 9 h),exhibiting higher performance compared to other evaluated CeO_(2)catalysts(6.4%-40.2%).Extensivecharacterizations and experimental investigations reveal that the density of weak base sites and oxygen vacancies on the CeO_(2)surface is positively correlated with the yield of methyl esters.Furthermore,the reaction pathway is investigated,which confirms that 1-(4-methoxyphenyl)ethanol first undergoes two reactions(i.e.,etherification and dehydrogenation)to produce intermediates of1-methoxy-4-(1-methoxy-ethyl)-benzene and 1-(4-methoxyphenyl)ethanone,respectively,followed by a series of functional group transformations to generate the targeted methyl anisate ultimately.展开更多
Heterogeneous precious metal catalysts are prone to agglomeration during preparation,requiring high usage with consequently high costs.Maximizing the efficiency of precious-metal utilization is of great significance i...Heterogeneous precious metal catalysts are prone to agglomeration during preparation,requiring high usage with consequently high costs.Maximizing the efficiency of precious-metal utilization is of great significance in the design of supported precious metal catalysts.Herein,2,2'-bipyridyl-5,5'-dicarboxylic acid was used as the ligand in constructing the UiO-67-Ce-BPyDC framework with Ce^(4+)coordination.This framework enables precise adsorption and coordination of Pd2+at the nitrogen sites of pyridine,promoting high dispersion of the Pd species at a single site,thereby facilitating controlled palladium loading.This precursor was used to fabricate supported Pd-based catalysts on CeO_(2)(Pd-N/CeO_(2)-P)via pyrolysis.Notably,because the Pd species are homogeneously distributed on CeO_(2)with strong interactions,Pd-N/CeO_(2)-P exhibits remarkable efficiency in cleaving the C-O bonds of diphenyl ether(DPE)to produce cyclohexanol,with a selectivity of 72.1%.The origin of the high selectivity of cyclohexanol is further elucidated using theoretical calculations;that is,DPE undergoes not only hydrogenolysis on Pd-N/CeO_(2)-P,but also hydrolysis to produce more cyclohexanol.This study not only demonstrates a successful strategy for designing highly dispersed metal catalysts,but also underscores the importance of such tailored catalysts in the advancement of sustainable lignin depolymerization technologies.展开更多
While variable regions of immunoglobulins are extensively diversified by V(D)J recombination and somatic hypermutation in vertebrates,the constant regions of immunoglobulin heavy chains also utilize certain mechanisms...While variable regions of immunoglobulins are extensively diversified by V(D)J recombination and somatic hypermutation in vertebrates,the constant regions of immunoglobulin heavy chains also utilize certain mechanisms to produce diversity,including class switch recombination(CSR),subclass differentiation,and alternative expression of the same gene.Many species of birds,reptiles,and amphibians express a truncated isoform of immunoglobulin Y(IgY),termed IgY(ΔFc),which lacks theυCH3 andυCH4 domains.In Anseriformes,IgY(ΔFc)arises from alternative transcriptional termination sites within the sameυgene,whereas in some turtles,intact IgY and IgY(ΔFc)are encoded by distinct genes.Different from the previously reported IgY(ΔFc)variants,this study identified a truncated IgY in the snake Elaphe taeniura,characterized by the loss of only a portion of the CH4 domain.Western blotting and liquid chromatographytandem mass spectrometry confirmed that this truncated IgY is generated by post-translational cleavage at N338 within the IgY heavy chain constant(CH)region.Furthermore,both human and snake asparaginyl endopeptidase were shown to cleave snake IgY in vitro.These findings reveal a novel mechanism for the production of shortened IgY forms,demonstrating that the immunoglobulin CH region undergoes diversification through distinct strategies across vertebrates.展开更多
Litchi downy blight,caused by the plant pathogenic oomycete Peronophythora litchii,is one of the most devastating diseases on litchi and resulted in huge economic losses.Autophagy plays an essential role in the develo...Litchi downy blight,caused by the plant pathogenic oomycete Peronophythora litchii,is one of the most devastating diseases on litchi and resulted in huge economic losses.Autophagy plays an essential role in the development and pathogenicity of the filamentous fungi.However,the function of autophagy in oomycetes remain elusive.Here,an autophagy-related protein Atg3 homolog PlAtg3 was identified and characterized in P.litchii.The absence of PlATG3 through the CRISPR/Cas9 gene replacement strategy compromised vegetative growth and sexual/asexual development.Cytological analyses revealed that the deletion of PlATG3 impaired autophagosome formation with monodansylcadaverine(MDC)staining and significantly disrupted zoospore release due to defects of sporangial cleavage with FM4-64 staining.Atg8 is considered to be an autophagy marker protein in various species.Western blot analysis indicated that PlAtg3 is involved in degradation of PlAtg8-PE.Interestingly,PlAtg3 was unable to interact with PlAtg8 in yeast two hybrid(Y2H)assays,possibly due to the absence of the Atg8 family interacting motif(AIM)in PlAtg3.Furthermore,pathogenicity assays revealed that the deletion of PlATG3 considerably reduced the virulence of P.litchii.Taken together,our data reveal that PlAtg3 plays an important role in radial growth,asexual/sexual development,sporangial cleavage and zoospore release,autophagosome formation,and pathogenicity in P.litchii.This study contributes to a better understanding of the pathogenicity mechanisms of P.litchii and provides insights for the development of more effective strategies to control oomycete diseases.展开更多
Renewable electrocatalytic upgrading of biomass feedstocks into valuable chemicals is one of the promising strategies to relieve the pressure of traditional energy-based systems.Through electrocatalytic carbon–carbon...Renewable electrocatalytic upgrading of biomass feedstocks into valuable chemicals is one of the promising strategies to relieve the pressure of traditional energy-based systems.Through electrocatalytic carbon–carbon bond cleavage of high selectivity,various functionalized molecules,such as organic acids,amides,esters,and nitriles,have great potential to be accessed from biomass.However,it has merely received finite concerns and interests in the biorefinery.This review first showcases the research progress on the electrocatalytic conversion of lipid/sugar-and lignin-derived molecules(e.g.,glycerol,mesoerythritol,xylose,glucose,1-phenylethanol,and cyclohexanol)into organic acids via specific carbon–carbon bond scission processes,with focus on disclosing reaction mechanisms,recognizing actual active species,and collecting feasible modification strategies.For the guidance of further extensive studies on biomass valorization,organic transformations via a variety of reactions,including decarboxylation,ring-opening,rearrangement,reductive hydrogenation,and carboxylation,are also disclosed for the construction of similar carbon skeletons/scaffolds.The remaining challenges,prospective applications,and future objectives in terms of biomass conversion are also proposed.This review is expected to provide references to develop renewed electrocatalytic carbon–carbon bond cleavage transformation paths/strategies for biomass upgrading.展开更多
Organic phosphorus compounds containing sp^(3)-C—P(O)bonds are increasingly widely applied in catalysis,pharmaceuticals,materials,pesticides,and other fields,and their synthesis has become a research hotspot in chemi...Organic phosphorus compounds containing sp^(3)-C—P(O)bonds are increasingly widely applied in catalysis,pharmaceuticals,materials,pesticides,and other fields,and their synthesis has become a research hotspot in chemistry.Diarylmethyl phosphine oxides are important organic phosphorus compounds containing sp^(3)-C—P(O)bonds,but their synthesis is limited.Traditional methods for their synthesis require the use of halogenated compounds and harsh reaction conditions.A new method for the copper-mediated synthesis of(diarylmethyl)diarylphosphine oxides has been developed.This method involves the cleavage of the sp^(3)-C—N bond in N-diarylmethylsulfonamides,leading to the formation of diarylmethyl carbocations.The carbocations then react with diarylphosphine oxides to construct sp^(3)-C—P(O)bonds.Our method only requires the addition of stoichiometric,inexpensive CuBr2 and produces a series of target compounds in satisfactory yields.Thus,it provides a convenient,and cost-effective pathway for the synthesis of diarylmethyl phosphine oxides.展开更多
The population of surface broken bonds of some typical sulfide, oxide and salt-type minerals which may belong to cubic, tetragonal, hexagonal, or orthorhombic system, were calculated. In terms of the calculation resul...The population of surface broken bonds of some typical sulfide, oxide and salt-type minerals which may belong to cubic, tetragonal, hexagonal, or orthorhombic system, were calculated. In terms of the calculation results, the cleavage natures of these minerals were analyzed, and the relationship between surface broken bonds density and surface energy was also established. The results show that the surface broken bonds properties could be used to predict the cleavage nature of most of minerals, and the predicted cleavage planes agree well with those reported in previous literature. Moreover, this work explored a rule that, surface broken bonds density is directly related to surface energy with determination coefficient(R2) of over 0.8, indicating that the former is a dominant factor to determine the latter. Therefore, anisotropic surface broken bonds density can be used to predict the stability of mineral surface and the reactivity of surface atoms.展开更多
[Objective] The aim was to optimize Yanbian cow oocytes mature in vitro and cleavage system after nuclear transfer based on uniform design. [Method] Oocytes were recovered by aspiration method, and oocytes were mature...[Objective] The aim was to optimize Yanbian cow oocytes mature in vitro and cleavage system after nuclear transfer based on uniform design. [Method] Oocytes were recovered by aspiration method, and oocytes were matured in vitro (IVM) with different conditions, and then carried out nucleus transfer, fusion, activation and in vitro culture (IVC) of embryo. Effects of ovary storage temperature, maturation time and follicular diameter size on in vitro maturation and cleavage rates of cow oocytes were compared. [ Result] The best conditions of IVM of Yanbian cow oocytes was that: the oocytes of 8 mm diameter were matured in vitro for 24 hours when the ovaries were stored at 26℃ or 31 ℃. The best cleave conditions after nucleus transfer of oocytes was that: the oocytes of 6 mm or 8 mm diameter were cultured in vitro for 24 hours when the ovaries were stored at 26℃. [ Conclusion] The result has some reference to Yanbian cow and other cow breeding and population expanding propagation.展开更多
Direct ethanol fuel cells(DEFCs)are a promising alternative to conventional energy sources,offering high energy density,environmental sustainability,and operational safety.Compared to methanol fuel cells,DEFCs exhibit...Direct ethanol fuel cells(DEFCs)are a promising alternative to conventional energy sources,offering high energy density,environmental sustainability,and operational safety.Compared to methanol fuel cells,DEFCs exhibit lower toxicity and a more mature preparation process.Unlike hydrogen fuel cells,DEFCs provide superior storage and transport feasibility,as well as cost-effectiveness,significantly enhancing their commercial viability.However,the stable C-C bond in ethanol creates a high activation energy barrier,often resulting in incomplete electrooxidation.Current commercial platinum(Pt)-and palladium(Pd)-based catalysts demonstrate low C-C bond cleavage efficiency(<7.5%),severely limiting DEFC energy output and power density.Furthermore,high catalyst costs and insufficient activity impede large-scale commercialization.Recent advances in DEFC anode catalyst design have focused on optimizing material composition and elucidating catalytic mechanisms.This review systematically examines developments in ethanol electrooxidation catalysts over the past five years,highlighting strategies to improve C1 pathway selectivity and C-C bond activation.Key approaches,such as alloying,nanostructure engineering,and interfacial synergy effects,are discussed alongside their mechanistic implications.Finally,we outline current challenges and future prospects for DEFC commercialization.展开更多
A mixture of hypophosphorous acid (H3PO2) and iodine in acetic acid can cleave the N-alkyl bond in a variety of N-1 substituted pyrimidine derivative in relatively high yields, without any damage to the amido bond in ...A mixture of hypophosphorous acid (H3PO2) and iodine in acetic acid can cleave the N-alkyl bond in a variety of N-1 substituted pyrimidine derivative in relatively high yields, without any damage to the amido bond in the non-nucleosides pyrimidine base skeleton.展开更多
In the realm of drug discovery,recent advancements have paved the way for innovative approaches and methodologies.This comprehensive review encapsulates six distinct yet interrelated mini-reviews,each shedding light o...In the realm of drug discovery,recent advancements have paved the way for innovative approaches and methodologies.This comprehensive review encapsulates six distinct yet interrelated mini-reviews,each shedding light on novel strategies in drug development.(a)The resurgence of covalent drugs is highlighted,focusing on the targeted covalent inhibitors(TCIs)and their role in enhancing selectivity and affinity.(b)The potential of the quantum mechanics-based computational aid drug design(CADD)tool,Cov_DOX,is introduced for predicting protein-covalent ligand binding structures and affinities.(c)The scaffolding function of proteins is proposed as a new avenue for drug design,with a focus on modulating protein-protein interactions through small molecules and proteolysis targeting chimeras(PROTACs).(d)The concept of pro-PROTACs is explored as a promising strategy for cancer therapy,combining the principles of prodrugs and PROTACs to enhance specificity and reduce toxicity.(e)The design of prodrugs through carbon-carbon bond cleavage is discussed,offering a new perspective for the activation of drugs with limited modifiable functional groups.(f)The targeting of programmed cell death pathways in cancer therapies with small molecules is reviewed,emphasizing the induction of autophagy-dependent cell death,ferroptosis,and cuproptosis.These insights collectively contribute to a deeper understanding of the dynamic landscape of drug discovery.展开更多
Novel benzo-bridged hexaphyrin(2.1.2.1.2.1)and its copper complex were synthesized.Single-crystal structures showed typical figure-of-eight Huckel topologies.NMR,NICS,HOMA,ACID,and EDDB analysis supported their non-ar...Novel benzo-bridged hexaphyrin(2.1.2.1.2.1)and its copper complex were synthesized.Single-crystal structures showed typical figure-of-eight Huckel topologies.NMR,NICS,HOMA,ACID,and EDDB analysis supported their non-aromatic properties owning to the strong local aromatic benzo rings cutting the global aromatic ring of the benzo-bridged figure-of-eight hexaphyrin(2.1.2.1.2.1).The redox properties and degenerate HOMOs and LUMOs levels indicate multielectron donating and accepting abilities.展开更多
The valorization of biomass to produce biofuels has become a heavily investigated field due to the depletion of fossil fuels and environmental concerns.Among them,the research on deoxygenation of fatty acids or esters...The valorization of biomass to produce biofuels has become a heavily investigated field due to the depletion of fossil fuels and environmental concerns.Among them,the research on deoxygenation of fatty acids or esters derived from biomass as well as municipal sludge organics to produce diesel-like hydrocarbons has become a hot topic.Fatty acid is a key intermediate derived from ester hydrolysis,therefore has attracted more attention as a model compound.In this review,we first introduce and compare the three reaction pathways of hydrodeoxygenation,decarboxylation and decarbonylation,for the deoxygenation of fatty acids and esters.The preference of reaction pathway is closely related to the type of raw materials and catalysts as well as reaction conditions.The special purpose of this review is to summarize the dilemma and possible strategies for deoxygenation of fatty acids,which is expected to provide guidance for future exploration and concentrates.The atom utilization along with stability during reaction in a long time is the most important index for commercial economy.Herein,we propose that the rational design and delicate synthesis of stable single-atom non-noble catalysts may be the best solution.The ultimately goal is aiming to develop sustainable production of green diesel hydrocarbons.展开更多
Lignin is the only largest renewable aromatic resource in nature.Currently,most lignin is underutilized for low-value applications due to the complex structure and recalcitrant chemical properties.Over the past decade...Lignin is the only largest renewable aromatic resource in nature.Currently,most lignin is underutilized for low-value applications due to the complex structure and recalcitrant chemical properties.Over the past decades,extensive research has been devoted to valorizing lignin into aromatic N-heterocycles in the presence of nitrogen sources.It overcomes the element limitation,expands the products portfolio and would play a momentous role in value-added biorefinery concept.In this review,the latest research progress in the synthesis of N-heterocyclic compounds from lignin,lignin model compounds,and lignin-derived monomers(phenols,aromatic alcohols,aldehydes,ketones,and ethers)is presented.According to the structural characteristics of the products,these achievements are classified by the construction of five-,six-,and seven-membered N-heterocyclic compounds through one-step,multi-step,or one-pot multi-step reactions.Furthermore,the tailor-designed routes and catalytic systems,along with the reaction mechanisms/pathways involved are entirely discussed to elucidate the challenges regarding the structural complexity of lignin,the incompatible catalysis for C–O cleavage and C–N formation,as well as the nitrogen-heterocyclic ring construction.The prospects,future research efforts and process developments for the refining of lignin into aromatic N-heterocyclic compounds are outlined in terms of economy,environmental friendliness,and safety so as to draw some guidelines for lignin valorization.展开更多
Pyridyl-based ketones and 1,6-diketones are both attractive and invaluable scaffolds which play pivotal roles in the construction and structural modification of a plethora of synthetically paramount natural products,p...Pyridyl-based ketones and 1,6-diketones are both attractive and invaluable scaffolds which play pivotal roles in the construction and structural modification of a plethora of synthetically paramount natural products,pharmaceuticals,organic materials and fine chemicals.In this context,we herein demonstrate an unprecedented,robust and generally applicable synthetically strategy to deliver these two crucial ketone frameworks via visible-light-induced ring-opening coupling reactions of cycloalcohols with vinylazaarenes and enones,respectively.A plausible mechanism involves the selectiveβ-C-C bond cleavage of cycloalcohols enabled by proton-coupled electron transfer and ensuing Giese-type addition followed by single electron reduction and protonation.The synthetic methodology exhibits broad substrate scope,excellent functional group compatibility as well as operational simplicity and environmental friendliness.展开更多
Ultrasound(US),as an efficient and non-invasive trigger,has been extensively explored in drug delivery and has many advantages,such as deep penetration,low invasiveness,and high biochemical precision.These advantages ...Ultrasound(US),as an efficient and non-invasive trigger,has been extensively explored in drug delivery and has many advantages,such as deep penetration,low invasiveness,and high biochemical precision.These advantages demonstrate the immense clinical potential of ultrasound.This study aimed to provide a comprehensive analysis of ultrasound-induced shear forces that exhibit covalent/non-covalent bond cleavage and reactive oxygen species(ROS)-mediated remote control of nanocarriers.By doing so,we can gain a deeper understanding of the vital role,significant advantages,and untapped potential of ultrasound in molecular-level drug activation.Furthermore,clinical translation faces challenges such as the low drug-loading capacity of polymer chains,frequency compatibility between ultrasound parameters and biological systems,insufficient ROS generation,and biocompatibility of current sonosensitizers.To solve these problems,ultrasound mechanochemistry has emerged as a versatile therapeutic modality to promote the development of medical treatments.展开更多
Designing Fischer-Tropsch synthesis(FTS)catalysts to selectively produce liquid hydrocarbon fuels is a crucial challenge.Herein,we selectively introduced Co nanoparticles(NPs)into the micropores and mesopores of an or...Designing Fischer-Tropsch synthesis(FTS)catalysts to selectively produce liquid hydrocarbon fuels is a crucial challenge.Herein,we selectively introduced Co nanoparticles(NPs)into the micropores and mesopores of an ordered mesoporous MFI zeolite(OMMZ)through impregnation,which controlled the carbon number distribution in the FTS products by tuning the position of catalytic active sites in differently sized pores.The Co precursors coordinated by acetate with a size of 9.4×4.2×2.5Åand by 2,2'-bipyridine with a size of 9.5×8.7×7.9Å,smaller and larger than the micropores(ca.5.5Å)of MFI,made the Co species incorporated in OMMZ's micropores and mesopores,respectively.The carbon number products synthesized with the Co NPs confined in mesopores were larger than that in micropores.The high jet and diesel selectivities of 66.5%and 65.3%were achieved with Co NPs confined in micropores and mesopores of less acidic Na-type OMMZ,respectively.Gasoline and jet selectivities of 76.7%and 70.8%were achieved with Co NPs confined in micropores and mesopores of H-type OMMZ with Brönsted acid sites,respectively.A series of characterizations revealed that the selective production of diesel and jet fuels was due to the C-C cleavage suppressing of heavier hydrocarbons by the Co NPs located in mesopores.展开更多
The Pfitzinger reaction has long served as a notable synthesis pathway for quinoline-4-carboxylic acids.Although recognized for its synthetic potential since its discovery>138 years ago,a truly catalytic variant ha...The Pfitzinger reaction has long served as a notable synthesis pathway for quinoline-4-carboxylic acids.Although recognized for its synthetic potential since its discovery>138 years ago,a truly catalytic variant has remained elusive until now.Herein,we present a novel 2-tert-butyl-1,1,3,3-tetramethylguanidine(BTMG)-catalyzed Pfitzinger reaction that employs N-[(α-trifluoromethyl)vinyl]isatins with amines and alcohols,providing direct routes to 2-CF_(3)-quinoline-4-carboxamides and carboxylic esters.This method is not only green and environmentally benign but also accommodates the introduction of other functional groups like CF_(2)H and CO_(2)Me at the C2 position of quinoline skeleton.The utility of this methodology was demonstrated by the broad substrate scope,the late-stage modification of commercial drugs,and the diverse derivatization of quinoline framework.More importantly,this work not only opens up a new avenue for the activation of amide C-N bonds in catalytic reaction development,but also unlocks the huge potential of some 2-trifluoromethyl quinolines with strong inhibitory activity against PTP1B or optoelectronic application in organic light-emitting diodes.展开更多
文摘The efficient conversion of lignin into mono-cycloalkanes via both C–O and C–C bonds cleavage are attractive,but challenging due to the high C–C bond dissociation energy.Previous studies have demonstrated that NbO_(x)-based catalysts exhibited exceptional capabilities for C_(Ar)–C bond cleavage and broken the limitation of lignin monomers.In this work,we presented an economical multifunctional Pt-Nb/MOR catalyst that achieved an impressive monomer yield of 147%during the depolymerization and hydrodeoxygenation of lignin into mono-cycloalkanes.Reaction pathway studies showed that unlike traditional NbO_(x)-based catalytic system,bicyclohexane was an important intermediate in this system and followed the C_(sp3)–C_(sp3)cleavage pathway after complete cyclic-hydrogenation.Deep investigations demonstrated that the doping of Nb in Pt/MOR not only enhanced the activation of hydrogen by Pt,but also increased the acidity of MOR,both of these are favor for the hydrogenolytic cleavage of C_(sp3)–C_(sp3)bonds.This work provides a low-cost catalyst to obtain high-yield monomers from lignin under relatively mild conditions and would help to design catalysts with higher activity for the valorization of lignin.
基金financially supported by the National Key Research and Development Program of China(No.2023YFD2200505)the National Natural Science Foundation of China(No.22202105)+3 种基金the Natural Science Foundation of Jiangsu Higher Education Institutions of China(No.21KJA150003)the Innovation and Entrepreneurship Team Program of Jiangsu Province(No.JSSCTD202345)the Postgraduate Research&Practice Innovation Program of Jiangsu Province(No.KYCX23_1163)the China Postdoctoral Science Foundation(Nos.2023M731703 and 2024T170415)
文摘The oxidation of lignin model compounds to esters via C-C bond cleavage has attracted considerable attention,as esters could be used as important polymer precursors and pharmaceutical intermediates.However,most studies focus on designing homogeneous or noble metal catalysts and conducting the reactions under basic conditions.Here,we report an efficient process for the C-C bond cleavage of lignin model compounds and selectively producing esters over different shaped CeO_(2)(i.e.,nanospheres(S),nanorods(R),nanoparticles(P),and nanocubes(C))under base-free conditions.Specifically,the yield of methyl anisate from the aerobic oxidation of l-(4-methoxyphenyl)ethanol reaches 77.6%over CeO_(2)-S in one hour(91%in 9 h),exhibiting higher performance compared to other evaluated CeO_(2)catalysts(6.4%-40.2%).Extensivecharacterizations and experimental investigations reveal that the density of weak base sites and oxygen vacancies on the CeO_(2)surface is positively correlated with the yield of methyl esters.Furthermore,the reaction pathway is investigated,which confirms that 1-(4-methoxyphenyl)ethanol first undergoes two reactions(i.e.,etherification and dehydrogenation)to produce intermediates of1-methoxy-4-(1-methoxy-ethyl)-benzene and 1-(4-methoxyphenyl)ethanone,respectively,followed by a series of functional group transformations to generate the targeted methyl anisate ultimately.
基金Project supported by the National Natural Science Foundation of China(22221001,22131007,22102193)the National Key R&D Program of China(2021YFA1501101,2022YFA1504601)+1 种基金the 111 Project(B20027)a Startup Program of the State Key Laboratory for Oxo Synthesis and Selective Oxidation of LICP(EOSX0184)。
文摘Heterogeneous precious metal catalysts are prone to agglomeration during preparation,requiring high usage with consequently high costs.Maximizing the efficiency of precious-metal utilization is of great significance in the design of supported precious metal catalysts.Herein,2,2'-bipyridyl-5,5'-dicarboxylic acid was used as the ligand in constructing the UiO-67-Ce-BPyDC framework with Ce^(4+)coordination.This framework enables precise adsorption and coordination of Pd2+at the nitrogen sites of pyridine,promoting high dispersion of the Pd species at a single site,thereby facilitating controlled palladium loading.This precursor was used to fabricate supported Pd-based catalysts on CeO_(2)(Pd-N/CeO_(2)-P)via pyrolysis.Notably,because the Pd species are homogeneously distributed on CeO_(2)with strong interactions,Pd-N/CeO_(2)-P exhibits remarkable efficiency in cleaving the C-O bonds of diphenyl ether(DPE)to produce cyclohexanol,with a selectivity of 72.1%.The origin of the high selectivity of cyclohexanol is further elucidated using theoretical calculations;that is,DPE undergoes not only hydrogenolysis on Pd-N/CeO_(2)-P,but also hydrolysis to produce more cyclohexanol.This study not only demonstrates a successful strategy for designing highly dispersed metal catalysts,but also underscores the importance of such tailored catalysts in the advancement of sustainable lignin depolymerization technologies.
基金supported by the Fundamental Research Funds for the Central Universities,Southwest Minzu University(ZYN2023097)Scientific and Technological Innovation Team for Qinghai-Xizang Plateau Research in Southwest Minzu University(2024CXTD13)。
文摘While variable regions of immunoglobulins are extensively diversified by V(D)J recombination and somatic hypermutation in vertebrates,the constant regions of immunoglobulin heavy chains also utilize certain mechanisms to produce diversity,including class switch recombination(CSR),subclass differentiation,and alternative expression of the same gene.Many species of birds,reptiles,and amphibians express a truncated isoform of immunoglobulin Y(IgY),termed IgY(ΔFc),which lacks theυCH3 andυCH4 domains.In Anseriformes,IgY(ΔFc)arises from alternative transcriptional termination sites within the sameυgene,whereas in some turtles,intact IgY and IgY(ΔFc)are encoded by distinct genes.Different from the previously reported IgY(ΔFc)variants,this study identified a truncated IgY in the snake Elaphe taeniura,characterized by the loss of only a portion of the CH4 domain.Western blotting and liquid chromatographytandem mass spectrometry confirmed that this truncated IgY is generated by post-translational cleavage at N338 within the IgY heavy chain constant(CH)region.Furthermore,both human and snake asparaginyl endopeptidase were shown to cleave snake IgY in vitro.These findings reveal a novel mechanism for the production of shortened IgY forms,demonstrating that the immunoglobulin CH region undergoes diversification through distinct strategies across vertebrates.
基金supported by the grants from the Hainan Provincial Natural Science Foundation,China(321QN190 and 321CXTD437)the National Natural Science Foundation of China(32202246 and 32160614)+1 种基金the Open Project Program of Fujian Key Laboratory for Monitoring and Integrated Management of Crop Pests,China(MIMCP-202102)the Scientific Research Foundation of Hainan University,China(KYQD(ZR)-21042 and KYQD(ZR)-20080)。
文摘Litchi downy blight,caused by the plant pathogenic oomycete Peronophythora litchii,is one of the most devastating diseases on litchi and resulted in huge economic losses.Autophagy plays an essential role in the development and pathogenicity of the filamentous fungi.However,the function of autophagy in oomycetes remain elusive.Here,an autophagy-related protein Atg3 homolog PlAtg3 was identified and characterized in P.litchii.The absence of PlATG3 through the CRISPR/Cas9 gene replacement strategy compromised vegetative growth and sexual/asexual development.Cytological analyses revealed that the deletion of PlATG3 impaired autophagosome formation with monodansylcadaverine(MDC)staining and significantly disrupted zoospore release due to defects of sporangial cleavage with FM4-64 staining.Atg8 is considered to be an autophagy marker protein in various species.Western blot analysis indicated that PlAtg3 is involved in degradation of PlAtg8-PE.Interestingly,PlAtg3 was unable to interact with PlAtg8 in yeast two hybrid(Y2H)assays,possibly due to the absence of the Atg8 family interacting motif(AIM)in PlAtg3.Furthermore,pathogenicity assays revealed that the deletion of PlATG3 considerably reduced the virulence of P.litchii.Taken together,our data reveal that PlAtg3 plays an important role in radial growth,asexual/sexual development,sporangial cleavage and zoospore release,autophagosome formation,and pathogenicity in P.litchii.This study contributes to a better understanding of the pathogenicity mechanisms of P.litchii and provides insights for the development of more effective strategies to control oomycete diseases.
基金financially supported by the National Natural Science Foundation of China(22368014)the Guizhou Provincial S&T Project(ZK[2022]011,GCC[2023]011)+1 种基金the Guizhou Provincial Higher Education Institution Program(Qianjiaoji[2023]082)supported by RUDN University Strategic Academic Leadership Program。
文摘Renewable electrocatalytic upgrading of biomass feedstocks into valuable chemicals is one of the promising strategies to relieve the pressure of traditional energy-based systems.Through electrocatalytic carbon–carbon bond cleavage of high selectivity,various functionalized molecules,such as organic acids,amides,esters,and nitriles,have great potential to be accessed from biomass.However,it has merely received finite concerns and interests in the biorefinery.This review first showcases the research progress on the electrocatalytic conversion of lipid/sugar-and lignin-derived molecules(e.g.,glycerol,mesoerythritol,xylose,glucose,1-phenylethanol,and cyclohexanol)into organic acids via specific carbon–carbon bond scission processes,with focus on disclosing reaction mechanisms,recognizing actual active species,and collecting feasible modification strategies.For the guidance of further extensive studies on biomass valorization,organic transformations via a variety of reactions,including decarboxylation,ring-opening,rearrangement,reductive hydrogenation,and carboxylation,are also disclosed for the construction of similar carbon skeletons/scaffolds.The remaining challenges,prospective applications,and future objectives in terms of biomass conversion are also proposed.This review is expected to provide references to develop renewed electrocatalytic carbon–carbon bond cleavage transformation paths/strategies for biomass upgrading.
文摘Organic phosphorus compounds containing sp^(3)-C—P(O)bonds are increasingly widely applied in catalysis,pharmaceuticals,materials,pesticides,and other fields,and their synthesis has become a research hotspot in chemistry.Diarylmethyl phosphine oxides are important organic phosphorus compounds containing sp^(3)-C—P(O)bonds,but their synthesis is limited.Traditional methods for their synthesis require the use of halogenated compounds and harsh reaction conditions.A new method for the copper-mediated synthesis of(diarylmethyl)diarylphosphine oxides has been developed.This method involves the cleavage of the sp^(3)-C—N bond in N-diarylmethylsulfonamides,leading to the formation of diarylmethyl carbocations.The carbocations then react with diarylphosphine oxides to construct sp^(3)-C—P(O)bonds.Our method only requires the addition of stoichiometric,inexpensive CuBr2 and produces a series of target compounds in satisfactory yields.Thus,it provides a convenient,and cost-effective pathway for the synthesis of diarylmethyl phosphine oxides.
基金Project(50831006)supported by the National Natural Science Foundation of ChinaProject(2012BAB10B05)supported by the National Key Technologies R&D Program of China
文摘The population of surface broken bonds of some typical sulfide, oxide and salt-type minerals which may belong to cubic, tetragonal, hexagonal, or orthorhombic system, were calculated. In terms of the calculation results, the cleavage natures of these minerals were analyzed, and the relationship between surface broken bonds density and surface energy was also established. The results show that the surface broken bonds properties could be used to predict the cleavage nature of most of minerals, and the predicted cleavage planes agree well with those reported in previous literature. Moreover, this work explored a rule that, surface broken bonds density is directly related to surface energy with determination coefficient(R2) of over 0.8, indicating that the former is a dominant factor to determine the latter. Therefore, anisotropic surface broken bonds density can be used to predict the stability of mineral surface and the reactivity of surface atoms.
文摘[Objective] The aim was to optimize Yanbian cow oocytes mature in vitro and cleavage system after nuclear transfer based on uniform design. [Method] Oocytes were recovered by aspiration method, and oocytes were matured in vitro (IVM) with different conditions, and then carried out nucleus transfer, fusion, activation and in vitro culture (IVC) of embryo. Effects of ovary storage temperature, maturation time and follicular diameter size on in vitro maturation and cleavage rates of cow oocytes were compared. [ Result] The best conditions of IVM of Yanbian cow oocytes was that: the oocytes of 8 mm diameter were matured in vitro for 24 hours when the ovaries were stored at 26℃ or 31 ℃. The best cleave conditions after nucleus transfer of oocytes was that: the oocytes of 6 mm or 8 mm diameter were cultured in vitro for 24 hours when the ovaries were stored at 26℃. [ Conclusion] The result has some reference to Yanbian cow and other cow breeding and population expanding propagation.
基金supported by the National Natural Science Foundation of China(22472023,22202037)the Jilin Province Science and Technology Development Program(20250102077JC)the Fundamental Research Funds for the Central Universities(2412024QD014,2412023QD019).
文摘Direct ethanol fuel cells(DEFCs)are a promising alternative to conventional energy sources,offering high energy density,environmental sustainability,and operational safety.Compared to methanol fuel cells,DEFCs exhibit lower toxicity and a more mature preparation process.Unlike hydrogen fuel cells,DEFCs provide superior storage and transport feasibility,as well as cost-effectiveness,significantly enhancing their commercial viability.However,the stable C-C bond in ethanol creates a high activation energy barrier,often resulting in incomplete electrooxidation.Current commercial platinum(Pt)-and palladium(Pd)-based catalysts demonstrate low C-C bond cleavage efficiency(<7.5%),severely limiting DEFC energy output and power density.Furthermore,high catalyst costs and insufficient activity impede large-scale commercialization.Recent advances in DEFC anode catalyst design have focused on optimizing material composition and elucidating catalytic mechanisms.This review systematically examines developments in ethanol electrooxidation catalysts over the past five years,highlighting strategies to improve C1 pathway selectivity and C-C bond activation.Key approaches,such as alloying,nanostructure engineering,and interfacial synergy effects,are discussed alongside their mechanistic implications.Finally,we outline current challenges and future prospects for DEFC commercialization.
文摘A mixture of hypophosphorous acid (H3PO2) and iodine in acetic acid can cleave the N-alkyl bond in a variety of N-1 substituted pyrimidine derivative in relatively high yields, without any damage to the amido bond in the non-nucleosides pyrimidine base skeleton.
基金supported by grants from the National Natural Science Foundation of China(No.82273770)the Foundation for Innovative Research Groups of the National Natural Science Foundation of Sichuan Province(No.24NSFTD0051).
文摘In the realm of drug discovery,recent advancements have paved the way for innovative approaches and methodologies.This comprehensive review encapsulates six distinct yet interrelated mini-reviews,each shedding light on novel strategies in drug development.(a)The resurgence of covalent drugs is highlighted,focusing on the targeted covalent inhibitors(TCIs)and their role in enhancing selectivity and affinity.(b)The potential of the quantum mechanics-based computational aid drug design(CADD)tool,Cov_DOX,is introduced for predicting protein-covalent ligand binding structures and affinities.(c)The scaffolding function of proteins is proposed as a new avenue for drug design,with a focus on modulating protein-protein interactions through small molecules and proteolysis targeting chimeras(PROTACs).(d)The concept of pro-PROTACs is explored as a promising strategy for cancer therapy,combining the principles of prodrugs and PROTACs to enhance specificity and reduce toxicity.(e)The design of prodrugs through carbon-carbon bond cleavage is discussed,offering a new perspective for the activation of drugs with limited modifiable functional groups.(f)The targeting of programmed cell death pathways in cancer therapies with small molecules is reviewed,emphasizing the induction of autophagy-dependent cell death,ferroptosis,and cuproptosis.These insights collectively contribute to a deeper understanding of the dynamic landscape of drug discovery.
基金partly supported by the National Natural Science Foundation of China(No.22301108)the Project Startup Foundation for Distinguished Scholars of Jiangsu University(Nos.4111310026 and 5501310014).
文摘Novel benzo-bridged hexaphyrin(2.1.2.1.2.1)and its copper complex were synthesized.Single-crystal structures showed typical figure-of-eight Huckel topologies.NMR,NICS,HOMA,ACID,and EDDB analysis supported their non-aromatic properties owning to the strong local aromatic benzo rings cutting the global aromatic ring of the benzo-bridged figure-of-eight hexaphyrin(2.1.2.1.2.1).The redox properties and degenerate HOMOs and LUMOs levels indicate multielectron donating and accepting abilities.
基金supported by the National Key R&D Program of China (No. 2021YFE0104900)Guangdong Basic and Applied Basic Research Foundation (No. 2023A1515030018)
文摘The valorization of biomass to produce biofuels has become a heavily investigated field due to the depletion of fossil fuels and environmental concerns.Among them,the research on deoxygenation of fatty acids or esters derived from biomass as well as municipal sludge organics to produce diesel-like hydrocarbons has become a hot topic.Fatty acid is a key intermediate derived from ester hydrolysis,therefore has attracted more attention as a model compound.In this review,we first introduce and compare the three reaction pathways of hydrodeoxygenation,decarboxylation and decarbonylation,for the deoxygenation of fatty acids and esters.The preference of reaction pathway is closely related to the type of raw materials and catalysts as well as reaction conditions.The special purpose of this review is to summarize the dilemma and possible strategies for deoxygenation of fatty acids,which is expected to provide guidance for future exploration and concentrates.The atom utilization along with stability during reaction in a long time is the most important index for commercial economy.Herein,we propose that the rational design and delicate synthesis of stable single-atom non-noble catalysts may be the best solution.The ultimately goal is aiming to develop sustainable production of green diesel hydrocarbons.
文摘Lignin is the only largest renewable aromatic resource in nature.Currently,most lignin is underutilized for low-value applications due to the complex structure and recalcitrant chemical properties.Over the past decades,extensive research has been devoted to valorizing lignin into aromatic N-heterocycles in the presence of nitrogen sources.It overcomes the element limitation,expands the products portfolio and would play a momentous role in value-added biorefinery concept.In this review,the latest research progress in the synthesis of N-heterocyclic compounds from lignin,lignin model compounds,and lignin-derived monomers(phenols,aromatic alcohols,aldehydes,ketones,and ethers)is presented.According to the structural characteristics of the products,these achievements are classified by the construction of five-,six-,and seven-membered N-heterocyclic compounds through one-step,multi-step,or one-pot multi-step reactions.Furthermore,the tailor-designed routes and catalytic systems,along with the reaction mechanisms/pathways involved are entirely discussed to elucidate the challenges regarding the structural complexity of lignin,the incompatible catalysis for C–O cleavage and C–N formation,as well as the nitrogen-heterocyclic ring construction.The prospects,future research efforts and process developments for the refining of lignin into aromatic N-heterocyclic compounds are outlined in terms of economy,environmental friendliness,and safety so as to draw some guidelines for lignin valorization.
基金financial support from National Natural Science Foundation of China(Nos.21801129,22078153 and22378201)National Key Research and Development Program of China(No.2022YFB3805603)+3 种基金Natural science research projects in Jiangsu Higher Education Institutions(No.18KJB150018)Open Research Fund of School of Chemistry and Chemical EngineeringHenan Normal University(No.2024Y16)Nanjing Tech University(Start-up Grant Nos.39837137,39837101 and 3827401739)for financial support。
文摘Pyridyl-based ketones and 1,6-diketones are both attractive and invaluable scaffolds which play pivotal roles in the construction and structural modification of a plethora of synthetically paramount natural products,pharmaceuticals,organic materials and fine chemicals.In this context,we herein demonstrate an unprecedented,robust and generally applicable synthetically strategy to deliver these two crucial ketone frameworks via visible-light-induced ring-opening coupling reactions of cycloalcohols with vinylazaarenes and enones,respectively.A plausible mechanism involves the selectiveβ-C-C bond cleavage of cycloalcohols enabled by proton-coupled electron transfer and ensuing Giese-type addition followed by single electron reduction and protonation.The synthetic methodology exhibits broad substrate scope,excellent functional group compatibility as well as operational simplicity and environmental friendliness.
基金financially supported by the Young Scientists Fund of the National Natural Science Foundation of China(No.22305173)Young Scientists Fund of the Natural Science Foundation of Tianjin(No.S25QNM009)+2 种基金Tianjin University Independent Innovation Fund(No.2025XSU-0008)the National Natural Science Foundation of China(No.22475151)Xiaomi Young Talents Program。
文摘Ultrasound(US),as an efficient and non-invasive trigger,has been extensively explored in drug delivery and has many advantages,such as deep penetration,low invasiveness,and high biochemical precision.These advantages demonstrate the immense clinical potential of ultrasound.This study aimed to provide a comprehensive analysis of ultrasound-induced shear forces that exhibit covalent/non-covalent bond cleavage and reactive oxygen species(ROS)-mediated remote control of nanocarriers.By doing so,we can gain a deeper understanding of the vital role,significant advantages,and untapped potential of ultrasound in molecular-level drug activation.Furthermore,clinical translation faces challenges such as the low drug-loading capacity of polymer chains,frequency compatibility between ultrasound parameters and biological systems,insufficient ROS generation,and biocompatibility of current sonosensitizers.To solve these problems,ultrasound mechanochemistry has emerged as a versatile therapeutic modality to promote the development of medical treatments.
文摘Designing Fischer-Tropsch synthesis(FTS)catalysts to selectively produce liquid hydrocarbon fuels is a crucial challenge.Herein,we selectively introduced Co nanoparticles(NPs)into the micropores and mesopores of an ordered mesoporous MFI zeolite(OMMZ)through impregnation,which controlled the carbon number distribution in the FTS products by tuning the position of catalytic active sites in differently sized pores.The Co precursors coordinated by acetate with a size of 9.4×4.2×2.5Åand by 2,2'-bipyridine with a size of 9.5×8.7×7.9Å,smaller and larger than the micropores(ca.5.5Å)of MFI,made the Co species incorporated in OMMZ's micropores and mesopores,respectively.The carbon number products synthesized with the Co NPs confined in mesopores were larger than that in micropores.The high jet and diesel selectivities of 66.5%and 65.3%were achieved with Co NPs confined in micropores and mesopores of less acidic Na-type OMMZ,respectively.Gasoline and jet selectivities of 76.7%and 70.8%were achieved with Co NPs confined in micropores and mesopores of H-type OMMZ with Brönsted acid sites,respectively.A series of characterizations revealed that the selective production of diesel and jet fuels was due to the C-C cleavage suppressing of heavier hydrocarbons by the Co NPs located in mesopores.
基金National Natural Science Foundation of China(Nos.22171056,22122402,21801050)Outstanding Youth Project of Guangdong Natural Science Foundation(Nos.2024B1515020036,2021B1515020048)+3 种基金Guangdong Natural Science Foundation(Nos.2023A1515011313,2021A1515010510,2024A1515030037)Tertiary Education Scientific Research Project of Guangzhou Municipal Education Bureau(No.202235305)the Open Fund from Key Laboratory of Organofluorine ChemistryShanghai Engineering Research Center of Molecular Therapeutics and New Drug Development are gratefully acknowledged for financial support.
文摘The Pfitzinger reaction has long served as a notable synthesis pathway for quinoline-4-carboxylic acids.Although recognized for its synthetic potential since its discovery>138 years ago,a truly catalytic variant has remained elusive until now.Herein,we present a novel 2-tert-butyl-1,1,3,3-tetramethylguanidine(BTMG)-catalyzed Pfitzinger reaction that employs N-[(α-trifluoromethyl)vinyl]isatins with amines and alcohols,providing direct routes to 2-CF_(3)-quinoline-4-carboxamides and carboxylic esters.This method is not only green and environmentally benign but also accommodates the introduction of other functional groups like CF_(2)H and CO_(2)Me at the C2 position of quinoline skeleton.The utility of this methodology was demonstrated by the broad substrate scope,the late-stage modification of commercial drugs,and the diverse derivatization of quinoline framework.More importantly,this work not only opens up a new avenue for the activation of amide C-N bonds in catalytic reaction development,but also unlocks the huge potential of some 2-trifluoromethyl quinolines with strong inhibitory activity against PTP1B or optoelectronic application in organic light-emitting diodes.
