Feeding strategies of an organism depend on the multimodal sensory processing that most efficiently integrates available visual,chemosensory,and/or mechanoreceptive cues as part of their environmental adaptation.The b...Feeding strategies of an organism depend on the multimodal sensory processing that most efficiently integrates available visual,chemosensory,and/or mechanoreceptive cues as part of their environmental adaptation.The blind cavefish morph of Astyanax mexicanus has developed sensory-dependent behaviors to find food more efficiently than their eyed,surface-morph counterparts while in darkness.In the absence of light,adult cavefish have evolved enhanced behaviors,such as vibration attraction behavior(VAB),and changes in feeding angle.Here,we identified evolved differences in cavefish larval prey capture(LPC)behavior.In the dark,LPC is more efficient in cavefish than in surface fish.Furthermore,different cave populations express laterality in their LPC and strike towards prey preferentially located on their left or right sides.This suggests the occurrence,to some extent,of divergent LPC evolution among cave populations.While LPC can be triggered exclusively by a vibration stimulus in both surface and cavefish,we provide evidence that LPC is,at least partially,a multimodal sensory process different from adult VAB.We also found that a lack of food may exacerbate the laterality of LPC.Thus,we proposed a mathematical model for explaining laterality based on a balance between:(1)enlarged range of foraging field(behavioral or perceptive)due to asymmetry,(2)food abundance,and(3)disadvantages caused by laterality(unequal lateral hydrodynamic resistance when swimming,allocation of resources for the brain and receptors,and predator escape).展开更多
Karst caves are characterized by darkness,low temperature,high humidity,and oligotrophic organisms due to its relatively closed and strongly zonal environments.Up to now,1626 species in 644 genera of fungi have been r...Karst caves are characterized by darkness,low temperature,high humidity,and oligotrophic organisms due to its relatively closed and strongly zonal environments.Up to now,1626 species in 644 genera of fungi have been reported from caves and mines worldwide.In this study,we investigated the culturable mycobiota in karst caves in southwest China.In total,251 samples from thirteen caves were collected and 2344 fungal strains were isolated using dilution plate method.Preliminary ITS analyses showed that these strains belonged to 610 species in 253 genera.Among these species,88.0%belonged to Ascomy-cota,8.0%Basidiomycota,1.9%Mortierellomycota,1.9%Mucoromycota,and 0.2%Glomeromycota.The majority of these species have been previously known from other environments,and some of them are known as mycorrhizal or pathogenic fungi.About 52.8%of these species were discovered for the first time in karst caves.Based on morphological and phyloge-netic distinctions,33 new species were identified and described in this paper.Meanwhile,one new genus of Cordycipitaceae,Gamszarea,and five new combinations are established.This work further demonstrated that Karst caves encompass a high fungal diversity,including a number of previously unknown species.Taxonomic novelties:New genus:Gamszarea Z.F.Zhang&L.Cai;Novel species:Amphichorda cavernicola,Aspergillus limoniformis,Aspergillus phialiformis,Aspergillus phialosimplex,Auxarthron chinense,Auxarthron guangxiense,Auxarthronopsis globiasca,Auxarthronopsis pedicellaris,Auxarthronopsis pulverea,Auxarthronopsis stercicola,Chrysosporium pallidum,Gamszarea humicola,Gamszarea lunata,Gamszarea microspora,Gymnoascus flavus,Jattaea reniformis,Lecanicillium magnisporum,Microascus collaris,Microas-cus levis,Microascus sparsimycelialis,Microascus superficialis,Microascus trigonus,Nigrospora globosa,Paracremonium apiculatum,Paracremonium ellipsoideum,Paraphaeosphaeria hydei,Pseudoscopulariopsis asperispora,Setophaeosphaeria microspora,Simplicillium album,Simplicillium humicola,Wardomycopsis dolichi,Wardomycopsis ellipsoconidiophora,Wardomycopsis fusca;New combinations:Gamszarea indonesiaca(Kurihara&Sukarno)Z.F.Zhang&L.Cai,Gamszarea kalimantanensis(Kurihara&Sukarno)Z.F.Zhang&L.Cai,Gamszarea restricta(Hubka,Kubátová,Nonaka,Čmoková&Řehulka)Z.F.Zhang&L.Cai,Gamszarea testudinea(Hubka,Kubátová,Nonaka,Čmoková&Řehulka)Z.F.Zhang&L.Cai,Gamszarea wallacei(H.C.Evans)Z.F.Zhang&L.Cai.展开更多
基金funded by German Sumbre at the Institut de Biologie de l’ENS (IBENS), CNRS, FranceSylvie Rétaux at the Paris-Saclay Institute of Neuroscience, CNRSUniversity Paris-Saclay, France
文摘Feeding strategies of an organism depend on the multimodal sensory processing that most efficiently integrates available visual,chemosensory,and/or mechanoreceptive cues as part of their environmental adaptation.The blind cavefish morph of Astyanax mexicanus has developed sensory-dependent behaviors to find food more efficiently than their eyed,surface-morph counterparts while in darkness.In the absence of light,adult cavefish have evolved enhanced behaviors,such as vibration attraction behavior(VAB),and changes in feeding angle.Here,we identified evolved differences in cavefish larval prey capture(LPC)behavior.In the dark,LPC is more efficient in cavefish than in surface fish.Furthermore,different cave populations express laterality in their LPC and strike towards prey preferentially located on their left or right sides.This suggests the occurrence,to some extent,of divergent LPC evolution among cave populations.While LPC can be triggered exclusively by a vibration stimulus in both surface and cavefish,we provide evidence that LPC is,at least partially,a multimodal sensory process different from adult VAB.We also found that a lack of food may exacerbate the laterality of LPC.Thus,we proposed a mathematical model for explaining laterality based on a balance between:(1)enlarged range of foraging field(behavioral or perceptive)due to asymmetry,(2)food abundance,and(3)disadvantages caused by laterality(unequal lateral hydrodynamic resistance when swimming,allocation of resources for the brain and receptors,and predator escape).
基金This study was financially supported by NSFC(31725001)the Science and Technology Partnership Program,MOST(KY201701011)+1 种基金Gansu Foundation of Ecological Conservation&Remediation(No.2018-20)Gansu Foundation of Inducing Scientific Innovation for Development(No.2017zx-10)。
文摘Karst caves are characterized by darkness,low temperature,high humidity,and oligotrophic organisms due to its relatively closed and strongly zonal environments.Up to now,1626 species in 644 genera of fungi have been reported from caves and mines worldwide.In this study,we investigated the culturable mycobiota in karst caves in southwest China.In total,251 samples from thirteen caves were collected and 2344 fungal strains were isolated using dilution plate method.Preliminary ITS analyses showed that these strains belonged to 610 species in 253 genera.Among these species,88.0%belonged to Ascomy-cota,8.0%Basidiomycota,1.9%Mortierellomycota,1.9%Mucoromycota,and 0.2%Glomeromycota.The majority of these species have been previously known from other environments,and some of them are known as mycorrhizal or pathogenic fungi.About 52.8%of these species were discovered for the first time in karst caves.Based on morphological and phyloge-netic distinctions,33 new species were identified and described in this paper.Meanwhile,one new genus of Cordycipitaceae,Gamszarea,and five new combinations are established.This work further demonstrated that Karst caves encompass a high fungal diversity,including a number of previously unknown species.Taxonomic novelties:New genus:Gamszarea Z.F.Zhang&L.Cai;Novel species:Amphichorda cavernicola,Aspergillus limoniformis,Aspergillus phialiformis,Aspergillus phialosimplex,Auxarthron chinense,Auxarthron guangxiense,Auxarthronopsis globiasca,Auxarthronopsis pedicellaris,Auxarthronopsis pulverea,Auxarthronopsis stercicola,Chrysosporium pallidum,Gamszarea humicola,Gamszarea lunata,Gamszarea microspora,Gymnoascus flavus,Jattaea reniformis,Lecanicillium magnisporum,Microascus collaris,Microas-cus levis,Microascus sparsimycelialis,Microascus superficialis,Microascus trigonus,Nigrospora globosa,Paracremonium apiculatum,Paracremonium ellipsoideum,Paraphaeosphaeria hydei,Pseudoscopulariopsis asperispora,Setophaeosphaeria microspora,Simplicillium album,Simplicillium humicola,Wardomycopsis dolichi,Wardomycopsis ellipsoconidiophora,Wardomycopsis fusca;New combinations:Gamszarea indonesiaca(Kurihara&Sukarno)Z.F.Zhang&L.Cai,Gamszarea kalimantanensis(Kurihara&Sukarno)Z.F.Zhang&L.Cai,Gamszarea restricta(Hubka,Kubátová,Nonaka,Čmoková&Řehulka)Z.F.Zhang&L.Cai,Gamszarea testudinea(Hubka,Kubátová,Nonaka,Čmoková&Řehulka)Z.F.Zhang&L.Cai,Gamszarea wallacei(H.C.Evans)Z.F.Zhang&L.Cai.
