triploblastic animals
三胚层动物
triploblastic organisms
三胚层生物
triploblastic development
三胚层发育
triploblastic embryos
三胚层胚胎
triploblastic phyla
三胚层门
most triploblasts
大多数三胚层动物
triploblastic symmetry
三胚层对称性
triploblastic body plan
三胚层体型
triploblastic lineage
三胚层谱系
becoming triploblastic
演化为三胚层
triploblastic animals possess three primary germ layers that give rise to all body tissues and organs.
三胚层动物拥有三个主要的胚层,这些胚层发育形成所有的身体组织和器官。
the evolution of triploblastic organisms marked a significant advancement in animal complexity.
三胚层生物的进化标志着动物复杂性方面的重大进步。
during triploblastic development, the ectoderm, mesoderm, and endoderm differentiate to form specialized structures.
在三胚层发育过程中,外胚层、中胚层和内胚层分化形成专门化的结构。
most bilaterally symmetrical animals belong to the triploblastic clade that emerged in the paleozoic era.
大多数两侧对称动物属于古生代出现的三胚层分支。
researchers study triploblastic embryos to understand the genetic mechanisms of tissue differentiation.
研究人员通过研究三胚层胚胎来理解组织分化的遗传机制。
the triploblastic body plan allows for complex organ systems not found in simpler organisms.
三胚层身体构型使复杂的器官系统成为可能,这在较简单的生物中并不存在。
molecular phylogenetics has clarified the relationships among major triploblastic lineages.
分子系统发育学已经阐明了主要三胚层谱系之间的关系。
some triploblastic parasites have evolved simplified body plans adapted to their hosts.
一些三胚层寄生虫已经进化出简化的身体构型以适应其宿主。
the triploblastic condition is considered a key innovation in animal evolution.
三胚层状态被认为是动物进化中的一个关键创新。
comparative genomics reveals conserved genetic pathways across diverse triploblastic species.
比较基因组学揭示了不同三胚层物种之间保守的遗传通路。
triploblastic flatworms exhibit remarkable regenerative capabilities due to their stem cell population.
三胚层扁虫因其干细胞群体而表现出显著的再生能力。
the transition to triploblastic organization enabled larger body sizes in ancestral chordates.
向三胚层组织的过渡使古代脊索动物能够拥有更大的体型。
triploblastic animals
三胚层动物
triploblastic organisms
三胚层生物
triploblastic development
三胚层发育
triploblastic embryos
三胚层胚胎
triploblastic phyla
三胚层门
most triploblasts
大多数三胚层动物
triploblastic symmetry
三胚层对称性
triploblastic body plan
三胚层体型
triploblastic lineage
三胚层谱系
becoming triploblastic
演化为三胚层
triploblastic animals possess three primary germ layers that give rise to all body tissues and organs.
三胚层动物拥有三个主要的胚层,这些胚层发育形成所有的身体组织和器官。
the evolution of triploblastic organisms marked a significant advancement in animal complexity.
三胚层生物的进化标志着动物复杂性方面的重大进步。
during triploblastic development, the ectoderm, mesoderm, and endoderm differentiate to form specialized structures.
在三胚层发育过程中,外胚层、中胚层和内胚层分化形成专门化的结构。
most bilaterally symmetrical animals belong to the triploblastic clade that emerged in the paleozoic era.
大多数两侧对称动物属于古生代出现的三胚层分支。
researchers study triploblastic embryos to understand the genetic mechanisms of tissue differentiation.
研究人员通过研究三胚层胚胎来理解组织分化的遗传机制。
the triploblastic body plan allows for complex organ systems not found in simpler organisms.
三胚层身体构型使复杂的器官系统成为可能,这在较简单的生物中并不存在。
molecular phylogenetics has clarified the relationships among major triploblastic lineages.
分子系统发育学已经阐明了主要三胚层谱系之间的关系。
some triploblastic parasites have evolved simplified body plans adapted to their hosts.
一些三胚层寄生虫已经进化出简化的身体构型以适应其宿主。
the triploblastic condition is considered a key innovation in animal evolution.
三胚层状态被认为是动物进化中的一个关键创新。
comparative genomics reveals conserved genetic pathways across diverse triploblastic species.
比较基因组学揭示了不同三胚层物种之间保守的遗传通路。
triploblastic flatworms exhibit remarkable regenerative capabilities due to their stem cell population.
三胚层扁虫因其干细胞群体而表现出显著的再生能力。
the transition to triploblastic organization enabled larger body sizes in ancestral chordates.
向三胚层组织的过渡使古代脊索动物能够拥有更大的体型。
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