The separation of archaebacteria into a separate domain suggests that they have a distinct evolutionary history and are not closely related to other organisms in the traditional bacteria domain. This indicates that archaebacteria have unique characteristics and may have diverged early in the evolutionary timeline.
The most accurate evidence of an evolutionary relationship between two organisms is the presence of shared genetic similarities, specifically in their DNA sequences. This indicates a common ancestry and evolutionary history between the two organisms.
The evolutionary relationship of a specific species to other organisms on a phylogenetic tree node shows how closely related that species is to other organisms based on their common ancestry. The closer the species is on the tree node, the more closely related they are in terms of evolution.
The evolutionary relationship of a specific species to other organisms within a phylogenetic tree node shows how closely related they are in terms of their common ancestry. The closer the species are on the tree, the more recent their shared ancestor.
Scientists classify archaebacteria based on their genetic and biochemical differences from other bacteria. They use molecular techniques like DNA sequencing to compare the genetic makeup of archaebacteria with that of other organisms to determine their evolutionary relationships. Additionally, scientists study the unique features of archaebacteria's cell walls, membranes, and metabolic processes to classify them into different groups.
their common evolutionary ancestry and shared genetic material, which have led to the conservation of certain molecular and structural features. This indicates a close evolutionary relationship and a common ancestor from which these organisms have diverged over time.
The most accurate evidence of an evolutionary relationship between two organisms is the presence of shared genetic similarities, specifically in their DNA sequences. This indicates a common ancestry and evolutionary history between the two organisms.
If two organisms share an evolutionary relationship, that means that they have a common ancestor on the evolutionary tree. The more recently the shared common ancestor lived, the more closely related the two present organisms are, evolutionarily.
If two organisms share an evolutionary relationship, that means that they have a common ancestor on the evolutionary tree. The more recently the shared common ancestor lived, the more closely related the two present organisms are, evolutionarily.
The evolutionary relationship of a specific species to other organisms on a phylogenetic tree node shows how closely related that species is to other organisms based on their common ancestry. The closer the species is on the tree node, the more closely related they are in terms of evolution.
chemosynthesis
The evolutionary relationship of a specific species to other organisms within a phylogenetic tree node shows how closely related they are in terms of their common ancestry. The closer the species are on the tree, the more recent their shared ancestor.
They show similarities between organisms structure. if the similarities are large then it shows that those organisms share a common ancestor.
Archaebacteria
Scientists classify archaebacteria based on their genetic and biochemical differences from other bacteria. They use molecular techniques like DNA sequencing to compare the genetic makeup of archaebacteria with that of other organisms to determine their evolutionary relationships. Additionally, scientists study the unique features of archaebacteria's cell walls, membranes, and metabolic processes to classify them into different groups.
I think you mean phylogeny. Phylogeny is the evolutionary history of a species or group of related species.
I don't really know that one I will have to look it up and put it up here
Eubacteria Archaebacteria Eukaryote