Bacteria (also referred as Eubacteria), Archaea, & Eukarya are the three realms of life. Microorganisms make up the Bacteria and Archaea, whereas plants, animals, plus microorganisms like fungi and protists make up the Eukarya.
Because they lack a nucleus, Bacteria and Archaea have been lumped together and dubbed Prokaryotes, however the Archaea are more closely linked to Eukaryotes than Bacteria. There are a few more significant distinctions between the three areas.
The Planet is 4.6 billion years old, and microbial life is considered to be first appeared around 3.8 and 3.9 bya; in reality, microbial life accounted for 80% of Earth’s history. Microbial life is by far the most common kind of life on the planet. The total number of microbial cells on Earth is estimated to be on the scale of 2.5 X 1030 cells, making it the largest fraction of biomass on the planet.
Phylogeny is the study of the evolutionary relationships between species. The 3 Domain System, suggested by Woese and many others, is a phylogenetic evolutionary model based on changes in nucleotide sequences in ribosomal RNAs as well as cell membrane lipid shape and antibiotic susceptibility.
Comparing the structure of rRNA is very useful. Because rRNA molecules perform the same function throughout nature, their structure does not change much over time. As a result, rRNA nucleotide sequence similarities and differences are a reliable indicator of how similar or dissimilar different cells and species are.
The origins of eukaryotic and prokaryotic cells are the subject of numerous theories. Since all cells are similar in nature, it is commonly assumed that they all descended from a single ancestor cell known as the last universal common ancestor (LUCA). These LUCAs subsequently differentiated into three distinct types of cells, each representing a distinct domain. The three domains are Archaea, Bacteria, and Eukarya.
DOMAINS:
PVC stands for Planctomycetes, Verrucomicrobia, and Chlamydiae, and refers to the three members of the superphylum. Individuals of both the PVC, while pertaining to the Bacteria domain, exhibit characteristics of the Archaea and Eukarya domains.
Similar to eukaryotic cells, some of these bacteria have cell compartmentalization, in which membranes surround areas of the cell core, such as clusters of ribosomes or DNA. Some, like eukaryotes, divide by budding or include sterols in their membranes.
Some, like eukaryotes and archaea, lack peptidoglycan. These bacteria are thought to constitute an intermediary step between an ancestor that evolved from a bacterium and an archael-eukaryotic ancestor before the domains Archaea and Eukarya split off.
ARCHAEBACTERIA:
- The Archaea is a type of archaea (archaebacteria)
- The Archaea are characterised by the following characteristics:
- Prokaryotic cells are archaea.
- Unlike Bacteria and Eukaryotes, Archaea have membranes made up of branching hydrocarbon chains (many of which have rings within them) connected to glycerol via ether bonds.
- Archaea’s cell walls are devoid of peptidoglycan.
- Some drugs that affect bacteria are ineffective against Archaea, yet some antibiotics that target Eukarya are effective.
- Archaea have its own rRNA, as evidenced by the presence of molecular regions that are distinct from those found in Bacteria and Eukarya.
Methanogens, extreme halophiles, & hyperthermophiles are among the archaea that exist in harsh settings. One reason for this is that ether-containing links in Archaea membranes are more stable than ester-containing linkages in Bacteria and Eukarya, and can resist greater temperatures and acid concentrations.
EUBACTERIA:
Bacteria (sometimes known as eubacteria or “real bacteria”) comprise prokaryotic cells which are encountered far more frequently than archaebacteria in daily life.
Eubacteria are present practically everywhere and kill tens of thousands of people each year, yet they also create antibiotics and act as food digesters in our stomachs. Bacteria are defined by the following characteristics:
- Prokaryotic cells are bacteria.
- They have membranes made up of linear polymer fatty acid chains connected to glycerol via ester bonds, just like the Eukarya.
- Bacteria, unlike Archaea and Eukarya, have peptidoglycan in their cell walls.
- Traditional antibacterial antibiotics are effective against bacteria, however most antibiotics that attack Eukarya are ineffective.
- Bacteria have their own rRNA, as evidenced by the presence of molecular regions that are distinct from those found in Archaea and Eukarya.
- Cyanobacteria, mycoplasmas, Gram-positive bacteria, & Gram-negative bacteria are all bacteria.
EUKARYOTES:
The following are characteristics of the Eukarya (sometimes spelled Eukarya):
- Eukaryotic cells are found in Eukarya.
- They have membranes made of linear polymer fatty acid chains connected to glycerol by ester bonds, just as Bacteria.
- Although not all Eukarya have cells with such a cell wall, those that do have a cell wall do not have peptidoglycan.
- Traditional antibacterial antibiotics are resistant to Eukarya, however most antibiotics that attack eukaryotic cells are not.
- Eukarya have their own rRNA, as evidenced by the presence of molecular regions that are distinct from those found in Archaea and Bacteria.
The kingdoms of Eukarya are classified into four groups:
- Protists are eukaryotic creatures that are primarily unicellular and simple. Slime moulds, euglenoids, algae, & protozoans are some examples.
- Fungi are multicellular or unicellular creatures that have eukaryotic cell types. Cell walls are present, but the cells are not organised into tissues. They don’t do photosynthesis and instead rely on absorption to get their nutrition. Club fungi, sac fungi, yeasts, & moulds are examples.
- Plants are multicellular that are made up of eukaryotic cells. Tissues are made up of cells that have cell walls. Photosynthesis and absorption are how they get their nourishment. Mosses, ferns, conifers, & blooming plants are examples.
- Animalia Kingdom: Eukaryotic cells make up multicellular organisms known as animals. Tissues are made up of cells that lack cell walls. They don’t do photosynthesis and rely on ingestion to get their nutrition. Sponge, worms, insects, & vertebrates are examples.
Changes that allow microbes to adapt to new settings or alter their virulence capabilities were previously assumed to be a very long-drawn-out process happening in an organism mainly via chromosomal rearrangements, mutations, gene deletions, and gene duplications.
Natural selection would then occur as a result of those alterations being handed down to the microbe’s descendants. Vertical gene transmission refers to the transfer of genes from a parent organism to its progeny.
Microbial genes are now recognised to be passed down not only vertically from a parent organism to its offspring, but also horizontally to relatives who are only distantly related, such as other species and genera.
Horizontal gene transfer is the term for this later phase. Genetic elements such as plasmids, integrons, transposons or even chromosomal DNA can easily be transported from one microbe to another by techniques including transformation, transduction, and conjugation. As a consequence, the ancient tri “tree of life” for microbes has evolved into a “net of life.”
Microbes have been found to live in a wide range of settings, many of which are quite hostile. They can quickly adjust their repertoire of protein activities by modifying, acquiring, or removing genes, resulting in astonishing and rapid flexibility. Horizontal gene transfer is the most common method of gene expansion.
CONCLUSION:
Phylogeny is the study of the evolutionary relationships between species. Organisms are grouped in to one of the 3 domains attributed to differences in nucleotide sequences in ribosomal RNAs (rRNA), lipid structure of the cell membrane, and antibiotic sensitivity. Creatures with prokaryotic cells are classified as Archaea or Bacteria, while organisms with eukaryotic cells are classified as Eukarya. Horizontal gene transfer, or the transmission of DNA to an individual that is not its progeny, is how bacteria transmit genes to other microbes.