First descriptions Bacteria were first observed by
Antonie van Leeuwenhoek in 1676, using a single-lens
microscope of his own design. He did not distinguish bacteria as a separate type of microorganism, calling all microorganisms, including bacteria, protists, and microscopic animals, "
animalcules". He published his observations in a series of letters to the
Royal Society. Early described genera of bacteria include
Vibrio and
Monas, by
O. F. Müller (1773, 1786), then classified as
Infusoria (however, many species before included in those genera are regarded today as protists, which are eukaryotes);
Polyangium, by
H. F. Link (1809), the first bacterium still recognized today;
Serratia, by
Bizio (1823); and
Spirillum, Spirochaeta and
Bacterium, by
Ehrenberg (1838). The term
Bacterium, introduced as a genus by Ehrenberg in 1838, became a catch-all for rod-shaped cells.
Haeckel in 1866 placed the group in the phylum
Moneres (from μονήρης: simple) in the kingdom
Protista and defines them as completely structureless and homogeneous organisms, consisting only of a piece of plasma. • (no envelope) •
Protogenes – such as
Protogenes primordialis, now classed as a eukaryote and not a bacterium •
Protamaeba – now classed as a eukaryote and not a bacterium •
Vibrio – a genus of comma shaped bacteria first described in 1854 •
Bacterium – a genus of rod shaped bacteria first described in 1828, that later gave its name to the members of the Monera, formerly referred to as "a moneron" (plural "monera") in English and ""(fem. pl. "") in German •
Bacillus – a genus of spore-forming rod shaped bacteria first described in 1835 •
Spirochaeta –
thin spiral shaped bacteria first described in 1835 • etc. • (with envelope) •
Protomonas – now classed as a eukaryote and not a bacterium. The name was reused in 1984 for an unrelated genus of Bacteria •
Vampyrella – now classed as a eukaryote and not a bacterium The classification of
Ferdinand Cohn (1872) was influential in the nineteenth century, and recognized six genera:
Micrococcus,
Bacterium,
Bacillus,
Vibrio,
Spirillum, and
Spirochaeta. The classification of
Cyanobacteria (colloquially "blue green algae") has been fought between being algae or bacteria (for example, Haeckel classified
Nostoc in the phylum Archephyta of Algae and Vuillemin, in a 1913 study, concluded that all species of the
Bacteria should fall into the genera
Planococcus,
Streptococcus,
Klebsiella,
Merista,
Planomerista,
Neisseria,
Sarcina,
Planosarcina,
Metabacterium,
Clostridium,
Serratia,
Bacterium, and
Spirillum. in 1875, Cohn recognized four
tribes: Spherobacteria, Microbacteria, Desmobacteria, and Spirobacteria. Stanier and van Neil in 1941 recognized the kingdom Monera with two phyla, Myxophyta and Schizomycetae, the latter comprising classes Eubacteriae (three orders), Myxobacteriae (one order), and Spirochetae (one order). In 1962, Bisset distinguished 1 class and 4 orders: Eubacteriales, Actinomycetales, Streptomycetales, and Flexibacteriales.
Walter Migula's system (1897), which was the most widely accepted system of its time and included all then-known species but was based only on morphology, contained the three basic groups Coccaceae, Bacillaceae, and Spirillaceae, but also Trichobacterinae for filamentous bacteria. Orla-Jensen in 1909 established two orders: Cephalotrichinae (seven families) and Peritrichinae (presumably with only one family). Bergey et al. in 1925 presented a classification which generally followed the 1920 Final Report of the Society of American Bacteriologists Committee (Winslow et al.), which divided class Schizomycetes into four orders: Myxobacteriales, Thiobacteriales, Chlamydobacteriales, and Eubacteriales, with a fifth group being four genera considered intermediate between bacteria and protozoans:
Spirocheta,
Cristospira,
Saprospira, and
Treponema. However, different authors often reclassified the genera due to the lack of visible traits to go by, resulting in a poor state which was summarised in 1915 by Robert Earle Buchanan. By then, the whole group received different ranks and names by different authors, namely: •
Schizomycetes (Naegeli 1857) •
Bacteria (Cohn 1872 b) •
Schizomycetaceae (DeToni and Trevisan 1889) Furthermore, the families into which the class was subdivided changed from author to author and for some, such as Zipf (1917), the names were in German and not in Latin. The first edition of the
Bacteriological Code in 1947 set a standardised system and authority for the classification of Bacteria. A. R. Prévot's system (1958) had four subphyla and eight classes, as follows: • Eubacteriales (classes Asporulales and Sporulales) • Mycobacteriales (classes Actinomycetales, Myxobacteriales, and Azotobacteriales) • Algobacteriales (classes Siderobacteriales and Thiobacteriales) • Protozoobacteriales (class Spirochetales)
Informal groups based on Gram staining Despite there being little agreement on the major subgroups of the
Bacteria,
Gram staining results were most commonly used as a classification tool. Consequently, until the advent of molecular phylogeny, the Kingdom
Prokaryota was divided into four divisions, A classification scheme still formally followed by Bergey's manual of systematic bacteriology for tome order •
Gracilicutes (gram-negative) •
Photobacteria (photosynthetic): class
Oxyphotobacteriae (water as electron donor, includes the order
Cyanobacteriales=blue-green algae, now phylum
Cyanobacteria) and class
Anoxyphotobacteriae (anaerobic phototrophs), orders:
Rhodospirillales and
Chlorobiales •
Scotobacteria (non-photosynthetic, now the
Proteobacteria and other gram-negative nonphotosynthetic phyla) •
Firmacutes [sic] (gram-positive, subsequently corrected to
Firmicutes) • several orders such as
Bacillales and
Actinomycetales (now in the phylum
Actinobacteria) •
Mollicutes (gram variable, e.g.
Mycoplasma) •
Mendocutes (uneven gram stain, "methanogenic bacteria", now known as the
Archaea)
Molecular era "Archaic bacteria" and Woese's reclassification Woese argued that the bacteria, archaea, and eukaryotes represent separate lines of descent that diverged early on from an ancestral colony of organisms. However, a few biologists argue that the Archaea and Eukaryota arose from a group of bacteria. In any case, it is thought that
viruses and archaea began relationships approximately two billion years ago, and that
co-evolution may have been occurring between members of these groups. It is possible that the last common ancestor of the bacteria and archaea was a thermophile, which raises the possibility that lower temperatures are "extreme environments" in archaeal terms, and organisms that live in cooler environments appeared only later. Since the Archaea and Bacteria are no more related to each other than they are to eukaryotes, the term
prokaryote only surviving meaning is "not a eukaryote", limiting its value. With improved methodologies it became clear that the methanogenic bacteria were profoundly different and were (erroneously) believed to be relics of ancient bacteria thus
Carl Woese, regarded as the forerunner of the molecular phylogeny revolution, identified three primary lines of descent: the
Archaebacteria, the
Eubacteria, and the
Urkaryotes, the latter now represented by the nucleocytoplasmic component of the
Eukaryotes. These lineages were formalised into the rank Domain (
regio in Latin) which divided Life into 3 domains: the
Eukaryota, the
Archaea and the
Bacteria.
Subdivisions In 1987 Carl Woese divided the
Eubacteria into 11 divisions based on
16S ribosomal RNA (SSU) sequences, which with several additions are still used today. Oren and Goker has also validly published a number of kingdoms as a layer higher than the division/phylum: some authors have opposed it for various reasons. One prominent scientist who opposed the three domain system was
Thomas Cavalier-Smith, who proposed that the
Archaea and the
Eukaryotes (the
Neomura) stem from Gram positive bacteria (
Posibacteria), which in turn derive from gram negative bacteria (
Negibacteria) based on several logical arguments, which are highly controversial and generally disregarded by the molecular biology community (
c.f. reviewers' comments on,) due to the subjective nature of the assumptions made. However, despite there being a wealth of statistically supported studies towards the rooting of the tree of life between the
Bacteria and the
Neomura by means of a variety of methods, including some that are impervious to accelerated evolution—which is claimed by Cavalier-Smith to be the source of the supposed fallacy in molecular methods Radhey Gupta's molecular taxonomy, based on conserved signature sequences of proteins, includes a monophyletic Gram negative clade, a monophyletic Gram positive clade, and a polyphyletic Archeota derived from Gram positives. Hori and Osawa's molecular analysis indicated a link between Metabacteria (=Archeota) and eukaryotes. The only cladistic analyses for bacteria based on classical evidence largely corroborate Gupta's results (see comprehensive mega-taxonomy).
James Lake presented a 2 primary kingdom arrangement (Parkaryotae + eukaryotes and eocytes + Karyotae) and suggested a 5 primary kingdom scheme (Eukaryota, Eocyta, Methanobacteria, Halobacteria, and Eubacteria) based on ribosomal structure and a 4 primary kingdom scheme (Eukaryota,
Eocyta,
Methanobacteria, and
Photocyta), bacteria being classified according to 3 major biochemical innovations: photosynthesis (Photocyta),
methanogenesis (Methanobacteria), and
sulfur respiration (
Eocyta). He has also discovered evidence that Gram-negative bacteria arose from a symbiosis between 2 Gram-positive bacteria. ==Authorities==