Escherichia coli

Escherichia coli (/ˌɛʃəˈrɪkiə ˈkoʊlaɪ/ ESH-ə-RIK-ee-ə KOH-lye)^[1]^[2] is a gram-negative, facultative anaerobic, rod-shaped, coliform bacterium of the genus Escherichia that is commonly found in the lower intestine of warm-blooded organisms.^[3]^[4] Most E. coli strains are harmless, but some serotypes such as EPEC, and ETEC are pathogenic and can cause serious food poisoning in their hosts, and are occasionally responsible for food contamination incidents that prompt product recalls.^[5]^[6] Most strains are part of the normal microbiota of the gut and are harmless or even beneficial to humans (although these strains tend to be less studied than the pathogenic ones).^[7] For example, some strains of E. coli benefit their hosts by producing vitamin K₂^[8] or by preventing the colonization of the intestine by pathogenic bacteria. These mutually beneficial relationships between E. coli and humans are a type of mutualistic biological relationship — where both the humans and the E. coli are benefitting each other.^[9]^[10] E. coli is expelled into the environment within fecal matter. The bacterium grows massively in fresh fecal matter under aerobic conditions for three days, but its numbers decline slowly afterwards.^[11]

"E. coli" redirects here. For the protozoan commensal, see Entamoeba coli.

E. coli and other facultative anaerobes constitute about 0.1% of gut microbiota,^[12] and fecal–oral transmission is the major route through which pathogenic strains of the bacterium cause disease. Cells are able to survive outside the body for a limited amount of time, which makes them potential indicator organisms to test environmental samples for fecal contamination.^[13]^[14] A growing body of research, though, has examined environmentally persistent E. coli which can survive for many days and grow outside a host.^[15]

The bacterium can be grown and cultured easily and inexpensively in a laboratory setting, and has been intensively investigated for over 60 years. E. coli is a chemoheterotroph whose chemically defined medium must include a source of carbon and energy.^[16] E. coli is the most widely studied prokaryotic model organism, and an important species in the fields of biotechnology and microbiology, where it has served as the host organism for the majority of work with recombinant DNA. Under favourable conditions, it takes as little as 20 minutes to reproduce.^[17]

Clinical data

US DailyMed: Escherichia coli

A07FA03 (WHO)

Proteomics

Proteome

The genome sequence of E. coli predicts 4288 protein-coding genes, of which 38 percent initially had no attributed function. Comparison with five other sequenced microbes reveals ubiquitous as well as narrowly distributed gene families; many families of similar genes within E. coli are also evident. The largest family of paralogous proteins contains 80 ABC transporters. The genome as a whole is strikingly organized with respect to the local direction of replication; guanines, oligonucleotides possibly related to replication and recombination, and most genes are so oriented. The genome also contains insertion sequence (IS) elements, phage remnants, and many other patches of unusual composition indicating genome plasticity through horizontal transfer.^[62]

Several studies have experimentally investigated the proteome of E. coli. By 2006, 1,627 (38%) of the predicted proteins (open reading frames, ORFs) had been identified experimentally.^[68] Mateus et al. 2020 detected 2,586 proteins with at least 2 peptides (60% of all proteins).^[69]

Post-translational modifications (PTMs)

Although much fewer bacterial proteins seem to have post-translational modifications (PTMs) compared to eukaryotic proteins, a substantial number of proteins are modified in E. coli. For instance, Potel et al. (2018) found 227 phosphoproteins of which 173 were phosphorylated on histidine. Interestingly, the majority of phosphorylated amino acids were serine (1,220 sites) with only 246 sites on histidine and 501 phosphorylated threonines and 162 tyrosines.^[70]

Interactome

The interactome of E. coli has been studied by affinity purification and mass spectrometry (AP/MS) and by analyzing the binary interactions among its proteins.

Protein complexes. A 2006 study purified 4,339 proteins from cultures of strain K-12 and found interacting partners for 2,667 proteins, many of which had unknown functions at the time.^[71] A 2009 study found 5,993 interactions between proteins of the same E. coli strain, though these data showed little overlap with those of the 2006 publication.^[72]

Binary interactions. Rajagopala et al. (2014) have carried out systematic yeast two-hybrid screens with most E. coli proteins, and found a total of 2,234 protein-protein interactions.^[73] This study also integrated genetic interactions and protein structures and mapped 458 interactions within 227 protein complexes.

Uses in biological computing

Since 1961, scientists proposed the idea of genetic circuits used for computational tasks. Collaboration between biologists and computing scientists has allowed designing digital logic gates on the metabolism of E. coli. As Lac operon is a two-stage process, genetic regulation in the bacteria is used to realize computing functions. The process is controlled at the transcription stage of DNA into messenger RNA.^[130]

Studies are being performed attempting to program E. coli to solve complicated mathematics problems, such as the Hamiltonian path problem.^[131]

A computer to control protein production of E. coli within yeast cells has been developed.^[132] A method has also been developed to use bacteria to behave as an LCD screen.^[133]^[134]

In July 2017, separate experiments with E. coli published on Nature showed the potential of using living cells for computing tasks and storing information.^[135] A team formed with collaborators of the Biodesign Institute at Arizona State University and Harvard's Wyss Institute for Biologically Inspired Engineering developed a biological computer inside E. coli that responded to a dozen inputs. The team called the computer "ribocomputer", as it was composed of ribonucleic acid.^[136]^[137] Meanwhile, Harvard researchers probed that is possible to store information in bacteria after successfully archiving images and movies in the DNA of living E. coli cells.^[138]^[139] In 2021, a team led by biophysicist Sangram Bagh realized a study with E. coli to solve 2 × 2 maze problems to probe the principle for distributed computing among cells.^[140]^[141]

History

In 1885, the German-Austrian pediatrician Theodor Escherich discovered this organism in the feces of healthy individuals. He called it Bacterium coli commune because it is found in the colon. Early classifications of prokaryotes placed these in a handful of genera based on their shape and motility (at that time Ernst Haeckel's classification of bacteria in the kingdom Monera was in place).^[100]^[142]^[143]

Bacterium coli was the type species of the now invalid genus Bacterium when it was revealed that the former type species ("Bacterium triloculare") was missing.^[144] Following a revision of Bacterium, it was reclassified as Bacillus coli by Migula in 1895^[145] and later reclassified in the newly created genus Escherichia, named after its original discoverer, by Aldo Castellani and Albert John Chalmers.^[146]

In 1996, an outbreak of E. coli food poisoning occurred in Wishaw, Scotland, killing 21 people.^[147]^[148] This death toll was exceeded in 2011, when the 2011 Germany E. coli O104:H4 outbreak, linked to organic fenugreek sprouts, killed 53 people.

Uses

E. coli has several practical uses besides its use as a vector for genetic experiments and processes. For example, E. coli can be used to generate synthetic propane and recombinant human growth hormone.^[149]^[150]