Horizontal gene transfer

thumb|Tree of life showing vertical and horizontal gene transfers

Horizontal gene transfer (HGT) or lateral gene transfer (LGT) is the movement of genetic material between organisms other than by the ("vertical") transmission of DNA from parent to offspring (reproduction). HGT is an important factor in the evolution of many organisms. HGT is influencing scientific understanding of higher-order evolution while more significantly shifting perspectives on bacterial evolution.

Horizontal gene transfer is the primary mechanism for the spread of antibiotic resistance in bacteria, and plays an important role in the evolution of bacteria that can degrade novel compounds such as human-created pesticides and in the evolution, maintenance, and transmission of virulence. It often involves temperate bacteriophages and plasmids. Genes responsible for antibiotic resistance in one species of bacteria can be transferred to another species of bacteria through various mechanisms of HGT such as transformation, transduction and conjugation, subsequently arming the antibiotic resistant genes' recipient against antibiotics. The rapid spread of antibiotic resistance genes in this manner is becoming a challenge to manage in the field of medicine. Ecological factors may also play a role in the HGT of antibiotic resistant genes.

Horizontal gene transfer is recognized as a pervasive evolutionary process that distributes genes between divergent prokaryotic lineages and can also involve eukaryotes. HGT events are thought to occur less frequently in eukaryotes than in prokaryotes. However, growing evidence indicates that HGT is relatively common among many eukaryotic species and can have an impact on adaptation to novel environments. Its study, however, is hindered by the complexity of eukaryotic genomes and the abundance of repeat-rich regions, which complicate the accurate identification and characterization of transferred genes.

It is postulated that HGT promotes the maintenance of a universal life biochemistry and, subsequently, the universality of the genetic code.

History

Griffith's experiment, reported in 1928 by Frederick Griffith, was the first experiment suggesting that bacteria are capable of transferring genetic information through a process known as transformation. Griffith's findings were followed by research in the late 1930s and early 1940s that isolated DNA as the material that communicated this genetic information.

Horizontal genetic transfer was then described in Seattle in 1951, in a paper demonstrating that the transfer of a viral gene into Corynebacterium diphtheriae created a virulent strain from a non-virulent strain, simultaneously revealing the mechanism of diphtheria (that patients could be infected with the bacteria but not have any symptoms, and then suddenly convert later or never), and giving the first example for the relevance of the lysogenic cycle. Inter-bacterial gene transfer was first described in Japan in a 1959 publication that demonstrated the transfer of antibiotic resistance between different species of bacteria. In the mid-1980s, Syvanen postulated that biologically significant lateral gene transfer has existed since the beginning of life on Earth and has been involved in shaping all of evolutionary history.

As Jian, Rivera and Lake (1999) put it: "Increasingly, studies of genes and genomes are indicating that considerable horizontal transfer has occurred between prokaryotes" (see also Lake and Rivera, 2007). The phenomenon appears to have had some significance for unicellular eukaryotes as well. As Bapteste et al. (2005) observe, "additional evidence suggests that gene transfer might also be an important evolutionary mechanism in protist evolution."

Grafting of one plant to another can transfer chloroplasts (organelles in plant cells that conduct photosynthesis), mitochondrial DNA, and the entire cell nucleus containing the genome to potentially make a new species. Some Lepidoptera (e.g. monarch butterflies and silkworms) have been genetically modified by horizontal gene transfer from the wasp bracovirus. Bites from insects in the family Reduviidae (assassin bugs) can, via a parasite, infect humans with the trypanosomal Chagas disease, which can insert its DNA into the human genome. It has been suggested that lateral gene transfer to humans from bacteria may play a role in cancer.

Aaron Richardson and Jeffrey D. Palmer state: "Horizontal gene transfer (HGT) has played a major role in bacterial evolution and is fairly common in certain unicellular eukaryotes. However, the prevalence and importance of HGT in the evolution of multicellular eukaryotes remain unclear."

Due to the increasing amount of evidence suggesting the importance of these phenomena for evolution (see below) molecular biologists such as Peter Gogarten have described horizontal gene transfer as "A New Paradigm for Biology".

Mechanisms

There are several mechanisms for horizontal gene transfer:

• Transformation, the genetic alteration of a cell resulting from the introduction, uptake and expression of foreign genetic material (DNA or RNA). This process is relatively common in bacteria, but less so in eukaryotes. Transformation is often used in laboratories to insert novel genes into bacteria for experiments or for industrial or medical applications. See also molecular biology and biotechnology.
• Transduction, the process in which bacterial DNA is moved from one bacterium to another by a virus (a bacteriophage, or phage).

Horizontal transposon transfer

A transposable element (TE) (also called a transposon or jumping gene) is a mobile segment of DNA that can sometimes pick up a resistance gene and insert it into a plasmid or chromosome, thereby inducing horizontal gene transfer of antibiotic resistance. On the transposable element side, spreading between genomes via horizontal transfer may be viewed as a strategy to escape purging due to purifying selection, mutational decay and/or host defense mechanisms.

HTT can occur with any type of transposable elements, but DNA transposons and LTR retroelements are more likely to be capable of HTT because both have a stable, double-stranded DNA intermediate that is thought to be sturdier than the single-stranded RNA intermediate of non-LTR retroelements, which can be highly degradable.

HTT has been shown to occur between species and across continents in both plants and animals (Ivancevic et al. 2013), though some TEs have been shown to more successfully colonize the genomes of certain species over others. Both spatial and taxonomic proximity of species has been proposed to favor HTTs in plants and animals. HTT detection is a difficult task because it is an ongoing phenomenon that is constantly changing in frequency of occurrence and composition of TEs inside host genomes. Furthermore, few species have been analyzed for HTT, making it difficult to establish patterns of HTT events between species. These issues can lead to the underestimation or overestimation of HTT events between ancestral and current eukaryotic species.

Viruses

The virus called Mimivirus infects amoebae. Another virus, called Sputnik, also infects amoebae, but it cannot reproduce unless mimivirus has already infected the same cell. <blockquote>Sputnik's genome reveals further insight into its biology. Although 13 of its genes show little similarity to any other known genes, three are closely related to mimivirus and mamavirus genes, perhaps cannibalized by the tiny virus as it packaged up particles sometime in its history. This suggests that the satellite virus could perform horizontal gene transfer between viruses, paralleling the way that bacteriophages ferry genes between bacteria.</blockquote>

Prokaryotes

Horizontal gene transfer is common among bacteria, even among very distantly related ones, and also between bacteria and archaea. This process is thought to be a significant cause of increased drug resistance when one bacterial cell acquires resistance, and the resistance genes are transferred to the other species. Transposition and horizontal gene transfer, along with strong natural selective forces have led to multi-drug resistant strains of S. aureus and many other pathogenic bacteria. Strategies to combat certain bacterial infections by targeting these specific virulence factors and mobile genetic elements have been proposed. and integrons. Still, they are more frequently a chromosomal-encoded barrier to MGE than an MGE-encoded tool for cell infection.

Lateral gene transfer via a mobile genetic element, namely the integrated conjugative element (ICE) Bs1 has been reported for its role in the global DNA damage SOS response of the gram positive Bacillus subtilis. Furthermore, it has been linked with the radiation and desiccation resistance of Bacillus pumilus SAFR-032 spores, isolated from spacecraft cleanroom facilities.

Transposon insertion elements have been reported to increase the fitness of gram-negative E. coli strains through either major transpositions or genome rearrangements, and increasing mutation rates. In a study on the effects of long-term exposure of simulated microgravity on non-pathogenic E. coli, the results showed transposon insertions occur at loci, linked to SOS stress response. When the same E. coli strain was exposed to a combination of simulated microgravity and trace (background) levels of (the broad spectrum) antibiotic (chloramphenicol), the results showed transposon-mediated rearrangements (TMRs), disrupting genes involved in bacterial adhesion, and deleting an entire segment of several genes involved with motility and chemotaxis. Both of these studies have implications for microbial growth, adaptation to and antibiotic resistance in real time space conditions.

Horizontal gene transfer is particularly active in bacterial genomes around the production of secondary or specialized metabolites. This is clearly exhibited within certain groups of bacteria including P. aeruginosa and actinomycetales, an order of Actinomycetota. Polyketide synthases (PKSs) and biosynthetic gene clusters provide modular organizations of associated genes making these bacteria well-adapted to acquire and discard helpful modular modifications via HGT. Certain areas of genes known as hotspots further increase the likelihood of horizontally transferred secondary metabolite-producing genes.

Bacterial transformation

thumb|1: Donor bacterium 2: Bacterium who will receive the gene 3: The red portion represents the gene that will be transferred. Transformation in bacteria happens in a certain environment.

Natural transformation is a bacterial adaptation for DNA transfer (HGT) that depends on the expression of numerous bacterial genes whose products are responsible for this process. In general, transformation is a complex, energy-requiring developmental process. In order for a bacterium to bind, take up and recombine exogenous DNA into its chromosome, it must become competent, that is, enter a special physiological state. Competence development in Bacillus subtilis requires expression of about 40 genes. The DNA integrated into the host chromosome is usually (but with infrequent exceptions) derived from another bacterium of the same species, and is thus homologous to the resident chromosome. The capacity for natural transformation occurs in at least 67 prokaryotic species. Transformation in bacteria can be viewed as a primitive sexual process, since it involves interaction of homologous DNA from two individuals to form recombinant DNA that is passed on to succeeding generations. Although transduction is the form of HGT most commonly associated with bacteriophages, certain phages may also be able to promote transformation.

Bacterial conjugation

thumb|1: Donor bacterium cell (F+ cell) 2: Bacterium that receives the plasmid (F- cell) 3: Plasmid that will be moved to the other bacterium 4: Pilus and T4SS. Conjugation in bacteria using a sex pilus; then the bacterium that received the plasmid can go give it to other bacteria as well.

thumb|E. coli cells going through conjugation and sharing genetic information. F-pilus is reaching towards other cell.

As mentioned before, conjugation is a method of horizontal gene transfer through cell to cell contact. These T4SS encoded within the plasmid carry other proteins and genes that help supplement the cell in conjugation. Research has shown that there are Single Binding DNA Binding proteins (SSBs) also encoded within the conjugative plasmid may help with conjugation and cell viability. This is thought to be the case because SSBs naturally are expressed to help with stabilizing single-stranded DNA (ssDNA). SSBs will also recruit other proteins like RadD or RecA expressed in events of DNA recombination, repair, and replication. Further showcasing their possible role in conjugation. Although it may help, studies have also shown for proteins like SSB to not be essential in conjugation. For example, the plasmid pCF10 from Enterococcus faecalis, a gram-positive bacterium, has a SSB like-protein called PrgE and was classified for not being required for conjugation. More work needs to be done on why proteins that bind to ssDNA are encoded into conjugative plasmids.

Conjugation in the case of microbiomes and symbioses is very important. From this process new genes are acquired that lead to increasing genetic diversity and evolution such as the acquisition of antibiotic resistance genes. Mycobacterium tuberculosis is a species that has evolved through methods like conjugation while gaining antibiotic resistance. This evolution or increase in genetic diversity is also seen in many other species. Due to this, there is a huge concern on how impactful conjugation or horizontal gene transfer can be on human health and your microbiome as pathogenic microbes can become more pathogenic. Studies have shown that even our own microbiome has a plethora of antimicrobial genes which if transferred to pathogenic microbes could be detrimental.

Conjugation in Mycobacterium smegmatis, like conjugation in E. coli, requires stable and extended contact between a donor and a recipient strain, is DNase resistant, and the transferred DNA is incorporated into the recipient chromosome by homologous recombination. However, unlike E. coli high frequency of recombination conjugation (Hfr), mycobacterial conjugation is a type of HGT that is chromosome rather than plasmid based. Furthermore, in contrast to E. coli (Hfr) conjugation, in M. smegmatis all regions of the chromosome are transferred with comparable efficiencies. Substantial blending of the parental genomes was found as a result of conjugation, and this blending was regarded as reminiscent of that seen in the meiotic products of sexual reproduction.

Archaeal DNA transfer

Haloarchaea are aerobic halophiles thought to have evolved from anaerobic methanogens. A large amount of their genome, 126 composite gene families, are derived from genetic material from bacterial genomes. This has allowed them to adapt to extremely salty environments.

The archaeon Sulfolobus solfataricus, when UV irradiated, strongly induces the formation of type IV pili which then facilitates cellular aggregation. Exposure to chemical agents that cause DNA damage also induces cellular aggregation. and UV-induced cultures display recombination rates that exceed those of uninduced cultures by as much as three orders of magnitude. S. solfataricus cells aggregate preferentially with other cells of their own species. and Ajon et al. UV exposure induces pili formation and cellular aggregation. and by DNA damaging chemicals.

The ups operon, containing five genes, is highly induced by UV irradiation. The proteins encoded by the ups operon are employed in UV-induced pili assembly and cellular aggregation leading to intercellular DNA exchange and homologous recombination. Since this system increases the fitness of S. acidocaldarius cells after UV exposure, Wolferen et al. considered that transfer of DNA likely takes place in order to repair UV-induced DNA damages by homologous recombination.

Eukaryotes

"Sequence comparisons suggest recent horizontal transfer of many genes among diverse species including across the boundaries of phylogenetic 'domains'. Thus determining the phylogenetic history of a species can not be done conclusively by determining evolutionary trees for single genes."

Organelle to nuclear genome

• Analysis of DNA sequences suggests that horizontal gene transfer has occurred within eukaryotes from the chloroplast and mitochondrial genomes to the nuclear genome. As stated in the endosymbiotic theory, chloroplasts and mitochondria probably originated as bacterial endosymbionts of a progenitor to the eukaryotic cell.

Organelle to organelle

• Mitochondrial genes moved to parasites of the Rafflesiaceae plant family from their hosts and from chloroplasts of a still-unidentified plant to the mitochondria of the bean Phaseolus.

Bacteria to fungi

• Horizontal transfer occurs from bacteria to some fungi, such as the yeast Saccharomyces cerevisiae.

Bacteria to plants

• Agrobacterium, a pathogenic bacterium that causes cells to proliferate as crown galls and proliferating roots is an example of a bacterium that can transfer genes to plants and this plays an important role in plant evolution.
• Land plants and their close relatives, the charophycean green algae, share a set of glycosyl hydrolases. These enzymes were likely transferred from bacteria and fungi to the last common ancestor of these organisms before the origin of land plants.

Bacteria to animals

• HhMAN1 is a gene in the genome of the coffee berry borer (Hypothenemus hampei) that resembles bacterial genes, and is thought to be transferred from bacteria in the beetle's gut.
• oskar is an essential gene for the specification of the germline in Holometabola and its origin is thought to be due to a HGT event followed by a fusion with a LOTUS domain.
• Bdelloid rotifers currently hold the 'record' for HGT in animals with ~8% of their genes from bacterial origins. Tardigrades were thought to break the record with 17.5% HGT, but that finding was an artifact of bacterial contamination.
• A study found the genomes of 40 animals (including 10 primates, four Caenorhabditis worms, and 12 Drosophila insects) contained genes which the researchers concluded had been transferred from bacteria and fungi by horizontal gene transfer. The researchers estimated that for some nematodes and Drosophila insects these genes had been acquired relatively recently.
• A bacteriophage-mediated mechanism transfers genes between prokaryotes and eukaryotes. Nuclear localization signals in bacteriophage terminal proteins (TP) prime DNA replication and become covalently linked to the viral genome. The role of virus and bacteriophages in HGT in bacteria, suggests that TP-containing genomes could be a vehicle of inter-kingdom genetic information transference all throughout evolution.
• The adzuki bean beetle has acquired genetic material from its (non-beneficial) endosymbiont Wolbachia. New examples have recently been reported demonstrating that Wolbachia bacteria represent an important potential source of genetic material in arthropods and filarial nematodes.
• The psyllid Pachypsylla venusta has acquired genes from its current endosymbiont Carsonella, and from many of its historical endosymbionts, too.
• A comparative analysis of 163 ant genomes identified 497 horizontally transferred protein-coding genes in 85 species, most of them derived from intracellular bacterial symbionts. Several of these genes appear to have contributed to ant adaptation, particularly in immunity and metabolism, and some were conserved across multiple species for up to 40 million years, consistent with purifying selection. Functional analysis of one transferred gene in Cardiocondyla ants further suggested that it has become integrated into the host’s core energy metabolism.

Plant to plant

• Striga hermonthica, a parasitic eudicot, has received a gene from sorghum (Sorghum bicolor) to its nuclear genome. The gene's functionality is unknown.
• A gene that allowed ferns to survive in dark forests came from the hornwort, which grows in mats on streambanks or trees. The neochrome gene arrived about 180 million years ago.
• Transfer of mRNA between host plants and heterotrophs plants in the Orobanchaceae have been directly observed. mRNA transcripts can therefore be a factor involved in the transfer and integration of foreign DNA in heterotrophs.

Plants to animals

• The eastern emerald sea slug Elysia chlorotica has been suggested by fluorescence in situ hybridization (FISH) analysis to contain photosynthesis-supporting genes obtained from an alga (Vaucheria litorea) in their diet. LGT in Sacoglossa is now thought to be an artifact and no trace of LGT was found upon sequencing the genome of Elysia chlorotica.
• The whitefly Bemisia tabaci acquired a plant detoxification gene that neutralizes plant toxins.

Plant to fungus

• Gene transfer between plants and fungi has been posited for a number of cases, including rice (Oryza sativa).
• Evidence of gene transfer from plants was documented in the fungus Colletotrichum.
• Plant expansin genes were transferred to fungi further enabling the fungi to infect plants.

Plant to bacteria

• Plant expansin genes were transferred to bacteria further enabling the bacteria to infect plants. Plants, fungi, and microorganisms can synthesize carotenoids, but torulene made by pea aphids is the only carotenoid known to be synthesized by an organism in the animal kingdom.

Fungi to fungi

• The toxin α-amanitin is found in numerous, seemingly unrelated genera fungi such as Amanita, Lepiota, and Galerina. Two biosynthetic genes involved in the production of α-amanitin are P450-29 and FMO1. Phylogenetic and genetic analyses of these genes strongly indicate that they were transferred between the genera via horizontal gene transfer.
• The ToxA protein (wheat virulence protein) included in a ~14 kb element, containing both coding and non-coding regions was transferred between different fungal wheat patogens: Parastagonospora nodorum, Pyrenophora tritici-repentis, and Bipolaris sorokiniana.
• A large genomic element named "Wallaby," approximately 500 kb in length, was recently transferred between two Penicillium species used in cheesemaking: P. camemberti and P. roqueforti. Wallaby contains around 250 genes, including several that are thought to play a role in microbial competition.

Fungi to oomycetes

• 4 genes from Magnaporthe grisea, the rice blast fungus, were suspected to be horizontally transferred from the genus Phytophthora, and hypothesized to play a role in the fungus evolution into a plant pathogen.

Oomycetes to fungi

• The oomycete species Phytophthora ramorum, Phytophthora sojae, Phytophthora infestans, and Hyaloperonospora parasitica were estimated to have 33 horizontal gene transfers from fungi. The transferred genes were hypothesized to be involved in functions that facilitate plant tissues colonization, such as secreted proteins to evade plant immune response and breaking down plant cell walls.

Animals to animals

• Smelt fish received antifreeze protein (AFP) gene from herring through a direct horizontal transfer.

Animals to bacteria

• The strikingly fish-like copper/zinc superoxide dismutase of Photobacterium leiognathi is most easily explained in terms of transfer of a gene from an ancestor of its fish host.

Human to protozoan

• The malaria pathogen Plasmodium vivax acquired genetic material from humans that might help facilitate its long stay in the body.

Human genome

• One study identified approximately 100 of humans' approximately 20,000 total genes which likely resulted from horizontal gene transfer, but this number has been challenged by several researchers arguing these candidate genes for HGT are more likely the result of gene loss combined with differences in the rate of evolution.

Compounds found to promote horizontal gene transfer

Through research into the growing issue of antibiotic resistance certain compounds have been observed to promote horizontal gene transfer. Antibiotics given to bacteria at non-lethal levels have been known to be a cause of antibiotic resistance Promiscuous DNA transfer has substantial evidence in its movement across the genome of numerous organisms, from movements in chloroplast to the nucleus, chloroplast to the mitochondria, and mitochondria to the nucleus.

History

In 1982, R. John Ellis defined this type of transpositional transfer mutation as "intracellular promiscuity". Ellis further explored the phenomenon of "intracellular promiscuity" through the experiments of David Stern and David Lonsdale, in which genetic transfer between chloroplasts to mitochondria was discovered, aiding in the definition and discovery of promiscuous DNA.

Mechanism

While much remains to be understood about how promiscuous DNA undergoes movement and transfer, numerous experiments have pointed to plastid sequences, ptDNA, as a key player. Plasmids, with their mobile nature and crucial role in horizontal gene transfer, are seen as a significant element in DNA that exchanges genetic information. This mobility makes ptDNA a potential donor for promiscuous DNA to traverse organellar barriers. These NUMTs, with their varying frequencies, sizes, and features, contribute to the genetic diversity across all eukaryotes and, in some cases, to diseases among humans. These fragments of ptDNA, similar to NUMTs in frequency, size, and features, also exhibit variability across species.

Artificial horizontal gene transfer

thumb|upright=1.35|Before it is transformed, a bacterium is susceptible to antibiotics. A plasmid can be inserted when the bacteria is under stress, and be incorporated into the bacterial DNA creating antibiotic resistance. When the plasmids are prepared they are inserted into the bacterial cell by either making pores in the plasma membrane with temperature extremes and chemical treatments, or making it semi permeable through the process of [[electrophoresis, in which electric currents create the holes in the membrane. After conditions return to normal the holes in the membrane close and the plasmids are trapped inside the bacteria where they become part of the genetic material and their genes are expressed by the bacteria.]]

Genetic engineering is essentially horizontal gene transfer, albeit with synthetic expression cassettes. The Sleeping Beauty transposon system (SB) was developed as a synthetic gene transfer agent that was based on the known abilities of Tc1/mariner transposons to invade genomes of extremely diverse species. The SB system has been used to introduce genetic sequences into a wide variety of animal genomes.

== In evolution ==<!-- This section is linked from Organism -->

Horizontal gene transfer is a potential confounding factor in inferring phylogenetic trees based on the sequence of one gene. For example, given two distantly related bacteria that have exchanged a gene a phylogenetic tree including those species will show them to be closely related because that gene is the same even though most other genes are dissimilar. For this reason, it is often ideal to use other information to infer robust phylogenies such as the presence or absence of genes or, more commonly, to include as wide a range of genes for phylogenetic analysis as possible.

For example, the most common gene to be used for constructing phylogenetic relationships in prokaryotes is the 16S ribosomal RNA gene since its sequences tend to be conserved among members with close phylogenetic distances, but variable enough that differences can be measured. However, in recent years it has also been argued that 16s rRNA genes can also be horizontally transferred. Although this may be infrequent, the validity of 16s rRNA-constructed phylogenetic trees must be reevaluated.

Biologist Johann Peter Gogarten suggests "the original metaphor of a tree no longer fits the data from recent genome research" therefore "biologists should use the metaphor of a mosaic to describe the different histories combined in individual genomes and use the metaphor of a net to visualize the rich exchange and cooperative effects of HGT among microbes".

Challenge to the tree of life

Horizontal gene transfer poses a possible challenge to the concept of the last universal common ancestor (LUCA) at the root of the tree of life that was first formulated by Carl Woese, which led him to propose the Archaea as a third domain of life. Indeed, it was while examining the new three-domain model of life that horizontal gene transfer arose as a complicating issue: Archaeoglobus fulgidus was seen as an anomaly with respect to a phylogenetic tree, based upon the encoding for the enzyme HMGCoA reductase; the organism in question is a definite Archaean, with all the cell lipids and transcription machinery that are expected of an Archaean, but whose HMGCoA genes are of bacterial origin. However, a LUCA can be identified, so horizontal transfers must have been relatively limited.

Other early HGTs are thought to have happened. The first common ancestor (FUCA), earliest ancestor of LUCA, had other descendants that had their own lineages. These now-extinct sister lineages of LUCA descending from FUCA are thought to have horizontally transferred some of their genes into the genome of early descendants of LUCA.

The potential of HGT to be used for dating phylogenies has recently been confirmed.

The chromosomal organization of horizontal gene transfer

The acquisition of new genes has the potential to disorganize the other genetic elements and hinder the function of the bacterial cell, thus affecting the competitiveness of bacteria. Consequently, bacterial adaptation lies in a conflict between the advantages of acquiring beneficial genes, and the need to maintain the organization of the rest of its genome. Horizontally transferred genes are typically concentrated in only ~1% of the chromosome (in regions called hotspots). This concentration increases with genome size and with the rate of transfer. Hotspots diversify by rapid gene turnover; their chromosomal distribution depends on local contexts (neighboring core genes), and content in mobile genetic elements. Hotspots concentrate most changes in gene repertoires, reduce the trade-off between genome diversification and organization, and should be treasure troves of strain-specific adaptive genes. Most mobile genetic elements and antibiotic resistance genes are in hotspots, but many hotspots lack recognizable mobile genetic elements and exhibit frequent homologous recombination at flanking core genes. Overrepresentation of hotspots with fewer mobile genetic elements in naturally transformable bacteria suggests that homologous recombination and horizontal gene transfer are tightly linked in genome evolution.

Genes

There is evidence for historical horizontal transfer of the following genes:

• Lycopene cyclase for carotenoid biosynthesis, between Chlorobiota and "Cyanobacteria".
• TetO gene conferring resistance to tetracycline, between Campylobacter jejuni.
• Neochrome, a gene in some ferns that enhances their ability to survive in dim light. Believed to have been acquired from algae sometime during the Cretaceous.
• Transfer of a cysteine synthase from a bacterium into phytophagous mites and Lepidoptera allowing the detoxification of cyanogenic glucosides produced by host plants.
• The LINE1 sequence has transferred from humans to the gonorrhea bacteria.

See also

• Agrobacterium, a bacterium well known for its ability to transfer DNA between itself and plants.
• Endogenous retrovirus
• Genetically modified organism
• Inferring horizontal gene transfer
• Integron
• Mobile genetic elements
• Phylogenetic network
• Phylogenetic tree
• Provirus
• Reassortment
• Retrotransposon
• Symbiogenesis
• Tree of life (biology)
• Xenobiology

== References ==<!-- GenomeRes9:689 -->

Further reading

• – Papers by Dr Michael Syvanen on Horizontal Gene Transfer
• This article seeks to shift the emphasis in early phylogenic adaptation from vertical to horizontal gene transfer. He uses the term "Darwinian Threshold" for the time of major transition of evolutionary mechanisms from mostly horizontal to mostly vertical transfer, and the "origin of speciation".
• This article proposes using the presence or absence of a set of genes to infer phylogenies, in order to avoid confounding factors such as horizontal gene transfer.

External links

• :Citizendium:Horizontal gene transfer
• :Citizendium:Horizontal gene transfer in prokaryotes
• :Citizendium:Horizontal gene transfer in plants
• :Citizendium:Horizontal gene transfer (History)