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Bacterial conjugation

December 02, 2023

Bacterial conjugation is the transfer of genetic material between bacterial cells by direct cell-to-cell contact or by a bridge-like connection between two cells.[1] This takes place through a pilus.[2] It is a parasexual mode of reproduction in bacteria.

A micrograph displaying Escherichia coli undergoing bacterial conjugation using F-pili. These long and extremely robust extracellular appendages serve as physical conduits for translocation of DNA. Adapted from [3]

It is a mechanism of horizontal gene transfer as are transformation and transduction although these two other mechanisms do not involve cell-to-cell contact.[4]

Classical E. coli bacterial conjugation is often regarded as the bacterial equivalent of sexual reproduction or mating since it involves the exchange of genetic material. However, it is not sexual reproduction, since no exchange of gamete occurs, and indeed no generation of a new organism: instead an existing organism is transformed. During classical E. coli conjugation the donor cell provides a conjugative or mobilizable genetic element that is most often a plasmid or transposon.[5] Most conjugative plasmids have systems ensuring that the recipient cell does not already contain a similar element.

The genetic information transferred is often beneficial to the recipient. Benefits may include antibiotic resistance, xenobiotic tolerance or the ability to use new metabolites.[6] Other elements can be detrimental and may be viewed as bacterial parasites.

Conjugation in Escherichia coli by spontaneous zygogenesis[7] and in Mycobacterium smegmatis by distributive conjugal transfer[8][9] differ from the better studied classical E. coli conjugation in that these cases involve substantial blending of the parental genomes.

History edit

The process was discovered by Joshua Lederberg and Edward Tatum[10] in 1946.

Mechanism edit

 
Schematic drawing of bacterial conjugation.

Conjugation diagram

  1. Donor cell produces pilus.
  2. Pilus attaches to recipient cell and brings the two cells together.
  3. The mobile plasmid is nicked and a single strand of DNA is then transferred to the recipient cell.
  4. Both cells synthesize a complementary strand to produce a double stranded circular plasmid and also reproduce pili; both cells are now viable donor for the F-factor.[1]

The F-factor is an episome (a plasmid that can integrate itself into the bacterial chromosome by homologous recombination) with a length of about 100 kb. It carries its own origin of replication, the oriV, and an origin of transfer, or oriT.[5] There can only be one copy of the F-plasmid in a given bacterium, either free or integrated, and bacteria that possess a copy are called F-positive or F-plus (denoted F+). Cells that lack F plasmids are called F-negative or F-minus (F) and as such can function as recipient cells.[citation needed]

Among other genetic information, the F-plasmid carries a tra and trb locus, which together are about 33 kb long and consist of about 40 genes. The tra locus includes the pilin gene and regulatory genes, which together form pili on the cell surface. The locus also includes the genes for the proteins that attach themselves to the surface of F bacteria and initiate conjugation. Though there is some debate on the exact mechanism of conjugation it seems that the pili are the structures through which DNA exchange occurs. The F-pili are extremely resistant to mechanical and thermochemical stress, which guarantees successful conjugation in a variety of environments.[11] Several proteins coded for in the tra or trb locus seem to open a channel between the bacteria and it is thought that the traD enzyme, located at the base of the pilus, initiates membrane fusion.

When conjugation is initiated by a signal the relaxase enzyme creates a nick in one of the strands of the conjugative plasmid at the oriT. Relaxase may work alone or in a complex of over a dozen proteins known collectively as a relaxosome. In the F-plasmid system the relaxase enzyme is called TraI and the relaxosome consists of TraI, TraY, TraM and the integrated host factor IHF. The nicked strand, or T-strand, is then unwound from the unbroken strand and transferred to the recipient cell in a 5'-terminus to 3'-terminus direction. The remaining strand is replicated either independent of conjugative action (vegetative replication beginning at the oriV) or in concert with conjugation (conjugative replication similar to the rolling circle replication of lambda phage). Conjugative replication may require a second nick before successful transfer can occur. A recent report claims to have inhibited conjugation with chemicals that mimic an intermediate step of this second nicking event.[12]

 
1.The insertion sequences (yellow) on both the F factor plasmid and the chromosome have similar sequences, allowing the F factor to insert itself into the genome of the cell. This is called homologous recombination and creates an Hfr (high frequency of recombination) cell. 2.The Hfr cell forms a pilus and attaches to a recipient F- cell. 3.A nick in one strand of the Hfr cell's chromosome is created. 4.DNA begins to be transferred from the Hfr cell to the recipient cell while the second strand of its chromosome is being replicated. 5.The pilus detaches from the recipient cell and retracts. The Hfr cell ideally wants to transfer its entire genome to the recipient cell. However, due to its large size and inability to keep in contact with the recipient cell, it is not able to do so. 6.a. The F- cell remains F- because the entire F factor sequence was not received. Since no homologous recombination occurred, the DNA that was transferred is degraded by enzymes.[13] b. In very rare cases, the F factor will be completely transferred and the F- cell will become an Hfr cell.[4]

If the F-plasmid that is transferred has previously been integrated into the donor's genome (producing an Hfr strain ["High Frequency of Recombination"]) some of the donor's chromosomal DNA may also be transferred with the plasmid DNA.[4] The amount of chromosomal DNA that is transferred depends on how long the two conjugating bacteria remain in contact. In common laboratory strains of E. coli the transfer of the entire bacterial chromosome takes about 100 minutes. The transferred DNA can then be integrated into the recipient genome via homologous recombination.

A cell culture that contains in its population cells with non-integrated F-plasmids usually also contains a few cells that have accidentally integrated their plasmids. It is these cells that are responsible for the low-frequency chromosomal gene transfers that occur in such cultures. Some strains of bacteria with an integrated F-plasmid can be isolated and grown in pure culture. Because such strains transfer chromosomal genes very efficiently they are called Hfr (high frequency of recombination). The E. coli genome was originally mapped by interrupted mating experiments in which various Hfr cells in the process of conjugation were sheared from recipients after less than 100 minutes (initially using a Waring blender). The genes that were transferred were then investigated.

Since integration of the F-plasmid into the E. coli chromosome is a rare spontaneous occurrence, and since the numerous genes promoting DNA transfer are in the plasmid genome rather than in the bacterial genome, it has been argued that conjugative bacterial gene transfer, as it occurs in the E. coli Hfr system, is not an evolutionary adaptation of the bacterial host, nor is it likely ancestral to eukaryotic sex.[14]

Spontaneous zygogenesis in E. coli

In addition to classical bacterial conjugation described above for E. coli, a form of conjugation referred to as spontaneous zygogenesis (Z-mating for short) is observed in certain strains of E. coli.[7] In Z-mating there is complete genetic mixing, and unstable diploids are formed that throw off phenotypically haploid cells, of which some show a parental phenotype and some are true recombinants.

Conjugal transfer in mycobacteria edit

Conjugation in Mycobacteria 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 Hfr conjugation, mycobacterial conjugation is chromosome rather than plasmid based.[8][9] Furthermore, in contrast to E. coli Hfr conjugation, in M. smegmatis all regions of the chromosome are transferred with comparable efficiencies. The lengths of the donor segments vary widely, but have an average length of 44.2kb. Since a mean of 13 tracts are transferred, the average total of transferred DNA per genome is 575kb.[9] This process is referred to as "Distributive conjugal transfer."[8][9] Gray et al.[8] found substantial blending of the parental genomes as a result of conjugation and regarded this blending as reminiscent of that seen in the meiotic products of sexual reproduction.

Conjugation-like DNA transfer in hyperthermophilic archaea edit

Hyperthermophilic archaea encode pili structurally similar to the bacterial conjugative pili.[15] However, unlike in bacteria, where conjugation apparatus typically mediates the transfer of mobile genetic elements, such as plasmids or transposons, the conjugative machinery of hyperthermophilic archaea, called Ced (Crenarchaeal system for exchange of DNA)[16] and Ted (Thermoproteales system for exchange of DNA),[15] appears to be responsible for the transfer of cellular DNA between members of the same species. It has been suggested that in these archaea the conjugation machinery has been fully domesticated for promoting DNA repair through homologous recombination rather than spread of mobile genetic elements.[15] In addition to the VirB2-like conjugative pilus, the Ced and Ted systems include components for the VirB6-like transmembrane mating pore and the VirB4-like ATPase.[15]

Inter-kingdom transfer edit

 
Agrobacterium tumefaciens gall at the root of Carya illinoensis.

Bacteria related to the nitrogen fixing Rhizobia are an interesting case of inter-kingdom conjugation.[17] For example, the tumor-inducing (Ti) plasmid of Agrobacterium and the root-tumor inducing (Ri) plasmid of A. rhizogenes contain genes that are capable of transferring to plant cells. The expression of these genes effectively transforms the plant cells into opine-producing factories. Opines are used by the bacteria as sources of nitrogen and energy. Infected cells form crown gall or root tumors. The Ti and Ri plasmids are thus endosymbionts of the bacteria, which are in turn endosymbionts (or parasites) of the infected plant.[citation needed]

The Ti and Ri plasmids can also be transferred between bacteria using a system (the tra, or transfer, operon) that is different and independent of the system used for inter-kingdom transfer (the vir, or virulence, operon). Such transfers create virulent strains from previously avirulent strains.[citation needed]

Genetic engineering applications edit

Conjugation is a convenient means for transferring genetic material to a variety of targets. In laboratories, successful transfers have been reported from bacteria to yeast,[18] plants, mammalian cells,[19][20] diatoms[21] and isolated mammalian mitochondria.[22] Conjugation has advantages over other forms of genetic transfer including minimal disruption of the target's cellular envelope and the ability to transfer relatively large amounts of genetic material (see the above discussion of E. coli chromosome transfer). In plant engineering, Agrobacterium-like conjugation complements other standard vehicles such as tobacco mosaic virus (TMV). While TMV is capable of infecting many plant families these are primarily herbaceous dicots. Agrobacterium-like conjugation is also primarily used for dicots, but monocot recipients are not uncommon.[citation needed]

See also edit

References edit

  1. ^ a b Holmes RK, Jobling MG (1996). "Genetics". In Baron S, et al. (eds.). Genetics: Conjugation. in: Baron's Medical Microbiology (4th ed.). Univ of Texas Medical Branch. ISBN 0-9631172-1-1. PMID 21413277.
  2. ^ Dr.T.S.Ramarao M.sc, Ph.D. (1991). B.sc Botany-Volume-1.
  3. ^ Patkowski, Jonasz (21 April 2023). "F-pilus, the ultimate bacterial sex machine". Nature Portfolio Microbiology Community.
  4. ^ a b c Griffiths AJF (1999). (7th ed.). San Francisco: W.H. Freeman. ISBN 978-0-7167-3520-5. Archived from the original on 2020-02-08. Retrieved 2023-08-11.{{cite book}}: CS1 maint: bot: original URL status unknown (link)
  5. ^ a b Ryan KJ, Ray CG, eds. (2004). Sherris Medical Microbiology (4th ed.). McGraw Hill. pp. 60–4. ISBN 978-0-8385-8529-0.
  6. ^ Holmes RK, Jobling MG (1996). "Genetics". In Baron S, et al. (eds.). Genetics: Exchange of Genetic Information. in: Baron's Medical Microbiology (4th ed.). Univ of Texas Medical Branch. ISBN 978-0-9631172-1-2. PMID 21413277.
  7. ^ a b Gratia JP, Thiry M (September 2003). "Spontaneous zygogenesis in Escherichia coli, a form of true sexuality in prokaryotes". Microbiology (Reading, Engl.). 149 (Pt 9): 2571–84. doi:10.1099/mic.0.26348-0. PMID 12949181.
  8. ^ a b c d Gray TA, Krywy JA, Harold J, Palumbo MJ, Derbyshire KM (July 2013). "Distributive conjugal transfer in mycobacteria generates progeny with meiotic-like genome-wide mosaicism, allowing mapping of a mating identity locus". PLOS Biol. 11 (7): e1001602. doi:10.1371/journal.pbio.1001602. PMC 3706393. PMID 23874149.
  9. ^ a b c d Derbyshire KM, Gray TA (2014). "Distributive Conjugal Transfer: New Insights into Horizontal Gene Transfer and Genetic Exchange in Mycobacteria". Microbiol Spectr. 2 (1): 61–79. doi:10.1128/microbiolspec.MGM2-0022-2013. PMC 4259119. PMID 25505644.
  10. ^ Lederberg J, Tatum EL (1946). "Gene recombination in E. coli". Nature. 158 (4016): 558. Bibcode:1946Natur.158..558L. doi:10.1038/158558a0. PMID 21001945. S2CID 1826960.
  11. ^ Patkowski, Jonasz B.; Dahlberg, Tobias; Amin, Himani; Gahlot, Dharmender K.; Vijayrajratnam, Sukhithasri; Vogel, Joseph P.; Francis, Matthew S.; Baker, Joseph L.; Andersson, Magnus; Costa, Tiago R. D. (5 April 2023). "The F-pilus biomechanical adaptability accelerates conjugative dissemination of antimicrobial resistance and biofilm formation". Nature Communications. 14 (1): 1879. doi:10.1038/s41467-023-37600-y. PMC 10076315. PMID 37019921.
  12. ^ Lujan SA, Guogas LM, Ragonese H, Matson SW, Redinbo MR (2007). "Disrupting antibiotic resistance propagation by inhibiting the conjugative DNA relaxase". PNAS. 104 (30): 12282–7. Bibcode:2007PNAS..10412282L. doi:10.1073/pnas.0702760104. JSTOR 25436291. PMC 1916486. PMID 17630285.
  13. ^ "Genetic Exchange". www.microbiologybook.org. Retrieved 2017-12-04.
  14. ^ Michod RE, Bernstein H, Nedelcu AM (2008). "Adaptive value of sex in microbial pathogens" (PDF). Infect Genet Evol. 8 (3): 267–285. doi:10.1016/j.meegid.2008.01.002. PMID 18295550.
  15. ^ a b c d Beltran, Leticia C.; Cvirkaite-Krupovic, Virginija; Miller, Jessalyn; Wang, Fengbin; Kreutzberger, Mark A. B.; Patkowski, Jonasz B.; Costa, Tiago R. D.; Schouten, Stefan; Levental, Ilya; Conticello, Vincent P.; Egelman, Edward H.; Krupovic, Mart (2023-02-07). "Archaeal DNA-import apparatus is homologous to bacterial conjugation machinery". Nature Communications. 14 (1): 666. Bibcode:2023NatCo..14..666B. doi:10.1038/s41467-023-36349-8. ISSN 2041-1723. PMC 9905601. PMID 36750723.
  16. ^ van Wolferen, Marleen; Wagner, Alexander; van der Does, Chris; Albers, Sonja-Verena (2016-03-01). "The archaeal Ced system imports DNA". Proceedings of the National Academy of Sciences of the United States of America. 113 (9): 2496–2501. Bibcode:2016PNAS..113.2496V. doi:10.1073/pnas.1513740113. ISSN 1091-6490. PMC 4780597. PMID 26884154.
  17. ^ Pan SQ, Jin S, Boulton MI, Hawes M, Gordon MP, Nester EW (July 1995). "An Agrobacterium virulence factor encoded by a Ti plasmid gene or a chromosomal gene is required for T-DNA transfer into plants". Mol. Microbiol. 17 (2): 259–69. doi:10.1111/j.1365-2958.1995.mmi_17020259.x. PMID 7494475. S2CID 38483513.
  18. ^ Heinemann JA, Sprague GF (July 1989). "Bacterial conjugative plasmids mobilize DNA transfer between bacteria and yeast". Nature. 340 (6230): 205–9. Bibcode:1989Natur.340..205H. doi:10.1038/340205a0. PMID 2666856. S2CID 4351266.
  19. ^ Kunik T, Tzfira T, Kapulnik Y, Gafni Y, Dingwall C, Citovsky V (February 2001). "Genetic transformation of HeLa cells by Agrobacterium". Proc. Natl. Acad. Sci. U.S.A. 98 (4): 1871–6. Bibcode:2001PNAS...98.1871K. doi:10.1073/pnas.041327598. PMC 29349. PMID 11172043.
  20. ^ Waters VL (December 2001). "Conjugation between bacterial and mammalian cells". Nat. Genet. 29 (4): 375–6. doi:10.1038/ng779. PMID 11726922. S2CID 27160.
  21. ^ Karas, Bogumil J.; Diner, Rachel E.; Lefebvre, Stephane C.; McQuaid, Jeff; Phillips, Alex P.R.; Noddings, Chari M.; Brunson, John K.; Valas, Ruben E.; Deerinck, Thomas J. (2015-04-21). "Designer diatom episomes delivered by bacterial conjugation". Nature Communications. 6: 6925. Bibcode:2015NatCo...6.6925K. doi:10.1038/ncomms7925. ISSN 2041-1723. PMC 4411287. PMID 25897682.
  22. ^ Yoon YG, Koob MD (2005). "Transformation of isolated mammalian mitochondria by bacterial conjugation". Nucleic Acids Res. 33 (16): e139. doi:10.1093/nar/gni140. PMC 1201378. PMID 16157861.

External links edit

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December 02, 2023
bacterial, conjugation, transfer, genetic, material, between, bacterial, cells, direct, cell, cell, contact, bridge, like, connection, between, cells, this, takes, place, through, pilus, parasexual, mode, reproduction, bacteria, micrograph, displaying, escheri. Bacterial conjugation is the transfer of genetic material between bacterial cells by direct cell to cell contact or by a bridge like connection between two cells 1 This takes place through a pilus 2 It is a parasexual mode of reproduction in bacteria A micrograph displaying Escherichia coli undergoing bacterial conjugation using F pili These long and extremely robust extracellular appendages serve as physical conduits for translocation of DNA Adapted from 3 It is a mechanism of horizontal gene transfer as are transformation and transduction although these two other mechanisms do not involve cell to cell contact 4 Classical E coli bacterial conjugation is often regarded as the bacterial equivalent of sexual reproduction or mating since it involves the exchange of genetic material However it is not sexual reproduction since no exchange of gamete occurs and indeed no generation of a new organism instead an existing organism is transformed During classical E coli conjugation the donor cell provides a conjugative or mobilizable genetic element that is most often a plasmid or transposon 5 Most conjugative plasmids have systems ensuring that the recipient cell does not already contain a similar element The genetic information transferred is often beneficial to the recipient Benefits may include antibiotic resistance xenobiotic tolerance or the ability to use new metabolites 6 Other elements can be detrimental and may be viewed as bacterial parasites Conjugation in Escherichia coli by spontaneous zygogenesis 7 and in Mycobacterium smegmatis by distributive conjugal transfer 8 9 differ from the better studied classical E coli conjugation in that these cases involve substantial blending of the parental genomes Contents 1 History 2 Mechanism 3 Conjugal transfer in mycobacteria 4 Conjugation like DNA transfer in hyperthermophilic archaea 5 Inter kingdom transfer 6 Genetic engineering applications 7 See also 8 References 9 External linksHistory editThe process was discovered by Joshua Lederberg and Edward Tatum 10 in 1946 Mechanism edit nbsp Schematic drawing of bacterial conjugation Conjugation diagram Donor cell produces pilus Pilus attaches to recipient cell and brings the two cells together The mobile plasmid is nicked and a single strand of DNA is then transferred to the recipient cell Both cells synthesize a complementary strand to produce a double stranded circular plasmid and also reproduce pili both cells are now viable donor for the F factor 1 The F factor is an episome a plasmid that can integrate itself into the bacterial chromosome by homologous recombination with a length of about 100 kb It carries its own origin of replication the oriV and an origin of transfer or oriT 5 There can only be one copy of the F plasmid in a given bacterium either free or integrated and bacteria that possess a copy are called F positive or F plus denoted F Cells that lack F plasmids are called F negative or F minus F and as such can function as recipient cells citation needed Among other genetic information the F plasmid carries a tra and trb locus which together are about 33 kb long and consist of about 40 genes The tra locus includes the pilin gene and regulatory genes which together form pili on the cell surface The locus also includes the genes for the proteins that attach themselves to the surface of F bacteria and initiate conjugation Though there is some debate on the exact mechanism of conjugation it seems that the pili are the structures through which DNA exchange occurs The F pili are extremely resistant to mechanical and thermochemical stress which guarantees successful conjugation in a variety of environments 11 Several proteins coded for in the tra or trb locus seem to open a channel between the bacteria and it is thought that the traD enzyme located at the base of the pilus initiates membrane fusion When conjugation is initiated by a signal the relaxase enzyme creates a nick in one of the strands of the conjugative plasmid at the oriT Relaxase may work alone or in a complex of over a dozen proteins known collectively as a relaxosome In the F plasmid system the relaxase enzyme is called TraI and the relaxosome consists of TraI TraY TraM and the integrated host factor IHF The nicked strand or T strand is then unwound from the unbroken strand and transferred to the recipient cell in a 5 terminus to 3 terminus direction The remaining strand is replicated either independent of conjugative action vegetative replication beginning at the oriV or in concert with conjugation conjugative replication similar to the rolling circle replication of lambda phage Conjugative replication may require a second nick before successful transfer can occur A recent report claims to have inhibited conjugation with chemicals that mimic an intermediate step of this second nicking event 12 nbsp 1 The insertion sequences yellow on both the F factor plasmid and the chromosome have similar sequences allowing the F factor to insert itself into the genome of the cell This is called homologous recombination and creates an Hfr high frequency of recombination cell 2 The Hfr cell forms a pilus and attaches to a recipient F cell 3 A nick in one strand of the Hfr cell s chromosome is created 4 DNA begins to be transferred from the Hfr cell to the recipient cell while the second strand of its chromosome is being replicated 5 The pilus detaches from the recipient cell and retracts The Hfr cell ideally wants to transfer its entire genome to the recipient cell However due to its large size and inability to keep in contact with the recipient cell it is not able to do so 6 a The F cell remains F because the entire F factor sequence was not received Since no homologous recombination occurred the DNA that was transferred is degraded by enzymes 13 b In very rare cases the F factor will be completely transferred and the F cell will become an Hfr cell 4 If the F plasmid that is transferred has previously been integrated into the donor s genome producing an Hfr strain High Frequency of Recombination some of the donor s chromosomal DNA may also be transferred with the plasmid DNA 4 The amount of chromosomal DNA that is transferred depends on how long the two conjugating bacteria remain in contact In common laboratory strains of E coli the transfer of the entire bacterial chromosome takes about 100 minutes The transferred DNA can then be integrated into the recipient genome via homologous recombination A cell culture that contains in its population cells with non integrated F plasmids usually also contains a few cells that have accidentally integrated their plasmids It is these cells that are responsible for the low frequency chromosomal gene transfers that occur in such cultures Some strains of bacteria with an integrated F plasmid can be isolated and grown in pure culture Because such strains transfer chromosomal genes very efficiently they are called Hfr high frequency of recombination The E coli genome was originally mapped by interrupted mating experiments in which various Hfr cells in the process of conjugation were sheared from recipients after less than 100 minutes initially using a Waring blender The genes that were transferred were then investigated Since integration of the F plasmid into the E coli chromosome is a rare spontaneous occurrence and since the numerous genes promoting DNA transfer are in the plasmid genome rather than in the bacterial genome it has been argued that conjugative bacterial gene transfer as it occurs in the E coli Hfr system is not an evolutionary adaptation of the bacterial host nor is it likely ancestral to eukaryotic sex 14 Spontaneous zygogenesis in E coliIn addition to classical bacterial conjugation described above for E coli a form of conjugation referred to as spontaneous zygogenesis Z mating for short is observed in certain strains of E coli 7 In Z mating there is complete genetic mixing and unstable diploids are formed that throw off phenotypically haploid cells of which some show a parental phenotype and some are true recombinants Conjugal transfer in mycobacteria editConjugation in Mycobacteria 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 Hfr conjugation mycobacterial conjugation is chromosome rather than plasmid based 8 9 Furthermore in contrast to E coli Hfr conjugation in M smegmatis all regions of the chromosome are transferred with comparable efficiencies The lengths of the donor segments vary widely but have an average length of 44 2kb Since a mean of 13 tracts are transferred the average total of transferred DNA per genome is 575kb 9 This process is referred to as Distributive conjugal transfer 8 9 Gray et al 8 found substantial blending of the parental genomes as a result of conjugation and regarded this blending as reminiscent of that seen in the meiotic products of sexual reproduction Conjugation like DNA transfer in hyperthermophilic archaea editHyperthermophilic archaea encode pili structurally similar to the bacterial conjugative pili 15 However unlike in bacteria where conjugation apparatus typically mediates the transfer of mobile genetic elements such as plasmids or transposons the conjugative machinery of hyperthermophilic archaea called Ced Crenarchaeal system for exchange of DNA 16 and Ted Thermoproteales system for exchange of DNA 15 appears to be responsible for the transfer of cellular DNA between members of the same species It has been suggested that in these archaea the conjugation machinery has been fully domesticated for promoting DNA repair through homologous recombination rather than spread of mobile genetic elements 15 In addition to the VirB2 like conjugative pilus the Ced and Ted systems include components for the VirB6 like transmembrane mating pore and the VirB4 like ATPase 15 Inter kingdom transfer edit nbsp Agrobacterium tumefaciens gall at the root of Carya illinoensis Bacteria related to the nitrogen fixing Rhizobia are an interesting case of inter kingdom conjugation 17 For example the tumor inducing Ti plasmid of Agrobacterium and the root tumor inducing Ri plasmid of A rhizogenes contain genes that are capable of transferring to plant cells The expression of these genes effectively transforms the plant cells into opine producing factories Opines are used by the bacteria as sources of nitrogen and energy Infected cells form crown gall or root tumors The Ti and Ri plasmids are thus endosymbionts of the bacteria which are in turn endosymbionts or parasites of the infected plant citation needed The Ti and Ri plasmids can also be transferred between bacteria using a system the tra or transfer operon that is different and independent of the system used for inter kingdom transfer the vir or virulence operon Such transfers create virulent strains from previously avirulent strains citation needed Genetic engineering applications editConjugation is a convenient means for transferring genetic material to a variety of targets In laboratories successful transfers have been reported from bacteria to yeast 18 plants mammalian cells 19 20 diatoms 21 and isolated mammalian mitochondria 22 Conjugation has advantages over other forms of genetic transfer including minimal disruption of the target s cellular envelope and the ability to transfer relatively large amounts of genetic material see the above discussion of E coli chromosome transfer In plant engineering Agrobacterium like conjugation complements other standard vehicles such as tobacco mosaic virus TMV While TMV is capable of infecting many plant families these are primarily herbaceous dicots Agrobacterium like conjugation is also primarily used for dicots but monocot recipients are not uncommon citation needed See also editSexual conjugation in algae and ciliates Transfection Triparental mating Zygotic inductionReferences edit a b Holmes RK Jobling MG 1996 Genetics In Baron S et al eds Genetics Conjugation in Baron s Medical Microbiology 4th ed Univ of Texas Medical Branch ISBN 0 9631172 1 1 PMID 21413277 Dr T S Ramarao M sc Ph D 1991 B sc Botany Volume 1 Patkowski Jonasz 21 April 2023 F pilus the ultimate bacterial sex machine Nature Portfolio Microbiology Community a b c Griffiths AJF 1999 An Introduction to genetic analysis 7th ed San Francisco W H Freeman ISBN 978 0 7167 3520 5 Archived from the original on 2020 02 08 Retrieved 2023 08 11 a href Template Cite book html title Template Cite book cite book a CS1 maint bot original URL status unknown link a b Ryan KJ Ray CG eds 2004 Sherris Medical Microbiology 4th ed McGraw Hill pp 60 4 ISBN 978 0 8385 8529 0 Holmes RK Jobling MG 1996 Genetics In Baron S et al eds Genetics Exchange of Genetic Information in Baron s Medical Microbiology 4th ed Univ of Texas Medical Branch ISBN 978 0 9631172 1 2 PMID 21413277 a b Gratia JP Thiry M September 2003 Spontaneous zygogenesis in Escherichia coli a form of true sexuality in prokaryotes Microbiology Reading Engl 149 Pt 9 2571 84 doi 10 1099 mic 0 26348 0 PMID 12949181 a b c d Gray TA Krywy JA Harold J Palumbo MJ Derbyshire KM July 2013 Distributive conjugal transfer in mycobacteria generates progeny with meiotic like genome wide mosaicism allowing mapping of a mating identity locus PLOS Biol 11 7 e1001602 doi 10 1371 journal pbio 1001602 PMC 3706393 PMID 23874149 a b c d Derbyshire KM Gray TA 2014 Distributive Conjugal Transfer New Insights into Horizontal Gene Transfer and Genetic Exchange in Mycobacteria Microbiol Spectr 2 1 61 79 doi 10 1128 microbiolspec MGM2 0022 2013 PMC 4259119 PMID 25505644 Lederberg J Tatum EL 1946 Gene recombination in E coli Nature 158 4016 558 Bibcode 1946Natur 158 558L doi 10 1038 158558a0 PMID 21001945 S2CID 1826960 Patkowski Jonasz B Dahlberg Tobias Amin Himani Gahlot Dharmender K Vijayrajratnam Sukhithasri Vogel Joseph P Francis Matthew S Baker Joseph L Andersson Magnus Costa Tiago R D 5 April 2023 The F pilus biomechanical adaptability accelerates conjugative dissemination of antimicrobial resistance and biofilm formation Nature Communications 14 1 1879 doi 10 1038 s41467 023 37600 y PMC 10076315 PMID 37019921 Lujan SA Guogas LM Ragonese H Matson SW Redinbo MR 2007 Disrupting antibiotic resistance propagation by inhibiting the conjugative DNA relaxase PNAS 104 30 12282 7 Bibcode 2007PNAS 10412282L doi 10 1073 pnas 0702760104 JSTOR 25436291 PMC 1916486 PMID 17630285 Genetic Exchange www microbiologybook org Retrieved 2017 12 04 Michod RE Bernstein H Nedelcu AM 2008 Adaptive value of sex in microbial pathogens PDF Infect Genet Evol 8 3 267 285 doi 10 1016 j meegid 2008 01 002 PMID 18295550 a b c d Beltran Leticia C Cvirkaite Krupovic Virginija Miller Jessalyn Wang Fengbin Kreutzberger Mark A B Patkowski Jonasz B Costa Tiago R D Schouten Stefan Levental Ilya Conticello Vincent P Egelman Edward H Krupovic Mart 2023 02 07 Archaeal DNA import apparatus is homologous to bacterial conjugation machinery Nature Communications 14 1 666 Bibcode 2023NatCo 14 666B doi 10 1038 s41467 023 36349 8 ISSN 2041 1723 PMC 9905601 PMID 36750723 van Wolferen Marleen Wagner Alexander van der Does Chris Albers Sonja Verena 2016 03 01 The archaeal Ced system imports DNA Proceedings of the National Academy of Sciences of the United States of America 113 9 2496 2501 Bibcode 2016PNAS 113 2496V doi 10 1073 pnas 1513740113 ISSN 1091 6490 PMC 4780597 PMID 26884154 Pan SQ Jin S Boulton MI Hawes M Gordon MP Nester EW July 1995 An Agrobacterium virulence factor encoded by a Ti plasmid gene or a chromosomal gene is required for T DNA transfer into plants Mol Microbiol 17 2 259 69 doi 10 1111 j 1365 2958 1995 mmi 17020259 x PMID 7494475 S2CID 38483513 Heinemann JA Sprague GF July 1989 Bacterial conjugative plasmids mobilize DNA transfer between bacteria and yeast Nature 340 6230 205 9 Bibcode 1989Natur 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animation Retrieved from https en wikipedia org w index php title Bacterial conjugation amp oldid 1176488117, wikipedia, wiki, book, books, library,

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