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Integration host factor

From Wikipedia, the free encyclopedia

Integration host factor subunit alpha
Crystallographic structure of the heterodimeric integration host factor (IHF) complex.[1] The alpha and beta subunits are colored cyan and green respectively while double stranded DNA is depicted as a brown cartoon.
Identifiers
OrganismEscherichia coli K12
SymbolihfA
Entrez945472
PDB1OWF
RefSeq (Prot)NP_416227.1
UniProtP0A6X7
Other data
ChromosomeGenomic: 1.8 - 1.8 Mb
Search for
StructuresSwiss-model
DomainsInterPro
Integration host factor subunit beta
Identifiers
OrganismEscherichia coli K12
SymbolihfB
Entrez945533
PDB1OWF
RefSeq (Prot)NP_415432.1
UniProtP0A6Y1
Other data
ChromosomeGenomic: 0.96 - 0.96 Mb
Search for
StructuresSwiss-model
DomainsInterPro

The integration host factor (IHF) is a bacterial DNA binding protein complex that facilitates genetic recombination, replication, and transcription by binding to specific DNA sequences and bending the DNA.[2] It also facilitates the integration of foreign DNA into the host genome.[3] It is a heterodimeric complex composed of two homologous subunits IHFalpha and IHFbeta.

Protein

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Integration Host factor is a DNA-binding/bending protein of E. coli and some of its bacteriophages, it is essential for gene regulation, site-specific recombination, and other physiological processes.[4] Being similar but just different enough from HU, a prominent binding protein, that specializes in the formation of bacterial nucleoids.[5] In addition, IHF is composed of two subunits, himA, and himD genes.[5] With this information, we know that IHF is a DNA-binding protein of E. coli as well as other bacteria used to regulate genes and other physiological operations.

Function

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When the Integration Host Factor was first discovered, it was only known for the site-specific recombination of bacteriophage.[4] This is all we knew for a while but through another article, we were able to find that with further research, IHF plays a key role in the scope of physiological processes of E. Coli, including site-specific recombination activities, phage packaging and partitioning, DNA replication, and the expression of many genes.[5] This leads to the fact that IHF is an essential protein used to replicate DNA, expression of genes, as well as phage packaging in cells.

lambda phage salmonella mutations

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The article discusses the Transfer of genetic information from E. coli to salmonella cells (via lambda phage) and how it can cause changes to the transduction and lysogenic phases, in some mutated Salmonella offspring. The results of these changes were the occurrence of no infectious centers and/or plaques present in mutated strains. The article also discusses the mating of E. Coli and salmonella cells using the lambda phage and the P1 pathway to deliver the genetic information from the E. Coli to the salmonella cells.

During this process the E. Coli k-12 genes are transduced into the salmonella and later expressed using IHF (integrated host factors), during the lytic phase. Some of the salmonella wild type mutations had changes to their lysogenic state, when galactose+ was present. This resulted in a failure of cell lysis, even if cells were treated with mitomycin, ultraviolet light and/or even heat, many of the mutated cells could still not achieve lysis. According to a supporting article (“Genetic recombination between Escherichia and Salmonella typhimurium”). By Baron, L.S., W.F. Carey.W.M. Spilman.1959. Proc.Nat.Acad.Sci.U.S.A.45:976-984. AFalkow,S., As well as  L.S.Baron.1970.(”Plasmid formation after lambda phage infection of Escherichlacolf-Salmonella typhosa hybrids”).J.Bacteriol.102:228-290.s The reason for these cells having resistant to lysis, as well as the survivability of these cells in harsh physical environments,this is due to salmonellas ability salmonella repressor synthesis, in the mutated forms of salmonella, this in turn makes the mutated strains immune from certain infection and various physical forces, which would kill non-mutated strains.[6]

The Enterobacteria is a virus, this virus or bacteriophage infects certain bacteria. In the lambda phage, it is specifically E. coli. The wild type, having a temperate life cycle, allows the virus to exist in 2 life cycle stages, A lysogeny, and a lytic stage. During these life cycles it destroys the cell through the process of lysis, during the lysis process the offspring of the virus are released from the burst cell. Certain mutated strains of the virus enter a lytic stage, instead of lysing the cell. During this phase, they saturate the cell with the copies of the bacteriophages of an already lysed cell. The cell has a capsid (head) and a tail, the capsid carries a double-stranded DNA which carries the infectious genetic coding material. During this phase, the virus locates coding that allows it to bind to the E. coli. The bacteriophage then injects genetic material into the cell. This usually occurs in the lytic phase. After this the virus will hijack the bacterial DNA, it then uses the cell's internal structures to produce many copies of the bacteriophages, this is followed by lysis and the virus is set free to infect other cells. During the lysogenic phase, the virus may insert itself into the DNA of the bacterial DNA. The virus may then develop into a non-parthenogenetic virus, where it exists as a commensal relationship and does not harm the bacterial cell.[6]

HU and IHF in experimentally mutated E.coli Strains

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HU and integration host factor function as auxiliary proteins in cleavage of phage lambda cohesive ends by terminase is an academic journal written by the Department of Molecular Genetics. In their article, they created isogenic strains of E.coli that were lacking HU or integration host factors to test whether bacteriophage would grow under these conditions.

HU and integration host factors (referred to as IHF throughout) are DNA-binding proteins that participate in several DNA replication processes.[7] HU and IHF are both responsible for inhibiting and stimulating DNA replication in E.coli. Structurally, HU and IHF are overall similar, which allows them to be interchangeable with one another. As proven in the Journal of Bacteriology experiment’s results, the two are interchangeable in some processes, but they are not perfectly interchangeable. If a bacteriophage contains a cos site mutation or the host has a DNA gyrase mutation, IHF is required for there to be growth of the bacteriophage [7]

The Journal of Bacteriology experiment tested multiple different things about bacteriophage growth when lacking HU or IHF or both. They found that if the phage was lacking both HU and IHF the lytic growth was restricted, and plaques were unable to form. There was also a noticeable difference in burst sizes when one was missing, compared to both of them missing. Similarly, those strains lacking HU or IHF showed that late gene transcription was reduced by 3 folds. Overall, they found that HU and IHF, having at least one of them present in bacteriophage is necessary for DNA maturation to occur.[7]

References

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  1. ^ PDB: 1OWG​; Lynch TW, Read EK, Mattis AN, Gardner JF, Rice PA (July 2003). "Integration host factor: putting a twist on protein-DNA recognition". Journal of Molecular Biology. 330 (3): 493–502. doi:10.1016/s0022-2836(03)00529-1. PMID 12842466.
  2. ^ Travers A (April 1997). "DNA-protein interactions: IHF--the master bender". Current Biology. 7 (4): R252–R254. Bibcode:1997CBio....7R.252T. doi:10.1016/s0960-9822(06)00114-x. PMID 9162504.
  3. ^ Friedman DI (November 1988). "Integration host factor: a protein for all reasons". Cell. 55 (4): 545–54. doi:10.1016/0092-8674(88)90213-9. hdl:2027.42/27063. PMID 2972385.
  4. ^ a b Freundlich M, Ramani N, Mathew E, Sirko A, Tsui P (September 1992). "The role of integration host factor in gene expression in Escherichia coli". Molecular Microbiology. 6 (18): 2557–2563. doi:10.1111/j.1365-2958.1992.tb01432.x. PMID 1447969.
  5. ^ a b c Tsui P, Huang L, Freundlich M (September 1991). "Integration host factor binds specifically to multiple sites in the ompB promoter of Escherichia coli and inhibits transcription". Journal of Bacteriology. 173 (18): 5800–5807. doi:10.1128/jb.173.18.5800-5807.1991. PMC 208313. PMID 1885551.
  6. ^ a b Baron LS, Penido E, Ryman IR, Falkow S (April 1970). "Behavior of coliphage lambda in hybrids between Escherichia coli and Salmonella". Journal of Bacteriology. 102 (1): 221–233. doi:10.1128/jb.102.1.221-233.1970. PMC 284990. PMID 4908675.
  7. ^ a b c Mendelson I, Gottesman M, Oppenheim AB (March 1991). "HU and integration host factor function as auxiliary proteins in cleavage of phage lambda cohesive ends by terminase". Journal of Bacteriology. 173 (5): 1670–1676. doi:10.1128/jb.173.5.1670-1676.1991. PMC 207316. PMID 1825651.