Guanosine pentaphosphate

(p)ppGpp, guanosine pentaphosphate and tetraphosphate, also known as the "magic spot" nucleotides,[1] are alarmones involved in the stringent response in bacteria that cause the inhibition of RNA synthesis when there is a shortage of amino acids. This inhibition by (p)ppGpp decreases translation in the cell, conserving amino acids present. Furthermore, ppGpp and pppGpp cause the up-regulation of many other genes involved in stress response such as the genes for amino acid uptake (from surrounding media) and biosynthesis.[2]

Guanosine pentaphosphate
Names
Other names
guanosine pentaphosphate (pppGpp), guanosine tetraphosphate (ppGpp)
Identifiers
CAS Number
DrugBank
PubChem CID
Properties
Chemical formula
C10H18N5O20P5
Molar mass 683.14 g·mol−1
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Infobox references

Discovery

ppGpp and pppGpp were first identified by Michael Cashel in 1969.[3] These nucleotides were found to accumulate rapidly in Escherichia coli cells starved for amino acids and inhibit synthesis of ribosomal and transfer RNAs.[4] It is now known that (p)ppGpp is also produced in response to other stressors including carbon and phosphate starvation. Historically, literature surrounding (p)ppGpp have given conflicting findings and information on its role in bacterial stress responses.[5]

Absence of (p)ppGpp

E.coli are shown to be more sensitive to accumulations of guanosine tetraphosphate than guanosine pentaphosphate. [6] A complete absence of (p)ppGpp causes multiple amino acid requirements, poor survival of aged cultures, aberrant cell division, morphology, and immotility, as well as being locked in a growth mode during entry into starvation.

Synthesis and degradation of (p)ppGpp

The synthesis and degradation of (p)ppGpp have been most extensively characterized in the bacterial model organism Escherichia coli.

RelA's Role in (p)ppGpp Synthesis

(p)ppGpp is created via pppGpp synthase, also known as RelA, and is converted from pppGpp to ppGpp via pppGpp phosphohydrolase. RelA is associated with about every one in two hundred ribosomes and it becomes activated when an uncharged transfer RNA (tRNA) molecule enters the A site of the ribosome, due to the shortage of amino acid required by the tRNA. If a mutant bacterium is relA it is said to be relaxed and no regulation of RNA production due to amino acid absence is seen.

SpoT's Role in (p)ppGpp Degradation

E. coli produces a second protein responsible for degradation of (p)ppGpp, SpoT. When the amino acid balance in the cell is restored, (p)ppGpp is hydrolyzed by SpoT and returned to a more energetically favorable state. This protein also has the capacity to synthesize (p)ppGpp, and seems to be the primary synthase under certain conditions of stress. Most other bacteria encode a single protein that is responsible for both synthesis and degradation of (p)ppGpp, generally homologs of SpoT.

Targets of (p)ppGpp

Targets of (p)ppGpp include rRNA operons, of which there are seven in E.coli, all of which have 2 promoters. When (p)ppGpp associates with the promoter it affects the RNA polymerase enzyme's ability to bind and initiate transcription. It is thought that (p)ppGpp may affect the stability of the open complex formed by RNA polymerase on DNA and therefore affect promoter clearance. Its presence also leads to an increase in pausing during transcription elongation and it competes with nucleoside triphosphate substrates.

There is now a consensus that (p)ppGpp is a determinant of growth rate control rather than nucleoside triphosphate (NTP) substrate concentrations.

Impact of (p)ppGpp on bacterial physiology

Inhibition of growth by inhibition of protein synthesis

ppGpp inhibits IF2-mediated fMet-Phe initiation dipeptide formation, probably by interfering with 30S and 50S subunit interactions. E. coli accumulates more ppGpp than pppGpp during amino acid starvation, and ppGpp has about 8-fold greater efficiency than that of pppGpp. While B. subtilis accumulates more pppGpp than ppGpp.

Inhibition of DNA replication

In E. coli amino acid starvation inhibited DNA replication at the initiation stage at oriC, most probably owing to the lack of the DnaA replication initiation protein. In B. subtilis, the replication arrest due to (p)ppGpp accumulation is caused by the binding of an Rtp protein to specific sites about 100-200kb away from oriC in both directions. DNA primase (DnaG) was directly inhibited by (p)ppGpp. Unlike E. coli, B. subtilis accumulates more pppGpp than ppGpp; the more abundant nucleotide is a more-potent DnaG inhibitor. ppGpp can bind with Obg protein which belongs to the conserved, small GTPase protein family. Obg protein interacts with several regulators (RsbT, RsbW, RsbX) necessary for the stress activation of sigma B.

Impact on phage replication and development

The (p)ppGpp levels of the host seem to act as a sensor for phage lambda development, primarily affecting transcription. Modest ppGpp levels inhibit pR and active pE, pI, and paQ promoters in vivo and have effects in vitro that seem to favor lysogeny. In contrast, absent or high concentrations of (p)ppGpp favor lysis. Modest ppGpp levels favor lysogeny by leading to low HflB (FtsH). When ppGpp is either absent or high, HflB protease levels are high; this leads to lower CII (a lysogeny-promoting phage protein) and favors lysis.

Characteristics of affected promoters

One of the key elements of promoters inhibited by (p)ppGpp is the presence of a GC-rich discriminator, defined as a region between TATA-box (-10 box) and +1 nt (where +1 is the transcription start site). Promoters negatively regulated by ppGpp have a 16-bp linker, in contrast with the 17-bp consensus. Promoters activated by ppGpp seem to have an AT-rich discriminator and linger linkers (for example, the his promoter linker is 18 bp).

RNAP is the target

Genetic evidence suggesting that RNAP was the target of ppGpp came from the discovery that M+ mutants (also called stringent RNAP mutants) display in vitro and in vivo mimicry of physiology and transcription regulation conferred by (p)ppGpp, even in its absence. Cross-linking ppGpp to RNAP reinforced this notion. Structural details of an association between ppGpp and RNAP came from the analysis of cocrystals that positioned ppGpp in the secondary channel of RNAP near the catalytic center.

DksA augments regulation

DksA is a 17-kDa protein, its structure is similar to GreA and GreB, which are well-characterized transcriptional elongation factors. GreA and GreB bind directly to RNAP rather than DNA and act by inserting their N-terminal coiled-coil finger domain through the RNAP secondary channel. Two conserved acidic residues at the tip of the finger domain are necessary to induce RNAP's intrinsic ability to cleave backtracked RNA. DksA also possesses two acidic residues at its finger tip, but it does not induce nucleolytic cleavage activity. Instead, these residues are proposed to stabilize ppGpp binding to RNAP by mutual coordination of an Mg2+ ion that is crucial for polymerization.

Transcription inhibition and activation

ppGpp directly inhibits transcription from ribosomal promoters. One model is ppGpp and DksA together and independently decrease the stability of the open complexes formed on DNA by RNAP. Another model is the trapping mechanism. In this model, RNAP is trapped by ppGpp in closed complexes and is unable to initiate transcription. Thus, ppGpp seems to act at many levels, and the mechanism of its action is a complex outcome of several factors, intrinsic promoter properties not being the least of them. The transcription activation by ppGpp can be direct or indirect. Direct activation occurs when RNAP interacts with effectors, such as ppGpp, DksA or both, to increase transcription from a given promoter. Indirect activation by these effectors of one promoter relies on inhibition of other (strong) promoters, leading to increased availability of RNAP that indirectly activates transcription initiation. The promoters that activated directly by ppGpp include PargI, PthrABC, PlivJ, and PhisG. The indirectly activation promoters include these dependent on sigma factors: S, H, N, E. When strong promoters, such as rrn, are inhibited, there more RNAP are available for these alternative sigma factors.

Pathogenesis and (p)ppGpp

When (p)ppGpp is absent, pathogenicity is compromised for reasons that vary with the organism studied. Deleting relA and spoT genes, but not relA alone, gave a (p)ppGpp0 state that resulted in strong attenuation in mice and noninvasiveness in vitro. Vaccine tests reveal that 30 days after single immunization with the (p)ppGpp0 strain, mice were protected from challenge with wild-type Salmonella at a dose 106-fold above the established LD50.

Polyphosphate accumulation

It was proposed that increased synthesis of (p)ppGpp would cause polyphosphate (PolyP) accumulation in E. coli.[7] The alarmone could interact with exopolyphosphatase PPX, which would inhibit the hydrolysis of PolyP, thus causing its accumulation in bacteria. Although it has recently been shown that it is actually DksA and not (p)ppGpp that causes this buildup.[8] It has been shown in Pseudomonas aeruginosa that the phoU mutant (phoU belongs to the Pho Regulon) synthesizes more (p)ppGpp and this would be one of the reasons that it accumulates more polyphosphate.[9]

References

  1. Adams, D.G.; Phillips, D.O.; Nichols, Josie M.; Carr, N.G. (1977-09-01). "The presence and absence of magic spot nucleotide modulation in cyanobacteria undergoing nutritional shift-down". FEBS Letters. 81 (1): 48–52. doi:10.1016/0014-5793(77)80925-3. PMID 409622. S2CID 12110840.
  2. Srivatsan, A.; Wang, J. D. (2008). "Control of bacterial transcription, translation and replication by (p)ppGpp". Current Opinion in Microbiology. 11 (2): 100–105. doi:10.1016/j.mib.2008.02.001. PMID 18359660.
  3. Cashel, Michael; Gallant, Jonathan (March 1969). "Two Compounds implicated in the Function of the RC Gene of Escherichia coli". Nature. 221 (5183): 838–841. Bibcode:1969Natur.221..838C. doi:10.1038/221838a0. ISSN 1476-4687. PMID 4885263. S2CID 4146964.
  4. Cashel M, Gentry DR, Hernandez VH, Vinella D: The stringent response. In Escherichia coli and Salmonella: cellular and molecular biology, edn 2. Edited by Neidhardt FC, Curtiss III R, Ingraham JL, Lin ECC, Low KB, Magasanik B, Reznikoff WS, Riley M, Schaechter M, Umbarger HE.ASM Press; 1996.
  5. Pacios, Olga; Blasco, Lucia; Bleriot, Inés; Fernandez-Garcia, Laura; Ambroa, Antón; López, María; Bou, German; Cantón, Rafael; Garcia-Contreras, Rodolfo; Wood, Thomas K.; Tomás, Maria (2020-09-21). "(p)ppGpp and Its Role in Bacterial Persistence: New Challenges". Antimicrobial Agents and Chemotherapy. 64 (10): e01283–20. doi:10.1128/AAC.01283-20. ISSN 0066-4804. PMC 7508602. PMID 32718971.
  6. Mechold, Undine; Potrykus, Katarzyna; Murphy, Helen; Murakami, Katsuhiko S.; Cashel, Michael (July 2013). "Differential regulation by ppGpp versus pppGpp in Escherichia coli". Nucleic Acids Research. 41 (12): 6175–6189. doi:10.1093/nar/gkt302. ISSN 1362-4962. PMC 3695517. PMID 23620295.
  7. Kuroda, Akio; Murphy, Helen; Cashel, Michael; Kornberg, Arthur (1997-08-22). "Guanosine Tetra- and Pentaphosphate Promote Accumulation of Inorganic Polyphosphate in Escherichia coli". Journal of Biological Chemistry. 272 (34): 21240–21243. doi:10.1074/jbc.272.34.21240. ISSN 0021-9258. PMID 9261133.
  8. Gray, Michael J. (2019-02-11). "Inorganic Polyphosphate Accumulation in Escherichia coli Is Regulated by DksA but Not by (p)ppGpp". Journal of Bacteriology. 201 (9). doi:10.1128/jb.00664-18. ISSN 0021-9193. PMC 6456864. PMID 30745375.
  9. de Almeida, Luiz Gustavo; Ortiz, Julia Helena; Schneider, René P.; Spira, Beny (2015-02-20). "phoUInactivation in Pseudomonas aeruginosa Enhances Accumulation of ppGpp and Polyphosphate". Applied and Environmental Microbiology. 81 (9): 3006–3015. Bibcode:2015ApEnM..81.3006D. doi:10.1128/aem.04168-14. ISSN 0099-2240. PMC 4393453. PMID 25710363.

Further reading

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