Histidine phosphotransfer domain explained

Symbol:Hpt
Histidine phosphotransfer domain
Pfam:PF01627
Interpro:IPR008207
Smart:HPT
Prosite:PS50894
Symbol:HPTransfase
Histidine phosphotransferase
Pfam:PF10090
Interpro:IPR018762

Histidine phosphotransfer domains and histidine phosphotransferases (both often abbreviated HPt) are protein domains involved in the "phosphorelay" form of two-component regulatory systems. These proteins possess a phosphorylatable histidine residue and are responsible for transferring a phosphoryl group from an aspartate residue on an intermediate "receiver" domain, typically part of a hybrid histidine kinase, to an aspartate on a final response regulator.

Function

In orthodox two-component signaling, a histidine kinase protein autophosphorylates on a histidine residue in response to an extracellular signal, and the phosphoryl group is subsequently transferred to an aspartate residue on the receiver domain of a response regulator. In phosphorelays, the "hybrid" histidine kinase contains an internal aspartate-containing receiver domain to which the phosphoryl group is transferred, after which an HPt protein containing a phosphorylatable histidine receives the phosphoryl group and finally transfers it to the response regulator. The relay system thus progresses in the order His-Asp-His-Asp, with the second His contributed by Hpt.[1] [2] [3] In some cases, a phosphorelay system is constructed from four separate proteins rather than a hybrid histidine kinase with an internal receiver domain, and in other examples both the receiver and the HPt domains are present in the histidine kinase polypeptide chain.[4] A census of two-component system domain architecture found that HPt domains in bacteria are more common as domains of larger proteins than they are as individual proteins.

Regulation

The increased complexity of the phosphorelay system compared to orthodox two-component signaling provides additional opportunities for regulation and improves the specificity of the response.[5] Although there is very little cross-talk between orthodox two-component systems, phosphorelays allow more complex signaling pathways; examples include a bifurcated pathway with multiple downstream outputs, as in the case of the Caulobacter crescentus ChpT HPt involved in cell cycle regulation,[6] or, alternatively, pathways in which more than one histidine kinase controls a single response regulator, such as the sporulation pathway in Bacillus subtilis, which can give rise to complex temporal variations.[7] In some known cases, there is an additional form of regulation in phosphohistidine phosphatase enzymes that act on HPt, such as the Escherichia coli protein SixA which targets ArcB.

Structure

The histidine phosphotransfer function can be carried out by proteins with at least two different architectures, both composed of a four-helix bundle but differing in the way the bundle is assembled. Most structurally characterized HPt proteins, such as the Hpt domain from the Escherichia coli protein ArcB and the Saccharomyces cerevisiae protein Ypd1, form the bundle as monomers. In the less common type, such as the Bacillus subtilis sporulation factor Spo0B or the Caulobacter crescentus protein ChpT, the bundle is assembled as a protein dimer, with similarity to the structure of histidine kinases. Monomeric HPt domains possess only one phosphorylatable histidine residue and interact with one response regulator, whereas dimers have two phosphorylation sites and can interact with two response regulators at the same time. Monomeric HPt domains have no enzymatic activity of their own and act purely as phosphate shuttles, while the dimeric Spo0B is catalytic; its phosphotransfer rate to the recipient response regulator is dramatically accelerated compared to histidine phosphate.[8] Despite possessing a second domain with some similarity to ATPase domains, dimeric HPt proteins have not been shown to bind or hydrolyze ATP and lack key residues present in other ATPases.

The monomeric and dimeric forms do not have detectable sequence similarity and are most likely not evolutionarily related; they are instead examples of convergent evolution. Although dimeric HPts likely originate from degenerate histidine kinases, it is possible that monomeric HPts have a number of distinct origins, as there are few evolutionary constraints on the structure.

Distribution

In bacteria, where two-component signaling is extremely common, about 25% of known histidine kinases are of the hybrid type. Two-component systems are much rarer in archaea and eukaryotes, and occur in lower eukaryotes and in plants but not in metazoans. Among known examples, most if not all eukaryotic two-component systems are hybrid kinase phosphorelays.

A bioinformatic census of bacterial genomes found large variations in the number of (monomeric) HPt domains identified in different bacterial phyla, with some genomes encoding no HPts at all. Relative to the number of histidine kinase and response regulators present in a genome, eukaryotes have more identifiable HPt domains than bacteria.[9] In fungi, the genomic inventory of HPt proteins varies, with filamentous fungi generally possessing more HPt proteins than yeasts; only one is encoded in the well-characterized Saccharomyces cerevisiae genome. Plants generally have more than one HPt, but fewer HPts than response regulators.[10]

Notes and References

  1. Capra EJ, Laub MT . Evolution of two-component signal transduction systems . Annual Review of Microbiology . 66 . 325–47 . 2012 . 22746333 . 4097194 . 10.1146/annurev-micro-092611-150039 .
  2. Surujon D, Ratner DI . Use of a Probabilistic Motif Search to Identify Histidine Phosphotransfer Domain-Containing Proteins . PLOS ONE . 11 . 1 . e0146577 . 2016 . 26751210 . 4709007 . 10.1371/journal.pone.0146577 . 2016PLoSO..1146577S . free .
  3. Xu Q, Carlton D, Miller MD, Elsliger MA, Krishna SS, Abdubek P, Astakhova T, Burra P, Chiu HJ, Clayton T, Deller MC, Duan L, Elias Y, Feuerhelm J, Grant JC, Grzechnik A, Grzechnik SK, Han GW, Jaroszewski L, Jin KK, Klock HE, Knuth MW, Kozbial P, Kumar A, Marciano D, McMullan D, Morse AT, Nigoghossian E, Okach L, Oommachen S, Paulsen J, Reyes R, Rife CL, Sefcovic N, Trame C, Trout CV, van den Bedem H, Weekes D, Hodgson KO, Wooley J, Deacon AM, Godzik A, Lesley SA, Wilson IA . Crystal structure of histidine phosphotransfer protein ShpA, an essential regulator of stalk biogenesis in Caulobacter crescentus . Journal of Molecular Biology . 390 . 4 . 686–98 . July 2009 . 19450606 . 2726009 . 10.1016/j.jmb.2009.05.023 .
  4. Book: Whitworth. David E.. Filloux. Alain A.M. . Alain Filloux. Bacterial regulatory networks. 2012. Caister Academic Press. Norfolk, U.K.. 9781908230034. Two-component Regulatory Systems in Prokaryotes. 191–222.
  5. Varughese KI . Molecular recognition of bacterial phosphorelay proteins . Current Opinion in Microbiology . 5 . 2 . 142–8 . April 2002 . 11934609 . 10.1016/s1369-5274(02)00305-3 .
  6. Blair JA, Xu Q, Childers WS, Mathews II, Kern JW, Eckart M, Deacon AM, Shapiro L . Branched signal wiring of an essential bacterial cell-cycle phosphotransfer protein . Structure . 21 . 9 . 1590–601 . September 2013 . 23932593 . 3787845 . 10.1016/j.str.2013.06.024 .
  7. Salazar ME, Laub MT . Temporal and evolutionary dynamics of two-component signaling pathways . Current Opinion in Microbiology . 24 . 7–14 . April 2015 . 25589045 . 4380680 . 10.1016/j.mib.2014.12.003 . 1721.1/105366 .
  8. Zapf J, Sen U, Hoch JA, Varughese KI . A transient interaction between two phosphorelay proteins trapped in a crystal lattice reveals the mechanism of molecular recognition and phosphotransfer in signal transduction . Structure . 8 . 8 . 851–62 . August 2000 . 10997904 . 10.1016/s0969-2126(00)00174-x . free .
  9. Salvado B, Vilaprinyo E, Sorribas A, Alves R . A survey of HK, HPt, and RR domains and their organization in two-component systems and phosphorelay proteins of organisms with fully sequenced genomes . PeerJ . 3 . e1183 . 2015 . 26339559 . 4558063 . 10.7717/peerj.1183 . free .
  10. Fassler JS, West AH . Histidine phosphotransfer proteins in fungal two-component signal transduction pathways . Eukaryotic Cell . 12 . 8 . 1052–60 . August 2013 . 23771905 . 3754533 . 10.1128/ec.00083-13 .