Identification of the structural and functional domains of the large serine recombinase TnpX from Clostridium perfringens

Members of the large serine resolvase family of site-specific recombinases are responsible for the movement of several mobile genetic elements; however, little is known regarding the structure or function of these proteins. TnpX is a serine recombinase that is responsible for the movement of the chloramphenicol resistance elements of the Tn4451/3 family. We have shown that TnpX binds differentially to its transposon and target sites, suggesting that resolvase-like excision and insertion were two distinct processes. To analyze the structural and functional domains of TnpX and, more specifically, to define the domains involved in protein-DNA and protein-protein interactions, we conducted limited proteolysis studies on the wild-type dimeric TnpX(1-707) protein and its functional truncation mutant, TnpX(1-597). The results showed that TnpX was organized into three major domains: domain I (amino acids (aa) 1-170), which included the resolvase catalytic domain; domain II (aa 170-266); and domain III (aa 267-707), which contained the dimerization region and two separate regions involved in binding to the DNA target. A small polypeptide (aa 533-587) was shown to bind specifically to the TnpX binding sites providing further evidence that it was the primary DNA binding region. In addition, a previously unidentified DNA binding site was shown to be located between residues 583 and 707. Finally, the DNA binding and multerimization but not the catalytic functions of TnpX could be reconstituted by recombining separate polypeptides that contain the N- and C-terminal regions of the protein. These data provide evidence that TnpX has separate catalytic, DNA binding, and multimerization domains.     

Diversity in the serine recombinases

Most site-specific recombinases fall into one of two families, based on evolutionary and mechanistic relatedness. These are the tyrosine recombinases or lambda integrase family and the serine recombinases or resolvase/invertase family. The tyrosine recombinases are structurally diverse and functionally versatile and include integrases, resolvases, invertases and transposases. Recent studies have revealed that the serine recombinase family is equally versatile and members have a variety of structural forms. The archetypal resolvase/invertases are highly regulated, only affect resolution or inversion and they have an N-terminal catalytic domain and a C-terminal DNA binding domain. Phage-encoded serine recombinases (e.g. phiC31 integrase) cause integration and excision with strictly controlled directionality, and have an N-terminal catalytic domain but much longer C-terminal domains compared with the resolvase/invertases. This high molecular weight group also contains transposases (e.g. TnpX from Tn4451). Other transposases, which belong to a third structurally different group, are similar in size to the resolvase/invertases but have the DNA binding domain N-terminal to the catalytic domain (e.g. IS607 transposase). These three structural groups represented by the resolvase/invertases, the large serine recombinases and relatives of IS607 transposase correlate with three major groupings seen in a phylogeny of the catalytic domains. These observations indicate that the serine recombinases are modular and that fusion of the catalytic domain to unrelated sequences has generated structural and functional diversity.     

Two distinct regions of the large serine recombinase TnpX are required for DNA binding and biological function

The large serine recombinase, TnpX, from the Clostridium perfringens integrative mobilizable element Tn 4451 , consists of three domains and has two known DNA binding regions. In this study random and site-directed mutagenesis was used to identify other regions of TnpX that were required for biological activity. Genetic and biochemical analysis of these mutants led to the identification of important TnpX residues in the N-terminal catalytic pocket. In addition, another region of TnpX (aa 243–261), which is conserved within large serine recombinases, was shown to be essential for both excision and insertion. Mutation of charged residues within this region led to a loss of biological activity and aberrant DNA binding. This phenotype was mediated by interaction with the distal DNA binding region (aa 598–707). In these mutants, removal of residues 598–707 resulted in loss of DNA binding, despite the presence of the primary DNA binding region (aa 533–583). Analysis of mutations within the aa 243–261 region indicated that different protein conformations were involved in the insertion and the excision reactions. In summary, we have shown that TnpX is a complex protein that has multiple intra- and intermolecular interaction sites, providing insight into the structural and functional complexity of this important enzyme family.     

Expanding the zinc-finger recombinase repertoire: directed evolution and mutational analysis of serine recombinase specificity determinants

The serine recombinases are a diverse family of modular enzymes that promote high-fidelity DNA rearrangements between specific target sites. Replacement of their native DNA-binding domains with custom-designed Cys₂–His₂ zinc-finger proteins results in the creation of engineered zinc-finger recombinases (ZFRs) capable of achieving targeted genetic modifications. The flexibility afforded by zinc-finger domains enables the design of hybrid recombinases that recognize a wide variety of potential target sites; however, this technology remains constrained by the strict recognition specificities imposed by the ZFR catalytic domains. In particular, the ability to fully reprogram serine recombinase catalytic specificity has been impeded by conserved base requirements within each recombinase target site and an incomplete understanding of the factors governing DNA recognition. Here we describe an approach to complement the targeting capacity of ZFRs. Using directed evolution, we isolated mutants of the β and Sin recombinases that specifically recognize target sites previously outside the scope of ZFRs. Additionally, we developed a genetic screen to determine the specific base requirements for site-specific recombination and showed that specificity profiling enables the discovery of unique genomic ZFR substrates. Finally, we conducted an extensive and family-wide mutational analysis of the serine recombinase DNA-binding arm region and uncovered a diverse network of residues that confer target specificity. These results demonstrate that the ZFR repertoire is extensible and highlights the potential of ZFRs as a class of flexible tools for targeted genome engineering.     

Two Clip Domain Family of Serine Proteases and a Serine Protease Homolog from the Fall Webworm, Hyphantria cunea; cDNA Cloning and Characterization

Two types of serine proteases and a serine protease homologue cDNAs were isolated from Hyphantria cunea larvae induced immune response due to an injection of a microorganism through RT‐PCR and cDNA library screening, and their characteristics were examined. The isolated cDNAs are composed 2.1 kb, 2.2 kb, and 2.5 kb nucleotide each, which encoded 388, 390, 580 amino acid residues, and were designated as HcPE‐1, HcPE‐2 and HcPE‐3, respectively. They were revealed as serine proteases or a serine protease homologue with the clip domain through a database search. The deduced amino acid sequence comparison showed high homology of 72‐78% among them. Six Cys residues of the N‐terminal clip domain forming the disulfide bond, Cys residues of the catalytic domain, and Cys residues forming inter‐bridge between clip domain and catalytic domain were also well preserved. Three amino acid residues, His, Asp, and Ser, within the active site were perfectly conserved in HcPE‐2 and HcPE‐3, however, His was replaced with Gln¹⁷⁸ in HcPE‐1. The Arg residues (HcPE‐1, Arg¹³²; HcPE‐2, Arg¹³⁴; HcPE‐3, Arg³²⁵) known as the activation sites by proteolytic cleavage were preserved well in all three types of protein. In case of HcPE‐3, three continuous clip‐like domains existed in the N terminal. As the result of phylogenetic analysis, three clip domain family of protein from H. cunea make groups with arthropod proclotting enzyme precursor. Northern blot analysis showed all three genes were induced through an injection of Escherichia coli, but expression patterns were varied.     

Conformational transitions driven by pyridoxal‐5′‐phosphate uptake in the psychrophilic serine hydroxymethyltransferase from Psychromonas ingrahamii

Serine hydroxymethyltransferase (SHMT) is a pyridoxal‐5′‐phosphate (PLP)‐dependent enzyme belonging to the fold type I superfamily, which catalyzes in vivo the reversible conversion of l ‐serine and tetrahydropteroylglutamate (H₄PteGlu) to glycine and 5,10‐methylenetetrahydropteroylglutamate (5,10‐CH₂‐H₄PteGlu). The SHMT from the psychrophilic bacterium Psychromonas ingrahamii (piSHMT) had been recently purified and characterized. This enzyme was shown to display catalytic and stability properties typical of psychrophilic enzymes, namely high catalytic activity at low temperature and thermolability. To gain deeper insights into the structure–function relationship of piSHMT, the three‐dimensional structure of its apo form was determined by X‐ray crystallography. Homology modeling techniques were applied to build a model of the piSHMT holo form. Comparison of the two forms unraveled the conformation modifications that take place when the apo enzyme binds its cofactor. Our results show that the apo form is in an “open” conformation and possesses four (or five, in chain A) disordered loops whose electron density is not visible by X‐ray crystallography. These loops contain residues that interact with the PLP cofactor and three of them are localized in the major domain that, along with the small domain, constitutes the single subunit of the SHMT homodimer. Cofactor binding triggers a rearrangement of the small domain that moves toward the large domain and screens the PLP binding site at the solvent side. Comparison to the mesophilic apo SHMT from Salmonella typhimurium suggests that the backbone conformational changes are wider in psychrophilic SHMT. Proteins 2014; 82:2831–2841. © 2014 Wiley Periodicals, Inc.     

A comprehensive approach to zinc-finger recombinase customization enables genomic targeting in human cells

Zinc-finger recombinases (ZFRs) represent a potentially powerful class of tools for targeted genetic engineering. These chimeric enzymes are composed of an activated catalytic domain derived from the resolvase/invertase family of serine recombinases and a custom-designed zinc-finger DNA-binding domain. The use of ZFRs, however, has been restricted by sequence requirements imposed by the recombinase catalytic domain. Here, we combine substrate specificity analysis and directed evolution to develop a diverse collection of Gin recombinase catalytic domains capable of recognizing an estimated 3.77 × 10⁷ unique DNA sequences. We show that ZFRs assembled from these engineered catalytic domains recombine user-defined DNA targets with high specificity, and that designed ZFRs integrate DNA into targeted endogenous loci in human cells. This study demonstrates the feasibility of generating customized ZFRs and the potential of ZFR technology for a diverse range of applications, including genome engineering, synthetic biology and gene therapy.     

DNA binding properties of TnpX indicate that different synapses are formed in the excision and integration of the Tn4451 family

Site-specific recombination is an important mechanism for genetic exchange. Insertional recombination mediated by the recently delineated large resolvase or serine recombinase proteins is unique within the resolvase family as integration was thought to be a reaction catalysed only by members of the integrase or tyrosine recombinase family of site-specific recombinases. The large resolvase TnpX is a serine recombinase that is responsible for the movement of the Tn4451/3 family of chloramphenicol resistance elements, which are found within two genera of the medically important clostridia. Deletion analysis of TnpX showed that the last 110 amino acids (aa) of TnpX, which comprise a cysteine rich region, were not essential for its biological function and that a region required for DNA binding was located between aa 493-597. Purified TnpX was shown to bind to the ends of the element and to the joint of the circular intermediate with high affinity but, most unusually, to bind to its target sites with a considerably lower affinity. Therefore, it was concluded that the resolvase-like excision and insertion reactions mediated by TnpX were distinct processes even though the same serine recombinase mechanism was involved. TnpX is the first large serine recombinase in which differential binding to its transposon and target sites has been demonstrated.     

Plasmid replication initiator RepB forms a hexamer reminiscent of ring helicases and has mobile nuclease domains

RepB initiates plasmid rolling‐circle replication by binding to a triple 11‐bp direct repeat (bind locus) and cleaving the DNA at a specific distant site located in a hairpin loop within the nic locus of the origin. The structure of native full‐length RepB reveals a hexameric ring molecule, where each protomer has two domains. The origin‐binding and catalytic domains show a three‐layer α–β–α sandwich fold. The active site is positioned at one of the faces of the β‐sheet and coordinates a Mn²⁺ ion at short distance from the essential nucleophilic Y99. The oligomerization domains (ODs), each consisting of four α‐helices, together define a compact ring with a central channel, a feature found in ring helicases. The toroidal arrangement of RepB suggests that, similar to ring helicases, it encircles one of the DNA strands during replication to confer processivity to the replisome complex. The catalytic domains appear to be highly mobile with respect to ODs. This mobility may account for the adaptation of the protein to two distinct DNA recognition sites.     

Binding of calcium is sensed structurally and dynamically throughout the second calcium‐binding domain of the sodium/calcium exchanger

We report the effects of Ca²⁺ binding on the backbone relaxation rates and chemical shifts of the AD and BD splice variants of the second Ca²⁺‐binding domain (CBD2) of the sodium–calcium exchanger. Analysis of the Ca²⁺‐induced chemical shifts perturbations yields similar K_D values of 16–24 μM for the two CBD2‐AD Ca²⁺‐binding sites, and significant effects are observed up to 20 Å away. To quantify the Ca²⁺‐induced chemical shift changes, we performed a comparative analysis of eight Ca²⁺‐binding proteins that revealed large differences between different protein folds. The CBD2 ¹⁵N relaxation data show the CBD2‐AD Ca²⁺ coordinating loops to be more rigid in the Ca²⁺‐bound state as well as to affect the FG‐loop located at the opposite site of the domain. The equivalent loops of the CBD2‐BD splice variant do not bind Ca²⁺ and are much more dynamic relative to both the Ca²⁺‐bound and apo forms of CBD2‐AD. A more structured FG‐loop in CBD2‐BD is suggested by increased S² order parameter values relative to both forms of CBD2‐AD. The chemical shift and relaxation data together indicate that, in spite of the small structural changes, the Ca²⁺‐binding event is felt throughout the molecule. The data suggest that the FG‐loop plays an important role in connecting the Ca²⁺‐binding event with the other cytosolic domains of the NCX, in line with in vivo and in vitro biochemical data as well as modeling results that connect the CBD2 FG‐loop with the first Ca²⁺‐binding domain of NCX. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Identification of a novel ligand binding site in phosphoserine phosphatase from the hyperthermophilic archaeon Thermococcus onnurineus

Phosphoserine phosphatase (PSP) catalyzes the final and irreversible step of L‐serine synthesis by hydrolyzing phosphoserine to produce L ‐serine and inorganic phosphate. Developing a therapeutic drug that interferes with serine production is of great interest to regulate the pathogenicity of some bacteria and control D ‐serine levels in neurological diseases. We determined the crystal structure of PSP from the hyperthermophilic archaeon Thermococcus onnurineus at 1.8 Å resolution, revealing an NDSB ligand bound to a novel site that is located in a fissure between the catalytic domain and the CAP module. The structure shows a half‐open conformation of the CAP 1 module with a unique protruding loop of residues 150–155 that possesses a helical conformation in other structures of homologous PSPs. Activity assays indicate that the enzyme exhibits marginal PSP activity at low temperature but a sharp increase in the k_cat/K_M value, approximately 22 fold, when the temperature is increased. Structural and biochemical analyses suggest that the protruding loop in the active site might be an essential component for the regulation of the activity of PSP from hyperthermophilic T. onnurineus. Identification of this novel binding site distantly located from the catalytic site may be exploited for the development of effective therapeutic allosteric inhibitors against PSP activity. © Proteins 2013. © 2012 Wiley Periodicals, Inc.     

The resolvase/invertase domain of the site-specific recombinase TnpX is functional and recognizes a target sequence that resembles the junction of the circular form of the Clostridium perfringens transposon Tn4451.

Tn4451 is a 6.3-kb chloramphenicol resistance transposon from Clostridium perfringens and is found on the conjugative plasmid pIP401. The element undergoes spontaneous excision from multicopy plasmids in Escherichia coli and C. perfringens and conjugative excision from pIP401 in C. perfringens. Tn4451 is excised as a circular molecule which is probably the transposition intermediate. Excision of Tn4451 is dependent upon the site-specific recombinase TnpX, which contains potential motifs associated with both the resolvase/invertase and integrase families of recombinases. Site-directed mutagenesis of conserved amino acid residues within these domains was used to show that the resolvase/invertase domain was essential for TnpX-mediated excision of Tn4451 from multicopy plasmids in E. coli. An analysis of Tn4451 target sites revealed that the transposition process showed target site specificity. The Tn4451 target sequence resembled the junction of the circular form, and insertion occurred at a GA dinucleotide. Tn4451 insertions were flanked by directly repeated GA dinucleotides, and there was also a GA at the junction of the circular form, where the left and right termini of Tn4451 were fused. We propose a model for Tn4451 excision and insertion in which the resolvase/invertase domain of TnpX introduces 2-bp staggered cuts at these GA dinucleotides. Analysis of Tn4451 derivatives with altered GA dinucleotides provided experimental evidence to support the model.     

The crystal structure of the catalytic domain of the site-specific recombination enzyme gamma delta resolvase at 2.7 A resolution

The crystal structure of the catalytic domain of the site-specific recombination enzyme gamma delta resolvase has been determined at 2.7 A resolution. Its first 120 amino acids form a central five-stranded, beta-pleated sheet surrounded by five alpha helices. In one of the four dyad-related dimers, the two active site Ser-10 residues are 19 A apart, perhaps close enough to contact and become covalently linked to the DNA at the recombination site. This dimer also forms the only closely packed tetramer found in the crystal. The subunit interface at a second dyad-related dimer is more extensive and more highly conserved among the homologous recombinases; however, its active site Ser-10 residues are more than 30 A apart. Side chains, identified by mutations that eliminate catalysis but not DNA binding, are located on the subunit surface near the active site serine and at the interface between a third dyad-related pair of subunits of the tetramer.     

Crystallographic and mutational studies on the tRNA thiouridine synthetase TtuA

In thermophilic bacteria, specific 2‐thiolation occurs on the conserved ribothymidine at position 54 (T54) in tRNAs, which is necessary for survival at high temperatures. T54 2‐thiolation is achieved by the tRNA thiouridine synthetase TtuA and sulfur‐carrier proteins. TtuA has five conserved CXXC/H motifs and the signature PP motif, and belongs to the TtcA family of tRNA 2‐thiolation enzymes, for which there is currently no structural information. In this study, we determined the crystal structure of a TtuA homolog from the hyperthermophilic archeon Pyrococcus horikoshii at 2.1 Å resolution. The P. horikoshii TtuA forms a homodimer, and each subunit contains a catalytic domain and unique N‐ and C‐terminal zinc fingers. The catalytic domain has much higher structural similarity to that of another tRNA modification enzyme, TilS (tRNA^Ile₂ lysidine synthetase), than to the other type of tRNA 2‐thiolation enzyme, MnmA. Three conserved cysteine residues are clustered in the putative catalytic site, which is not present in TilS. An in vivo mutational analysis in the bacterium Thermus thermophilus demonstrated that the three conserved cysteine residues and the putative ATP‐binding residues in the catalytic domain are important for the TtuA activity. A positively charged surface that includes the catalytic site and the two zinc fingers is likely to provide the tRNA‐binding site. Proteins 2013; 81:1232–1244. © 2013 Wiley Periodicals, Inc.     

Recognition of β-calcineurin by the domains of calmodulin: thermodynamic and structural evidence for distinct roles

Calcineurin (CaN, PP2B, PPP3), a heterodimeric Ca²⁺‐calmodulin‐dependent Ser/Thr phosphatase, regulates swimming in Paramecia, stress responses in yeast, and T‐cell activation and cardiac hypertrophy in humans. Calcium binding to CaN_B (the regulatory subunit) triggers conformational change in CaN_A (the catalytic subunit). Two isoforms of CaN_A (α, β) are both abundant in brain and heart and activated by calcium‐saturated calmodulin (CaM). The individual contribution of each domain of CaM to regulation of calcineurin is not known. Hydrodynamic analyses of (Ca²⁺)₄‐CaM_1–148 bound to βCaNp, a peptide representing its CaM‐binding domain, indicated a 1:1 stoichiometry. βCaNp binding to CaM increased the affinity of calcium for the N‐ and C‐domains equally, thus preserving intrinsic domain differences, and the preference of calcium for sites III and IV. The equilibrium constants for individual calcium‐saturated CaM domains dissociating from βCaNp were ～1 μM. A limiting K_d ≤ 1 nM was measured directly for full‐length CaM, while thermodynamic linkage analysis indicated that it was approximately 1 pM. βCaNp binding to ¹⁵N‐(Ca²⁺)₄‐CaM_1–148 monitored by ¹⁵N/¹HN HSQC NMR showed that association perturbed the N‐domain of CaM more than its C‐domain. NMR resonance assignments of CaM and βCaNp, and interpretation of intermolecular NOEs observed in the ¹³C‐edited and ¹²C‐¹⁴N‐filtered 3D NOESY spectrum indicated anti‐parallel binding. The sole aromatic residue (Phe) located near the βCaNp C‐terminus was in close contact with several residues of the N‐domain of CaM outside the hydrophobic cleft. These structural and thermodynamic properties would permit the domains of CaM to have distinct physiological roles in regulating activation of βCaN. Proteins 2011. © 2010 Wiley‐Liss, Inc.     

Roles of two large serine recombinases in mobilizing the methicillin‐resistance cassette SCCmec

Methicillin‐resistant Staphylococcus aureus (MRSA) emerged via acquisition of a mobile element, staphylococcal cassette chromosome mec (SCCmec). Integration and excision of SCCmec is mediated by an unusual site‐specific recombination system. Most variants of SCCmec encode two recombinases, CcrA and CcrB, that belong to the large serine family. Since CcrA and CcrB are always found together, we sought to address their specific roles. We show here that CcrA and CcrB can carry out both excisive and integrative recombination in Escherichia coli in the absence of any host‐specific or SCCmec‐encoded cofactors. CcrA and CcrB are promiscuous in their substrate choice: they act on many non‐canonical pairs of recombination sites in addition to the canonical ones, which may explain tandem insertions into the SCCmec attachment site. Moreover, CcrB is always required, but CcrA is only required if one of the four half‐sites is present. Recombinational activity correlates with DNA binding: CcrA recognizes only that half‐site, which overlaps a conserved coding frame on the host chromosome. Therefore, we propose that CcrA serves as a specificity factor that emerged through modular evolution to enable recognition of a bacterial recombination site that is not an inverted repeat.     

Crystal structure of Lon protease: molecular architecture of gated entry to a sequestered degradation chamber

Lon proteases are distributed in all kingdoms of life and are required for survival of cells under stress. Lon is a tandem fusion of an AAA+ molecular chaperone and a protease with a serine‐lysine catalytic dyad. We report the 2.0‐Å resolution crystal structure of Thermococcus onnurineus NA1 Lon (TonLon). The structure is a three‐tiered hexagonal cylinder with a large sequestered chamber accessible through an axial channel. Conserved loops extending from the AAA+ domain combine with an insertion domain containing the membrane anchor to form an apical domain that serves as a gate governing substrate access to an internal unfolding and degradation chamber. Alternating AAA+ domains are in tight‐ and weak‐binding nucleotide states with different domain orientations and intersubunit contacts, reflecting intramolecular dynamics during ATP‐driven protein unfolding and translocation. The bowl‐shaped proteolytic chamber is contiguous with the chaperone chamber allowing internalized proteins direct access to the proteolytic sites without further gating restrictions.     

Topoisomerases and site-specific recombinases: similarities in structure and mechanism

The processes of DNA topoisomerization and site-specific recombination are fundamentally similar: DNA cleavage by forming a phospho-protein covalent linkage, DNA topological rearrangement, and DNA ligation coupled with protein regeneration. Type IB DNA topoisomerases are structurally and mechanistically homologous to tyrosine recombinases. Both enzymes nick DNA double helices independent of metal ions, form 3′-phosphotyrosine intermediates, and rearrange the free 5′ ends relative to the uncut strands by swiveling. In contrast, serine recombinases generate 5′-phospho-serine intermediates. A 180° relative rotation of the two halves of a 100?kDa terameric serine recombinase and DNA complex has been proposed as the mechanism of strand exchange. Here I propose an alternative mechanism. Interestingly, the catalytic domain of serine recombinases has structural similarity to the TOPRIM domain, conserved among all Type IA and Type II topoisomerases and responsible for metal binding and DNA cleavage. TOPRIM topoisomerases also cleave DNA to generate 5′-phosphate and 3′-OH groups. Based on the existing biochemical data and crystal structures of topoisomerase II and serine recombinases bound to pre- and post-cleavage DNA, I suggest a strand passage mechanism for DNA recombination by serine recombinases. This mechanism is reminiscent of DNA topoisomerization and does not require subunit rotation.     

Missense substitutions reflecting regulatory control of transmitter phosphatase activity in two‐component signalling

Negative control in two‐component signal transduction results from sensor transmitter phosphatase activity for phospho‐receiver dephosphorylation. A hypothetical mechanism for this reaction involves a catalytic residue in the H‐box active‐site region. However, a complete understanding of transmitter phosphatase regulation is hampered by the abundance of kinase‐competent, phosphatase‐defective missense substitutions (K⁺ P^– phenotype) outside of the active‐site region. For the Escherichia coli NarX sensor, a model for the HisKA_3 sequence family, DHp domain K⁺ P^– mutants defined two classes. Interaction mutants mapped to the active site‐distal base of the DHp helix 1, whereas conformation mutants were affected in the X‐box region of helix 2. Thus, different types of perturbations can influence transmitter phosphatase activity indirectly. By comparison, K⁺ P^– substitutions in the HisKA sensors EnvZ and NtrB additionally map to a third region, at the active site‐proximal top of the DHp helix 1, independently identified as important for DHp‐CA domain interaction in this sensor class. Moreover, the NarX transmitter phosphatase activity was independent of nucleotides, in contrast to the activity for many HisKA family sensors. Therefore, distinctions involving both the DHp and the CA domains suggest functional diversity in the regulation of HisKA and HisKA_3 transmitter phosphatase activities.