Histidine kinases in plants: Cross talk between hormone and stress responses

Two-component signaling pathways involve sensory histidine kinases (HK), histidine phosphotransfer proteins (HpT) and response regulators (RR). Recent advancements in genome sequencing projects for a number of plant species have established the TCS family to be multigenic one. In plants, HKs operate through the His–Asp phosphorelay and control many physiological and developmental processes throughout the lifecycle of plants. Despite the huge diversity reported for the structural features of the HKs, their functional redundancy has also been reported via mutant approach. Several sensory HKs having a CHASE domain, transmembrane domain(s), transmitter domain and receiver domain have been reported to be involved in cytokinin and ethylene signaling. On the other hand, there are also increasing evidences for some of the sensory HKs to be performing their role as osmosensor, clearly indicating toward a possible cross-talk between hormone and stress responsive cascades. In this review, we bring out the latest knowledge about the structure and functions of histidine kinases in cytokinin and ethylene signaling and their role(s) in development and the regulation of environmental stress responses.     

Evolution of prokaryotic two-component system signaling pathways: gene fusions and fissions

Two-component systems (TCSs) are common signal transduction systems, typically comprising paired histidine protein kinase (HK) and response regulator (RR) proteins. In many examples, it appears RR and HK genes have fused, producing a "hybrid kinase " We have characterized a set of prokaryotic genes encoding RRs, HKs, and hybrid kinases, enabling characterization of gene fusion and fission. Primary factors correlating with fusion rates are the presence of transmembrane helices in HKs and the presence of DNA-binding domains in RRs, features that require correct (and separate) spatial location. In the absence of such features, there is a relative abundance of fused genes. The order of paired HK and RR genes and the nucleotide distance between encoded domains also correlate with apparent gene fusion rates. We propose that localization requirements and relative positioning of encoded domains within TCS genes affect the function (and therefore retention) of hybrid kinases resulting from gene fusion.     

Structural characterization of the intra-membrane histidine kinase YbdK from Bacillus subtilis in DPC micelles

Bacterial histidine kinases (HKs) play a critical role in signal transduction for cellular adaptation to environmental conditions and stresses. YbdK from Bacillus subtilis is a 320-residue intra-membrane sensing HK characterized by a short input domain consisting of two transmembrane helices without an extracytoplasmic domain. While the cytoplasmic domains of HKs have been studied in detail, the intra-membrane sensing domain systems are still uncharacterized due to difficulties in handling the transmembrane domain. Here, we successfully obtained pure recombinant transmembrane domain of YbdK (YbdK-TM) from E. coli and analyzed the characteristics of YbdK-TM using nuclear magnetic resonance (NMR) and other biophysical methods. YbdK-TM was found to form homo-dimers in DPC micelles based on cross-linking assays and analytical ultracentrifugation analyses. We estimated the size of the YbdK-TM DPC complex to be 46 kDa using solution state NMR T₁/T₂ relaxation analyses in DPC micelles. These results provide information that will allow functional and structural studies of intra-membrane sensing HKs to begin.     

Functional insights from the molecular modelling of a novel two-component system

Two-component systems (TCSs) are the major signalling pathway in bacteria and represent potential drug targets. Among the 11 paired TCS proteins present in Mycobacterium tuberculosis H37Rv, the histidine kinases (HKs) Rv0600c (HK1) and Rv0601c (HK2) are annotated to phosphorylate one response regulator (RR) Rv0602c (TcrA). We wanted to establish the sequence-structure-function relationship to elucidate the mechanism of phosphotransfer using in silico methods. Sequence alignments and codon usage analysis showed that the two domains encoded by a single gene in homologous HKs have been separated into individual open-reading frames in M. tuberculosis. This is the first example where two incomplete HKs are involved in phosphorylating a single RR. The model shows that HK2 is a unique histidine phosphotransfer (HPt)-mono-domain protein, not found as lone protein in other bacteria. The secondary structure of HKs was confirmed using "far-UV" circular dichroism study of purified proteins. We propose that HK1 phosphorylates HK2 at the conserved H131 and the phosphoryl group is then transferred to D73 of TcrA.     

Functional characterization in vitro of all two-component signal transduction systems from Escherichia coli

Bacteria possess a signal transduction system, referred to as a two-component system, for adaptation to external stimuli. Each two-component system consists of a sensor protein-histidine kinase (HK) and a response regulator (RR), together forming a signal transduction pathway via histidyl-aspartyl phospho-relay. A total of 30 sensor HKs, including as yet uncharacterized putative HKs (BaeS, BasS, CreC, CusS, HydH, RstB, YedV, and YfhK), and a total of 34 RRs, including putative RRs (BaeR, BasR, CreB, CusR, HydG, RstA, YedW, YfhA, YgeK, and YhjB), have been suggested to exist in Escherichia coli. We have purified the carboxyl-terminal catalytic domain of 27 sensor HKs and the full-length protein of all 34 RRs to apparent homogeneity. Self-phosphorylation in vitro was detected for 25 HKs. The rate of self-phosphorylation differed among HKs, whereas the level of phosphorylation was generally co-related with the phosphorylation rate. However, the phosphorylation level was low for ArcB, HydH, NarQ, and NtrB even though the reaction rate was fast, whereas the level was high for the slow phosphorylation species BasS, CheA, and CreC. By using the phosphorylated HKs, we examined trans-phosphorylation in vitro of RRs for all possible combinations. Trans-phosphorylation of presumed cognate RRs by HKs was detected, for the first time, for eight pairs, BaeS-BaeR, BasS-BasR, CreC-CreB, CusS-CusR, HydH-HydG, RstB-RstA, YedV-YedW, and YfhK-YfhA. All trans-phosphorylation took place within less than 1/2 min, but the stability of phosphorylated RRs differed, indicating the involvement of de-phosphorylation control. In addition to the trans-phosphorylation between the cognate pairs, we detected trans-phosphorylation between about 3% of non-cognate HK-RR pairs, raising the possibility that the cross-talk in signal transduction takes place between two-component systems.     

Genetic architecture of male sterility and segregation distortion in Drosophila pseudoobscura Bogota-USA hybrids

Understanding the genetic basis of reproductive isolation between recently diverged species is a central problem in evolutionary genetics. Here, I present analyses of the genetic architecture underlying hybrid male sterility and segregation distortion between the Bogota and USA subspecies of Drosophila pseudoobscura. Previously, a single gene, Overdrive (Ovd), was shown to be necessary but not sufficient for both male sterility and segregation distortion in F(1) hybrids between these subspecies, requiring several interacting partner loci for full manifestation of hybrid phenomena. I map these partner loci separately on the Bogota X chromosome and USA autosomes using a combination of different mapping strategies. I find that hybrid sterility involves a single hybrid incompatibility of at least seven interacting partner genes that includes three large-effect loci. Segregation distortion involves three loci on the Bogota X chromosome and one locus on the autosomes. The genetic bases of hybrid sterility and segregation distortion are at least partially--but not completely--overlapping. My results lay the foundation for fine-mapping experiments to identify the complete set of genes that interact with Overdrive. While individual genes that cause hybrid sterility or inviability have been identified in a few cases, my analysis provides a comprehensive look at the genetic architecture of all components of a hybrid incompatibility underlying F(1) hybrid sterility. Such an analysis would likely be unfeasible for most species pairs due to their divergence time and emphasizes the importance of young species pairs such as the D. pseudoobscura subspecies studied here.     

Phylogenetic analysis of fungal centromere H3 proteins

Centromere H3 proteins (CenH3's) are variants of histone H3 specialized for packaging centromere DNA. Unlike canonical H3, which is among the most conserved of eukaryotic proteins, CenH3's are rapidly evolving, raising questions about orthology and conservation of function across species. To gain insight on CenH3 evolution and function, a phylogenetic analysis was undertaken on CenH3 proteins drawn from a single, ancient lineage, the Fungi. Using maximum-likelihood methods, a credible phylogeny was derived for the conserved histone fold domain (HFD) of 25 fungal CenH3's. The collection consisted mostly of hemiascomycetous yeasts, but also included basidiomycetes, euascomycetes, and an archaeascomycete. The HFD phylogeny closely recapitulated known evolutionary relationships between the species, supporting CenH3 orthology. The fungal CenH3's lacked significant homology in their N termini except for those of the Saccharomyces/Kluyveromyces clade that all contained a region homologous to the essential N-terminal domain found in Saccharomyces cerevisiae Cse4. The ability of several heterologous CenH3's to function in S. cerevisiae was tested and found to correlate with evolutionary distance. Domain swapping between S. cerevisiae Cse4 and the noncomplementing Pichia angusta ortholog showed that species specificity could not be explained by the presence or absence of any recognized secondary structural element of the HFD.     

Integration of rotation and piston motions in coiled-coil signal transduction

A coordinated response to a complex and dynamic environment requires an organism to simultaneously monitor and interpret multiple signaling cues. In bacteria and some eukaryotes, environmental responses depend on the histidine autokinases (HKs). For example, VirA, a large integral membrane HK from Agrobacterium tumefaciens, regulates the expression of virulence genes in response to signals from multiple molecular classes (phenol, pH, and sugar). The ability of this pathogen to perceive inputs from different known host signals within a single protein receptor provides an opportunity to understand the mechanisms of signal integration. Here we exploited the conserved domain organization of the HKs and engineered chimeric kinases to explore the signaling mechanisms of phenol sensing and pH/sugar integration. Our data implicate a piston-assisted rotation of coiled coils for integration of multiple inputs and regulation of critical responses during pathogenesis.     

The sixth HAMP domain negatively regulates the activity of the group III HHK containing seven HAMP domains

In fungi, the group III hybrid histidine kinases (HHK) act as important sensors to regulate osmoadaptation, hyphal growth, morphogenesis, conidia formation and virulence. They are molecular targets for antifungal agent fludioxonil. They typically have HAMP domain repeats at the NH₂-terminus that are important for their activity. Interestingly, the numbers of HAMP domain vary among the orthologs from different genera. The orthologs from basidiomycetes harbor seven HAMP domains whereas those from yeast contain five HAMP domains. In order to understand the functioning of a seven-HAMP module, we have constructed a yeast-like chimera DhNik1–Tco1 containing seven HAMP domains. The functional characterization of this chimera in yeast Saccharomyces cerevisiae showed that the sixth HAMP domain played important regulatory role. Our results indicated that the negative regulation of histidine kinase activity by the penultimate HAMP domain could possibly be an evolutionarily conserved theme in the group III HHK containing different lengths of poly HAMP module.     

On the Diversity of the Laccase Gene: A Phylogenetic Perspective from Botryosphaeria rhodina (Ascomycota: Fungi) and Other Related Taxa

The present study is the first describing the sequencing of a fragment of the copper-oxidase domain of a laccase gene in the family Botryosphaeriaceae. The aim of this work was to assess the degree of genetic and evolutionary relationships of a laccase gene from Botryosphaeria rhodina MAMB-05 with other ascomycete and basidiomycete laccase genes. The 193-amino acid sequences of the copper-oxidase domain from several different fungi, insects, a plant, and a bacterial species were retrieved from GenBank and aligned. Phylogenetic analyses were performed using neighbor-joining, maximum parsimony, and Bayesian inference methods. The organisms studied clustered into five gene clades: fungi (ascomycetes and basidiomycetes), insects, plants, and bacteria. Also, the topologies showed that fungal laccases of the ascomycetes and basidiomycetes are clearly separated into two distinct clusters. This evidence indicated that B. rhodina MAMB-05 and other closely related ascomycetes are a new biological resource given the biotechnological potential of their laccase genes.     

Genome-wide comparison of the His-to-Asp phosphorelay signaling components of three symbiotic genera of Rhizobia.

Histidine-to-aspartate (His-Asp) phosphorelay (or two-component) systems are very common signal transduction mechanisms that are implicated in a wide variety of cellular responses to environmental stimuli. The His-Asp phosphorelay components include "sensor histidine kinase (HK)", "phosphotransfer intermediate (HPt)", and "response regulator (RR)". With special reference to three bacterial species (Mesorhizobium loti, Bradyrhizobium japonicum, Sinorhizobium meliloti), each of which belongs to a different genera of Rhizobia, here we attempted to compile all of the His-Asp phosphorelay components in order to reveal a comparative genome-wide overview as to the His-Asp phosphorelay. It was revealed that M. loti has 47 HKs, 1 HPts, and 58 RRs; B. japonicum has 80 HKs, 3 HPts, and 91 RRs; whereas S. meliloti has 40 HKs, 1 HPt, and 58 RRs. These His-Asp phosphorelay components were extensively compiled and characterized. The resulting overview as to the His-Asp phosphorelay of Rhizobia will provide us with a basis for understanding of the fundamental mechanisms underlying interactions between plants and microorganisms (including symbiosis), as well as nitrogen fixation.     

Wood-inhabiting ligninolytic basidiomycetes in soils: Ecology and constraints for applicability in bioremediation

Ligninolytic basidiomycetes associated with wood decay are a physiologically distinct group of saprotrophic fungi capable of decomposition of all major components of wood. Although wood is their natural substrate, several species can survive in soil if suitable substrates are available, the soil-colonizing ability of species in the genera Phanerochaete, Pleurotus and Trametes being comparable to that of the soil-inhabiting basidiomycetes utilizing plant litter. Wood-inhabiting ligninolytic basidiomycetes (WLB) in soil interact with soil microflora, and some species are very efficient competitors affecting both the soil microbial biomass and the composition of the indigenous microbial community. The extracellular enzymes utilized by saprotrophic basidiomycetes for nutrient acquisition participate in the interspecific interactions with other soil biota but are also involved in the transformation of soil organic matter – lignocellulose and humic compounds. Bioremediation research has significantly enriched our knowledge of the ecology of basidiomycetes, but it has also identified several limitations for practical applicability of WLB at a field scale, and has led to the conclusion that natural attenuation or bioaugmentation are todays methods of choice for on site treatment.     

The HWE histidine kinases, a new family of bacterial two-component sensor kinases with potentially diverse roles in environmental signaling

Two-component signal transduction pathways play a major role in the response of bacteria to external cues. These pathways are initiated by large collection of histidine kinases (HKs) containing a sensor domain that perceives the environmental signal followed by an HK domain that triggers a histidine-aspartate phosphorelay. Previous phylogenetic analyses identified 11 major families of two-component HKs by comparing signature motifs within the HK domain. Here we describe a new family with homology to Agrobacterium tumefaciens BphP2, an HK first discovered by the presence of a phytochrome sensor domain involved in light perception. Members of this sensor HK family differ from most others by the absence of a recognizable F box and the presence of several uniquely conserved residues, including a histidine in the N box and a tryptophan-X-glutamic acid sequence in the G1 box, which we have used to define the family (HWE). At least 81 members were identified in a variety of alpha- and gamma-proteobacteria, with a significant enrichment in the Rhizobiaceae family. Several representatives were shown to have HK activity in vitro, supporting their proposed participation in phosphorelays. One or more domains related to signal transduction were evident N-terminal to the HK domain, including chemotactic methyltransferase domains, suggesting that this family has multiple roles in environmental signaling. The discovery of the HWE family further extends the diversity within the HK superfamily and expands the importance of two-component signaling in bacteria.     

Two-component signal transduction systems of Xanthomonas spp.: a lesson from genomics

The two-component signal transduction systems (TCSTSs), consisting of a histidine kinase sensor (HK) and a response regulator (RR), are the dominant molecular mechanisms by which prokaryotes sense and respond to environmental stimuli. Genomes of Xanthomonas generally contain a large repertoire of TCSTS genes (approximately 92 to 121 for each genome), which encode diverse structural groups of HKs and RRs. Among them, although a core set of 70 TCSTS genes (about two-thirds in total) which accumulates point mutations with a slow rate are shared by these genomes, the other genes, especially hybrid HKs, experienced extensive genetic recombination, including genomic rearrangement, gene duplication, addition or deletion, and fusion or fission. The recombinations potentially promote the efficiency and complexity of TCSTSs in regulating gene expression. In addition, our analysis suggests that a co-evolutionary model, rather than a selfish operon model, is the major mechanism for the maintenance and microevolution of TCSTS genes in the genomes of Xanthomonas. Genomic annotation, secondary protein structure prediction, and comparative genomic analyses of TCSTS genes reviewed here provide insights into our understanding of signal networks in these important phytopathogenic bacteria.     

Genetic architecture and genomic patterns of gene flow between hybridizing species of Picea

Hybrid zones provide an opportunity to study the effects of selection and gene flow in natural settings. We employed nuclear microsatellites (single sequence repeat (SSR)) and candidate gene single-nucleotide polymorphism markers (SNPs) to characterize the genetic architecture and patterns of interspecific gene flow in the Picea glauca × P. engelmannii hybrid zone across a broad latitudinal (40–60 degrees) and elevational (350–3500 m) range in western North America. Our results revealed a wide and complex hybrid zone with broad ancestry levels and low interspecific heterozygosity, shaped by asymmetric advanced-generation introgression, and low reproductive barriers between parental species. The clinal variation based on geographic variables, lack of concordance in clines among loci and the width of the hybrid zone points towards the maintenance of species integrity through environmental selection. Congruency between geographic and genomic clines suggests that loci with narrow clines are under strong selection, favoring either one parental species (directional selection) or their hybrids (overdominance) as a result of strong associations with climatic variables such as precipitation as snow and mean annual temperature. Cline movement due to past demographic events (evidenced by allelic richness and heterozygosity shifts from the average cline center) may explain the asymmetry in introgression and predominance of P. engelmannii found in this study. These results provide insights into the genetic architecture and fine-scale patterns of admixture, and identify loci that may be involved in reproductive barriers between the species.     

Segmental Helical Motions and Dynamical Asymmetry Modulate Histidine Kinase Autophosphorylation

Histidine kinases (HKs) are dimeric receptors that participate in most adaptive responses to environmental changes in prokaryotes. Although it is well established that stimulus perception triggers autophosphorylation in many HKs, little is known on how the input signal propagates through the HAMP domain to control the transient interaction between the histidine-containing and ATP-binding domains during the catalytic reaction. Here we report crystal structures of the full cytoplasmic region of CpxA, a prototypical HK involved in Escherichia coli response to envelope stress. The structural ensemble, which includes the Michaelis complex, unveils HK activation as a highly dynamic process, in which HAMP modulates the segmental mobility of the central HK α-helices to promote a strong conformational and dynamical asymmetry that characterizes the kinase-active state. A mechanical model based on our structural and biochemical data provides insights into HAMP-mediated signal transduction, the autophosphorylation reaction mechanism, and the symmetry-dependent control of HK kinase/phosphatase functional states.     

The Hybrid Histidine Kinase LadS Forms a Multicomponent Signal Transduction System with the GacS/GacA Two-Component System in Pseudomonas aeruginosa

In response to environmental changes, Pseudomonas aeruginosa is able to switch from a planktonic (free swimming) to a sessile (biofilm) lifestyle. The two-component system (TCS) GacS/GacA activates the production of two small non-coding RNAs, RsmY and RsmZ, but four histidine kinases (HKs), RetS, GacS, LadS and PA1611, are instrumental in this process. RetS hybrid HK blocks GacS unorthodox HK autophosphorylation through the formation of a heterodimer. PA1611 hybrid HK, which is structurally related to GacS, interacts with RetS in P. aeruginosa in a very similar manner to GacS. LadS hybrid HK phenotypically antagonizes the function of RetS by a mechanism that has never been investigated. The four sensors are found in most Pseudomonas species but their characteristics and mode of signaling may differ from one species to another. Here, we demonstrated in P. aeruginosa that LadS controls both rsmY and rsmZ gene expression and that this regulation occurs through the GacS/GacA TCS. We additionally evidenced that in contrast to RetS, LadS signals through GacS/GacA without forming heterodimers, either with GacS or with RetS. Instead, we demonstrated that LadS is involved in a genuine phosphorelay, which requires both transmitter and receiver LadS domains. LadS signaling ultimately requires the alternative histidine-phosphotransfer domain of GacS, which is here used as an Hpt relay by the hybrid kinase. LadS HK thus forms, with the GacS/GacA TCS, a multicomponent signal transduction system with an original phosphorelay cascade, i.e. H1_LadS→D1_LadS→H2_GacS→D2_GacA. This highlights an original strategy in which a unique output, i.e. the modulation of sRNA levels, is controlled by a complex multi-sensing network to fine-tune an adapted biofilm and virulence response.     

Effect of tree host species on fungal community composition in a tropical rain forest in Panama

Abstract.  To determine whether host species influence the composition of fungal communities, the ascomycetes and basidiomycetes present on three tree species ( Prioria copaifera (Fabaceae), Quararibea asterolepis (Bombacaceae), and Trichilia tuberculata (Meliaceae)) were sampled on the 50-ha Forest Dynamics Project plot in lowland moist tropical forest on Barro Colorado Island, Panama. The most abundant fungal morphotypes of both ascomycetes and basidiomycetes were generalists found on all three hosts, but detrended correspondence analysis revealed distinct differences in fungal community composition among host trees. These differences among hosts were constant across census years. Randomization tests revealed that there were significantly fewer host-generalist fungi than expected for ascomycetes but not for basidiomycetes. These results indicate that host composition plays a role in structuring both ascomycete and basidiomycete fungal communities, but that the most successful fungal morphotypes are capable of colonizing multiple host species.     

A new promising phylogenetic marker to study the diversity of fungal communities: The Glycoside Hydrolase 63 gene

In molecular ecology, the development of efficient molecular markers for fungi remains an important research domain. Nuclear ribosomal internal transcribed spacer (ITS) region was proposed as universal DNA barcode marker for fungi, but this marker was criticized for Indel‐induced alignment problems and its potential lack of phylogenetic resolution. Our main aim was to develop a new phylogenetic gene and a putative functional marker, from single‐copy gene, to describe fungal diversity. Thus, we developed a series of primers to amplify a polymorphic region of the Glycoside Hydrolase GH63 gene, encoding exo‐acting α‐glucosidases, in basidiomycetes. These primers were validated on 125 different fungal genomic DNAs, and GH63 amplification yield was compared with that of already published functional markers targeting genes coding for laccases, N‐acetylhexosaminidases, cellobiohydrolases and class II peroxidases. Specific amplicons were recovered for 95% of the fungal species tested, and GH63 amplification success was strikingly higher than rates obtained with other functional genes. We downloaded the GH63 sequences from 483 fungal genomes publicly available at the JGI mycocosm database. GH63 was present in 461 fungal genomes belonging to all phyla, except Microsporidia and Neocallimastigomycota divisions. Moreover, the phylogenetic trees built with both GH63 and Rpb1 protein sequences revealed that GH63 is also a promising phylogenetic marker. Finally, a very high proportion of GH63 proteins was predicted to be secreted. This molecular tool could be a new phylogenetic marker of fungal species as well as potential indicator of functional diversity of basidiomycetes fungal communities in term of secretory capacities.