Cyclic Di-GMP Phosphodiesterases RmdA and RmdB Are Involved in Regulating Colony Morphology and Development in Streptomyces coelicolor

Cyclic dimeric GMP (c-di-GMP) regulates numerous processes in Gram-negative bacteria, yet little is known about its role in Gram-positive bacteria. Here we characterize two c-di-GMP phosphodiesterases from the filamentous high-GC Gram-positive actinobacterium Streptomyces coelicolor, involved in controlling colony morphology and development. A transposon mutation in one of the two phosphodiesterase genes, SCO0928, hereby designated rmdA (regulator of morphology and development A), resulted in decreased levels of spore-specific gray pigment and a delay in spore formation. The RmdA protein contains GGDEF-EAL domains arranged in tandem and possesses c-di-GMP phosphodiesterase activity, as is evident from in vitro enzymatic assays using the purified protein. RmdA contains a PAS9 domain and is a hemoprotein. Inactivation of another GGDEF-EAL-encoding gene, SCO5495, designated rmdB, resulted in a phenotype identical to that of the rmdA mutant. Purified soluble fragment of RmdB devoid of transmembrane domains also possesses c-di-GMP phosphodiesterase activity. The rmdA rmdB double mutant has a bald phenotype and is impaired in aerial mycelium formation. This suggests that RmdA and RmdB functions are additive and at least partially overlapping. The rmdA and rmdB mutations likely result in increased local pools of intracellular c-di-GMP, because intracellular c-di-GMP levels in the single mutants did not differ significantly from those of the wild type, whereas in the double rmdA rmdB mutant, c-di-GMP levels were 3-fold higher than those in the wild type. This study highlights the importance of c-di-GMP-dependent signaling in actinomycete colony morphology and development and identifies two c-di-GMP phosphodiesterases controlling these processes.     

Role of EAL-containing proteins in multicellular behavior of Salmonella enterica serovar Typhimurium

GGDEF and EAL domain proteins are involved in turnover of the novel secondary messenger cyclic di(3'-->5')-guanylic acid (c-di-GMP) in many bacteria. The rdar morphotype, a multicellular behavior of Salmonella enterica serovar Typhimurium characterized by the expression of the extracellular matrix components cellulose and curli fimbriae is controlled by c-di-GMP. In this work the roles of the EAL and GGDEF-EAL domain proteins on rdar morphotype development were investigated. Knockout of four of 15 EAL and GGDEF-EAL domain proteins upregulated rdar morphotype expression and expression of CsgD, the central regulator of the rdar morphotype, and partially downregulated c-di-GMP concentrations. More-detailed analysis showed that the EAL domain protein STM4264 and the GGDEF-EAL domain protein STM1703, which highly downregulated the rdar morphotype, have overlapping yet distinct functions. Another subset of EAL and GGDEF-EAL domain proteins influenced multicellular behavior in liquid culture and flagellum-mediated motility. Consequently, this work has shown that several EAL and GGDEF-EAL domain proteins, which act as phosphodiesterases, play a determinative role in the expression level of multicellular behavior of Salmonella enterica serovar Typhimurium.     

Identification and characterization of a cyclic di-GMP-specific phosphodiesterase and its allosteric control by GTP

Cyclic diguanylic acid (c-di-GMP) is a global second messenger controlling motility and adhesion in bacterial cells. Synthesis and degradation of c-di-GMP is catalyzed by diguanylate cyclases (DGC) and c-di-GMP-specific phosphodiesterases (PDE), respectively. Whereas the DGC activity has recently been assigned to the widespread GGDEF domain, the enzymatic activity responsible for c-di-GMP cleavage has been associated with proteins containing an EAL domain. Here we show biochemically that CC3396, a GGDEF-EAL composite protein from Caulobacter crescentus is a soluble PDE. The PDE activity, which rapidly converts c-di-GMP into the linear dinucleotide pGpG, is confined to the C-terminal EAL domain of CC3396, depends on the presence of Mg2+ ions, and is strongly inhibited by Ca2+ ions. Remarkably, the associated GGDEF domain, which contains an altered active site motif (GEDEF), lacks detectable DGC activity. Instead, this domain is able to bind GTP and in response activates the PDE activity in the neighboring EAL domain. PDE activation is specific for GTP (K(D) 4 microM) and operates by lowering the K(m) for c-di-GMP of the EAL domain to a physiologically significant level (420 nM). Mutational analysis suggested that the substrate-binding site (A-site) of the GGDEF domain is involved in the GTP-dependent regulatory function, arguing that a catalytically inactive GGDEF domain has retained the ability to bind GTP and in response can activate the neighboring EAL domain. Based on this we propose that the c-di-GMP-specific PDE activity is confined to the EAL domain, that GGDEF domains can either catalyze the formation of c-di-GMP or can serve as regulatory domains, and that c-di-GMP-specific phosphodiesterase activity is coupled to the cellular GTP level in bacteria.     

Binding of cyclic diguanylate in the non-catalytic EAL domain of FimX induces a long-range conformational change

FimX is a multidomain signaling protein required for type IV pilus biogenesis and twitching motility in the opportunistic pathogen Pseudomonas aeruginosa. FimX is localized to the single pole of the bacterial cell, and the unipolar localization is crucial for the correct assembly of type IV pili. FimX contains a non-catalytic EAL domain that lacks cyclic diguanylate (c-di-GMP) phosphodiesterase activity. It was shown that deletion of the EAL domain or mutation of the signature EVL motif affects the unipolar localization of FimX. However, it was not understood how the C-terminal EAL domain could influence protein localization considering that the localization sequence resides in the remote N-terminal region of the protein. Using hydrogen/deuterium exchange-coupled mass spectrometry, we found that the binding of c-di-GMP to the EAL domain triggers a long-range (∼ca. 70 Å) conformational change in the N-terminal REC domain and the adjacent linker. In conjunction with the observation that mutation of the EVL motif of the EAL domain abolishes the binding of c-di-GMP, the hydrogen/deuterium exchange results provide a molecular explanation for the mediation of protein localization and type IV pilus biogenesis by c-di-GMP through a remarkable allosteric regulation mechanism.     

Genomic analysis of cyclic-di-GMP-related genes in rhizobial type strains and functional analysis in Rhizobium etli

Rhizobia are soil bacteria that can fix nitrogen in symbiosis with leguminous plants or exist free living in the rhizosphere. Crucial to their complex lifestyle is the ability to sense and respond to diverse environmental stimuli, requiring elaborate signaling pathways. In the majority of bacteria, the nucleotide-based second messenger cyclic diguanosine monophosphate (c-di-GMP) is involved in signal transduction. Surprisingly, little is known about the importance of c-di-GMP signaling in rhizobia. We have analyzed the genome sequences of six well-studied type species (Bradyrhizobium japonicum, Mesorhizobium loti, Rhizobium etli, Rhizobium leguminosarum, Sinorhizobium fredii, and Sinorhizobium meliloti) for proteins possibly involved in c-di-GMP signaling based on the presence of four domains: GGDEF (diguanylate cyclase), EAL and HD-GYP (phosphodiesterase), and PilZ (c-di-GMP sensor). We find that rhizobia possess a high number of these proteins. Conservation analysis suggests that c-di-GMP signaling proteins modulate species-specific pathways rather than ancient rhizobia-specific processes. Two hybrid GGDEF-EAL proteins were selected for functional analysis, R. etli RHE_PD00105 (CdgA) and RHE_PD00137 (CdgB). Expression of cdgA and cdgB is repressed by the alarmone (p)ppGpp. cdgB is significantly expressed on plant roots and free living. Mutation of cdgA, cdgB, or both does not affect plant root colonization, nitrogen fixation capacity, biofilm formation, motility, and exopolysaccharide production. However, heterologous expression of the individual GGDEF and EAL domains of each protein in Escherichia coli strongly suggests that CdgA and CdgB are bifunctional proteins, possessing both diguanylate cyclase and phosphodiesterase activities. Taken together, our results provide a platform for future studies of c-di-GMP signaling in rhizobia.     

Systematic Nomenclature for GGDEF and EAL Domain-Containing Cyclic Di-GMP Turnover Proteins of Escherichia coli

In recent years, Escherichia coli has served as one of a few model bacterial species for studying cyclic di-GMP (c-di-GMP) signaling. The widely used E. coli K-12 laboratory strains possess 29 genes encoding proteins with GGDEF and/or EAL domains, which include 12 diguanylate cyclases (DGC), 13 c-di-GMP-specific phosphodiesterases (PDE), and 4 “degenerate” enzymatically inactive proteins. In addition, six new GGDEF and EAL (GGDEF/EAL) domain-encoding genes, which encode two DGCs and four PDEs, have recently been found in genomic analyses of commensal and pathogenic E. coli strains. As a group of researchers who have been studying the molecular mechanisms and the genomic basis of c-di-GMP signaling in E. coli, we now propose a general and systematic dgc and pde nomenclature for the enzymatically active GGDEF/EAL domain-encoding genes of this model species. This nomenclature is intuitive and easy to memorize, and it can also be applied to additional genes and proteins that might be discovered in various strains of E. coli in future studies.     

Effects of increased and deregulated expression of cell division genes on the morphology and on antibiotic production of streptomycetes

This paper describes the effects of increased expression of the cell division genes ftsZ, ftsQ, and ssgA on the development of both solid- and liquid-grown mycelium of Streptomyces coelicolor and Streptomyces lividans. Over-expression of ftsZ in S. coelicolor M145 inhibited aerial mycelium formation and blocked sporulation. Such deficient sporulation was also observed for the ftsZ mutant. Over-expression of ftsZ also inhibited morphological differentiation in S. lividans 1326, although aerial mycelium formation was less reduced. Furthermore, antibiotic production was increased in both strains, and in particular the otherwise dormant actinorhodin biosynthesis cluster of S. lividans was activated in liquid- and solid-grown cultures. No significant alterations were observed when the gene dosage of ftsQ was increased. Analysis by transmission electron microscopy of an S. coelicolor strain over-expressing ssgA showed that septum formation had strongly increased in comparison to wild-type S. coelicolor, showing that SsgA clearly influences Streptomyces cell division. The morphology of the hyphae was affected such that irregular septa were produced with a significantly wider diameter, thereby forming spore-like compartments. This suggests that ssgA can induce a process similar to submerged sporulation in Streptomyces strains that otherwise fail to do so. A working model is proposed for the regulation of septum formation and of submerged sporulation.     

The signaling protein MucG negatively affects the production and the molecular mass of alginate in Azotobacter vinelandii

Azotobacter vinelandii is a soil bacterium that produces the polysaccharide alginate. In this work, we identified a miniTn5 mutant, named GG9, which showed increased alginate production of higher molecular mass, and increased expression of the alginate biosynthetic genes algD and alg8 when compared to its parental strain. The miniTn5 was inserted within ORF Avin07920 encoding a hypothetical protein. Avin07910, located immediately downstream and predicted to form an operon with Avin07920, encodes an inner membrane multi-domain signaling protein here named mucG. Insertional inactivation of mucG resulted in a phenotype of increased alginate production of higher molecular mass similar to that of mutant GG9. The MucG protein contains a periplasmic and putative HAMP and PAS domains, which are linked to GGDEF and EAL domains. The last two domains are potentially involved in the synthesis and degradation, respectively, of bis-(3′-5′)-cyclic dimeric GMP (c-di-GMP), a secondary messenger that has been reported to be essential for alginate production. Therefore, we hypothesized that the negative effect of MucG on the production of this polymer could be explained by the putative phosphodiesterase activity of the EAL domain. Indeed, we found that alanine replacement mutagenesis of the MucG EAL motif or deletion of the entire EAL domain resulted in increased alginate production of higher molecular mass similar to the GG9 and mucG mutants. To our knowledge, this is the first reported protein that simultaneous affects the production of alginate and its molecular mass.

     

Modulation of Biofilm-Formation in Salmonella enterica Serovar Typhimurium by the Periplasmic DsbA/DsbB Oxidoreductase System Requires the GGDEF-EAL Domain Protein STM3615

In Salmonella enterica serovar Typhimurium (S. Typhimurium), biofilm-formation is controlled by the cytoplasmic intracellular small-molecular second messenger cyclic 3′, 5′-di- guanosine monophosphate (c-di-GMP) through the activities of GGDEF and EAL domain proteins. Here we describe that deleting either dsbA or dsbB, respectively encoding a periplasmic protein disulfide oxidase and a cytoplasmic membrane disulfide oxidoreductase, resulted in increased biofilm-formation on solid medium. This increased biofilm-formation, defined as a red, dry and rough (rdar) colony morphotype, paralleled with enhanced expression of the biofilm master regulator CsgD and the biofilm-associated fimbrial subunit CsgA. Deleting csgD in either dsb mutant abrogated the enhanced biofilm-formation. Likewise, overexpression of the c-di-GMP phosphodiesterase YhjH, or mutationally inactivating the CsgD activator EAL-domain protein YdiV, reduced biofilm-formation in either of the dsb mutants. Intriguingly, deleting the GGDEF-EAL domain protein gene STM3615 (yhjK), previously not connected to rdar morphotype development, also abrogated the escalated rdar morphotype formation in dsb mutant backgrounds. Enhanced biofilm-formation in dsb mutants was furthermore annulled by exposure to the protein disulfide catalyst copper chloride. When analyzed for the effect of exogenous reducing stress on biofilm-formation, both dsb mutants initially showed an escalated rdar morphotype development that later dissolved to reveal a smooth mucoid colony morphotype. From these results we conclude that biofilm-development in S. Typhimurium is affected by periplasmic protein disulphide bond status through CsgD, and discuss the involvement of selected GGDEF/EAL domain protein(s) as signaling mediators.     

Fluorescence Time-lapse Imaging of the Complete S. venezuelae Life Cycle Using a Microfluidic Device

Live-cell imaging of biological processes at the single cell level has been instrumental to our current understanding of the subcellular organization of bacterial cells. However, the application of time-lapse microscopy to study the cell biological processes underpinning development in the sporulating filamentous bacteria Streptomyces has been hampered by technical difficulties. Here we present a protocol to overcome these limitations by growing the new model species, Streptomyces venezuelae, in a commercially available microfluidic device which is connected to an inverted fluorescence widefield microscope. Unlike the classical model species, Streptomyces coelicolor, S. venezuelae sporulates in liquid, allowing the application of microfluidic growth chambers to cultivate and microscopically monitor the cellular development and differentiation of S. venezuelae over long time periods. In addition to monitoring morphological changes, the spatio-temporal distribution of fluorescently labeled target proteins can also be visualized by time-lapse microscopy. Moreover, the microfluidic platform offers the experimental flexibility to exchange the culture medium, which is used in the detailed protocol to stimulate sporulation of S. venezuelae in the microfluidic chamber. Images of the entire S. venezuelae life cycle are acquired at specific intervals and processed in the open-source software Fiji to produce movies of the recorded time-series.     

Identification of the YfgF MASE1 domain as a modulator of bacterial responses to aspartate

Complex 3′-5′-cyclic diguanylic acid (c-di-GMP) responsive regulatory networks that are modulated by the action of multiple diguanylate cyclases (DGC; GGDEF domain proteins) and phosphodiesterases (PDE; EAL domain proteins) have evolved in many bacteria. YfgF proteins possess a membrane-anchoring domain (MASE1), a catalytically inactive GGDEF domain and a catalytically active EAL domain. Here, sustained expression of the Salmonella enterica spp. Enterica ser. Enteritidis YfgF protein is shown to mediate inhibition of the formation of the aspartate chemotactic ring on motility agar under aerobic conditions. This phenomenon was c-di-GMP-independent because it occurred in a Salmonella strain that lacked the ability to synthesize c-di-GMP and also when PDE activity was abolished by site-directed mutagenesis of the EAL domain. YfgF-mediated inhibition of aspartate chemotactic ring formation was impaired in the altered redox environment generated by exogenous p-benzoquinone. This ability of YfgF to inhibit the response to aspartate required a motif, ²¹³Lys-Lys-Glu²¹⁵, in the predicted cytoplasmic loop between trans-membrane regions 5 and 6 of the MASE1 domain. Thus, for the first time the function of a MASE1 domain as a redox-responsive regulator of bacterial responses to aspartate has been shown.     

Interplay between the cyclic di-GMP network and the cell–cell signalling components coordinates virulence-associated functions in Xanthomonas oryzae pv. oryzae

Xanthomonas oryzae pv. oryzae (Xoo) causes a serious disease of rice known as bacterial leaf blight. Several virulence-associated functions have been characterized in Xoo. However, the role of important second messenger c-di-GMP signalling in the regulation of virulence-associated functions still remains elusive in this phytopathogen. In this study we have performed an investigation of 13 c-di-GMP modulating deletion mutants to understand their contribution in Xoo virulence and lifestyle transition. We show that four Xoo proteins, Xoo2331, Xoo2563, Xoo2860 and Xoo2616, are involved in fine-tuning the in vivo c-di-GMP abundance and also play a role in the regulation of virulence-associated functions. We have further established the importance of the GGDEF domain of Xoo2563, a previously characterized c-di-GMP phosphodiesterase, in the virulence-associated functions of Xoo. Interestingly the strain harbouring the GGDEF domain deletion (ΔXoo2563_GGDEF) exhibited EPS deficiency and hypersensitivity to streptonigrin, indicative of altered iron metabolism. This is in contrast to the phenotype exhibited by an EAL overexpression strain wherein, the ΔXoo2563_GGDEF exhibited other phenotypes, similar to the strain overexpressing the EAL domain. Taken together, our results indicate a complex interplay of c-di-GMP signalling with the cell–cell signalling to coordinate virulence-associated function in Xoo.     

The EAL domain protein VieA is a cyclic diguanylate phosphodiesterase

The newly recognized bacterial second messenger 3',5'-cyclic diguanylic acid (cyclic diguanylate (c-di-GMP)) has been shown to regulate a wide variety of bacterial behaviors and traits. Biosynthesis and degradation of c-di-GMP have been attributed to the GGDEF and EAL protein domains, respectively, based primarily on genetic evidence. Whereas the GGDEF domain was demonstrated to possess diguanylate cyclase activity in vitro, the EAL domain has not been tested directly for c-di-GMP phosphodiesterase activity. This study describes the analysis of c-di-GMP hydrolysis by an EAL domain protein in a purified system. The Vibrio cholerae EAL domain protein VieA has been shown to inversely regulate biofilm-specific genes (vps) and virulence genes (ctxA), presumably by decreasing the cellular pool of c-di-GMP. VieA was maximally active at neutral pH, physiological ionic strength, and ambient temperatures and demonstrated c-di-GMP hydrolytic activity with a Km of 0.06 microM. VieA was unable to hydrolyze cGMP. The putative metal coordination site of the EAL domain, Glu170, was demonstrated to be necessary for VieA activity. Furthermore, the divalent cations Mg2+ and Mn2+ were necessary for VieA activity; conversely, Ca2+ and Zn2+ were potent inhibitors of the VieA phosphodiesterase. Calcium inhibition of the VieA EAL domain provides a potential mechanism for regulation of c-di-GMP degradation.     

Restriction enzyme map for streptomycete plasmid pUC3

A restriction enzyme map for the streptomycete plasmid pUC3 was constructed for the enzymes XhoI, EcoRI, HindIII, PstI, BamH-I, and BglII. The plasmid was isolated from Streptomyces sp. 3022a which produces chloramphenicol and has been referred to as S. venezuelae (Bewick et al., 1976 and Bewick and Williams, 1977, Microbios, 19, 27–35).     

GGDEF and EAL domains inversely regulate cyclic di-GMP levels and transition from sessility to motility

Cyclic nucleotides represent second messenger molecules in all kingdoms of life. In bacteria, mass sequencing of genomes detected the highly abundant protein domains GGDEF and EAL. We show here that the GGDEF and EAL domains are involved in the turnover of cyclic-di-GMP (c-di-GMP) in vivo whereby the GGDEF domain stimulates c-di-GMP production and the EAL domain c-di-GMP degradation. Thus, most probably, GGDEF domains function as c-di-GMP cyclase and EAL domains as phosphdiesterase. We further show that, in the pathogenic organism Salmonella enterica serovar Typhimurium, the nosocomial pathogen Pseudomonas aeruginosa and the commensal species Escherichia coli, GGDEF and EAL domains mediate similar phenotypic changes related to the transition between sessility and motility. Thus, the data suggest that c-di-GMP is a novel global second messenger in bacteria the metabolism of which is controlled by GGDEF and EAL domain proteins.     

The Functional Role of a Conserved Loop in EAL Domain-Based Cyclic di-GMP-Specific Phosphodiesterase

EAL domain-based cyclic di-GMP (c-di-GMP)-specific phosphodiesterases play important roles in bacteria by regulating the cellular concentration of the dinucleotide messenger c-di-GMP. EAL domains belong to a family of (β/α)₈ barrel fold enzymes that contain a functional active site loop (loop 6) for substrate binding and catalysis. By examining the two EAL domain-containing proteins RocR and PA2567 from Pseudomonas aeruginosa, we found that the catalytic activity of the EAL domains was significantly altered by mutations in the loop 6 region. The impact of the mutations ranges from apparent substrate inhibition to alteration of oligomeric structure. Moreover, we found that the catalytic activity of RocR was affected by mutating the putative phosphorylation site (D56N) in the phosphoreceiver domain, with the mutant exhibiting a significantly smaller Michealis constant (K_m) than that of the wild-type RocR. Hydrogen-deuterium exchange by mass spectrometry revealed that the decrease in K_m correlates with a change of solvent accessibility in the loop 6 region. We further examined Acetobacter xylinus diguanylate cyclase 2, which is one of the proteins that contains a catalytically incompetent EAL domain with a highly degenerate loop 6. We demonstrated that the catalytic activity of the stand-alone EAL domain toward c-di-GMP could be recovered by restoring loop 6. On the basis of these observations and in conjunction with the structural data of two EAL domains, we proposed that loop 6 not only mediates the dimerization of EAL domain but also controls c-di-GMP and Mg²⁺ ion binding. Importantly, sequence analysis of the 5,862 EAL domains in the bacterial genomes revealed that about half of the EAL domains harbor a degenerate loop 6, indicating that the mutations in loop 6 may represent a divergence of function for EAL domains during evolution.The cyclic dinucleotide cyclic di-GMP (c-di-GMP) has emerged as a major bacterial messenger for mediating a variety of cellular functions that range from virulence expression and biofilm formation (5, 14, 30). The cellular concentration of c-di-GMP is controlled by the GGDEF domain proteins with diguanylate cyclase (DGC) activity and the EAL domain proteins with c-di-GMP-specific phosphodiesterase (PDE) activity. GGDEF domains catalyze the synthesis of c-di-GMP from GTP, whereas EAL domains catalyze the hydrolysis of c-di-GMP to generate the linear 5′-pGpG. Although a family of HD-GYP domain proteins has also been found as c-di-GMP-specific PDEs, the overwhelmingly large number of genes encoding the EAL domains in bacterial genomes suggests that the EAL domains are the major PDEs for maintaining the cellular c-di-GMP concentration. Remarkably, multiple copies of EAL domain-encoding genes are usually found in bacterial cells, with as many as 21 in Pseudomonas aeruginosa and 32 in Vibrio cholerae. Although many of the EAL domains were found to function as PDE domains for c-di-GMP degradation, emerging evidence suggests that some EAL domains function as ligand- or protein-binding domains without catalytic activity (24, 28, 40).The detailed structure and catalytic mechanism of the EAL domains have started to be elucidated recently. The crystal structures of two proteins with EAL domains, TdEAL and YkuI, have been determined (Protein Data Bank accession nos. 2BAS, 2R6O, and 2w27) (23). EAL domains adopt a (β/α)₈ barrel fold that contains two extended strands, including an antiparallel strand. The (β/α)₈ barrel fold, first found in triosephosphate isomerase, has been observed in a diversity of enzymes that include many hydrolyases and isomerases (34). Similar to other (β/α)₈ barrel fold enzymes, the catalytic residues of the EAL domain are located at the C-terminal ends of the β-strands and the beginning of the β→α loops connecting the β-strands and α-helices. In the proposed mechanism, EAL domains catalyze the hydrolysis of c-di-GMP by using a Mg²⁺ ion and a general base catalyst (Glu) for generating the nucleophilic H₂O (28). The catalytic mechanism is supported by the crystal structure of the YkuI-substrate binary complex (Protein Data Bank accession no. 2w27) and the model of the TdEAL-substrate complex (23, 28). Both structures showed that the EAL domains bind c-di-GMP in such a configuration that the scissile phosphorus-oxygen bond aligns linearly with the attaching water and the general base catalyst. The catalytic mechanism can account for the lack of catalytic activity for most known inactive EAL domains, with the loss of enzymatic activity arising from the absence of the general base catalyst and/or the residues that coordinate the Mg²⁺ ion (28).It is well-known that many (β/α)₈ barrel fold enzymes contain a flexible active site loop between the β6 strand and α6 helix (34). Despite the diverse reactions catalyzed by (β/α)₈ barrel fold enzymes, this extended loop, often referred to as loop 6, plays an important role as a functional lid for substrate sequestering, solvent exclusion, and product release (15). The loop was found to facilitate substrate binding and conformational transition in tryptophan synthase (3, 4) and functions as a lid for substrate sequestering during catalysis in inosine 5′-monophosphate dehydrogenase (22). Notably, it was shown that the loop sways from the active site in the nonactive structure of ribulose-1,5-bisphosphate carboxylase but folds over to shield the active site from the solvent in the activated structure (21). Similar functions have also been proposed for loop 6 in other (β/α)₈ barrel fold enzymes, such as triosephosphate isomerase and phosphoriboxyl anthranilate isomerase (15, 25, 26). Hence, it seems that the functional role of loop 6 has been well preserved in (β/α)₈ barrel fold enzymes during evolution. The (β/α)₈ barrel folded EAL domains also contain an eight-residue loop between the β6 strand and α6 helix that seems to be critical for catalysis. Schmidt and coworkers (32) first noticed that the catalytically active EAL domains seem to contain a conserved motif that was later confirmed to contain loop 6 [DFG(T/A)GYSS] and one of the residues (Asp) for Mg²⁺ binding (28, 32). We previously noticed that mutation of the essential catalytic residues is usually accompanied by the degeneration of loop 6 in catalytically inactive EAL domains (28). Moreover, we observed that the mutation of a residue interacting with loop 6 in the EAL domain-containing RocR abolished enzymatic activity, which led us to postulate a critical role for loop 6 in catalysis (28).To elucidate the precise role played by loop 6 in c-di-GMP hydrolysis, we examined three EAL domain-containing proteins that include RocR, PA2567, and A. xylinus DGC2. The residues of loop 6 [DFG(A/T)SYSS] in RocR and PA2567 are well conserved, as observed in other catalytically active EAL domains. We show that mutations in the loop 6 region in RocR and PA2567 had significant effect on the structure and catalysis of the EAL domain. By using the method of hydrogen-deuterium (H/D) exchange-coupled mass spectrometry, we demonstrated that a single remote mutation in the phosphoreceiver domain of RocR caused correlated changes in loop 6 conformation and catalytic properties. We further show that the catalytic activity of the inactive EAL domain of A. xylinus DGC2 can be recovered by restoring loop 6. The functional roles of loop 6 in EAL domains in substrate binding and catalysis were discussed in conjunction with the structural data for two EAL domains.     

Interactions of actinomycetes with Macrophomina phaseoli (Maubl.) Ashby; The cause of root rot of cotton

Macrophomina phaseoli, the cause of root rot of cotton, was inhibited byStreptomyces albus, S. griseus andS. noursei in agar culture.S. aureofaciens, S. flaveolus, S. rimosus, S. scabies andS. venezuelae were non-antagonistic. Only the antagonisticStreptomyces were found to reduceMacrophomina infection on cotton seedlings in soil without any deleterious effect on cotton growth.