The Pseudomonas syringae avrRpt2 gene product promotes pathogen virulence from inside plant cells.

Several bacterial avr genes have been shown to contribute to virulence on susceptible plants lacking the corresponding resistance (R) gene. The mechanisms by which avr genes promote parasitism and disease, however, are not well understood. We investigated the role of the Pseudomonas syringae pv. tomato avrRpt2 gene in pathogenesis by studying the interaction of P. syringae pv. tomato strain PstDC3000 expressing avrRpt2 with several Arabidopsis thaliana lines lacking the corresponding R gene, RPS2. We found that PstDC3000 expressing avrRpt2 grew to significantly higher levels and often resulted in the formation of more severe disease symptoms in ecotype No-0 plants carrying a mutant RPS2 allele, as well as in two Col-0 mutant lines, cpr5 rps2 and coil rps2, that exhibit enhanced resistance. We also generated transgenic A. thaliana lines expressing avrRpt2 and demonstrated, by using several different assays, that expression of avrRpt2 within the plant also promotes virulence of PstDC3000. Thus, AvrRpt2 appears to promote pathogen virulence from within the plant cell.

Novel gene structure and evolutionary context of Caenorhabditis elegans globin.

Animal and plant globin-encoding genes (Glo) contain two introns in strictly conserved positions. Plant Glo genes possess an additional, centrally located intron. We have determined the cDNA sequence and gene structure of a putative Glo gene from the free-living nematode, Caenorhabditis elegans. The gene encodes a one-domain globin with a single intron, corresponding to the central intron of plant Glo genes. The two introns common to virtually all animal and plant Glo genes are missing. Comparison with the related organisms Trichostrongylus colubriformis, Ascaris suum and Pseudoterranova decipiens, provides evidence of gene duplication, intron loss, and functional divergence within the Glo genes of the nematode phylum. It is now apparent that differential intron loss during evolution has generated Glo genes with a panoply of exon/intron permutations.

A dsbA mutant of Pseudomonas syringae exhibits reduced virulence and partial impairment of type III secretion.

Abstract To identify virulence genes of P. syringae pv. tomato strain DC3000 we screened for mutants with reduced virulence on its plant hosts, Arabidopsis thaliana and tomato. We isolated a Tn5-insertion mutant that exhibited reduced virulence on both hosts. Further characterization showed that this mutant carried a single Tn5 insertion in the dsbA gene, which encodes a periplasmic disulphide bond-forming protein. In addition to reduced virulence, the dsbA mutant exhibits mucoid colony morphology, loss of fluorescence, decreased motility, and a reduced growth rate in culture. The dsbA mutant is able to multiply in A. thaliana and tomato plants, trigger the hypersensitive response on tobacco and elicit Pto-mediated resistance in tomato, indicating that type III secretion occurs in this background. However, type III secretion appears to function with reduced efficiency in the dsbA mutant, as type III-dependent secretion of HrpZ and AvrRpt2 is impaired. These findings indicate that while the dsbA gene is required for multiple cellular functions in P. syringae, type III secretion in P. syringae is only partially dependent on dsbA.

Subunit interactions in Ascaris hemoglobin octamer formation.

The oxygen-avid, perienteric hemoglobin of Ascaris is a homooctamer. Each subunit contains two tandem globin domains that are highly homologous with the exception of a charged COOH-terminal extension. In solution, recombinant domain one (D1) exists as a monomer, whereas recombinant domain two with the COOH-terminal tail (D2) is primarily an octamer. To examine the role of the COOH-terminal extension in Ascaris hemoglobin multimer formation, we attached the tail to the monomeric, heme-containing proteins, myoglobin and D1; neither construct was capable of multimer formation. Additionally, we removed the tail from both full-length Ascaris hemoglobin and D2. This substantially decreased, but did not eliminate, multimerization. We further characterized subunit interactions by disrupting full-length hemoglobin multimers with the chaotropic salt, NaSCN, which yielded intermediate oligomers. In solution, D2 demonstrated a greater propensity to dissociate than full-length hemoglobin, indicating that D1 contributes to octamer stability. D1 formed a weak dimer in its crystal; thus, we analyzed interactions along the subunit interface. Hydrogen bonds as well as hydrophobic and electrostatic forces appeared to contribute to dimer formation. Amino acid substitutions along this interface in D2 are predicted to enhance subunit interactions for that domain. Our studies reveal that the COOH-terminal tail is necessary, but not sufficient, for efficient octamer formation. Other regions, possibly with the E- and F-helices and AB loops of both domains, appear to be important for Ascaris hemoglobin octamer formation.

The structure of Ascaris hemoglobin domain I at 2.2 A resolution: molecular features of oxygen avidity.

The perienteric hemoglobin of the parasitic nematode Ascaris has an exceptionally high affinity for oxygen. It is an octameric protein containing two similar heme-binding domains per subunit, but recombinant constructs expressing a single, monomeric heme-binding domain (domain 1; D1) retain full oxygen avidity. We have solved the crystal structure of D1 at 2.2 A resolution. Analysis of the structure reveals a characteristic globin fold and illuminates molecular features involved in oxygen avidity of Ascaris perienteric hemoglobin. A strong hydrogen bond between tyrosine at position 10 in the B helix (tyrosine-B10) and the distal oxygen of the ligand, combined with a weak hydrogen bond between glutamine-E7 and the proximal oxygen, grips the ligand in the binding pocket. A third hydrogen bond between these two amino acids appears to stabilize the structure. The B helix of D1 is displaced laterally by 2.5 A when compared with sperm whale myoglobin. This shifts the tyrosine-B10 hydroxyl far enough from liganded oxygen to form a strong hydrogen bond without steric hindrance. Changes in the F helix compared with myoglobin contribute to a tilted heme that may also be important for oxygen affinity.

The tyrosine B10 hydroxyl is crucial for oxygen avidity of Ascaris hemoglobin.

The parasitic nematode Ascaris suum has a gene encoding a two-domain hemoglobin with remarkable oxygen avidity. The strong interaction with oxygen is a consequence of a particularly slow oxygen off-rate. The single polypeptide chain consists of two domains, each of which can be expressed separately in Escherichia coli as a globin-like protein exhibiting oxygen binding characteristics comparable with the native molecule. Site-directed mutagenesis was performed on the gene segment encoding domain one. The E7 position, involved in forming a hydrogen bond with the liganded oxygen in vertebrate globins, is a glutamine in both Ascaris domains. Conversion of this residue to leucine or alanine produced a hemoglobin variant with an oxygen off-rate 5- or 60-fold faster than that of unaltered domain one. Replacement of the tyrosine B10 with either phenylalanine or leucine (as found in vertebrate globins) yielded hemoglobin mutants with oxygen off-rates 280- or 570-fold faster, approaching rates found with vertebrate myoglobins. The data suggest that the distal glutamine hydrogen bonds with the liganded oxygen and that the tyrosine B10 hydroxyl contributes an additional hydrogen bond that appears substantially responsible for the extreme oxygen avidity of Ascaris hemoglobin.

Ascaris hemoglobin gene: plant-like structure reflects the ancestral globin gene.

Animal globin genes have two introns at strictly conserved positions, while plant globin genes have both of these as well as an additional, central intron. It has been proposed that a common ancestor gene had three introns, one of which was subsequently lost from animal but not plant globin genes. We have elucidated the cDNA sequence and gene structure of a hemoglobin from the parasitic nematode Ascaris suum and found a plant-like central intron, providing strong evidence for a three-intron ancestor of modern globin genes.

Caenorhabditis globin genes: rapid intronic divergence contrasts with conservation of silent exonic sites.

Globin genes from the Caenorhabditis species briggsae and remanei were identified and compared with a previously described C. elegans globin gene. The encoded globins share between 86% and 93% amino acid identity, with most of the changes in or just before the putative B helix. C. remanei was found to have two globin alleles, Crg1-1 and Crg1-2. The coding sequence for each is interrupted by a single intron in the same position. The exons of the two genes are only 1% divergent at the nucleotide level and encode identical polypeptides. In contrast, intron sequence divergence is 16% and numerous insertions and deletions have significantly altered the size and content of both introns. Genetic crosses show that Crg1-1 and Crg1-2 segregate as alleles. Homozygous lines for each allele were constructed and northern analysis confirmed the expression of both alleles. These data reveal an unusual situation wherein two alleles encoding identical proteins have diverged much more rapidly in their introns than the silent sites of their coding sequences, suggesting multiple gene conversion events.

Expression, characterization, and crystallization of oxygen-avid Ascaris hemoglobin domains.

The Ascaris perienteric hemoglobin is 10(4) times more oxygen-avid than mammalian hemoglobins. Inspection of its primary structure fails to explain this extraordinary association with oxygen. The Ascaris hemoglobin gene encodes a 40-kDa, two-domain globin; the two domains (D1 and D2) are 63% identical, and each is capable of binding a single heme. The native protein is an octamer. At the end of D2 is a highly charged carboxyl-terminal extension containing four direct repeats of HKEE. We have expressed the two domains separately in E. coli. Both individual domains are extremely oxygen-avid. D2, with attached COOH-terminal tail, is capable of multimerization, whereas D1 remains a monomer. Recombinant D1 readily forms diffractable, red, prismatic crystals. We conclude that: 1) the basis of the hemoglobin's oxygen avidity rests in an isolated heme pocket and does not involve inter-domain interactions and 2) multimerization is mediated through sequences in the second domain, most probably via the charged COOH-terminal tail.

Hydrogen bonding of tyrosine B10 to heme-bound oxygen in Ascaris hemoglobin. Direct evidence from UV resonance Raman spectroscopy.

The hemoglobin from Ascaris suum, a parasitic nematode, has a spontaneous dissociation rate for the dioxygen ligand that is 3 orders of magnitude less than for mammalian myoglobins or hemoglobins. In this hemoglobin, the distal histidine is replaced with a glutamine which is capable of forming a stabilizing hydrogen bond to the bound dioxygen. A single hydrogen bond from a glutamine is, under typical circumstances, not sufficient to account for the low off rate for oxygen. Several studies point to a second hydrogen bond to the heme-bound dioxygen originating from tyrosine B10 as the source of this unusual reactivity. In this study ultraviolet (UV) resonance Raman spectroscopy is used to directly observe the formation of this hydrogen bond upon oxygen binding. The study reveals that both oxygen and carbon monoxide induce similar conformational changes in the globin upon binding to the heme; however, in the case of oxygen, a strong hydrogen bond involving a tyrosine is also observed. Similar studies on the QE7L mutant of this Hb suggest that the glutamine plays a role in stabilizing a rigid tertiary structure associated with the distal heme pocket. This conformation maintains the tyrosine in an orientation conducive to hydrogen bond formation with a heme-bound dioxygen ligand.

1H NMR investigation of the distal hydrogen bonding network and ligand tilt in the cyanomet complex of oxygen-avid Ascaris suum hemoglobin.

The O(2)-avid hemoglobin from the parasitic nematode Ascaris suum exhibits one of the slowest known O(2) off rates. Solution (1)H NMR has been used to investigate the electronic and molecular structural properties of the active site for the cyano-met derivative of the recombinant first domain of this protein. Assignment of the heme, axial His, and majority of the residues in contact with the heme reveals a molecular structure that is the same as reported in the A. suum HbO(2) crystal structure (Yang, J., Kloek, A., Goldberg, D. E., and Mathews, F. S. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 4224-4228) with the exception that the heme in solution is rotated by 180 degrees about the alpha,gamma-meso axis relative to that in the crystal. The observed dipolar shifts, together with the crystal coordinates of HbO(2), provide the orientation of the magnetic axes in the molecular framework. The major magnetic axis, which correlates with the Fe-CN vector, is found oriented approximately 30 degrees away from the heme normal and indicates significant steric tilt because of interaction with Tyr(30)(B10). The three side chain labile protons for the distal residues Tyr(30)(B10) and Gln(64)(E7) were identified, and their relaxation, dipolar shifts, and nuclear Overhauser effects to adjacent residues used to place them in the distal pocket. It is shown that these two distal residues exhibit the same orientations ideal for H bonding to the ligand and to each other, as found in the A. suum HbO(2) crystal. It is concluded that the ligated cyanide participates in the same distal H bonding network as ligated O(2). The combination of the strong steric tilt of the bound cyanide and slow ring reorientation of the Tyr(30)(B10) side chain supports a crowded and constrained distal pocket.

Origin of the anomalous Fe-CO stretching mode in the CO complex of Ascaris hemoglobin.

We report an unusually high frequency (543 cm(-)(1)) for an Fe-CO stretching mode in the CO complex of Ascaris suum hemoglobin as compared to vertebrate hemoglobins in which the frequency of the Fe-CO mode is much lower. A second Fe-CO stretching mode in Ascaris hemoglobin is observed at 515 cm(-1). We propose that these two Fe-CO stretching modes arise from two protein conformers corresponding to interactions of the heme-bound CO with the B10-tyrosine or the E7-glutamine residues. This postulate is supported by spectra from the B10-Tyr --> Phe mutant in which the 543 cm(-1) line is absent. Thus, a strong polar interaction, such as hydrogen bonding, of the CO with the distal B10 tyrosine residue is the dominant factor that causes this anomalously high frequency. Strong hydrogen bonding between O(2) and distal residues in the oxy complex of Ascaris hemoglobin has been shown to result in a rigid structure, rendering an extremely low oxygen off rate [Gibson, Q. H., and Smith, M. H. (1965) Proc. R. Soc. London B 163, 206-214]. In contrast, the CO off rate in Ascaris hemoglobin is very similar to that in sperm whale myoglobin. The high CO off rate relative to that of O(2) in Ascaris hemoglobin is attributed to a rapid equilibrium between the two conformations of the protein in the CO adduct, with the off rate being determined by the conformer with the higher rate.

Resistance to Pseudomonas syringae conferred by an Arabidopsis thaliana coronatine-insensitive (coi1) mutation occurs through two distinct mechanisms.

A new allele of the coronatine-insensitive locus (COI1) was isolated in a screen for Arabidopsis thaliana mutants with enhanced resistance to the bacterial pathogen Pseudomonas syringae. This mutant, designated coi1-20, exhibits robust resistance to several P. syringae isolates but remains susceptible to the virulent pathogens Erisyphe and cauliflower mosaic virus. Resistance to P. syringae strain PstDC3000 in coi1-20 plants is correlated with hyperactivation of PR-1 expression and accumulation of elevated levels of salicylic acid (SA) following infection, suggesting that the SA-mediated defense response pathway is sensitized in this mutant. Restriction of growth of PstDC3000 in coi1-20 leaves is partially dependent on NPR1 and fully dependent on SA, indicating that SA-mediated defenses are required for restriction of PstDC3000 growth in coi1-20 plants. Surprisingly, despite high levels of PstDC3000 growth in coi1-20 plants carrying the salicylate hydroxylase (nahG) transgene, these plants do not exhibit disease symptoms. Thus resistance to P. syringae in coi1-20 plants is conferred by two different mechanisms: (i) restriction of pathogen growth via activation of the SA-dependent defense pathway; and (ii) an SA-independent inability to develop disease symptoms. These findings are consistent with the hypotheses that the P. syringae phytotoxin coronatine acts to promote virulence by inhibiting host defense responses and by promoting lesion formation.

A survey of SL1-spliced transcripts from the root-lesion nematode Pratylenchus penetrans.

Plant-parasitic nematodes are important and cosmopolitan pathogens of crops. Here, we describe the generation and analysis of 1928 expressed sequence tags (ESTs) of a splice-leader 1 (SL1) library from mixed life stages of the root-lesion nematode Pratylenchus penetrans. The ESTs were grouped into 420 clusters and classified by function using the Gene Ontology (GO) hierarchy and the Kyoto KEGG database. Approximately 80% of all translated clusters show homology to Caenorhabditis elegans proteins, and 37% of the C. elegans gene homologs had confirmed phenotypes as assessed by RNA interference tests. Use of an SL1-PCR approach, while ensuring the cloning of the 5' ends of mRNAs, has demonstrated bias toward short transcripts. Putative nematode-specific and Pratylenchus -specific genes were identified, and their implications for nematode control strategies are discussed.

A comparison of functional and structural consequences of the tyrosine B10 and glutamine E7 motifs in two invertebrate hemoglobins (Ascaris suum and Lucina pectinata).

The architecture of the distal heme pocket in hemoglobins and myoglobins can play an important role in controlling ligand binding dynamics. The size and polarity of the residues occupying the distal pocket may contribute steric and dielectric effects. In vertebrate systems, the distal pocket typically contains a "distal" histidine at position E7 and a leucine at position B10. There are several invertebrate organisms that have hemoglobins or myoglobins that display a pattern in which residues E7 and B10 are a glutamine and tyrosine, respectively. These proteins often have very high oxygen affinities stemming from very slow ligand off rates. In this study, two such hemoglobins, one from the nematode Ascaris suum and the other from the sulfide-fixing clam Lucina pectinata, are compared with respect to conformational and functional properties. Ultraviolet resonance Raman spectroscopy and visible resonance Raman spectroscopy are used to probe, respectively, the ligand-dependent hydrogen bonding pattern of the tyrosine residues and the proximal heme pocket interactions. Fourier transform infrared absorption spectroscopy is used to probe the dielectric properties of the distal heme pocket through the stretching frequency of carbon monoxide bound to the heme. Functionality is probed through the geminate rebinding of both CO and O2. The findings reveal two very different patterns indicative of two different mechanisms for achieving low oxygen off rates. In Hb Ascaris, a hydrogen bonding network that includes the E7 Gln, B10 Tyr, and oxygen bound to the heme results in a tight cage for the oxygen. Dissociation of the O2 requires a large amplitude conformational fluctuation that results both in a spontaneous dissociation of the oxygen through the loss of hydrogen bond stabilization and in an enhanced probability for ligand escape though the transient disruption and opening of the tight distal cage. In the case of the Hb from Lucina, there is no evidence for a tight cage. Instead the data support a model in which the hydrogen bonding network is far more tenuous and the equilibrium state of distal pocket is far more open and accessible than is the case in Ascaris. The results explain why Hb Ascaris has one of the highest oxygen affinities known (P50 approximately 10(-)3 Torr) while Hb Lucina II has an oxygen affinity comparable to that of Mb (P50 = 0.13 Torr) even though both of these Hbs contain the B10 Tyr and E7 Gln motif and display very low oxygen off rates. The roles of water and proximal strain are discussed.