Alternative splicing of Myb-related genes MYR1 and MYR2 may modulate activities through changes in dimerization,localization, or protein folding

Arabidopsis genes MYR1 and MYR2 are regulators of flowering time under low light intensity. These Myb-related genes are expressed as alternative splice variants affected in their coiled-coil and DNA-binding domains. We tested whether alternative splicing could affect dimerization and localization of MYR1 and MYR2, thereby potentially affecting their activity. Using MYR1 as a model for variants within the coiled-coil region, we detected 2 types of homodimers. For MYR2, alternative splicing in the DNA-binding Myb-like domain abolished the ability of MYR2 to dimerize. Alternative splicing in the coiled-coil domain did not affect nuclear localization, as determined by transient expression in tobacco, while alternative splicing in the DNA-binding domain of MYR2 yielded a distinct intranuclear localization pattern that may reflect changes in phosphorylation-dependent protein folding. Thus alternative splicing of these genes may result in changes in dimerization or protein folding resulting in changes in activity and abundance of MYR1 or MYR2 protein.     

Orchestration of Haemophilus influenzae RecJ Exonuclease by Interaction with Single-Stranded DNA-Binding Protein

RecJ exonuclease plays crucial roles in several DNA repair and recombination pathways, and its ubiquity in bacterial species points to its ancient origin and vital cellular function. RecJ exonuclease from Haemophilus influenzae is a 575-amino-acid protein that harbors the characteristic motifs conserved among RecJ homologs. The purified protein exhibits a processive 5′-3′ single-stranded-DNA-specific exonuclease activity. The exonuclease activity of H. influenzae RecJ (HiRecJ) was supported by Mg^2 + or Mn^2 + and inhibited by Cd^2 +, suggesting a different mode of metal binding in HiRecJ as compared to Escherichia coli RecJ (EcoRecJ). Site-directed mutagenesis of highly conserved residues in HiRecJ abolished enzymatic activity. Interestingly, substitution of alanine for aspartate 77 resulted in a catalytically inactive enzyme that bound to DNA with a significantly higher affinity as compared to the wild-type enzyme. Noticeably, steady-state kinetic studies showed that H. influenzae single-stranded DNA-binding protein (HiSSB) increased the affinity of HiRecJ for single-stranded DNA and stimulated its exonuclease activity. HiSSB, whose C-terminal tail had been deleted, failed to enhance RecJ exonuclease activity. More importantly, HiRecJ was found to directly associate with its cognate single-stranded DNA-binding protein (SSB), as demonstrated by various in vitro assays. Interaction studies carried out with the truncated variants of HiRecJ and HiSSB revealed that the two proteins interact via the C-terminus of SSB protein and the core-catalytic domain of RecJ. Taken together, these results emphasize direct interaction between RecJ and SSB, which confers functional cooperativity to these two proteins. In addition, these results implicate SSB as being involved in the recruitment of RecJ to DNA and provide insights into the interplay between these proteins in repair and recombination pathways.     

A Conserved Region between the TPR and Activation Domains of p67phox Participates in Activation of the Phagocyte NADPH Oxidase

The phagocyte NADPH oxidase, dormant in resting cells, is activated during phagocytosis to produce superoxide, a precursor of microbicidal oxidants. The membrane-integrated protein gp91^phox serves as the catalytic core, because it contains a complete electron-transporting apparatus from NADPH to molecular oxygen for superoxide production. Activation of gp91^phox requires the cytosolic proteins p67^phox, p47^phox, and Rac (a small GTPase). p67^phox, comprising 526 amino acids, moves upon cell stimulation to the membrane together with p47^phox and there interacts with Rac; these processes are prerequisite for gp91^phox activation. Here we show that a region of p67^phox (amino acids 190–200) C-terminal to the Rac-binding domain is evolutionarily well conserved and participates in oxidase activation at a later stage in conjunction with an activation domain. Alanine substitution for Tyr-198, Leu-199, or Val-204 abrogates the ability of p67^phox to support superoxide production by gp91^phox-based oxidase as well as its related oxidases Nox1 and Nox3; the activation also involves other invariant residues such as Leu-193, Asp-197, and Gly-200. Intriguingly, replacement of Gln-192 by alanine or that of Tyr-198 by phenylalanine or tryptophan rather enhances superoxide production by gp91^phox-based oxidase, suggesting a tuning role for these residues. Furthermore, the Y198A/V204A or L199A/V204A substitution leads to not only a complete loss of the activity of the reconstituted oxidase system but also a significant decrease in p67^phox interaction with the gp91^phox NADPH-binding domain, although these mutations affect neither the protein integrity nor the Rac binding activity. Thus the extended activation domain of p67^phox (amino acids 190–210) containing the D(Y/F)LGK motif plays an essential role in oxidase activation probably by interacting with gp91^phox.     

A novel protein with a fibrinogen-like domain involved in the innate immune response of Marsupenaeus japonicus

Fibrinogen-related proteins play important roles in innate immunity. We isolated a fibrinogen-related protein gene (MjFREP1) in kuruma shrimp Marsupenaeus japonicus. MjFREP1 encoded a protein of 270 amino acids, including a 223 amino acid fibrinogen-like domain. Quantitative real-time polymerase chain reaction analysis shows that MjFREP1 is mainly expressed in the gills and the expression is significantly upregulated by Vibrio anguillarum, Staphylococcus aureus, or white spot syndrome virus (WSSV) challenge. Recombinant MjFREP1 fibrinogen-like domain agglutinates Gram-positive bacteria Bacillus subtilis, Bacillus thuringiensis, Bacillus megaterium, and S. aureus in the presence of calcium ions. The fibrinogen-like domain of MjFREP1 binds peptidoglycans, LPS, bacteria, and the VP28 of WSSV. These results suggest that the MjFREP1 may play an important role in the shrimp immune response against different pathogens.     

In vivo analysis in Drosophila reveals differential requirements of contact residues in Axin for interactions with GSK3β or β-catenin

Proper regulation of the Wingless/Wnt signaling pathway is essential for normal development. The scaffolding protein Axin plays a key role in this process through interactions with Drosophila Shaggy and Armadillo. In the current studies, we used a yeast two-hybrid assay to identify ten amino acids in Axin that are critical for in vitro interaction with Shaggy and two for interaction with Armadillo. We then generated five Axin variants in which individual putative contact amino acids were mutated and compared their activity, as assayed by rescue of axin null mutant flies, to that of Axin lacking the entire Shaggy (AxinΔSgg) or Armadillo (AxinΔArm) binding domain. Although we expected these mutants to function identically to Axin in which the entire binding domain was deleted, we instead observed a spectrum of phenotypic rescue. Specifically, two point mutants within the Shaggy binding domain showed loss of activity similar to that of AxinΔSgg and dominantly interfered with complex function, whereas a third mutant allele, AxinK446E, retained most function. Two Axin point mutants within the Armadillo binding domain were weak alleles and retained most function. These findings demonstrate the importance of in vivo verification of the role of specific amino acids within a protein.     

The Bacillus subtilis Chemoreceptor McpC Senses Multiple Ligands Using Two Discrete Mechanisms

Bacillus subtilis can perform chemotaxis toward all 20 l-amino acids normally found in proteins. Loss of a single chemoreceptor, McpC, was previously found to reduce chemotaxis to 19 of these amino acids. In this study, we investigated the amino acid-sensing mechanism of McpC. We show that McpC alone can support chemotaxis to 17 of these amino acids to varying degrees. Eleven amino acids were found to directly bind the amino-terminal sensing domain of McpC in vitro. Sequence analysis indicates that the McpC sensing domain exhibits a dual Per-Arnt-Sim (PAS) domain structure. Using this structure as a guide, we were able to isolate mutants that suggest that four amino acids (arginine, glutamine, lysine, and methionine) are sensed by an indirect mechanism. We identified four candidate binding lipoproteins associated with amino acid transporters that may function in indirect sensing: ArtP, GlnH, MetQ, and YckB. ArtP was found to bind arginine and lysine; GlnH, glutamine; MetQ, methionine; and YckB, tryptophan. In addition, we found that ArtP, MetQ, and YckB bind the sensing domain of McpC, suggesting that the three participate in the indirect sensing of arginine, lysine, methionine, and possibly tryptophan as well. Taken together, these results further our understanding of amino acid chemotaxis in B. subtilis and gain insight into how a single chemoreceptor is able to sense many amino acids.     

Cloning,chromosome mapping and expression pattern of porcine PLIN and M6PRBP1 genes

The PAT proteins, named after the three PLIN/ADRP/TIP47 (PAT) proteins, PLIN for perilipin, ADRP for adipose differentiation-related protein and TIP47 for tail-interacting protein of 47 kDa, now officially named M6PRBP1 for mannose-6-phosphate receptor binding protein 1, is a set of intracellular lipid droplet binding proteins. They are localized in the outer membrane monolayer enveloping lipid droplets and are involved in the metabolism of intracellular lipid. This work describes the cloning and sequencing of porcine PLIN and M6PRBP1 cDNAs, the chromosome mapping of these two genes, as well as the expression pattern of porcine PAT genes. Sequence analysis shows that the porcine PLIN cDNA contains an open reading frame of 1551 bp encoding 516 amino acids and that the porcine M6PRBP1 cDNA contains a coding region of 1320 bp encoding 439 amino acids. Comparison of PLIN and M6PRBP1 amino-acid sequences among various species reveals that porcine and bovine proteins are the most conserved. Porcine PLIN and M6PRBP1 genes have been mapped to pig chromosomes 7 and 2, respectively, by radiation hybrid analysis using the IMpRH panel. Expression analyses in pig showed a high expression of PLIN mRNA in adipose tissue, M6PRBP1 mRNA in small intestine, kidney and spleen and ADRP mRNA in adipose tissue, lung and spleen.     

Two Complementary Enzymes for Threonylation of tRNA in Crenarchaeota: Crystal Structure of Aeropyrum pernix Threonyl-tRNA Synthetase Lacking a cis-Editing Domain

In protein synthesis, threonyl-tRNA synthetase (ThrRS) must recognize threonine (Thr) from the 20 kinds of amino acids and the cognate tRNA^Thr from different tRNAs in order to generate Thr-tRNA^Thr. In general, an organism possesses one kind of gene corresponding to ThrRS. However, it has been recently found that some organisms have two different genes for ThrRS in the genome, suggesting that their proteins ThrRS-1 and ThrRS-2 function separately and complement each other in the threonylation of tRNA^Thr, one for catalysis and the other for trans-editing of misacylated Ser-tRNA^Thr. In order to clarify their three-dimensional structures, we performed X-ray analyses of two putatively assigned ThrRSs from Aeropyrum pernix (ApThrRS-1 and ApThrRS-2). These proteins were overexpressed in Escherichia coli, purified, and crystallized. The crystal structure of ApThrRS-1 has been successfully determined at 2.3 Å resolution. ApThrRS-1 is a dimeric enzyme composed of two identical subunits, each containing two domains for the catalytic reaction and for anticodon binding. The essential editing domain is completely missing as expected. These structural features reveal that ThrRS-1 catalyzes only the aminoacylation of the cognate tRNA, suggesting the necessity of the second enzyme ThrRS-2 for trans-editing. Since the N-terminal sequence of ApThrRS-2 is similar to the sequence of the editing domain of ThrRS from Pyrococcus abyssi, ApThrRS-2 has been expected to catalyze deaminoacylation of a misacylated serine moiety at the CCA terminus.     

The regulatory function of N-terminal AAA+ ATPase domain of eukaryote-like archaeal Orc1/Cdc6 protein during DNA replication initiation

Archaeal replication machinery represents a core version of this in eukaryotes. The crenarchaeon Sulfolobus solfataricus has the potential to be a powerful model system to understand the central mechanism of eukaryotic DNA replication because it contains three active origins of replication and three eukaryote-like Orc1/Cdc6 proteins (SsoCdc6-1, SsoCdc6-2, and SsoCdc6-3). In this study, we investigate the DNA-binding activities of the N-terminal AAA⁺ ATPase domains of these Orc1/Cdc6 proteins, including their functional interactions with the other SsoCdc6 proteins, on duplex DNA substrates derived from the origins of S. solfataricus. We showed that the ATPase domain of SsoCdc6-2 retained to a great extent the origin DNA-binding activity, and likewise maintained its stimulating effect on SsoCdc6-3. Second, the ATPase domain of SsoCdc6-1, which also stimulated the DNA-binding ability of SsoCdc6-3, demonstrated a significantly improved DNA-binding activity at the forked substrate, but only showed a very weak ability towards the blunt DNA. Third, the ATPase domain of SsoCdc6-3, although having lost much of its DNA-binding activity from the origin, inhibited both SsoCdc6-1 and SsoCdc6-2. These imply that the N-terminal AAA⁺ ATPase domain of archaeal Orc1/Cdc6 protein could be differentially involved in origin recognition during DNA replication initiation even if lacking conventional C-terminal winged helix DNA-binding elements. Our findings further propose that conserved AAA⁺ ATPase domains of Orc1/Cdc6 proteins determine their defined and coordinated functions not only in the archaeon species but also in eukaryotes during the early events of DNA replication.     

The C-terminal residues of the 2b protein of Cucumber mosaic virus are important for efficient expression in Escherichia coli and DNA-binding

The RNA silencing suppressor 2b protein of Cucumber mosaic virus (CMV) is difficult to produce in Escherichia coli. We compared two CMV 2b proteins that differ in their toxicity against E. coli and found that the acidic amino acid residues in the C-terminal significantly affected the toxicity and expression level of the protein in E. coli. In addition, in a DNA-binding assay, 2b had the ability to bind to DNA, and this ability was affected by the charge on the C-terminal residues of 2b. We concluded that the C-terminal residues were important for 2b’s DNA-binding ability, which may partly explain the toxicity of the protein.