Suppression of protein l-isoaspartyl (d-aspartyl) methyltransferase results in hyperactivation of EGF-stimulated MEK-ERK signaling in cultured mammalian cells

l-Aspartyl (l-Asp) and l-asparaginyl residues in proteins isomerize or racemize to d,l-isoaspartyl (d,l-isoAsp) or d-aspartyl (d-Asp) residues during protein aging. These atypical aspartyl residues can interfere with the biological function of the protein and lead to cellular dysfunction. Protein l-isoaspartyl (d-aspartyl) methyltransferase (PIMT) is a repair enzyme that facilitates conversion of l-isoAsp and d-Asp to l-Asp. PIMT deficient mice exhibit accumulation of l-isoAsp in several tissues and die, on average, 12 days after birth from progressive epileptic seizures with grand mal and myoclonus features. However, little is known about the molecular mechanisms by which accumulation of the aberrant residues leads to cellular abnormalities. In this study, we established PIMT-knockdown cells using a short interfering RNA expression system and characterized the resultant molecular abnormalities in intracellular signaling pathways. PIMT-knockdown cells showed significant accumulation of proteins with isomerized residues, compared to control cells. In the PIMT-knockdown cells, Raf-1, MEK, and ERK, members of the MAPK cascade, were hyperphosphorylated after EGF stimulation compared to control cells. These results suggest that PIMT repair of abnormal proteins is necessary to maintain normal MAPK signaling.     

Differentiating analogous tRNA methyltransferases by fragments of the methyl donor

Bacterial TrmD and eukaryotic-archaeal Trm5 form a pair of analogous tRNA methyltransferase that catalyze methyl transfer from S-adenosyl methionine (AdoMet) to N(1) of G37, using catalytic motifs that share no sequence or structural homology. Here we show that natural and synthetic analogs of AdoMet are unable to distinguish TrmD from Trm5. Instead, fragments of AdoMet, adenosine and methionine, are selectively inhibitory of TrmD rather than Trm5. Detailed structural information of the two enzymes in complex with adenosine reveals how Trm5 escapes targeting by adopting an altered structure, whereas TrmD is trapped by targeting due to its rigid structure that stably accommodates the fragment. Free energy analysis exposes energetic disparities between the two enzymes in how they approach the binding of AdoMet versus fragments and provides insights into the design of inhibitors selective for TrmD.     

Crystallographic and mutational studies on the tRNA thiouridine synthetase TtuA

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

Functional analysis of membranous Fo-a subunit of F1Fo-ATP synthase by in vitro protein synthesis

The a subunit of F(1)F(o) (F(1)F(o)-ATP synthase) is a highly hydrophobic protein with five putative transmembrane helices which plays a central role in H(+)-translocation coupled with ATP synthesis/hydrolysis. In the present paper, we show that the a subunit produced by the in vitro protease-free protein synthesis system (the PURE system) is integrated into a preformed F(o) a-less F(1)F(o) complex in Escherichia coli membrane vesicles and liposomes. The resulting F(1)F(o) has a H(+)-coupled ATP synthesis/hydrolysis activity that is approximately half that of the native F(1)F(o). By using this procedure, we analysed five mutations of F(1)F(o), where the conserved residues in the a subunit (Asn(90), Asp(112), Arg(169), Asn(173) and Gln(217)) were individually replaced with alanine. All of the mutant F(o) a subunits were successfully incorporated into F(1)F(o), showing the advantage over conventional expression in E. coli by which three (N90A, D112A, and Q217A) mutant a subunits were not found in F(1)F(o). The N173A mutant retained full activity and the mutants D112A and Q217A had weak, but detectable, activity. No activity was observed for the R169A and N90A mutants. Asn(90) is located in the middle of putative second transmembrane helix and likely to play an important role in H(+)-translocation. The present study exemplifies that the PURE system provides an alternative approach when in vivo expression of membranous components in protein complexes turns out to be difficult.     

Sulfidogenesis in low pH (3.8-4.2) media by a mixed population of acidophilic bacteria

A defined mixed bacterial culture was established which catalyzed dissimilatory sulfate reduction, using glycerol as electron donor, at pH 3.8-4.2. The bacterial consortium comprised a endospore-forming sulfate reducing bacterium (isolate M1) that had been isolated from acidic sediment in a geothermal area of Montserrat (West Indies) and which had 94% sequence identity (of its 16S rRNA gene) to the Gram-positive neutrophile Desulfosporosinus orientis, and a Gram-negative (non sulfate-reducing) acidophile (isolate PFBC) that shared 99% gene identity with Acidocella aromatica. Whilst M1 was an obligate anaerobe, isolate PFBC, as other Acidocella spp., only grew in pure culture in aerobic media. Analysis of microbial communities, using a combination of total bacterial counts and fluorescent in situ hybridization, confirmed that concurrent growth of both bacteria occurred during sulfidogenesis under strictly anoxic conditions in a pH-controlled fermenter. In pure culture, M1 oxidized glycerol incompletely, producing stoichiometric amounts of acetic acid. In mixed culture with PFBC, however, acetic acid was present only in small concentrations and its occurrence was transient. Since M1 did not oxidize acetic acid, it was inferred that this metabolite was catabolized by Acidocella PFBC which, unlike glycerol, was shown to support the growth of this acidophile under aerobic conditions. In fermenter cultures maintained at pH 3.8-4.2, sulfidogenesis resulted in the removal of soluble zinc (as solid phase ZnS) whilst ferrous iron remained in solution. Potential syntrophic interactions, involving hydrogen transfer between M1 and PFBC, are discussed, as is the potential of sulfidogenesis in acidic liquors for the selective recovery of heavy metals from wastewaters.     

Thermal unfolding of ribonuclease T1 studied by multi-dimensional NMR spectroscopy

Thermal unfolding of ribonculease (RNase) T1 was studied by 1H nuclear Overhauser enhancement spectroscopy (NOESY) and 1H- 15N heteronuclear single-quantum coherence (HSQC) NMR spectroscopy at various temperatures. Native RNase T1 is a single-chain molecule of 104 amino acid residues, and has a single alpha-helix and two beta-sheets, A and B, which consist of two and five strands, respectively. Singular value decomposition analysis based on temperature-dependent HSQC spectra revealed that the thermal unfolding of RNase T1 can be described by a two-state transition model. The midpoint temperature and the change in enthalpy were determined as 54.0 degrees C and 696 kJ/mol, respectively, which are consistent with results obtained by other methods. To analyze the transition profile in more detail, we investigated local structural changes using temperature-dependent NOE intensities. The results indicate that the helical region starts to unfold at lower temperature than some beta-strands (B3, B4, and B5 in beta-sheet B). These beta-strands correspond to the hydrophobic cluster region, which had been expected to be a folding core. This was confirmed by structure calculations using the residual NOEs observed at 56 degrees C. Thus, the two-state transition of RNase T1 appears to involve locally different conformational changes.     

F0F1-ATPase/synthase is geared to the synthesis mode by conformational rearrangement of epsilon subunit in response to proton motive force and ADP/ATP balance

The epsilon subunit in F0F1-ATPase/synthase undergoes drastic conformational rearrangement, which involves the transition of two C-terminal helices between a hairpin "down"-state and an extended "up"-state, and the enzyme with the up-fixed epsilon cannot catalyze ATP hydrolysis but can catalyze ATP synthesis (Tsunoda, S. P., Rodgers, A. J. W., Aggeler, R., Wilce, M. C. J., Yoshida, M., and Capaldi, R. A. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 6560-6564). Here, using cross-linking between introduced cysteine residues as a probe, we have investigated the causes of the transition. Our findings are as follows. (i) In the up-state, the two helices of epsilon are fully extended to insert the C terminus into a deeper position in the central cavity of F1 than was thought previously. (ii) Without a nucleotide, epsilon is in the up-state. ATP induces the transition to the down-state, and ADP counteracts the action of ATP. (iii) Conversely, the enzyme with the down-state epsilon can bind an ATP analogue, 2',3'-O-(2,4,6-trinitrophenyl)-ATP, much faster than the enzyme with the up-state epsilon. (iv) Proton motive force stabilizes the up-state. Thus, responding to the increase of proton motive force and ADP, F0F1-ATPase/synthase would transform the epsilon subunit into the up-state conformation and change gear to the mode for ATP synthesis.     

Characterization of a 24-kb plasmid pCGR2 newly isolated from Corynebacterium glutamicum

A 24-kb plasmid with 21 open reading frames (ORFs) was newly isolated from Corynebacterium glutamicum ATCC 14997 and named pCGR2. Three of its ORFs were indispensable for stable autonomous replication of pCGR2 in C. glutamicum: in the absence of selective pressure, deletion derivatives of pCGR2 containing the three ORFs showed stability in C. glutamicum for over 50 generations. The first of these ORFs encoded replicase repA whose gene product revealed high amino acid sequence similarity to corresponding gene products of C. glutamicum pCG1-family plasmids in general, and to that of pTET3 plasmid repA in particular. The other two ORFs were located upstream of repA and exhibited high sequence similarity to pTET3 parA and parB, respectively. Interestingly, plasmids based on the pCGR2 were compatible not only with those based on different family plasmids (pBL1, pCASE1) but also with those based on pCG1-family plasmid. Plasmids comprising pCGR2 repA showed a copy number of four in C. glutamicum. The number increased to 240 upon introduction of a mutation within the repA origin of the putative promoter for counter-transcribed RNA. This 60-fold increase in copy number should immensely contribute towards enhanced expression of desired genes in C. glutamicum.     

Macroscopic Streamer Growths in Acidic, Metal-Rich Mine Waters in North Wales Consist of Novel and Remarkably Simple Bacterial Communities

The microbial composition of acid streamers (macroscopic biofilms) in acidic, metal-rich waters in two locations (an abandoned copper mine and a chalybeate spa) in north Wales was studied using cultivation-based and biomolecular techniques. Known chemolithotrophic and heterotrophic acidophiles were readily isolated from disrupted streamers, but they accounted for only <1 to 7% of the total microorganisms present. Fluorescent in situ hybridization (FISH) revealed that 80 to 90% of the microbes in both types of streamers were β-Proteobacteria. Terminal restriction fragment length polymorphism analysis of the streamers suggested that a single bacterial species was dominant in the copper mine streamers, while two distinct bacteria (one of which was identical to the bacterium found in the copper mine streamers) accounted for about 90% of the streamers in the spa water. 16S rRNA gene clone libraries showed that the β-proteobacterium found in both locations was closely related to a clone detected previously in acid mine drainage in California and that its closest characterized relatives were neutrophilic ammonium oxidizers. Using a modified isolation technique, this bacterium was isolated from the copper mine streamers and shown to be a novel acidophilic autotrophic iron oxidizer. The β-proteobacterium found only in the spa streamers was closely related to the neutrophilic iron oxidizer Gallionella ferruginea. FISH analysis using oligonucleotide probes that targeted the two β-proteobacteria confirmed that the biodiversity of the streamers in both locations was very limited. The microbial compositions of the acid streamers found at the two north Wales sites are very different from the microbial compositions of the previously described acid streamers found at Iron Mountain, California, and the Rio Tinto, Spain.