Libby amphibole-induced mesothelial cell autoantibodies bind to surface plasminogen and alter collagen matrix remodeling.

Lamellar pleural thickening (LPT) is a fibrotic disease induced by exposure to Libby amphibole (LA) asbestos that causes widespread scarring around the lung, resulting in deterioration of pulmonary function. Investigating the effects of autoantibodies to mesothelial cells (MCAA) present in the study populations has been a major part of the effort to understand the mechanism of pathogenesis. It has been shown in vitro that human mesothelial cells (Met5a) exposed to MCAA increase collagen deposition into the extracellular matrix (ECM). In this study, we sought to further elucidate how MCAA drive increased collagen deposition by identifying the protein targets bound by MCAA on the cellular surface using biotinylation to label and isolate surface proteins. Isolated surface protein fractions were identified as containing MCAA targets using ELISA The fractions that demonstrated binding by MCAA were then analyzed by tandem mass spectrometry (MS/MS) and MASCOT analysis. The most promising result from the MASCOT analysis, plasminogen (PLG), was tested for MCAA binding using purified human PLG in an ELISA We report that serum containing MCAA bound at an optical density (OD) 3 times greater than that of controls, and LA-exposed subjects had a high frequency of positive tests for anti-PLG autoantibodies. This work implicates the involvement of the plasminogen/plasmin system in the mechanism of excess collagen deposition in Met5a cells exposed to MCAA Elucidating this mechanism could contribute to the understanding of LPT.

Circular dichroism and fluorescence spectroscopy of cysteinyl-tRNA synthetase from Halobacterium salinarum ssp. NRC-1 demonstrates that group I cations are particularly effective in providing structure and stability to this halophilic protein.

Proteins from extremophiles have the ability to fold and remain stable in their extreme environment. Here, we investigate the presence of this effect in the cysteinyl-tRNA synthetase from Halobacterium salinarum ssp. NRC-1 (NRC-1), which was used as a model halophilic protein. The effects of salt on the structure and stability of NRC-1 and of E. coli CysRS were investigated through far-UV circular dichroism (CD) spectroscopy, fluorescence spectroscopy, and thermal denaturation melts. The CD of NRC-1 CysRS was examined in different group I and group II chloride salts to examine the effects of the metal ions. Potassium was observed to have the strongest effect on NRC-1 CysRS structure, with the other group I salts having reduced strength. The group II salts had little effect on the protein. This suggests that the halophilic adaptations in this protein are mediated by potassium. CD and fluorescence spectra showed structural changes taking place in NRC-1 CysRS over the concentration range of 0-3 M KCl, while the structure of E. coli CysRS was relatively unaffected. Salt was also shown to increase the thermal stability of NRC-1 CysRS since the melt temperature of the CysRS from NRC-1 was increased in the presence of high salt, whereas the E. coli enzyme showed a decrease. By characterizing these interactions, this study not only explains the stability of halophilic proteins in extremes of salt, but also helps us to understand why and how group I salts stabilize proteins in general.

Protein adaptations in archaeal extremophiles.

Extremophiles, especially those in Archaea, have a myriad of adaptations that keep their cellular proteins stable and active under the extreme conditions in which they live. Rather than having one basic set of adaptations that works for all environments, Archaea have evolved separate protein features that are customized for each environment. We categorized the Archaea into three general groups to describe what is known about their protein adaptations: thermophilic, psychrophilic, and halophilic. Thermophilic proteins tend to have a prominent hydrophobic core and increased electrostatic interactions to maintain activity at high temperatures. Psychrophilic proteins have a reduced hydrophobic core and a less charged protein surface to maintain flexibility and activity under cold temperatures. Halophilic proteins are characterized by increased negative surface charge due to increased acidic amino acid content and peptide insertions, which compensates for the extreme ionic conditions. While acidophiles, alkaliphiles, and piezophiles are their own class of Archaea, their protein adaptations toward pH and pressure are less discernible. By understanding the protein adaptations used by archaeal extremophiles, we hope to be able to engineer and utilize proteins for industrial, environmental, and biotechnological applications where function in extreme conditions is required for activity.

Novel 4,4'-diether-2,2'-bipyridine cisplatin analogues are more effective than cisplatin at inducing apoptosis in cancer cell lines.

The synthesis and characterization of dichloro(4,4'-bis[methoxy]-2,2'-bipyridine)platinum (1) and dichloro(4,4'-bis[3-methoxy-n-propyl]-2,2'-bipyridine)platinum (2) are described. As analogues to CDDP, these 4,4'-disubstituted 2,2'-bipyridine complexes exhibit decreased EC(50) values of 10-100 times in cancer cell lines of the lung, prostate, and melanoma with several combinations of complex and cell line less than 10 microM. Flow cytometry data indicate 'blocks' of MDA-MD-435 cycle by 1 (G2/M) and 2 (S). Observed cell survival trends in the presence of 1, 2 under ionizing radiation mimic those of CDDP. Preliminary structure activity relationships are discussed for the 4,4'-substitutions made on the bipyridine ring.

The archetype gamma-class carbonic anhydrase (Cam) contains iron when synthesized in vivo.

A recombinant protein overproduction system was developed in Methanosarcina acetivorans to facilitate biochemical characterization of oxygen-sensitive metalloenzymes from strictly anaerobic species in the Archaea domain. The system was used to overproduce the archetype of the independently evolved gamma-class carbonic anhydrase. The overproduced enzyme was oxygen sensitive and had full incorporation of iron instead of zinc observed when overproduced in Escherichia coli. This, the first report of in vivo iron incorporation for any carbonic anhydrase, supports the need to reevaluate the role of iron in all classes of carbonic anhydrases derived from anaerobic environments.

Positively selected sites on the surface glycoprotein (G) of infectious hematopoietic necrosis virus.

Mutations in the surface glycoprotein (G) of infectious hematopoietic necrosis virus (IHNV), a rhabdovirus that causes significant losses in hatcheries raising salmonid fish, were studied. A 303 nt segment (mid-G region) of this protein from 88 Idaho isolates of IHNV was sequenced. Evidence of positive selection at individual codon sites was estimated by using a Bayesian method (MrBayes). A software algorithm (CPHmodels) was used to construct a three-dimensional (3D) representation of the IHNV protein. The software identified structural homologies between the IHNV G protein and the surface glycoprotein of vesicular stomatitis virus (VSV) and used the VSV structure as a template for predicting the IHNV structure. The amino acids predicted to be under positive selection were mapped onto the proposed IHNV 3D structure and appeared at sites on the surface of the protein where antigen-antibody interaction should be possible. The sites identified as being under positive selection on the IHNV protein corresponded to those reported by others as active sites of mutation for IHNV, and also as antigenic sites on VSV. Knowledge of the sites where genetic variation is positively selected enables a better understanding of the interaction of the virus with its host, and with the host immune system. This information could be used to develop strategies for vaccine development for IHNV, as well as for other viruses.

Catalysis by the second class of tRNA(m1G37) methyl transferase requires a conserved proline.

The enzyme tRNA(m1G37) methyl transferase catalyzes the transfer of a methyl group from S-adenosyl methionine (AdoMet) to the N1 position of G37, which is 3' to the anticodon sequence and whose modification is important for maintaining the reading frame fidelity. While the enzyme in bacteria is highly conserved and is encoded by the trmD gene, recent studies show that the counterpart of this enzyme in archaea and eukarya, encoded by the trm5 gene, is unrelated to trmD both in sequence and in structure. To further test this prediction, we seek to identify residues in the second class of tRNA(m1G37) methyl transferase that are required for catalysis. Such residues should provide mechanistic insights into the distinct structural origins of the two classes. Using the Trm5 enzyme of the archaeon Methanocaldococcus jannaschii (previously MJ0883) as an example, we have created mutants to test many conserved residues for their catalytic potential and substrate-binding capabilities with respect to both AdoMet and tRNA. We identified that the proline at position 267 (P267) is a critical residue for catalysis, because substitution of this residue severely decreases the kcat of the methylation reaction in steady-state kinetic analysis, and the k(chem) in single turnover kinetic analysis. However, substitution of P267 has milder effect on the Km and little effect on the Kd of either substrate. Because P267 has no functional side chain that can directly participate in the chemistry of methyl transfer, we suggest that its role in catalysis is to stabilize conformations of enzyme and substrates for proper alignment of reactive groups at the enzyme active site. Sequence analysis shows that P267 is embedded in a peptide motif that is conserved among the Trm5 family, but absent from the TrmD family, supporting the notion that the two families are descendants of unrelated protein structures.

Acquisition of an insertion peptide for efficient aminoacylation by a halophile tRNA synthetase.

Enzymes of halophilic organisms contain unusual peptide motifs that are absent from their mesophilic counterparts. The functions of these halophile-specific peptides are largely unknown. Here we have identified an unusual peptide that is unique to several halophile archaeal cysteinyl-tRNA synthetases (CysRS), which catalyze attachment of cysteine to tRNA(Cys) to generate the essential cysteinyl-tRNA(Cys) required for protein synthesis. This peptide is located near the active site in the catalytic domain and is highly enriched with acidic residues. In the CysRS of the extreme halophile Halobacterium species NRC-1, deletion of the peptide reduces the catalytic efficiency of aminoacylation by a factor of 100 that largely results from a defect in kcat, rather than the Km for tRNA(Cys). In contrast, maintaining the peptide length but substituting acidic residues in the peptide with neutral or basic residues has no major deleterious effect, suggesting that the acidity of the peptide is not important for the kcat of tRNA aminoacylation. Analysis of general protein structure under physiological high salt concentrations, by circular dichroism and by fluorescence titration of tRNA binding, indicates little change due to deletion of the peptide. However, the presence of the peptide confers tolerance to lower salt levels, and fluorescence analysis in 30% sucrose reveals instability of the enzyme without the peptide. We suggest that the stability associated with the peptide can be used to promote proper enzyme conformation transitions in various stages of tRNA aminoacylation that are associated with catalysis. The acquisition of the peptide by the halophilic CysRS suggests an enzyme adaptation to high salinity.

Distinct origins of tRNA(m1G37) methyltransferase.

The enzyme tRNA(m1G37) methyltransferase catalyzes the transfer of a methyl group from S-adenosyl-l-methionine (AdoMet) to the N1 position of G37 in the anticodon loop of a subset of tRNA. The modified guanosine is 3' to the anticodon and is important for maintenance of reading frame during decoding of genetic information. While the methyltransferase is well conserved in bacteria and is easily identified (encoded by the trmD gene), the identity of the enzyme in eukarya and archaea is less clear. Here, we report that the enzyme encoded by Mj0883 of Methanocaldococcus jannaschii is the archaeal counterpart of the bacterial TrmD. However, despite catalyzing the same reaction and displaying similar enzymatic properties, MJ0883 and bacterial TrmD are completely unrelated in sequence. The catalytic domain of MJ0883, when aligned with the five known structural folds (I-V) that have been described to bind AdoMet, is of the class I fold, similar to the ancient Rossmann fold that binds nucleotides. In contrast, the catalytic domain of the bacterial TrmD has the unusual class IV fold of a trefoil knot structure. Thus, both the sequence and structural arrangements of tRNA(m1G37) methyltransferase have distinct evolutionary origins among primary kingdoms, revealing an unexpected but remarkable non-orthologous gene displacement to achieve an important tRNA modification.

Aminoacylation of an unusual tRNA(Cys) from an extreme halophile.

The extreme halophile Halobacterium species NRC-1 overcomes external near-saturating salt concentrations by accumulating intracellular salts comparable to those of the medium. This raises the fundamental question of how halophiles can maintain the specificity of protein-nucleic acid interactions that are particularly sensitive to high salts in mesophiles. Here we address the specificity of the essential aminoacylation reaction of the halophile, by focusing on molecular recognition of tRNA(Cys) by the cognate cysteinyl-tRNA synthetase. Despite the high salt environments of the aminoacylation reaction, and despite an unusual structure of the tRNA with an exceptionally large dihydrouridine loop, we show that aminoacylation of the tRNA proceeds with a catalytic efficiency similar to that of its mesophilic counterparts. This is manifested by an essentially identical K(m) for tRNA to those of the mesophiles, and by recognition of the same nucleotide determinants that are conserved in evolution. Interestingly, aminoacylation of the halophile tRNA(Cys) is more closely related to that of bacteria than eukarya by placing a strong emphasis on features of the tRNA tertiary core. This suggests an adaptation to the highly negatively charged tRNA sugar-phosphate backbone groups that are the key elements of the tertiary core.

Association of an aminoacyl-tRNA synthetase with a putative metabolic protein in archaea.

Aminoacyl-tRNA synthetases are essential enzymes that catalyze attachment of amino acids to tRNAs for decoding of genetic information. In higher eukaryotes, several synthetases associate with non-synthetase proteins to form a high-molecular mass complex that may improve the efficiency of protein synthesis. This multi-synthetase complex is not found in bacteria. Here we describe the isolation of a non-synthetase protein from the archaeon Methanocaldococcus jannaschii that was copurified with prolyl-tRNA synthetase (ProRS). This protein, Mj1338, also interacts with several other tRNA synthetases and has an affinity for general tRNA, suggesting the possibility of forming a multi-synthetase complex. However, unlike the non-synthetase proteins in the eukaryotic complex, the protein Mj1338 is predicted to be a metabolic protein, related to members of the family of H(2)-forming N(5),N(10)-methylene tetrahydromethanopterin (5,10-CH(2)-H(4)MP) dehydrogenases that are involved in the one-carbon metabolism of the archaeon. The association of Mj1338 with ProRS, and with other components of the protein synthesis machinery, thus suggests the possibility of a closer link between metabolism and decoding in archaea than in eukarya or bacteria.