Peripheral Blood Gene Expression Changes Associated With Primary Graft Dysfunction After Lung Transplantation.

Recipient responses to primary graft dysfunction (PGD) after lung transplantation may have important implications to the fate of the allograft. We therefore evaluated longitudinal differences in peripheral blood gene expression in subjects with PGD. RNA expression was measured throughout the first transplant year in 106 subjects enrolled in the Clinical Trials in Organ Transplantation-03 study using a panel of 100 hypothesis-driven genes. PGD was defined as grade 3 in the first 72 posttransplant hours. Eighteen genes were differentially expressed over the first year based on PGD development, with significant representation from innate and adaptive immunity genes, with most differences identified very early after transplant. Sixteen genes were overexpressed in the blood of patients with PGD compared to those without PGD within 7 days of allograft reperfusion, with most transcripts encoding innate immune/inflammasome-related proteins, including genes previously associated with PGD. Thirteen genes were underexpressed in patients with PGD compared to those without PGD within 7 days of transplant, highlighted by T cell and adaptive immune regulation genes. Differences in gene expression present within 2 h of reperfusion and persist for days after transplant. Future investigation will focus on the long-term implications of these gene expression differences on the outcome of the allograft.

Gene set enrichment analysis identifies key innate immune pathways in primary graft dysfunction after lung transplantation.

We hypothesized alterations in gene expression could identify important pathways involved in transplant lung injury. Broncho alveolar lavage fluid (BALF) was sampled from donors prior to procurement and in recipients within an hour of reperfusion as part of the NIAID Clinical Trials in Organ Transplantation Study. Twenty-three patients with Grade 3 primary graft dysfunction (PGD) were frequency matched with controls based on donor age and recipient diagnosis. RNA was analyzed using the Human Gene 1.0 ST array. Normalized mRNA expression was transformed and differences between donor and postreperfusion values were ranked then tested using Gene Set Enrichment Analysis. Three-hundred sixty-two gene sets were upregulated, with eight meeting significance (familywise-error rate, FWER p-value <0.05), including the NOD-like receptor inflammasome (NLR; p < 0.001), toll-like receptors (TLR; p < 0.001), IL-1 receptor (p = 0.001), myeloid differentiation primary response gene 88 (p = 0.001), NFkB activation by nontypeable Haemophilus influenzae (p = 0.001), TLR4 (p = 0.008) and TLR 9 (p = 0.018). The top five ranked individual transcripts from these pathways based on rank metric score are predominantly present in the NLR and TLR pathways, including IL1ß (1.162), NLRP3 (1.135), IL1α (0.952), IL6 (0.931) and CCL4 (0.842). Gene set enrichment analyses implicate inflammasome-mediated and innate immune signaling pathways as key mediators of the development of PGD in lung transplant patients.

MicroRNA expression profiles of seminoma from paraffin-embedded formalin-fixed tissue.

In this study, we used microRNA (miRNA) microarrays in an unbiased screen for aberrantly expressed miRNAs in seminoma, a primitive type of germ cell tumor. Formalin-fixed and paraffin-embedded (FFPE) surgical samples from 11 cases of normal testicular tissue resected for nonneoplastic causes and from 11 cases of seminoma were assessed for miRNA expression. Normal testicular tissue and seminoma were paired by race. We found 112 miRNAs to be differentially expressed between seminoma and normal testicular tissue; 52 miRNAs were overexpressed, and 60, downregulated in seminoma. We did not observe significant differences between black and white populations in our race-paired study. The upregulation of the expression of hsa-mir-21, hsa-mir-372, hsa-mir-373, has-mir-221, and hsa-mir-222 was validated by reverse transcription and real-time PCR. Hsa-mir-372 was upregulated around 1,270-fold (95 % confidence interval (CI) 525.2-3,064.8; p = 8.1e-5 by Mann-Whitney U test). Hsa-mir-373 was upregulated around 1,530-fold (95 % CI 620.5-3,785.6; p = 8.0e-5 by Mann-Whitney U test), consistent with previous reports, indicating that the miRNAs in FFPE are well preserved, and FFPE can be a valuable source for the miRNA study of seminoma. In addition, expression of hsa-mir-21 (12.2-fold, 0.0095), hsa-mir-221 (3.8-fold, 0.014) and hsa-mir-222 (3.8-fold, 0.019) was found elevated in seminoma compared to normal testicular tissue.

Antibiotic-based selection for bacterial genes that are specifically induced during infection of a host.

We have recently described a genetic system, termed in vivo expression technology (IVET), that uses an animal as a selective medium to identify genes that pathogenic bacteria specifically express when infecting host tissues. Here, the potential utility of the IVET approach has been expanded with the development of a transcriptional-fusion vector, pIVET8, which uses antibiotics resistance as the basis for selection in host tissues. pIVET8 contains promoterless chloramphenicol acetyltransferase (cat) and lacZY genes. A pool of Salmonella typhimurium clones carrying random cat-lac transcriptional fusions, produced with pIVET8, was used to infect BALB/c mice that were subsequently treated with intraperitoneal injections of chloramphenicol. Strains that survived the selection by expressing the cat gene in the animal were then screened for those that had low-level lacZY expression on laboratory medium. These strains carry operon fusions to genes that are specifically induced in vivo (ivi genes). One of the ivi genes identified (fadB) encodes an enzyme involved in fatty acid oxidation, suggesting that this enzyme might contribute to the metabolism of bactericidal or proinflammatory host fatty acids. The pIVET8-based selection system was also used to identify S. typhimurium genes that are induced in cultured macrophages. The nature of ivi gene products will provide a more complete understanding of the metabolic, physiological, and genetic factors that contribute to the virulence of microbial pathogens.

The N-end rule in Escherichia coli: cloning and analysis of the leucyl, phenylalanyl-tRNA-protein transferase gene aat.

The N-end rule relates the in vivo half-life of a protein to the identity of its N-terminal residue. Distinct versions of the N-end rule operate in bacteria, fungi, and mammals. We report the cloning and analysis of aat, the Escherichia coli gene that encodes leucyl, phenylalanyl-tRNA-protein transferase (L/F-transferase), a component of the bacterial N-end rule pathway. L/F-transferase is required for the degradation of N-end rule substrates bearing an N-terminal arginine or lysine. The aat gene maps to the 19-min region of the E. coli chromosome and encodes a 234-residue protein whose sequence lacks significant similarities to sequences in data bases. In vitro, L/F-transferase catalyzes the posttranslational conjugation of leucine or phenylalanine to the N termini of proteins that bear an N-terminal arginine or lysine. However, the isolation and sequence analysis of a beta-galactosidase variant engineered to expose an N-terminal arginine in vivo revealed the conjugation of leucine but not of phenylalanine to the N terminus of the beta-galactosidase variant. Thus, the specificity of L/F-transferase in vivo may be greater than that in vitro. The aat gene is located approximately 1 kb from clpA, which encodes a subunit of ATP-dependent protease Clp. Although both aat and clpA are required for the degradation of certain N-end rule substrates, their nearly adjacent genes are convergently transcribed. The aat gene lies downstream of an open reading frame that encodes a homolog of the mammalian multidrug resistance P glycoproteins.

Ubiquitin-specific proteases of Saccharomyces cerevisiae. Cloning of UBP2 and UBP3, and functional analysis of the UBP gene family.

In eukaryotes, both natural and engineered ubiquitin (Ub) fusions to itself or other proteins are cleaved by processing proteases after the last (Gly76) residue of ubiquitin. YUH1 and UBP1, the genes for two ubiquitin-specific proteases of the yeast Saccharomyces cerevisiae, have been cloned previously and shown to encode nonhomologous proteins. Using an Escherichia coli-based genetic screen, we have isolated two other yeast genes for ubiquitin-specific proteases, named UBP2 and UBP3. Ubp2 (1,264 residues), Ubp3 (912 residues), and the previously cloned Ubp1 (809 residues) are largely dissimilar except for two short regions containing Cys and His which encompass their putative active sites. Neither of these proteases has sequence similarities to Yuh1. Both Ubp2 and the previously identified Ubp1 cleave in vitro at the C terminus of the ubiquitin moiety in natural and engineered fusions irrespective of their size, poly-Ub being the exception. However, both Ubp1 and Ubp2 are also capable of cleaving poly-Ub when coexpressed with it in E. coli, suggesting that such cleavage is largely cotranslational. Although inactive in E. coli extracts, Ubp3 was active with all of the tested ubiquitin fusions except poly-Ub when coexpressed with them in E. coli. Null yuh1 ubp1 ubp2 ubp3 quadruple mutants are viable and retain the ability to deubiquitinate ubiquitin fusions, indicating the presence of at least one more ubiquitin-specific processing protease in S. cerevisiae.

The N-end rule in bacteria.

The N-end rule relates the in vivo half-life of a protein to the identity of its amino-terminal residue. Distinct versions of the N-end rule operate in all eukaryotes examined. It is shown that the bacterium Escherichia coli also has the N-end rule pathway. Amino-terminal arginine, lysine, leucine, phenylalanine, tyrosine, and tryptophan confer 2-minute half-lives on a test protein; the other amino-terminal residues confer greater than 10-hour half-lives on the same protein. Amino-terminal arginine and lysine are secondary destabilizing residues in E. coli because their activity depends on their conjugation to the primary destabilizing residues leucine or phenylalanine by leucine, phenylalanine-transfer RNA-protein transferase. The adenosine triphosphate-dependent protease Clp (Ti) is required for the degradation of N-end rule substrates in E. coli.

Cloning and functional analysis of the ubiquitin-specific protease gene UBP1 of Saccharomyces cerevisiae.

In eukaryotes, both natural and engineered fusions of ubiquitin to itself or other proteins are cleaved by processing proteases after the last (Gly76) residue of ubiquitin. Using the method of sib selection, and taking advantage of the fact that bacteria such as Escherichia coli lack ubiquitin-specific enzymes, we have cloned a gene, named UBP1, of the yeast Saccharomyces cerevisiae that encodes a ubiquitin-specific processing protease. With the exception of polyubiquitin, the UBP1 protease cleaves at the carboxyl terminus of the ubiquitin moiety in natural and engineered fusions irrespective of their size or the presence of an amino-terminal ubiquitin extension. These properties of UBP1 distinguish it from the previously cloned yeast protease YUH1, which deubiquitinates relatively short ubiquitin fusions but is virtually inactive with longer fusions such as ubiquitin-beta-galactosidase. The amino acid sequence of the 809-residue UBP1 lacks significant similarities to other known proteins, including the 236-residue YUH1 protease. Null ubp1 mutants are viable, and retain the ability to deubiquitinate ubiquitin-beta-galactosidase, indicating that the family of ubiquitin-specific proteases in yeast is not limited to UBP1 and YUH1.

Universality and structure of the N-end rule.

Our previous work has shown that, in the yeast Saccharomyces cerevisiae, any of the eight stabilizing amino-terminal residues confers a long (greater than 20 h) half-life on a test protein beta-galactosidase (beta gal), whereas 12 destabilizing amino-terminal residues confer on beta gal half-lives from less than 3 min to 30 min. We now show that an analogous single-residue code (the N-end rule) operates in an in vitro system derived from mammalian reticulocytes. We also show that the N-end rule has a hierarchical structure. Specifically, amino-terminal Glu and Asp (and also Cys in reticulocytes) are secondary destabilizing residues in that they are destabilizing through their ability to be conjugated to primary destabilizing residues such as Arg. Amino-terminal Gln and Asn are tertiary destabilizing residues in that they are destabilizing through their ability to be converted, via selective deamidation, into secondary destabilizing residues Glu and Asp. Furthermore, in reticulocytes, distinct types of the N-end-recognizing activity are shown to be specific for three classes of primary destabilizing residues: basic (Arg, Lys, His), bulky hydrophobic (Phe, Leu, Trp, Tyr), and small uncharged (Ala, Ser, Thr). Features of the N-end rule in reticulocytes suggest that the exact form of the N-end rule may depend on the cell's physiological state, thereby providing a mechanism for selective destruction of preexisting proteins upon cell differentiation.

A multiubiquitin chain is confined to specific lysine in a targeted short-lived protein.

The ubiquitin-dependent degradation of a test protein beta-galactosidase (beta gal) is preceded by ubiquitination of beta gal. The many (from 1 to more than 20) ubiquitin moieties attached to a molecule of beta gal occur as an ordered chain of branched ubiquitin-ubiquitin conjugates in which the carboxyl-terminal Gly76 of one ubiquitin is jointed to the internal Lys48 of an adjacent ubiquitin. This multiubiquitin chain is linked to one of two specific Lys residues in beta gal. These same Lys residues have been identified by molecular genetic analysis as components of the aminoterminal degradation signal in beta gal. The experiments with ubiquitin mutated at its Lys48 residue indicate that the multiubiquitin chain in a targeted protein is essential for the degradation of the protein.

Monocyte adhesion to subendothelial components.

Human monocytes have been shown to penetrate the endothelial layer of large blood vessels and to adhere to the subendothelial basement membrane. To determine the active components of this process, we have studied the ability of monocytes to adhere to isolated components of the subendothelial matrix. Using a quantitative dot-blot adhesion assay, we find that monocytes adhere preferentially to immobilized laminin and elastin. The monocytes adhere less well to fibronectin and bind poorly or not at all to collagen types I and IV, or to heparan sulfate. Monocyte binding to elastin requires an intact, crosslinked molecule as no binding was observed to soluble, acid-alcohol elastin extracts, to pepsin or elastase digests of elastin, to tropoelastin monomer, or to desmosine/isodesmosine crosslinks. Similar binding profiles to elastin, laminin, and fibronectin were seen with the established human leukocyte cell line U937. The promyelocytic cell line HL60 adhered equally well to laminin but showed slightly reduced adhesion to elastin when compared with the fresh monocytes or U937 cells. Freshly isolated human erythrocytes did not demonstrate significant adhesion to fibronectin, laminin, or elastin.