Associations of the Methylation Levels of NFAT5, PVT1, RPS6KA1, and MIB1 with Steroid-Resistant Asthma.

BACKGROUND: This study detected the methylation levels of nuclear factor-5 (NFAT5), PVT1, ribosomal protein S6 kinase A-1 (RPS6KA1), and MIB1 in patients with steroid-resistant asthma (SRA) and explored their associations with SRA. METHODS: In our pilot study, we found abnormal methylation of NFAT5, PVT1, RPS6KA1, and MIB1 in SRA patients according to genome-wide methylation screening. This study expanded the sample size to further validate the results of the pilot study. Twenty patients with SRA, 20 patients with bronchial asthma, and 20 healthy volunteers constituted the SRA group, asthma control group, and healthy control group, respectively. The clinical data of all the participants were collected. Peripheral blood was taken for DNA extraction. The methylation loci and levels of NFAT5, PVT1, RPS6KA1, and MIB1 were detected using the Sequenom MassARRAY Nanodispenser RS1000. Data were processed and analyzed with SPSS 22.0 software. RESULTS: There were 24 CpG loci detected in the NFAT5 segment 7 in the PVT1 segment, 4 in the RPS6KA1 segment, and 3 in the MIB1 segment. Among these genes, RPS6KA exhibited hypomethylation in the SRA group, which showed significant differences at the CpG_1, CpG_2, and CpG_3 loci compared with the other groups (p < 0.05). No significant differences in the methylation levels of NFAT5, PVT1, and MIB1 were observed among the groups (p > 0.05). CONCLUSIONS: RPS6KA1 is hypomethylated in SRA patients, which may play a role in the development of SRA via the MAPK signaling pathway. However, the influence of the methylation of NFAT5, PVT1, and MIB1 on SRA development remains to be explored.

Graph based analysis for gene segment organization In a scrambled genome.

DNA recombinant processes can involve gene segments that overlap or interleave with gene segments of another gene. Such gene segment appearances relative to each other are called here gene segment organization. We use graphs to represent the gene segment organization in a chromosome locus. Vertices of the graph represent contigs resulting after the recombination and the edges represent the gene segment organization prior to rearrangement. To each graph we associate a vector whose entries correspond to graph properties, and consider this vector as a point in a higher dimensional Euclidean space such that cluster formations and analysis can be performed with a hierarchical clustering method. The analysis is applied to a recently sequenced model organism Oxytricha trifallax, a species of ciliate with highly scrambled genome that undergoes massive rearrangement process after conjugation. The analysis shows some emerging star-like graph structures indicating that segments of a single gene can interleave, or even contain all of the segments from fifteen or more other genes in between its segments. We also observe that as many as six genes can have their segments mutually interleaving or overlapping.

Immune receptor recombinations from breast cancer exome files, independently and in combination with specific HLA alleles, correlate with better survival rates.

PURPOSE: Immune characterizations of cancers, including breast cancer, have led to information useful for prognoses and are considered to be important in the future of refining the use of immunotherapies, including immune checkpoint inhibitor therapies. In this study, we sought to extend these characterizations with genomics approaches, particularly with cost-effective employment of exome files. METHODS: By recovery of immune receptor recombination reads from the cancer genome atlas (TCGA) breast cancer dataset, we observed associations of these recombinations with T-cell and B-cell biomarkers and with distinct survival rates. RESULTS: Recovery of TRD or IGH recombination reads was associated with an improved disease-free survival (p = 0.047 and 0.045, respectively). Determination of the HLA types using the exome files allowed matching of T-cell receptor V- and J-gene segment usage with specific HLA alleles, in turn allowing a refinement of the association of immune receptor recombination read recoveries with survival. For example, the TRBV7, HLA-C*07:01 combination represented a significantly worse, disease-free outcome (p = 0.014) compared to all other breast cancer samples. By direct comparisons of distinct TRB gene segment usage, HLA allele combinations revealed breast cancer subgroups, within the entire TCGA breast cancer dataset with even more dramatic survival distinctions. CONCLUSIONS: In sum, the use of exome files for recovery of adaptive immune receptor recombination reads, and the simultaneous determination of HLA types, has the potential of advancing the use of immunogenomics for immune characterization of breast tumor samples.

Automated analysis of high-throughput B-cell sequencing data reveals a high frequency of novel immunoglobulin V gene segment alleles.

Individual variation in germline and expressed B-cell immunoglobulin (Ig) repertoires has been associated with aging, disease susceptibility, and differential response to infection and vaccination. Repertoire properties can now be studied at large-scale through next-generation sequencing of rearranged Ig genes. Accurate analysis of these repertoire-sequencing (Rep-Seq) data requires identifying the germline variable (V), diversity (D), and joining (J) gene segments used by each Ig sequence. Current V(D)J assignment methods work by aligning sequences to a database of known germline V(D)J segment alleles. However, existing databases are likely to be incomplete and novel polymorphisms are hard to differentiate from the frequent occurrence of somatic hypermutations in Ig sequences. Here we develop a Tool for Ig Genotype Elucidation via Rep-Seq (TIgGER). TIgGER analyzes mutation patterns in Rep-Seq data to identify novel V segment alleles, and also constructs a personalized germline database containing the specific set of alleles carried by a subject. This information is then used to improve the initial V segment assignments from existing tools, like IMGT/HighV-QUEST. The application of TIgGER to Rep-Seq data from seven subjects identified 11 novel V segment alleles, including at least one in every subject examined. These novel alleles constituted 13% of the total number of unique alleles in these subjects, and impacted 3% of V(D)J segment assignments. These results reinforce the highly polymorphic nature of human Ig V genes, and suggest that many novel alleles remain to be discovered. The integration of TIgGER into Rep-Seq processing pipelines will increase the accuracy of V segment assignments, thus improving B-cell repertoire analyses.

In vitro and in vivo characterization of a novel H1N1/2009 influenza virus reassortant with an NS gene from a highly pathogenic H5N1 virus, isolated from a human.

The triple-reassortant H1N1/2009 influenza A virus, which caused the first influenza pandemic of the 21st century, is generally associated with mild disease and a relatively low mortality rate comparable to that of seasonal influenza virus outbreaks. There is a growing concern about the potential for reassortment between the low-mortality H1N1/2009 and other high-mortality influenza viruses. Here, we describe and characterize a novel reassortant H1N1/2009 influenza virus, isolated from a human sample, that contained an NS gene from a highly pathogenic H5N1 virus. We evaluated the effect of the acquired NS gene on viral virulence both in vitro and in vivo and found that the novel NS-reassorted influenza virus replicated well in different cell lines and several organs of BALB/c mice without prior adaption and induced a cytokine imbalance. Therefore, there is a continued risk for further reassortment of the H1N1/2009 virus, and therefore, systematic surveillance should be enhanced to prepare for the next possible pandemic.

Gene Segment Interactions Can Drive the Emergence of Dominant Yet Suboptimal Gene Constellations During Influenza Virus Reassortment.

A segmented genome enables influenza virus to undergo reassortment when two viruses infect the same cell. Although reassortment is involved in the creation of pandemic influenza strains and is routinely used to produce influenza vaccines, our understanding of the factors that drive the emergence of dominant gene constellations during this process is incomplete. Recently, we defined a spectrum of interactions between the gene segments of the A/Udorn/307/72 (H3N2) (Udorn) strain that occur within virus particles, a major interaction being between the NA and PB1 gene segments. In addition, we showed that the Udorn PB1 is preferentially incorporated into reassortant viruses that express the Udorn NA. Here we use an influenza vaccine seed production model where eggs are coinfected with Udorn and the high yielding A/Puerto Rico/8/34 (H1N1) (PR8) virus and track viral genotypes through the reassortment process under antibody selective pressure to determine the impact of Udorn NA-PB1 co-selection. We discovered that 86% of the reassortants contained the PB1 from the Udorn parent after the initial co-infection and this bias towards Udorn PB1 was maintained after two further passages. Included in these were certain gene constellations containing Udorn HA, NA, and PB1 that confered low replicative fitness yet rapidly became dominant at the expense of more fit progeny, even when co-infection ratios of the two viruses favoured PR8. Fitness was not compromised, however, in the corresponding reassortants that also contained Udorn NP. Of particular note is the observation that relatively unfit reassortants could still fulfil the role of vaccine seed candidates as they provided high haemagglutinin (HA) antigen yields through co-production of non-infectious particles and/or by more HA molecules per virion. Our data illustrate the dynamics and complexity of reassortment and highlight how major gene segment interactions formed during packaging, in addition to antibody pressure, initially restrict the reassortant viruses that are formed.

Preimmune Control of the Variance of TCR CDR-B3: Insights Gained From Germline Replacement of a TCR Dß Gene Segment With an Ig D H Gene Segment.

We have previously shown that the sequence of the immunoglobulin diversity gene segment (D H ) helps dictate the structure and composition of complementarity determining region 3 of the immunoglobulin heavy chain (CDR-H3). In order to test the role of germline D sequence on the diversity of the preimmune TCRß repertoire of T cells, we generated a mouse with a mutant TCRß DJC locus wherein the Dß2-Jß2 gene segment cluster was deleted and the remaining diversity gene segment, Dß1 (IMGT:TRDB1), was replaced with DSP2.3 (IMGT:IGHD2-02), a commonly used B cell immunoglobulin D H gene segment. Crystallographic studies have shown that the length and thus structure of TCR CDR-B3 places amino acids at the tip of CDR-B3 in a position to directly interact with peptide bound to an MHC molecule. The length distribution of complementarity determining region 3 of the T cell receptor beta chain (CDR-B3) has been proposed to be restricted largely by MHC-specific selection, disfavoring CDR-B3 that are too long or too short. Here we show that the mechanism of control of CDR-B3 length depends on the Dß sequence, which in turn dictates exonucleolytic nibbling. By contrast, the extent of N addition and the variance of created CDR3 lengths are regulated by the cell of origin, the thymocyte. We found that the sequence of the D and control of N addition collaborate to bias the distribution of CDR-B3 lengths in the pre-immune TCR repertoire and to focus the diversity provided by N addition and the sequence of the D on that portion of CDR-B3 that is most likely to interact with the peptide that is bound to the presenting MHC.

Detection and Molecular Characterization of Picobirnaviruses (PBVs) in the Mongoose: Identification of a Novel PBV Using an Alternative Genetic Code.

We report high rates of detection (35.36%, 29/82) of genogroup-I (GI) picobirnaviruses (PBVs) in non-diarrheic fecal samples from the small Indian mongoose (Urva auropunctata). In addition, we identified a novel PBV-like RNA-dependent RNA polymerase (RdRp) gene sequence that uses an alternative mitochondrial genetic code (that of mold or invertebrate) for translation. The complete/nearly complete gene segment-2/RdRp gene sequences of seven mongoose PBV GI strains and the novel PBV-like strain were obtained by combining a modified non-specific primer-based amplification method with conventional RT-PCRs, facilitated by the inclusion of a new primer targeting the 3'-untranslated region (UTR) of PBV gene segment-2. The mongoose PBV and PBV-like strains retained the various features that are conserved in gene segment-2/RdRps of other PBVs. However, high genetic diversity was observed among the mongoose PBVs within and between host species. This is the first report on detection of PBVs in the mongoose. Molecular characterization of the PBV and PBV-like strains from a new animal species provided important insights into the various features and complex diversity of PBV gene segment-2/putative RdRps. The presence of the prokaryotic ribosomal binding site in the mongoose PBV genomes, and analysis of the novel PBV-like RdRp gene sequence that uses an alternative mitochondrial genetic code (especially that of mold) for translation corroborated recent speculations that PBVs may actually infect prokaryotic or fungal host cells.

Classification and enzyme kinetics of formate dehydrogenases for biomanufacturing via CO2 utilization.

The reversible interconversion of formate (HCOO-) and carbon dioxide (CO2) is catalyzed by formate dehydrogenase (FDH, EC 1.17.1.9). This enzyme can be used as a first step in the utilization of CO2 as carbon substrate for production of high-in-demand chemicals. However, comparison and categorization of the very diverse group of FDH enzymes has received only limited attention. With specific emphasis on FDH catalyzed CO2 reduction to HCOO-, we present a novel classification scheme for FDHs based on protein sequence alignment and gene organization analysis. We show that prokaryotic FDHs can be neatly divided into six meaningful sub-types. These sub-types are discussed in the context of overall structural composition, phylogeny of the gene segment organization, metabolic role, and catalytic properties of the enzymes. Based on the available literature, the influence of electron donor choice on the efficacy of FDH catalyzed CO2 reduction is quantified and compared. This analysis shows that methyl viologen and hydrogen are several times more potent than NADH as electron donors. Hence, the new FDH classification scheme and the electron donor analysis provide an improved base for developing FDH-facilitated CO2 reduction as a viable step in the utilization of CO2 as carbon source for green production of chemicals.

High detection rates of picobirnaviruses in free roaming rats (Rattus spp.): Molecular characterization of complete gene segment-2.

We report here high rates of detection (54%, 21/39) of picobirnaviruses (PBVs) in feces/intestinal contents of free roaming, apparently healthy rats (Rattus spp.) on the Caribbean island of St. Kitts. One of the PBV strains, strain PBV/Rat/KNA/Rat9/2017, was molecularly characterized for complete gene segment-2. To determine the nucleotide (nt) sequence of full-length gene segment-2, the 5'- and 3'- portions of gene segment-2 of strain Rat9 containing an overlapping region were amplified using a non-specific primer-based amplification method with modifications. The complete gene segment-2 of PBV strain Rat9 was 1730 bp in length, encoding a putative RNA-dependent RNA polymerase (RdRp) of 535 amino acid (aa). By nt and deduced aa sequence identities and phylogenetic analysis, the complete gene segment-2 of strain Rat9 exhibited high genetic diversity with those of PBVs from other host species. On the other hand, 5'- and 3'- end nt sequences of gene segment-2, and the three domains of putative RdRp that are conserved in PBVs were retained in strain Rat9. To our knowledge, this is the first report on molecular characterization of complete gene segment-2 of a PBV strain from Rattus spp., providing important insights into the putative RdRp, and genetic diversity and evolution of PBV in rats. The high detection rates of PBV in free roaming rats on St. Kitts emphasizes the importance of further studies on epidemiology and genetic makeup of PBVs in Rattus spp.

Detection of picobirnaviruses in vervet monkeys (Chlorocebus sabaeus): Molecular characterization of complete genomic segment-2.

During 2014-2015, 270 fecal samples were collected from non-diarrheic, captive and wild African green monkeys (AGMs) on the island of St. Kitts, Caribbean region. By RNA-PAGE, picobirnaviruses (PBVs) were detected in sixteen captive AGMs. By RT-PCR and sequencing of partial gene segment-2, PBVs in 15 of these 16 samples were assigned to genogroup-I. The full-length nucleotide (nt) sequence of gene segment-2 of one of the genogroup-I PBV strains, strain PBV/African green monkey/KNA/016593/2015, was obtained using a non-specific primer-based amplification method with modifications. Gene segment-2 of strain 016593 was 1707bp long, and encoded a putative RNA-dependent RNA polymerase (RdRp) of 538aa. Furthermore, the nearly complete gene segment-2 sequences of three other AGM PBV strains were determined using primers designed from gene segment-2 sequence of 016593. The gene segment-2 of the 4 AGM PBV strains were almost identical to each other, and exhibited a high degree of genetic diversity (maximum nt and deduced aa sequence identities of 66.4% and 65.3%, respectively) with those of PBVs from other host species. The 5'- and 3'- (except for one mismatch) end nt sequences and the three domains of RdRps were retained in the AGM PBV strains. To our knowledge, this is the first report on detection, and molecular characterization of complete gene segment-2 of PBVs in vervet monkeys. PBVs were detected for the first time from the Caribbean region.

Molecular characterization of complete genomic segment-2 of picobirnavirus strains detected in a cat and a dog.

We report here molecular characterization of complete genomic segment-2 of picobirnavirus (PBV) strains PBV/Cat/KNA/K40/2014 and PBV/Dog/KNA/RVC7/2015 detected in a cat (Felis catus) and a dog (Canis lupus familiaris), respectively, on the Caribbean island of St. Kitts. To obtain the full-length nucleotide (nt) sequence of gene segment-2 of the canine and feline PBV strains, the 5'- and 3'- portions of gene segment-2 containing an overlapping region were amplified using a non-specific primer-based amplification method with modifications. The complete gene segment-2 of feline PBV strain K40 and canine PBV strain RVC7 was 1784nt and 1689nt long, respectively, and encoded a putative RNA-dependent RNA polymerase (RdRp) of 534 amino acid (aa) and 531 aa, respectively. The complete gene segment-2 of strains K40 and RVC7 exhibited a high degree of genetic diversity between themselves, and with those of PBVs from other host species. On the other hand, both the canine and feline PBV strains retained the 5'- and 3'- end nucleotide sequences and the three domains of putative RdRp that are conserved in PBVs. To our knowledge, this is the first report on molecular characterization of complete gene segment-2 of PBV strains detected in cats and dogs, allowing us to study the features of putative RdRps of PBVs in these host species, and providing important insights into the genetic makeup and evolution of feline and canine PBV strains. PBVs were detected for the first time in cats and dogs from the Caribbean region.

Infectious Salmon Anaemia Virus (ISAV) RNA Binding Protein Encoded by Segment 8 ORF2 and Its Interaction with ISAV and Intracellular Proteins.

Infectious salmon anaemia virus (ISAV) is an orthomyxovirus infecting salmonid fish. The virus is adapted to low temperature and has a replication optimum between 10-15 °C. In this study the subcellular localization and protein interactions for the protein encoded by the largest open reading frame of gene segment 8 (s8ORF2) were investigated. In ISAV infected cells the s8ORF2 protein was found mainly in the cytosol but a minor fraction of cells expressed the protein in the nucleus as well. Green fluorescent protein-tagged s8ORF2 did not leak out of the cell when the plasma membrane was permeabilized, suggesting interactions with intracellular structural components. The s8ORF2 protein exists both as monomer and homodimer, and co-immunoprecipitation experiments strongly suggests it binds to the ISAV fusion-, nucleo- and matrix proteins. Two versions of s8ORF2 were detected with apparent molecular weights of 24-26 and 35 kDa in lysates of infected cells. The 35 kDa type is an early viral protein while the smaller version appears during the later phases of infection. The 24-26 kDa type was also the predominant form in viral particles. The s8ORF2 protein has previously been shown to bind RNA and interfere with interferon induction and signaling. Here we found that a fraction of the s8ORF2 protein pool in infected cells is likely to be conjugated to the interferon stimulated gene 15 (ISG15) and ubiquitin. Furthermore, several endogenous proteins pulled down by the s8ORF2 protein were identified by liquid chromatography mass spectrometry (LC-MS).

The role of evolutionarily conserved germ-line DH sequence in B-1 cell development and natural antibody production.

Because of N addition and variation in the site of VDJ joining, the third complementarity-determining region of the heavy chain (CDR-H3) is the most diverse component of the initial immunoglobulin antigen-binding site repertoire. A large component of the peritoneal cavity B-1 cell component is the product of fetal and perinatal B cell production. The CDR-H3 repertoire is thus depleted of N addition, which increases dependency on germ-line sequence. Cross-species comparisons have shown that DH gene sequence demonstrates conservation of amino acid preferences by reading frame. Preference for reading frame 1, which is enriched for tyrosine and glycine, is created both by rearrangement patterns and by pre-BCR and BCR selection. In previous studies, we have assessed the role of conserved DH sequence by examining peritoneal cavity B-1 cell numbers and antibody production in BALB/c mice with altered DH loci. Here, we review our finding that changes in the constraints normally imposed by germ-line-encoded amino acids within the CDR-H3 repertoire profoundly affect B-1 cell development, especially B-1a cells, and thus natural antibody immunity. Our studies suggest that both natural and somatic selection operate to create a restricted B-1 cell CDR-H3 repertoire.