Eleanor L. Marshall scite author profile

The complex repertoire of immune receptors generated by B and T cells enables recognition of diverse threats to the host organism. Here, we show that massively parallel DNA sequencing of rearranged immune receptor loci can provide direct detection and tracking of immune diversity and expanded clonal lymphocyte populations in physiological and pathological contexts. DNA was isolated from blood and tissue samples, a series of redundant primers was used to amplify diverse DNA rearrangements, and the resulting mixtures of bar-coded amplicons were sequenced with long-read ultradeep sequencing. Individual DNA molecules were then characterized on the basis of DNA segments that had been joined to make a functional (or nonfunctional) immune effector. Current experimental designs can accommodate up to 150 samples in a single sequence run, with the depth of sequencing sufficient to identify stable and dynamic aspects of the immune repertoire in both normal and diseased circumstances. These data provide a high-resolution picture of immune spectra in normal individuals and in patients with hematological malignancies, illuminating, in the latter case, both the initial behavior of clonal tumor populations and the later suppression or reemergence of such populations after treatment.

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Individual Variation in the Germline Ig Gene Repertoire Inferred from Variable Region Gene Rearrangements

Boyd

Gaëta²,

Jackson

et al. 2010

240

297

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Individual variation in the Ig germline gene repertoire leads to individual differences in the combinatorial diversity of the Ab repertoire, but the study of such variation has been problematic. The application of high-throughput DNA sequencing to the study of rearranged Ig genes now makes this possible. The sequencing of thousands of VDJ rearrangements from an individual, either from genomic DNA or expressed mRNA, should allow their germline IGHV, IGHD, and IGHJ repertoires to be inferred. In addition, where previously mere glimpses of diversity could be gained from sequencing studies, new large data sets should allow the rearrangement frequency of different genes and alleles to be seen with clarity. We analyzed the DNA of 108,210 human IgH chain rearrangements from 12 individuals and determined their individual IGH genotypes. The number of reportedly functional IGHV genes and allelic variants ranged from 45 to 60, principally because of variable levels of gene heterozygosity, and included 14 previously unreported IGHV polymorphisms. New polymorphisms of the IGHD3-16 and IGHJ6 genes were also seen. At heterozygous loci, remarkably different rearrangement frequencies were seen for the various IGHV alleles, and these frequencies were consistent between individuals. The specific alleles that make up an individual’s Ig genotype may therefore be critical in shaping the combinatorial repertoire. The extent of genotypic variation between individuals is highlighted by an individual with aplastic anemia who appears to lack six contiguous IGHD genes on both chromosomes. These deletions significantly alter the potential expressed IGH repertoire, and possibly immune function, in this individual.

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Human Responses to Influenza Vaccination Show Seroconversion Signatures and Convergent Antibody Rearrangements

Jackson

Liu

Roskin

et al. 2014

Cell Host & Microbe

240

238

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Summary B cells produce a diverse antibody repertoire by undergoing gene rearrangements. Pathogen exposure induces the clonal expansion of B cells expressing antibodies that can bind the infectious agent. To assess human B cell responses to trivalent seasonal influenza and monovalent pandemic H1N1 vaccination, we sequenced gene rearrangements encoding the immunoglobulin heavy chain, a major determinant of epitope recognition. The magnitude of B cell clonal expansions correlates with an individual’s secreted antibody response to the vaccine and the expanded clones are enriched for those expressing influenza-specific mAbs. Additionally, B cell responses to pandemic influenza H1N1 vaccination and infection in different people show a prominent family of convergent antibody heavy chain gene rearrangements specific to influenza antigens. These results indicate that microbes can induce specific signatures of immunoglobulin gene rearrangements and that pathogen exposure can potentially be assessed from B cell repertoires.

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Effects of Aging, Cytomegalovirus Infection, and EBV Infection on Human B Cell Repertoires

et al. 2014

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Elderly humans show decreased humoral immunity to pathogens and vaccines, yet the effects of aging on B cells are not fully known. Chronic viral infection by cytomegalovirus (CMV) is implicated as a driver of clonal T cell proliferations in some aging humans, but whether CMV or Epstein-Barr virus (EBV) infection contributes to alterations in the B cell repertoire with age is unclear. We have used high-throughput DNA sequencing of immunoglobulin heavy chain (IGH) gene rearrangements to study the B cell receptor repertoires over two successive years in 27 individuals ranging in age from 20 to 89 years. Some features of the B cell repertoire remain stable with age, but elderly subjects show increased numbers of B cells with long CDR3 regions, a trend toward accumulation of more highly mutated IgM and IgG immunoglobulin genes, and persistent clonal B cell populations in the blood. Seropositivity for CMV or EBV infection alters B cell repertoires, regardless of the individual's age: EBV infection correlates with the presence of persistent clonal B cell expansions, while CMV infection correlates with the proportion of highly mutated antibody genes. These findings isolate effects of aging from those of chronic viral infection on B cell repertoires, and provide a baseline for understanding human B cell responses to vaccination or infectious stimuli.

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Identification of a Rapid Mammalian Deadenylation-Dependent Decay Pathway and Its Inhibition by a Viral RNA Element

et al. 2006

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Cellular RNAs are subject to quality-control pathways that insure the fidelity of gene expression. We previously identified a 79 nt element, the ENE, that is essential for the nuclear accumulation of a viral polyadenylated nuclear (PAN) RNA. Here, we show that intron-less polyadenylated transcripts such as PAN RNA and beta-globin cRNA exhibit two-component exponential decay kinetics in which some transcripts are rapidly degraded (t(1/2) = approximately 15 min) while others decay more slowly (t(1/2) = approximately 3 hr). Inclusion of the ENE protects such transcripts from rapid decay in a poly(A)-dependent fashion. The ENE inhibits deadenylation and decay in nuclear extract and prevents deadenylation of naked RNA by a purified deadenylase, likely through snoRNA-like intramolecular hybridization with the poly(A) tail. The ENE causes increased accumulation of splicing-defective beta-globin pre-mRNAs in vivo. We propose that the ENE-controlled rapid-decay mechanism for polyadenylated transcripts comprises a nuclear pre-mRNA surveillance system in mammalian cells.

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