Positive selection of Tcrb-V10b+ T cells

The Tcrb-V10b⁺ T cell population has been examined with a newly established antibody, KT10b, specific for Tcrb-V10b but not Tcrb-V10a. H-2E⁺ mice have higher levels of Tcrb-V10b⁺ T cells (4.3%–11.%) than H-2E^– mice (2.2%–4.9%). This difference appears to be determined by levels of Tcrb-V10b⁺ T cells in the CD4 population. F₁ mice between H-2E⁺ and H-2E^– mice dominantly express higher levels of Tcrb-V10b⁺ T cells. [NOD (E–) x (NOD x A (E⁺))F₁] backcross mice show positive selection of Tcrb-V10b⁺ CD4⁺ T cells by H-2E. On the other hand other backcross analyses reveal positive selection of Tcrb-V10b⁺ CD8⁺ T cells by certain major histocompatibility class I molecules. Involvement of non-H-2 antigens in these positive selections remain to be determined. Address correspondence and offprint requests to: K. Tomonari.     

The genetic basis of negative selection of Tcrb-Vll+ T cells

Non-H-2 genes responsible for negative selection of Tcrb-V 11⁺ T cells were examined using backcross mice of various strains with C58, which does not delete Tcrb-V 11⁺ T cells. Two independently segregating genes were found: one leading to partial deletion was closely linked toLy-2/Ly-3 on chromosome 6, and the second giving virtually complete deletion has not yet been mapped. The A strain had only the former, whereas BALB/c, BALBK, B10.BR, CBA-T6, C3H/He, and DBA/2 expressed both of these genes. Although a gene(s) of the NIH strain led only to partial deletion, the chromosomal localization of the gene(s) has not yet been determined: no informative polymorphic molecules are expressed from genes on chromosome 6 of this strain.     

Positive selection by the pre-TCR yields mature CD8+ T cells

It has been of much interest whether there is functional redundancy between the constitutively signaling pre-Talpha/TCRbeta (pre-TCR) and ligated TCRalphabeta complexes, which independently operate the two distinct checkpoints during thymocyte development, i.e., the pre-TCR involved in beta-selection at the CD4(-)CD8(-) double-negative stage and the TCRalphabeta being crucial for positive/negative selection at the CD4(+)CD8(+) double-positive stage. We found that the pre-TCR expressed on double-positive cells in TCRalpha-deficient (TCRalpha(-/-)) mice produced a small number of mature CD8(+) T cells. Surprisingly, when pre-Talpha was overexpressed, resulting in augmentation of pre-TCR expression, there was a striking increase of the CD8(+) T cells. In addition, even in the absence of up-regulation of pre-TCR expression, a similar increase of CD8(+) T cells was also observed in TCRalpha(-/-) mice overexpressing Egr-1, which lowers the threshold of signal strength required for positive selection. In sharp contrast, the CD8(+) T cells drastically decreased in the absence of pre-Talpha on a TCRalpha(-/-) background. Thus, the pre-TCR appears to functionally promote positive selection of CD8(+) T cells. The biased production of CD8(+) T cells via the pre-TCR might also support the potential involvement of signal strength in CD4/CD8 lineage commitment.     

B cells participate in thymic negative selection of murine auto-reactive CD4+ T cells

It is well documented that thymic epithelial cells participate in the process of negative selection in the thymus. In recent years it was reported that also dendritic cells enter the thymus and contribute to this process, thus allowing for the depletion of thymocytes that are specific to peripherally expressed self-antigens. Here we report that also B cells may take part in the elimination of auto-reactive thymocytes. Using a unique mouse model we show that B cells induce negative selection of self-reactive thymocytes in a process that leads to the deletion of these cells whereas regulatory T cells are spared. These findings have direct implication in autoimmunity, as expression of a myelin antigen by B cells in the thymus renders the mice resistant to autoimmune inflammation of the CNS.     

Co-segregation of a gene encoding a deletion ligand for Tcrb-V3+ T cells with Mtv-3

A gene encoding the endogenous superantigen Mls^c, which deletes Tcrb-V3⁺ T cells in the NOD inbred mouse strain, was found to co-segregate with Mtv-3 on chromosome 11. This identifies a fourth gene encoding a deletion ligand for Tcrb-V3⁺ T cells and extends recently published observations in support of the hypothesis that a number of endogenous superantigens are the products of Mtv proviruses. Address correspondence and offprint requests to : K. Tomonari.     

Positive and negative selection on the mitochondrial genome

Several recent studies have confirmed that mitochondrial DNA variation and evolution are not consistent with the neutral theory of molecular evolution and might be inappropriate for estimating effective population sizes. Evidence for the action of both positive and negative selection on mitochondrial genes has been put forward, and the complex genetics of mitochondrial DNA adds to the challenge of resolving this debate. The solution could lie in distinguishing genetic drift from 'genetic draft' and in dissecting the physiology of mitochondrial fitness.     

Positive and negative selection on mammalian Y chromosomes

Y chromosomes are genetically degenerate in most organisms studied. The loss of genes from Y chromosomes is thought to be due to the inefficiency of purifying selection in nonrecombining regions, which leads to the accumulation of deleterious mutations via the processes of hitchhiking, background selection, and Muller's ratchet. As the severity of these processes depends on the number of functional genes linked together on the nonrecombining Y, it is not clear whether these processes are still at work on the old, gene-poor mammalian Y chromosomes. If purifying selection is indeed less efficient in the Y-linked, compared to the X-linked genes, deleterious nonsynonymous substitutions are expected to accumulate faster on the Y chromosome. However, positive selection on Y-linked genes could also increase the rate of amino acid-changing substitutions. Thus, the previous reports of an elevated nonsynonymous substitution rate in Y-linked genes are still open to interpretation. Here, we report evidence for positive selection in two out of three studied mammalian Y-linked genes, suggesting that adaptive Darwinian evolution may be common on mammalian Y chromosomes. Taking positive selection into account, we demonstrate that purifying selection is less efficient in mammalian Y-linked genes compared to their X-linked homologues, suggesting that these genes continue to degenerate.     

Preferential escape of subdominant CD8+ T cells during negative selection results in an altered antiviral T cell hierarchy

Negative selection is designed to purge the immune system of high-avidity, self-reactive T cells and thereby protect the host from overt autoimmunity. In this in vivo viral infection model, we show that there is a previously unappreciated dichotomy involved in negative selection in which high-avidity CD8(+) T cells specific for a dominant epitope are eliminated, whereas T cells specific for a subdominant epitope on the same protein preferentially escape deletion. Although this resulted in significant skewing of immunodominance and a substantial depletion of the most promiscuous T cells, thymic and/or peripheral deletion of high-avidity CD8(+) T cells was not accompanied by any major change in the TCR V beta gene family usage or an absolute deletion of a single preferred complementarity-determining region 3 length polymorphism. This suggests that negative selection allows high-avidity CD8(+) T cells specific for subdominant or cryptic epitopes to persist while effectively deleting high-avidity T cells specific for dominant epitopes. By allowing the escape of subdominant T cells, this process still preserves a relatively broad peripheral TCR repertoire that can actively participate in antiviral and/or autoreactive immune responses.     

Positive and negative selection in murine ultraconserved noncoding elements

There are many more selectively constrained noncoding than coding nucleotides in the mammalian genome, but most mammalian noncoding DNA is subject to weak selection, on average. One of the most striking discoveries to have emerged from comparisons among mammalian genomes is the hundreds of noncoding elements of more than 200 bp in length that show absolute conservation among mammalian orders. These elements represent the tip of the iceberg of a much larger class of conserved noncoding elements (CNEs). Much evidence suggests that CNEs are selectively constrained and not mutational cold-spots, and there is evidence that some CNEs play a role in the regulation of development. Here, we quantify negative and positive selection acting in murine CNEs by analyzing within-species nucleotide variation and between-species divergence of CNEs that we identified using a phylogenetically independent comparison. The distribution of fitness effects of new mutations in CNEs, inferred from within-species polymorphism, suggests that CNEs receive a higher number of strongly selected deleterious mutations and many fewer nearly neutral mutations than amino acid sites of protein-coding genes or regulatory elements close to genes. However, we also show that CNEs experience a far higher proportion of adaptive substitutions than any known category of genomic sites in murids. The absolute rate of adaptation of CNEs is similar to that of amino acid sites of proteins. This result suggests that there is widespread adaptation in mammalian conserved noncoding DNA elements, some of which have been implicated in the regulation of crucially important processes, including development.     

Positive and negative selection on the human genome.

The distinction between deleterious, neutral, and adaptive mutations is a fundamental problem in the study of molecular evolution. Two significant quantities are the fraction of DNA variation in natural populations that is deleterious and destined to be eliminated and the fraction of fixed differences between species driven by positive Darwinian selection. We estimate these quantities using the large number of human genes for which there are polymorphism and divergence data. The fraction of amino acid mutations that is neutral is estimated to be 0.20 from the ratio of common amino acid (A) to synonymous (S) single nucleotide polymorphisms (SNPs) at frequencies of > or =15%. Among the 80% of amino acid mutations that are deleterious at least 20% of them are only slightly deleterious and often attain frequencies of 1-10%. We estimate that these slightly deleterious mutations comprise at least 3% of amino acid SNPs in the average individual or at least 300 per diploid genome. This estimate is not sensitive to human population history. The A/S ratio of fixed differences is greater than that of common SNPs and suggests that a large fraction of protein divergence is adaptive and driven by positive Darwinian selection.     

Positive and negative selection in the DAZ gene family

Because a microdeletion containing the DAZ gene is the most frequently observed deletion in infertile men, the DAZ gene was considered a strong candidate for the azoospermia factor. A recent evolutionary analysis, however, suggested that DAZ was free from functional constraints and consequently played little or no role in human spermatogenesis. The major evidence for this surprising conclusion is that the nonsynonymous substitution rate is similar to the synonymous rate and to the rate in introns. In this study, we reexamined the evolution of the DAZ gene family by using maximum-likelihood methods, which accommodate variable selective pressures among sites or among branches. The results suggest that DAZ is not free from functional constraints. Most amino acids in DAZ are under strong selective constraint, while a few sites are under diversifying selection with nonsynonymous/ synonymous rate ratios (d(N)/d(S)) well above 1. As a result, the average d(N)/d(S) ratio over sites is not a sensible measure of selective pressure on the protein. Lineage-specific analysis indicated that human members of this gene family were evolving by positive Darwinian selection, although the evidence was not strong.     

Positive and negative selection on noncoding DNA in Drosophila simulans

There is now a wealth of evidence that some of the most important regions of the genome are found outside those that encode proteins, and noncoding regions of the genome have been shown to be subject to substantial levels of selective constraint, particularly in Drosophila. Recent work has suggested that these regions may also have been subject to the action of positive selection, with large fractions of noncoding divergence having been driven to fixation by adaptive evolution. However, this work has focused on Drosophila melanogaster, which is thought to have experienced a reduction in effective population size (N(e)), and thus a reduction in the efficacy of selection, compared with its closest relative Drosophila simulans. Here, we examine patterns of evolution at several classes of noncoding DNA in D. simulans and find that all noncoding DNA is subject to the action of negative selection, indicated by reduced levels of polymorphism and divergence and a skew in the frequency spectrum toward rare variants. We find that the signature of negative selection on noncoding DNA and nonsynonymous sites is obscured to some extent by purifying selection acting on preferred to unpreferred synonymous codon mutations. We investigate the extent to which divergence in noncoding DNA is inferred to be the product of positive selection and to what extent these inferences depend on selection on synonymous sites and demography. Based on patterns of polymorphism and divergence for different classes of synonymous substitution, we find the divergence excess inferred in noncoding DNA and nonsynonymous sites in the D. simulans lineage difficult to reconcile with demographic explanations.     

Separation of helper and suppressor T lymphocytes. III. Positive and negative effects of mixed lymphocyte reaction-activated T cells.

Using a Ficoll velocity sedimentation gradient, we provide evidence to show that stimulatory and inhibitory activities induced in mixed lymphocyte culture belong to two distinct subpopulations of T cells. Slow- to medium-sedimenting, nonproliferating cells enhance the humoral response of normal cells to SRBC whereas fast-sedimenting cells inhibit that response. Cytotoxic lymphocytes are found in the same fractions as suppressor cells but appear to be differentiable from the latter in terms of maturation kinetics and specificity.     

Peptide specificity of thymic selection of CD4+CD25+ T cells.

The CD4(+)CD25(+) regulatory T cells can be found in the thymus, but their need to undergo positive and negative selection has been questioned. Instead, it has been hypothesized that CD4(+)CD25(+) cells mature following TCR binding to MHC backbone, to low abundant MHC/peptide complexes, or to class II MHC loaded with peripheral autoantigens. In all these circumstances, processes that are distinct from positive and negative selection would govern the provenance of CD4(+)CD25(+) cells in the thymus. By comparing the development of CD4(+)CD25(-) and CD4(+)CD25(+) cells in mice expressing class II MHC molecules bound with one or many peptide(s), we show that the CD4(+)CD25(+) cells appear during natural selection of CD4(+) T cells. The proportion of CD4(+)CD25(+) cells in the population of CD4(+) thymocytes remains constant, and their total number reflects the complexity of selecting class II MHC/peptide complexes. Hence, thymic development of CD4(+)CD25(+) cells does not exclusively depend on the low-density, high-affinity MHC/peptide complexes or thymic presentation of peripheral self-Ags, but, rather, these cells are selected as a portion of the natural repertoire of CD4(+) T cells. Furthermore, while resistant to deletion mediated by endogenous superantigen(s), these cells were negatively selected on class II MHC/peptide complexes. We postulate that while the CD4(+)CD25(+) thymocytes are first detectable in the thymic medulla, their functional commitment occurs in the thymic cortex.     

Positive and negative selection towards tetracycline resistance genes in manure treatment lagoons

Aims: To evaluate the role of manure treatment lagoons of swine operations in the fate of faeces‐ and feed‐borne tetracycline‐resistant genes (TRG). Methods and Results: Samples of feed, faeces, lagoon liquid and lagoon sediment in farm’s vicinity were collected at three swine operations varied on their operational practices and analysed on the presence and frequencies of incidence of sixteen TRG in upstream sources (feed, faeces) and downstream receptacles (lagoon liquid and sediments). The highest frequency of TRG incidence was observed in a farm with extensive antibiotic usage and the lowest in the antibiotic‐free farm. The study revealed a decrease in TRG richness and diversity in the downstream habitats of each farm. The observed TRG diverged into two groups, the persistent genes that were detected both upstream and downstream, and the transient genes that were detected in the upstream habitats but became nondetectable in the lagoons. Quantitative PCR analysis revealed that upstream concentrations and abundances (determined as TRG/16S rRNA gene ratios) of transient and persistent TRG were similar; however, the former were attenuated in the lagoons to the levels below the detection limit, whereas the latter were ～ 100‐1000 fold amplified in their (mostly) liquid phases and were also detected in farms’ vicinities. Conclusion: Manure lagoons of swine operations imposed both positive and negative selection towards faeces‐ and feed‐borne TRG that, respectively, caused either their proliferation or attenuation in those environments. Significance and Impact of the Study: The study reveals that discharge of antibiotic resistance genes from swine farms to the environment is linked to their positive selection (defined as an impact leading to proliferation of those genes) in manure lagoons.