CD127 and CD25 expression defines CD4+ T cell subsets that are differentially depleted during HIV infection

Decreased CD4(+) T cell counts are the best marker of disease progression during HIV infection. However, CD4(+) T cells are heterogeneous in phenotype and function, and it is unknown how preferential depletion of specific CD4(+) T cell subsets influences disease severity. CD4(+) T cells can be classified into three subsets by the expression of receptors for two T cell-tropic cytokines, IL-2 (CD25) and IL-7 (CD127). The CD127(+)CD25(low/-) subset includes IL-2-producing naive and central memory T cells; the CD127(-)CD25(-) subset includes mainly effector T cells expressing perforin and IFN-gamma; and the CD127(low)CD25(high) subset includes FoxP3-expressing regulatory T cells. Herein we investigated how the proportions of these T cell subsets are changed during HIV infection. When compared with healthy controls, HIV-infected patients show a relative increase in CD4(+)CD127(-)CD25(-) T cells that is related to an absolute decline of CD4(+)CD127(+)CD25(low/-) T cells. Interestingly, this expansion of CD4(+)CD127(-) T cells was not observed in naturally SIV-infected sooty mangabeys. The relative expansion of CD4(+)CD127(-)CD25(-) T cells correlated directly with the levels of total CD4(+) T cell depletion and immune activation. CD4(+)CD127(-)CD25(-) T cells were not selectively resistant to HIV infection as levels of cell-associated virus were similar in all non-naive CD4(+) T cell subsets. These data indicate that, during HIV infection, specific changes in the fraction of CD4(+) T cells expressing CD25 and/or CD127 are associated with disease progression. Further studies will determine whether monitoring the three subsets of CD4(+) T cells defined based on the expression of CD25 and CD127 should be used in the clinical management of HIV-infected individuals.     

Cloning and gene map assignment of the Xiphophorus DNA ligase 1 gene

Fishes represent the stem vertebrate condition and have maintained several gene arrangements common to mammalian genomes throughout the 450 Myr of divergence from a common ancestor. One such syntenic arrangement includes the GPI-PEPD enzyme association on Xiphophorus linkage group IV and human chromosome 19. Previously we assigned the Xiphophorus homologue of the human ERCC2 gene to linkage group U5 in tight association with the CKM locus. CKM is also tightly linked to the ERCC2 locus on human chromosome 19, leading to speculation that human chromosome 19 may have arisen by fusion of two ancestral linkage groups which have been maintained in fishes. To investigate this hypothesis further, we isolated and sequenced Xiphophorus fish genomic regions exhibiting considerable sequence similarity to the human DNA ligase 1 amino acid sequence. Comparison of the fish DNA ligase sequence with those of other species suggests several modes of amino acid conservation in this gene. A 2.2-kb restriction fragment containing part of an X. maculatus DNA ligase 1 exon was used in backcross hybrid mapping with 12 enzyme or RFLP loci. Significant linkage was observed between the nucleoside phosphorylase (NP2) and the DNA ligase (LIG1) loci on Xiphophorus linkage group VI. This assignment suggests that the association of four DNA repair-related genes on human chromosome 19 may be the result of chance chromosomal rearrangements.      

Comparative nuclear and mitochondrial genome diversity in humans and chimpanzees

Restriction mapping and sequencing have shown that humans have substantially lower levels of mitochondrial genome diversity (d) than chimpanzees. In contrast, humans have substantially higher levels of heterozygosity (H) at protein-coding loci, suggesting a higher level of diversity in the nuclear genome. To investigate the discrepancy further, we sequenced a segment of the mitochondrial genome control region (CR) from 49 chimpanzees. The majority of these were from the Pan troglodytes versus subspecies, which was underrepresented in previous studies. We also estimated the average heterozygosity at 60 short tandem repeat (STR) loci in both species. For a total sample of 115 chimpanzees, d = 0.075 +/0 0.037, compared to 0.020 +/- 0.011 for a sample of 1,554 humans. The heterozygosity of human STR loci is significantly higher than that of chimpanzees. Thus, the higher level of nuclear genome diversity relative to mitochondrial genome diversity in humans is not restricted to protein-coding loci. It seems that humans, not chimpanzees, have an unusual d/H ratio, since the ratio in chimpanzees is similar to that in other catarrhines. This discrepancy in the relative levels of nuclear and mitochondrial genome diversity in the two species cannot be explained by differences in mutation rate. However, it may result from a combination of factors such as a difference in the extent of sex ratio disparity, the greater effect of population subdivision on mitochondrial than on nuclear genome diversity, a difference in the relative levels of male and female migration among subpopulations, diversifying selection acting to increase variation in the nuclear genome, and/or directional selection acting to reduce variation in the mitochondrial genome.      

Preexisting influenza-specific CD4+ T cells correlate with disease protection against influenza challenge in humans

Protective immunity against influenza virus infection is mediated by neutralizing antibodies, but the precise role of T cells in human influenza immunity is uncertain. We conducted influenza infection studies in healthy volunteers with no detectable antibodies to the challenge viruses H3N2 or H1N1. We mapped T cell responses to influenza before and during infection. We found a large increase in influenza-specific T cell responses by day 7, when virus was completely cleared from nasal samples and serum antibodies were still undetectable. Preexisting CD4+, but not CD8+, T cells responding to influenza internal proteins were associated with lower virus shedding and less severe illness. These CD4+ cells also responded to pandemic H1N1 (A/CA/07/2009) peptides and showed evidence of cytotoxic activity. These cells are an important statistical correlate of homotypic and heterotypic response and may limit severity of influenza infection by new strains in the absence of specific antibody responses. Our results provide information that may aid the design of future vaccines against emerging influenza strains.     

CCR2 identifies a stable population of human effector memory CD4+ T cells equipped for rapid recall response

Because T cells act primarily through short-distance interactions, homing receptors can identify colocalizing cells that serve common functions. Expression patterns for multiple chemokine receptors on CD4(+) T cells from human blood suggested a hierarchy of receptors that are induced and accumulate during effector/memory cell differentiation. We characterized CD4(+)CD45RO(+) T cells based on expression of two of these receptors, CCR5 and CCR2, the principal subsets being CCR5(-)CCR2(-) (～70%), CCR5(+)CCR2(-) (～25%), and CCR5(+)CCR2(+) (～5%). Relationships among expression of CCR5 and CCR2 and CD62L, and the subsets' proliferation histories, suggested a pathway of progressive effector/memory differentiation from the CCR5(-)CCR2(-) to CCR5(+)CCR2(-) to CCR5(+)CCR2(+) cells. Sensitivity and rapidity of TCR-mediated activation, TCR signaling, and effector cytokine production by the subsets were consistent with such a pathway. The subsets also showed increasing responsiveness to IL-7, and the CCR5(+)CCR2(+) cells were CD127(bright) and invariably showed the greatest response to tetanus toxoid. CCR5(+)CCR2(+) cells also expressed the largest repertoire of chemokine receptors and migrated to the greatest number of chemokines. By contrast, the CCR5(+)CCR2(-) cells had the greatest percentages of regulatory T cells, activated/cycling cells, and CMV-reactive cells, and were most susceptible to apoptosis. Our results indicate that increasing memory cell differentiation can be uncoupled from susceptibility to death, and is associated with an increase in chemokine responsiveness, suggesting that vaccination (or infection) can produce a stable population of effector-capable memory cells that are highly enriched in the CCR5(+)CCR2(+) subset and ideally equipped for rapid recall responses in tissue.     

Reconstitution of CD4 T Cells in Bronchoalveolar Lavage Fluid after Initiation of Highly Active Antiretroviral Therapy

The massive depletion of gastrointestinal-tract CD4 T cells is a hallmark of the acute phase of HIV infection. In contrast, the depletion of the lower-respiratory-tract mucosal CD4 T cells as measured in bronchoalveolar lavage (BAL) fluid is more moderate and similar to the depletion of CD4 T cells observed in peripheral blood (PB). To understand better the dynamics of disease pathogenesis and the potential for the reconstitution of CD4 T cells in the lung and PB following the administration of effective antiretroviral therapy, we studied cell-associated viral loads, CD4 T-cell frequencies, and phenotypic and functional profiles of antigen-specific CD4 T cells from BAL fluid and blood before and after the initiation of highly active antiretroviral therapy (HAART). The major findings to emerge were the following: (i) BAL CD4 T cells are not massively depleted or preferentially infected by HIV compared to levels for PB; (ii) BAL CD4 T cells reconstitute after the initiation of HAART, and their infection frequencies decrease; (iii) BAL CD4 T-cell reconstitution appears to occur via the local proliferation of resident BAL CD4 T cells rather than redistribution; and (iv) BAL CD4 T cells are more polyfunctional than CD4 T cells in blood, and their functional profile is relatively unchanged after the initiation of HAART. Taken together, these data suggest mechanisms for mucosal CD4 T-cell depletion and interventions that might aid in the reconstitution of mucosal CD4 T cells.The assessment of the degree of memory CD4 T-cell depletion at mucosal sites during human immunodeficiency virus (HIV) infection is perhaps the most comprehensive way to estimate the impact of HIV on the T-cell pool. As such, the massive depletion of gastrointestinal CD4 T cells is a hallmark of HIV and simian immunodeficiency virus (SIV) infection (5, 12, 17, 19, 20, 30). This depletion occurs during the acute phase of infection and is maintained throughout the chronic phase. Mechanisms underlying this depletion have been shown to include the direct consequence of target cell infection (4, 19) and virus-induced Fas-mediated apoptosis (17). However, while it is clear that the substantial depletion of CD4 T cells occurs in the gastrointestinal (GI) tract and vaginal mucosa (31) of SIV-infected macaques and HIV-infected individuals (5, 12, 20, 30), similar depletion does not manifest at all mucosal sites, particularly the lung, in human studies (4).Highly active antiretroviral therapy (HAART) has significantly improved the prognosis of HIV-infected individuals (15, 16). Individuals who initiate HAART before their CD4 T-cell counts in peripheral blood (PB) fall below 350 cells/μl have significantly improved survival compared to that of individuals who initiate HAART with CD4 T-cell counts less than 350 cells/μl (15). Several studies also have shown that when HAART is initiated after CD4 T-cell counts fall below 350 cells/μl, the reconstitution of CD4 T cells in the GI tract is very poor, even after years of therapy (10, 12, 21). However, HIV-infected individuals treated with HAART during the early phase of infection may reconstitute CD4 T cells in the GI tract (18, 21). In contrast to the GI tract, little is known regarding CD4 T-cell reconstitution in the lung compartment during the course of HIV treatment. Nevertheless, the timing of HAART initiation after infection appears to be an important predictor of successful mucosal T-cell reconstitution.The massive depletion of CD4 T cells during the acute phase of infection does not occur at all mucosal sites, as CD4 T cells in bronchoalveolar lavage (BAL) are relatively spared and are slowly depleted during the chronic phase of infection (4). Despite this preservation of lung CD4 T cells, diminished BAL T-cell immune responses to certain pathogens have been reported in HIV-infected subjects (14). Given that many patients worldwide have access to and will receive antiretroviral therapy, the study of mucosal responses longitudinally during the course of treatment is likely to enhance our understanding of immune restoration. In addition, the early cellular events following HAART initiation are likely to skew the immune system toward both protective (i.e., immunosurveillance) and pathological (i.e., immune reconstitution inflammatory syndrome) responses. In this context, the study of the human pulmonary immune response remains an important aspect of HIV infection and treatment. To examine the dynamics of lung CD4 T-cell reconstitution, we studied the treatment of naïve HIV-infected individuals longitudinally during their course of HAART. We sampled peripheral blood and BAL T cells prior to, at 1 month, and after 1 year of HAART. From each subject and within each compartment, we examined the proliferative and functional capacity of stimulated CD4 and CD8 T cells.     

The rational design of an AIDS vaccine

The extraordinary genetic diversity and immune evasion of human immunodeficiency virus (HIV) pose significant challenges for vaccine development. AIDS vaccine design requires a scientifically driven, rational approach that encompasses the latest advances in viral molecular genetics, structural biology, and immunology.     

HIV infected CD4+ T cell clones are more stable than uninfected clones during long-term antiretroviral therapy

Although combination antiretroviral therapy (ART) blocks HIV replication, it is not curative because infected CD4+ T cells that carry intact, infectious proviruses persist. Understanding the behavior of clones of infected T cells is important for understanding the stability of the reservoir; however, the stabilities of clones of infected T cells in persons on long-term ART are not well defined. We determined the relative stabilities of clones of infected and uninfected CD4+ T cells over time intervals of one to four years in three individuals who had been on ART for 9–19 years. The largest clones of uninfected T cells were larger than the largest clones of infected T cells. Clones of infected CD4+ T cells were more stable than clones of uninfected CD4+ T cells of a similar size. Individual clones of CD4+ T cells carrying intact, infectious proviruses can expand, contract, or remain stable over time.     

Multimodality imaging of anomalous pulmonary veins

Partial anomalous pulmonary venous connection (PAPVC) is an extremely rare congenital condition where one or more of the pulmonary veins are connected to the venous circulation. Although initially suspected with unexplained right ventricular enlargement on transthoracic echocardiography (TTE), cardiac MRI is able to delineate the anatomical variant. We present a case of a 65-year-old male diagnosed with left sided PAPVC using multimodality cardiac imaging.