Evolution of broadly cross-reactive HIV-1-neutralizing activity: therapy-associated decline, positive association with detectable viremia, and partial restoration of B-cell subpopulations.

Little is known about the stability of HIV-1 cross-neutralizing responses. Taking into account the fact that neutralization breadth has been positively associated with plasma viral load, there is no explanation for the presence of broadly neutralizing responses in a group of patients on treatment with undetectable viremia. In addition, the B-cell profile responsible for broadly cross-neutralizing responses is unknown. Here we studied the evolution of neutralizing responses and the B-cell subpopulation distribution in a group of patients with broadly cross-reactive HIV-1-neutralizing activity. We studied neutralization breadth evolution in a group of six previously identified broadly cross-neutralizing patients and six control patients during a 6-year period with a previously described minipanel of recombinant viruses from five different subtypes. B-cell subpopulation distribution during the study was also determined by multiparametric flow cytometry. Broadly cross-neutralizing activity was transient in four broad cross-neutralizers and stable, up to 4.6 years, in the other two. In four out of five broad cross-neutralizers who initiated treatment, a neutralization breadth loss occurred after viremia had been suppressed for as much as 20 months. B-cell subpopulation analyses revealed a significant increase in the frequency of naive B cells in broadly cross-reactive samples, compared with samples with less neutralization breadth (increased from 44% to 62%). We also observed a significant decrease in tissue-like and activated memory B cells (decreased from 19% to 12% and from 17% to 9%, respectively). Our data suggest that HIV-1 broadly cross-neutralizing activity is variable over time and associated with detectable viremia and partial B-cell restoration.

Expression profiles of novel cell surface molecules on B-cell subsets and plasma cells as analyzed by flow cytometry.

Cell surface molecules are present on several lymphocyte subsets and are differentially expressed during lymphocyte development and activation. Human Leukocyte Differentiation Antigen (HLDA) Workshops have played an essential role in the identification and characterization of the molecules found in the membrane of hematopoietic cells. In the present study, the reactivities of sixty-five monoclonal antibodies (mAbs) submitted to the HLDA9 Workshop were tested. A multicolor flow cytometric analysis was performed in order to determine the expression profiles of these proteins on peripheral blood lymphocytes, hematopoietic cell lines, and tonsil B-cells. The following B-cell subsets were assessed: mature naïve, pre-germinal center, germinal center, unswitched and switched memory, plasmablasts, and plasma cells. Immunohistochemical analysis on formalin-fixed paraffin-embedded tonsils was also carried out. Remarkably, a large group of immunoglobulin family inhibitory cell surface molecules were observed on several distinct B-cell subsets including: CD152 (CTLA4), CD170 (Siglec-5), CD272 (BTLA), CD305 (LAIR1), CD307d (FCRL4), and CD329 (Siglec-9). The following molecules were also found to be differentially expressed on B-cell subsets (CD80, CD185 (CXCR5), CD196 (CCR6), CD270 (TNFRSF14), CD307a-c (FCRL1-3), CD319 (SLAMF7) and CD362 (SDC2)) or delineated B-cell subpopulations (CD126 (IL-6R), CD255 (TNFSF12), CD264 (TNFRSF10D), CD267 (TNFRSF13B) and CD329 (Siglec-9)). Of these, only CD307a, CD307b, and CD307d presented a B-cell-specific expression pattern. Our results show that several of these molecules are capable of further subdividing the known B-cell subsets and, in fact, may represent new markers for research, diagnosis, and eventually targets for the treatment of B-cell malignancies and autoimmune diseases.

Similar gene expression profiles in smokers and patients with moderate COPD.

Chronic obstructive pulmonary disease (COPD) is characterized by multiple cellular and structural changes affecting the airways, lung parenchyma and vasculature, some of which are also identified in smokers without COPD. The molecular mechanisms underlying these changes remain poorly understood. With the aim of identifying mediators potentially implicated in the pathogenic processes that occur in COPD and their potential relationship with cigarette smoking, we evaluated the mRNA expression of genes involved in inflammation, tissue remodeling and vessel maintenance. Lung tissue samples were obtained from 60 patients who underwent lung resection (nonsmokers, n=12; smokers, n=12; and moderate COPD, n=21) or lung transplant (severe-to-very severe COPD, n=15). PCR arrays containing 42 genes coding for growth factors/receptors, cytokines, metalloproteinases, adhesion molecules, and vessel maintenance mediators were used. Smoking-induced changes include the up-regulation of inflammatory genes (IL-1ß, IL-6, IL-8, CCL2, and CCL8) and the decreased expression of growth factor/receptor genes (BMPR2, CTGF, FGF1, KDR and TEK) and genes coding for vessel maintenance factors (EDNRB). All these genes exhibited a similar profile in moderate COPD patients. The up-regulation of MMP1 and MMP9 was the main change associated with COPD. Inflammatory genes as well as the endothelial selectin gene (SELE) were down-regulated in patients with more severe COPD. Clustering analysis revealed a closer relationship between moderate COPD and smokers than between both subsets of COPD patients for this selected set of genes. The study reveals striking similarities between smokers and COPD patients with moderate disease emphasizing the crucial role of cigarette smoking in the genesis of these changes, and provides additional evidence of the involvement of the matrix metalloproteinase's in the remodeling process of the lung in COPD.

New B-cell CD molecules.

B cells not only play a pivotal role in humoral immunity, but also are involved in a broad spectrum of immune responses, including antigen presentation and T-cell function regulation. The identification of cell-surface CD molecules derived from a series of Human Leukocyte Differentiation Antigens (HLDA) Workshops has been instrumental to the discovery and functional characterization of human B-cell populations. Moreover, many events regulating B-cell development, activation, and effector functions are orchestrated by these cell-surface molecules. During the Ninth HLDA Workshop (HLDA9) eighteen new CDs were allocated to cell-surface molecules expressed on B cells: CD210a (IL10RA), CD215 (IL15RA), CD270 (TNFRSF14), CD307a (FCRL1), CD307b (FCRL2), CD307c (FCRL3), CD307d (FCRL4), CD351 (FCAMR), CD352 (SLAMF6), CD353 (SLAMF8), CD354 (TREM1), CD355 (CRTAM), CD357 (TNFRSF18), CD358 (TNFRSF21), CD360 (IL21RA), CD361 (EVI2B), CD362 (SDC2), and CD363 (S1PR1). Here we present their expression patterns on leukocytes, including T lymphocytes, NK cells, granulocytes, monocytes, plasmacytoid and monocyte-derived dendritic cells, and several B-cell subsets. These new CD molecules are expressed on B cells at various stages of differentiation; from bone marrow precursor pro-B cells to plasma cells. Three of them, CD307a, CD307b and CD307d, exhibit a B-cell restricted expression pattern, whereas the rest are also present on other leukocytes. In this paper we also review the structural characteristics, expression, and function of these new CD molecules. The availability of monoclonal antibodies directed against novel B cell-surface molecules will have broad implications not only for B-cell biology, but also for the development of new diagnostic and therapeutic tools.

Analysis of HLDA9 mAbs on plasmacytoid dendritic cells.

Dendritic cells are a heterogeneous population of bone marrow derived leucocytes that play a crucial role in both pathogen recognition and the initiation of primary T cell immune responses. Plasmacytoid dendritic cells (pDCs), also known as natural interferon-producing cells, comprise one of two major human dendritic cell subsets that strongly influences immune balance. pDCs remain a poorly characterized subset. Several studies have suggested the existence of a close phenotypic and functional relationship between B-cells and pDCs. The surface reactivity of a panel of 96 monoclonal antibodies submitted to the ninth Human Leukocyte Differentiation Antigens workshop (HLDA9) B cell section was analyzed using pDCs as target cells. The results showed that eight of the mAbs reacted positively on pDCs: CD86, CD229, CD319, CD305, CD184, CD84, CD85g and FcɛRIa, confirming previously published reports. Interestingly, this study also revealed the expression of eight surface molecules not previously described on pDCs, including CD352(NTBA), CD272(BTLA), CD357(GITR), CD48, CD270(HVEM), Galectin-3, CD148, and CD361. The present report summarizes the expression of these molecules on freshly isolated pDCs. Significantly, we have identified several new molecules expressed by these intriguing cells, ones we believe will open new avenues for the study of pDC functionality and their role in human health and diseases.

Expression of SLAM (CD150) cell-surface receptors on human B-cell subsets: from pro-B to plasma cells.

The SLAM (CD150) family receptors are leukocyte cell-surface glycoproteins involved in leukocyte activation. These molecules and their adaptor protein SAP contribute to the effective germinal center formation, generation of high-affinity antibody-secreting plasma cells, and memory B cells, thereby facilitating long-term humoral immune response. Multi-color flow cytometric analysis was performed to determine the expression of CD48 (SLAMF2), CD84 (SLAMF5), CD150 (SLAM or SLAMF1), CD229 (Ly9 or SLAMF3), CD244 (2B4 or SLAMF4), CD319 (CRACC, CS1, or SLAMF7), and CD352 (NTB-A or SLAMF6) on human cell lines and B-cell subsets. The following subsets were assessed: pro-B, pre-B, immature-B, and mature-B cells from bone marrow; transitional and B1/B2 subsets from peripheral blood; and naïve, pre-germinal center, germinal center, memory, plasmablasts, and plasma cells from tonsil and spleen. All receptors were expressed on B cells, with the exception of CD244. SLAM family molecules were widely distributed during B-cell development, maturation and terminal differentiation into plasmablasts and plasma cells, but their expression among various B-cell subsets differed significantly. Such heterogeneous expression patterns suggest that SLAM molecules play an essential and non-redundant role in the control of humoral immune responses.