Yu-Chang Wu

B-cell diversity decreases in old age and is correlated with poor health status.

Older people suffer from a decline in immune system, which affects their ability to respond to infections and to raise efficient responses to vaccines. Effective and specific antibodies in responses from older individuals are decreased in favour of non‐specific antibody production. We investigated the B‐cell repertoire in DNA samples from peripheral blood of individuals aged 86–94 years, and a control group aged 19–54 years, using spectratype analysis of the IGHV complementarity determining region (CDR)3. We found that a proportion of older individuals had a dramatic collapse in their B‐cell repertoire diversity. Sequencing of polymerase chain reaction products from a selection of samples indicated that this loss of diversity was characterized by clonal expansions of B cells in vivo. Statistical analysis of the spectratypes enabled objective comparisons and showed that loss of diversity correlated very strongly with the general health status of the individuals; a distorted spectratype can be used to predict frailty. Correlations with survival and vitamin B12 status were also seen. We conclude that B‐cell diversity can decrease dramatically with age and may have important implications for the immune health of older people. B‐cell immune frailty is also a marker of general frailty.

High-throughput immunoglobulin repertoire analysis distinguishes between human IgM memory and switched memory B-cell populations

B-cell receptor (BCR) diversity is achieved centrally by rearrangement of Variable, Diversity, and Joining genes, and peripherally by somatic hypermutation and class-switching of the rearranged genes. Peripheral B-cell populations are subject to both negative and positive selection events in the course of their development that have the potential to shape the BCR repertoire. The origin of IgM(+)IgD(+)CD27(+) (IgM memory) cells is controversial. It has been suggested that they may be a prediversified, antigen-independent, population of cells or that they are a population of cells that develop in response to T-independent antigens. Most recently, it was suggested that the majority of IgM memory cells are directly related to switched memory cells and are early emigrants from the germinal center reaction. Advances in sequencing technology have enabled us to undertake large scale IGH repertoire analysis of transitional, naive, IgM memory and switched memory B-cell populations. We find that the memory B-cell repertoires differ from the transitional and naive repertoires, and that the IgM memory repertoire is distinct from that of class-switched memory. Thus we conclude that a large proportion of IgM memory cells develop in response to different stimuli than for class-switched memory cell development.

Vaccination‐induced changes in human B‐cell repertoire and pneumococcal IgM and IgA antibody at different ages

It is well known that older people are more susceptible to morbidity and mortality from infectious diseases, particularly from pulmonary diseases such as pneumococcal pneumonia where vaccines do not provide efficient protection as in younger populations. We have previously shown that the B‐cell repertoire in the old is reduced and hypothesise that this may contribute to the impaired humoral responses of the elderly. Here, we investigated the repertoire and antibody responses to winter vaccination in two age groups, aged 18–49 and 65–89. We found that the serum IgM and IgA pneumococcal responses were significantly impaired in the older group, with no difference in IgG levels. IGHM spectratype analysis seems to be the most promising in terms of its predictive ability for vaccine responses. Spectratypes showed a clear change in the repertoire at day 7 after vaccination, with a return to the baseline levels at day 28. The changes at day 7 reflected expansion of IGH sequences that have smaller, more hydrophilic, CDR3 regions, and these changes were attenuated in the older group. The older group was more likely to have spectratypes indicative of a reduced diversity at day 0 and day 28. On average, the baseline repertoire in the older group was comprised of larger CDR3 regions than in the younger group. In conclusion, IgA and IgM responses are significantly impaired in the elderly pneumococcal response and are likely key mediators of protection. Hydrophilicity and/or small size of the IGH CDR3 appear to be important in these responses.

The ageing B cell population: Composition and function

Age related changes in the structure and function of the immune system, collectively termed immunosenescence, result in poor responses to infections, increased susceptibility to cancers and increased incidence of autoimmune diseases. The humoral immune response, maintained by the B cell compartment, has a key role in an effective immune system—not only in producing high affinity antibodies that are crucial for vaccination strategies, but in assisting other components of the immune system in their function. Hence an understanding of B cell immunosenescence in particular is vital in designing strategies to combat the effects of age on immune function. Numerous studies have been undertaken using small animal models in order to understand immunosenescence, and these have contributed greatly to our understanding of the events that underpin impaired immune responses. However, there are key differences between the human and the mouse and a clear understanding of these differences is required when extrapolating from one species to the other. In this article we present an overview of B cell development and summarise current data on age-related B cell changes, at both the population level and at the individual mechanistic level. Areas of similarity and difference between human and mouse models are highlighted.

B cell immunosenescence: different features of naive and memory B cells in elderly

Elderly people show a reduced protection against new infections and a decreased response to vaccines as a consequence of impairment of both cellular and humoral immunity. In this paper we have studied memory/naïve B cells in the elderly, evaluating surface immunoglobulin expression, production of the pro- and anti-inflammatory cytokines, tumor necrosis factor (TNF)-α and interleukin (IL)-10, and presence of somatic hypermutation, focusing on the IgG+IgD−CD27− double negative (DN) B cells that are expanded in the elderly. Our results show that naïve B cells from young donors need a sufficiently strong stimulus to be activated “in vitro”, while naïve B cells from old subjects are able to produce IL-10 and TNF-α when stimulated “physiologically” (α-CD40/IL-4), suggesting that these cells might play a role in the control of the immuno-inflammatory environment in the elderly. In addition, in the elderly there is an accumulation of DN B cells with a reduced rate of somatic hypermutation. Thus, DN B lymphocytes may be exhausted cells that are expanded and accumulate as a by-product of persistent stimulation or impaired germinal center formation.

B cells and immunosenescence: A focus on IgG+IgD―CD27― (DN) B cells in aged humans

Immunosenescence contributes to the decreased ability of the elderly to control infectious diseases, which is also reflected in their generally poor response to new antigens and vaccination. It is known that the T cell branch of the immune system is impaired in the elderly mainly due to expansion of memory/effector cells that renders the immune system less able to respond to new antigens. B lymphocytes are also impaired in the elderly in terms of their response to new antigens. In this paper we review recent work on B cell immunosenescence focusing our attention on memory B cells and a subset of memory B cells (namely IgG(+)IgD(-)CD27(-)) that we have demonstrated is increased in healthy elderly.

Immunoglobulin kappa variable region gene selection during early human B cell development in health and systemic lupus erythematosus

The unique specificity of the B cell receptor is generated by an ordered sequence of gene rearrangement events. Once IGH genes have rearranged, rearrangement at the IGK locus is initiated followed by the IGL locus if functional IGK rearrangement is not achieved. Receptor specificity can subsequently be altered by secondary light chain editing based on the features of the heavy and light chain combination. The final profile of expressed genes is not random and biases in this profile are associated with several autoimmune diseases. However, how and when biases are created is not known. To increase our understanding of the processes of selection and editing of IGK rearrangements, we compared four groups of rearrangements of IGK acquired by next generation sequencing. First, expressed rearrangements of IGK from cDNA of IGK expressing B cells. Second, productive rearrangements of IGK from DNA of the same kappa expressing B cells. Third, non-productive rearrangements of IGK from DNA of IGK and IGL expressing B cells, and fourth productively rearranged IGK from DNA of IGL expressing B cells. The latter group would have been rejected during B cell development in favour of rearrangement at the IGL locus and are therefore selected against. We saw evidence that rearranged IGK segments can be selected at a checkpoint where the decision to rearrange the IGL locus is made. In addition, our data suggest that mechanisms regulating the expression or not of IGK rearrangements may also contribute to repertoire development and also that this latter component of the selection process is defective in SLE.

Age-related aspects of human IgM+ B cell heterogeneity

The CD27+IgD+ B cell population, known as IgM memory, reduces with age. It is thought that this population is responsible for pneumococcal polysaccharide T‐independent responses, and that the age‐related reduction might be partially responsible for the increased susceptibility of older people to bacterial pathogens. There are other IgM+ B cell populations that do not express IgD. We compared the different IgM populations using high‐throughput sequencing of the immunoglobulin (Ig) gene repertoire and multidimensional cell phenotyping and found that the different populations of IgM cells, defined by CD27 and IgD expression, have repertoire differences. Some of these differences are likely indicative of different selection pressures in an immune response, although the older individuals were found to have a changed repertoire in naive B cells, which may contribute to some of the changes seen in memory cells. In addition, even within the CD27+IgD+ IgM memory population there are multiple cell types. We show that the level of IgM expression varies substantially and hypothesize that this distinguishes between T‐dependent and T‐independent types of IgM memory cells. Significant age‐related changes in the relative proportions of these populations may exacerbate the reduction in T‐independent responders in old age.

Understanding the Mechanisms of Immune System Aging: Immune System Cell Development and Antibody Repertoires

The incidence of infectious diseases, autoimmune syndromes, and various forms of cancer is elevated in older adults, and consequently, age-related changes in adaptive immunity have been studied extensively. These age-related changes include reduced antibody production after immunization or infection, reduced affinities of the antibodies produced, and the increased production of autoantibodies. To understand the increased susceptibility to disease with age, it is necessary to study the age-related changes in the immune system. Lymphocytes are small white blood cells that are predominantly responsible for the activities of the immune system. The two major classes of lymphocytes are B cells and T cells, both of which recognize specific antigen targets and are responsible for the learning and memory of the immune system. B cells are also responsible for antibody production. A shift in the phenotypes of these cells from naive cells to memory lymphocytes is seen with advancing age and this shift could explain the reduced capacity of older adults to produce immune responses to antigens that they have not previously encountered. The mechanisms underlying these age-related changes in B-cell function have not yet been clarified. This chapter focuses on how the repertoire diversity, population dynamics, and functions of B cells alter during the aging process. These findings extend our understanding of age-related adaptive immunity and may in the future provide a basis for interventions that delay immunosenescence. Understanding the reasons for age-related changes in the mechanisms that control B-cell populations is critical if we are to develop technologies to overcome these defects.