The role of the thymus in immunosenescence: lessons from the study of thymectomized individuals
Abstract
The thymus is the major site of T cell production and a key organ of the immune system. Its natural involution during the course of life has cast doubts as to its importance for the integrity of our immunity in adulthood. We provide here an overview of the recent works focusing on the immunological evaluation of subjects thymectomized during early childhood due to cardiac surgery of congenital heart defects. These studies represent new advances in our appreciation of the role of the thymus in humans and more generally in our understanding of the development of immunosenescence.
The role of the thymus
The thymus is a central
lymphoid organ in humans. It is devoted to thymocyte differentiation and
maturation, and is therefore the primary source of circulating T lymphocytes.
Anatomically, the thymus is located in the upper anterior portion of the
thorax, just behind the sternum and in front of the great vessels. Its weight
in proportion to body weight is greatest shortly before birth. Although its
size continues to increase until it reaches its maximum absolute weight during
puberty, its functional compartments (the medulla and the cortex) and T cell
output activity diminish after the first years of life onwards. Subsequently,
the thymus undergoes a process known as involution, which is defined as a
decrease in the size, weight and activity of the gland with advancing age.
Thymic involution is thought to result from high levels of circulating sex
hormones in particular during puberty, lower population of precursor cells from
the bone marrow and changes in thymic microenvironment. Although it continues
to serve as the site of T-cell differentiation and maturation
throughout adulthood [1], the thymus largely degenerates into fatty tissue in elderly
adults [2]. Since the atrophy of this organ and the reduction of its
activity are natural processes which start relatively early in life, its
importance beyond the initial production of T cells has remained a matter of
debate and its role during adulthood has even be disregarded.
Congenital heart defects and thymectomy
In order to facilitate the surgical correction of life-threatening
congenital heart defects (CHD), it is common to ablate this gland, a process
known as thymectomy. CHD is one of the most common defects at birth. The
Children's Heart Foundation estimates that nearly one of every 100 babies is
born with a CHD (http://www.childrensheartfoundation.org).
CHD include a number of problems:
septal defects, defects causing obstruction in the heart or blood vessels,
cyanotic defects or even complex abnormalities. Some of these defects are mild
and may need little or no medical treatment even through adulthood. But others
can be lethal, either immediately to the newborn or over time. In this case,
invasive surgery to correct the defect remains the solution of choice. However,
surgical access to the heart and great vessels is obstructed by the thymus,
particularly after birth or during infancy when it occupies the largest
relative space. The thymus is thus removed to access the heart region in order
to repair the defect. Over the last 30 years, open heart surgery in newborns
has become an increasingly safe and routinely performed surgical procedure, in
particular since there has been no clinical report of immune disorders (e.g.
immunodeficiency) as a consequence of thymectomy in CHD subjects [3, 4]. In rodents, it has long been shown that thymectomy can result in
partial immunodeficiency, mainly affecting cell mediated immune responses [5]. However, rodents are born with a relatively immature immune
system and an imcomplete TCR repertoire, whereas human newborns should have
already a fully developed TCR repertoire diversity at birth [6, 7]. Young adults thymectomized during early childhood represent
nonetheless a particularly informative group to evaluate the importance of the
thymus beyond the production of the initial T cell stock, and to study the
long-term consequences of early thymectomy in adult life.
Consequences on the T cell compartment
A number of studies have
shown that thymectomy in infants results in alterations of the peripheral T
cell compartment characterized by reduced CD4+ and CD8+ T cell counts,
affecting mainly the naive T cells identified through the expression of CD45RA
CD62L CCR7 and CD27 [8-14]. Decrease of naive CD4+ T cells was found to depend on
chronological age and time post thymectomy [13]. Moreover, thymectomized individuals present decreased
proportions of CD4+ T cells expressing CD31 or CD103, or displaying T cell
receptor excision circles (TREC) contents (i.e. markers of recent thymic
emigrants)[9, 13, 14]. These alterations are attributed to the loss of thymic
function, with an increase of peripheral proliferation of naive T cells.
Analyses of the TCR repertoire revealed also a marked reduction in diversity
within the CD8+ T cell compartment in some thymectomized patients, close to the
changes found in individuals of old age, reflecting the accumulation of
oligoclonal memory T cell populations in the periphery [14]. In a study with 20 cardiac transplants recipients, who had
thymectomy 1 to 10 years prior to transplantation, a restricted TCR repertoire
was also reported [12]. Regulatory CD4+CD25+ T cell numbers have been shown to be
reduced in thymectomized patients, despite no apparent change in the
proportions of the naive regulatory T cells (CD4+CD25+CD62L+) [11, 14]. It is possible that regulatory T cells mature earlier in
life than other CD4+ T cells, and thus, may be less influenced by thymectomy.
On the functional side, lymphocytes of thymectomized patients show an
appropriate proliferative response to tetanus toxoid and phytohemagglutinin [8, 9]. Moreover, already existing memory T cells (e.g. specific for persisting
viruses like EBV) in thymectomized patients present regular functional and
phenotypic attributes; thus thymectomy does not seem to prevent the normal
development of memory T cells [14]. Overall, these findings highlight a reduced production of naïve
CD4+ and CD8+ T cells, and a disequilibrium of the naïve to memory T cell
ratio, as consequences of thymectomy.
Thymectomy and the heterogeneity of profiles
Importantly, studies on thymectomized individuals show also that
there is a certain degree of heterogeneity between donors with regard to
immunological attributes: some thymectomized individuals present satisfactory
naïve T cell counts (i.e. close to non-thymectomized controls) despite no signs
of thymic regeneration, while other donors present marked alterations. Despite
their young age, some patients can have indeed profound perturbations that are
typically associated with advanced aging (i.e. > 75 years old): decreased T
cell count and very low naïve T cell frequency, reduced T cell repertoire
diversity, and increased numbers of highly differentiated memory T cells with
shortened telomeres [14]. Several factors may explain the heterogeneity between
thymectomized patients in terms of immune phenotype and the maintenance of the
peripheral naïve T cells in some donors. First, cervical extensions of the
thymic tissue may remain in situ and contribute to the influx of naïve T
cells; second, T cells may be generated de novo at extrathymic sites;
third, human recent thymic emigrants generated before thymectomy may be
long-lived and persist for decades; and fourth, antigen-independent homeostatic
proliferation in the peripherymay compensate for the loss of thymic
output in thymectomized patients. Nonetheless, extrinsic factors that impact
indirectly on the level of naïve T cells and thus the function of the thymus
may also be contemplated. Of note, a recent publication shows that exacerbated
alterations in the T cell compartment in young adults thymectomized after birth
were observed in those who were cytomegalovirus (CMV) seropositive [14]. Although an increased risk of acquiring CMV due to a potentially
weakened immunity associated with thymectomy cannot be excluded, this marked
immunosenescent phenotype is most likely the direct consequence of CMV
infection through the establishment of an anti-CMV immune response in
thymectomized patients. CMV is indeed known to impose a particular strong
pressure on the immune system in normal healthy individuals [15]. CMV infection results in a massive expansion of CMV specific
memory T cells, which can start from the early days of life and can reach up to
40% of total T cells during chronic infection [16]. Normal healthy adults infected with CMV present generally
reduced proportions of naïve T cells and an accumulation of highly
differentiated memory T cells associated with a loss of T cell repertoire
diversity compared to CMV seronegative controls [17]. CMV infection is connected to the phenomenon of memory
inflation, which is characterized by a progressive increase in the number of
CMV specific memory T cells during chronic infection, with the continuous
recruitment of naïve T cells, as shown in the murine CMV infection model [18]. In the context of inadequate T cell renewal due to thymectomy,
CMV infection may thus lead to premature exhaustion of the naïve T cell
compartment and loss of T cell repertoire diversity. Thymectomized individuals
infected with CMV represent obviously an extreme situation, nonetheless its
study provides interesting insights underlying the long term consequences of
infections on our immune system and the development of immunosenescence with
age. We learn that beyond its role in the initial production of T lymphocytes,
the capacity of the thymus to produce T lymphocytes is necessary to maintain
the integrity of the cellular immunity in the face of recurrent challenges by
pathogens during the course of life, and thus to delay the onset of
immunosenescence.
Immune risk profile
Can thymectomy represent an
immunological risk for CHD patients who underwent open heart surgery, in
particular considering the high prevalence of CMV infection in the general
population (50 to 80%)? To date, it is unclear whether thymectomized patients
with a prematurely aged immune system are at greater risk to develop
inflammatory diseases, autoimmunity, or cancer and may suffer from increased
morbidity or mortality due infectious diseases and opportunistic pathogens, as
this is observed with old age. Considering that some thymectomized patients
present significant reductions in naïve T cell frequencies, immune responses to
new antigens or vaccination may be diminished. In the elderly, poor responses
to new infectious antigens and vaccinations have been explained by the
reduction in recent thymic emigrants associated with immunosenescence [19]. Only one prospective cohort study analyzed the specific humoral
immune response to a new antigen by immunizing thymectomized children with
tick-borne encephalitis (TBE) vaccine [20]. The thymectomized children showed a significantly delayed
primary immune response compared to age-matched, non-thymectomized children,
similar to the findings of TBE vaccination in elderly patients after
physiological thymus involution [21]. A decreased ability of thymectomized patients to respond
appropriately to new antigens may gain more relevance in later life. It is
important to bear in mind that the oldest thymectomized CHD patients are still
young, since open heart surgery in newborns is a relatively recent surgical
procedure (safely performed over the last 30-40 years). Follow-up programs
(e.g. infection rates and antibody levels against vaccines) of thymectomized
adults that reach older age will be required to establish if thymectomy
represents a risk associated with higher than expected rates of age-associated
immune conditions. It is likely that patients with residual thymic tissue after
heart surgery, late thymectomy or CMV seronegativity will have close to normal
immune attributes and will develop no related clinical conditions. However, one
may speculate that early and complete resection of the thymus followed by
infection with CMV may have adverse consequences on the immune competence in
the long run. Decreased T cell count, very low naïve T cell frequency,
reduced T cell receptor repertoire diversity, and increased numbers of
senescent like memory T cells, as found in CMV infected thymectomized patients,
are clear signs of immune deterioration. These alterations of the T cell
compartment are reminiscent of the immune risk phenotype (IRP), defined by
gerontologists as a cluster of immune measures that are predictive of early
all-cause mortality in the elderly [22, 23]. In view of the immediate and obvious benefit of open
heart surgery in the context of CHD, the adverse consequences of thymectomy may
be considered as secondary. Nonetheless, partial resection of the thymus during
cardiac surgery should be encouraged in order to limit premature aging of the
immune system.
Conflicts of Interest
The authors of this manuscript have no conflict of
interest to declare.
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