Thymocyte development in vitro: implications for studies of ageing and thymic involution

Insulin-like growth factor-I regulation of immune function: a potential therapeutic target in autoimmune diseases?

This topically limited review explores the relationship between the immune system and insulin-like growth factors (IGF-I and IGF-II) and the proteins through which they act, including IGF-I receptor (IGF-IR) and the IGF-I binding proteins. The IGF/IGF-IR pathway plays important and diverse roles in tissue development and function. It regulates cell cycle progression, apoptosis, and the translation of proteins. Many of the consequences ascribed to IGF-IR activation result from its association with several accessory proteins that are either identical or closely related to those involved in insulin receptor signaling. Relatively recent awareness that IGF-I and IGF-IR regulate immune function has cast this pathway in an unexpected light; it may represent an important switch governing the quality and amplitude of immune responses. IGF-I/IGF-IR signaling may also participate in the pathogenesis of autoimmune diseases, although its relationship with these processes seems complex and relatively unexplored. On the one hand, IGF-I seems to protect experimental animals from developing insulin-deficient diabetes mellitus. In contrast, activating antibodies directed at IGF-IR have been detected in patients with Graves' disease, where the receptor is overexpressed by multiple cell types. The frequency of IGF-IR+ B and T cells is substantially increased in patients with that disease. Potential involvement of IGF-I and IGF-IR in the pathogenesis of autoimmune diseases suggests that this pathway might constitute an attractive therapeutic target. IGF-IR has been targeted in efforts directed toward drug development for cancer, employing both small-molecule and monoclonal antibody approaches. These have been generally well-tolerated. Recognizing the broader role of IGF-IR in regulating both normal and pathological immune responses may offer important opportunities for therapeutic intervention in several allied diseases that have proven particularly difficult to treat.

Nerve growth factor immunoreactivity of mast cells in acute involuted human thymus

The acute involution of the thymus is induced by either exogenous or endogenous factors, including some infections (infection type involution). The present study was focused on both detection and immunocytochemical analysis of NGF immunopositive mast cells in child thymus with acute infection-induced involution. Autopsy thymus specimens from children with infection diseases (Sepsis, Encephalomyelitis, Varicella) were examined at light and electron microscopic level and compared to normal infantile thymuses. We observed a redistribution of NGF immunopositive mast cells in infection-affected child thymus, which lobular architecture was collapsed. A positive correlation between the degree of the involutive changes, increased distribution and enhanced NGF immunoreactivity of mast cells was defined. The possible involvement of NGF immunopositive mast cells in the process of acute thymus involution is discussed.

Epithelial framework reorganization during human thymus involution

BACKGROUND

The thymus undergoes age-related (physiological) involution in the course of normal ontogenetic development. In addition to this chronic involution, the thymus can also undergo an acute (age-independent) regression, defined as spontaneous, transient involution. This process is induced by either exogenous or endogenous factors, including some infections (infection-type involution).

OBJECTIVE

The purpose of the present work was to undertake a comparative study of the epithelial framework organization and cytokeratin immunoreactivity of human thymic epithelial cells during age-related and infection-induced involution.

METHODS

Routine methods for light and transmission electron microscopy, as well as indirect immunoperoxidase staining and immunogold electron microscopy, were applied.

RESULTS

The epithelial thymocyte microenvironment was of a generally similar cellular composition in both chronically and acutely involuted thymus. Structurally, aged thymus glands and infection-affected thymus glands displayed a large mass of adipose tissue containing scattered islands composed of epithelial cells, lymphocytes and reticular connective tissue. Correlation between thymus involution and regional peculiarities in the presence and distribution of cytokeratin-immunopositive cells and their intermediate filaments was investigated.

CONCLUSION

The epithelial framework of the thymus undergoes reorganization during both age-related and infection-induced thymus involution. The involutionary processes demonstrated essential regional and intracellular (structural and immunocytochemical) differences. The epithelial cell rearrangement and cytokeratin modulation that we observed might be involved in thymic microenvironment plasticity and reorganization in the course of these processes.