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Normal Structure, Function and Histology of the Thymus

AstraZeneca, Alderley Park, Macclesfield, Cheshire, SK10 4TG, United Kingdom

Correspondence: Address correspondence to: Gail Pearse, AstraZeneca, 23F22A, Mere-side, Alderley Park, Macclesfield, Cheshire, SK10 4TG, United Kingdom; e-mail:Gail.Pearse{at}astrazeneca.com

	Abstract

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The thymus, a primary lymphoid organ and the initial site for development of T cell immunological function, is morphologically similar across species. It is actually an epithelial organ in which its epithelial cells provide a framework containing T cells as well as smaller numbers of other lymphoid cells. A symbiotic interaction exists between the thymic microinvironment and developing T cells, and the specificity of T cell release into the systemic circulation is under thymic control. The thymic cortex in a young animal is heavily populated by developing T cells along with a smaller proportion of associated epithelial cells. Larger, more mature T cells are found in the medulla where epithelial and other cell types are more abundant. Understanding normal morphological features of the thymus and their perturbations provides a cornerstone to assessing immune system function.

Key Words: T cells • epithelial cells • positive & negative selection • SCID mice • anatomy • epithelium-free areas

	Embrology/Development

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The rodent thymus develops from the endoderm of the 3rd and 4th pharangeal pouches and surrounding mesenchyme. (Dijkstra and Sminia, 1990) The pharangeal pouch connects with the pharynx via the thymopharangeal duct, remnants of which may be incorporated into the developing thymus giving rise to epithelial cystic structures (Figures 1 and 2). As development progresses, the thymus along with the thyroid and parathyroid, sharing the same pharangeal pouch origin, migrate caudally. They separate around day 15 when the thymus migrates into the thorax. Embryonic thymic remnants can give rise to ectopic thymic tissue in the neck (Figure 3), thyroid (Figure 4) and parathyroid glands (Suster and Rosai, 1992). Once migration is complete the epithelial cells organize into a loose meshwork separated by the developing vasculature. Following the rapid population with lymphocyte precursors from developing hematopoetic tissues (gestational day 11–12 in the mouse), the thymus becomes a lymphoepithelial organ. Because of their common pharyngeal pouch origin, ectopic thyroid (Figure 5) and parathyroid (Figure 6) can occasionally be found in the thymus.

View larger version (818K): [in this window] [in a new window]   Figure 1 Representative examples of thymic cysts. Thymic cysts represent developmental remnants in the genesis of the thymus from the thymopharyngeal duct. (A) A large cyst filled with amorphous eosinophilic material extended from the surface of the thymus in this 2-year-old male F344 rat. The adjacent thymic parenchyma is undergoing involution. (B) A higher magnification of A showing the cyst wall lined by columnar ciliated epithelium. (C) This small cyst from a SCID mouse on a BALB/c background is located at the edge of the thymus. The thymic parenchyma lacks a distinct cortex and medulla. Brown fat is present at the left side of the image. (D) This higher magnification of C shows the cyst lining consisting of ciliated columnar epithelium with occasional goblet cells. 2.—A thymic cyst in a dog. The cyst is lined by columnar epithelium and a few of the lining cells have visible cilia on their luminal surface. The cyst contains amphophilc flocculent material. Photomicrograph courtesy of Dr. Michael Leach. 3.—Ectopic thymic tissue is located in the neck adjacent to the trachea and esophagus in this 2-year-old female F344 rat. The ectopic thymic tissue has undergone age-associated involution.

View larger version (698K): [in this window] [in a new window]   Figure 4 Ectopic thymus is located at the edge of the thyroid and parathyroid in this rat. The ectopic thymus consists of both cortex and medulla and should be completely functional. Photomicrograph courtesy of Dr. Michael Leach. 5.—The edge of this mouse thymus contains an island of ectopic thyroid tissue that appears histologically normal. Photomicrograph courtesy of Dr. Michael Leach. 6.—Ectopic parathyroid in the thymus. (A) Ectopic parathyroid is attached to the capsule of the thymus in this 2-year-old female F344 rat. The thymus is undergoing age-associated involution with loss of a distinct cortex and medulla and presence of developing glandular structures. (B) Higher magnification of the ectopic parathyroid in A. The histomorphological features of the parathyroid are normal.

	Fixation and Processing of the Thymus

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Thymic weights are usually measured prior to fixation and following removal of adjacent fat and connective tissue. The thymus of aged, immunosuppressed, or immunodefficient animals may be difficult to locate. In this case, adipose and connective tissues from the anterior mediastinum containing thymic tissue should be collected and fixed without weighing (Kuper et al., 1995).

In routine studies, the thymus is normally fixed in 10% buffered formalin. The majority of thymic T cells can be shown to express CD3 on formalin fixed, paraffin-embedded tissue. Similarly, B cells can be demonstrated in formalin fixed tissue with antibodies to CD45R. However, if specific phenotyping of T cells is required, use of antigen retrieval methods and use of frozen sections may be required (Ward et al., 2006). Some authors prefer that the tissue should be snap-frozen, since phenotyping involves the use of antibodies against cell surface antigens such as CD4 and CD8, which are present only in small amounts and which are lost with conventional fixation (Schuurman et al., 1994). Ethanol fixation is preferred for the demonstration of keratin expression. Special fixation methods used for various procedures in immunotoxicity studies are discussed by Kuper et al. (1995).

Following fixation, the thymus is trimmed transversely through the middle of the organ, to include both lobes and then embedded. (Figure 7).

View larger version (48K): [in this window] [in a new window]   Figure 7 An illustration of a recommended sampling of the bilobed thymus in the rodent. Consistent sampling of the thymus in a study will allow for more accurate comparison of relative amounts of cortex and medulla among the study animals.

	Normal Anatomy

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View larger version (1275K): [in this window] [in a new window]   Figure 8 Comparative features of rat and mouse thymic tissue. (A) This thymus from a 3-month-old female Wistar rat shows the relative amounts of cortex and medulla. The rat thymus is partially subdivided into lobules separated by thin bands of connective tissue which are continuous with the thin connective tissue capsule. (B) A higher magnification of A. (C) In contrast to the rat, the mouse thymus does not have sublobulation. This is a normal thymus from a 3-month-old B6C3F1 mouse taken at the same magnification as the rat thymus in A. (D) A higher magnification of C. The mouse thymus is enclosed in a very thin connective tissue capsule which is not visible even at this magnification.

	Blood, Lymphatic and Nerve Supply

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Prothymocytes are thought to enter the thymic stroma through the large venules at the corticomedullary junction, and re-enter the circulation through the vascular lining of post-capilliary venules. These perivascular areas contain accumulations of phenotypically mature T cells that express the marker Mel 14, a receptor involved in the migration of lymphocytes through the lymphoid vasculature (van Ewijk et al., 1988). Efferent lymphatics drain into an adjacent pair of lymph nodes. The thymus has no afferent lymphatics. The rodent thymus has an abundant noradrenergic innervation but some cholinergic innervation has also been demonstrated (De Waal et al., 1997). Nerves follow the vasculature, within the capsule and septae and the highest concentration of nerve fibres is in the corticomedullary junction.

	Histology

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Of the various lymphoid tissues, the thymus is histologically most consistent across species (Haley, 2003). It is unique among the lymphoid organs in being an epithelial organ. The epithelial cells form an open framework containing predominantly T lymphocytes, smaller populations of B lymphocytes and plasma cells and scattered populations of other cells such as neuroendocrine cells. It is divided into a morphologically distinct cortex and medulla separated by a vascular corticomedullary zone.

Epithelial Stroma
The bulk of the supporting framework in the thymus is composed of the network of epithelial-reticular cells (Banks, 1993). Epithelial cells in the subcapsular region of the thymus form a layer 1 or 2 cells deep. In the outer cortex and ensheathing blood vessels, epithelial cells are thin and sheet-like, but elsewhere they assume a stellate appearance.

Epithelial cells are divided into distinct populations that differ in antigenic expression, ultrastructural characteristics (DeWaal et al., 1997), and their capacity to synthesize the thymic hormones thymulin, thymosin, thymopoetin and thymic humoral factor. Immunohistochemically, epithelial cells can be divided into four distinct subtypes: subcapsular cortical, inner cortical, medullary and Hassalls corpuscles. A decrease in the number of different antigenic epithelial populations occurs with age in mice. Main antigenic determinants of human thymic epithelium are listed in Table 1. More extensive and detailed lists of immunohistochemical markers are provided by Greaves (2000); Kuper et al. (1995); and Suster and Rosai (1992).

Epithelium-free areas (or "holes") are compartments lacking stromal elements, which have been identified in the sub-capsular area, extending deep into the cortex (Bruijntjes et al., 1993; Elmore, 2006).

Cortex
Histologically, the darkly staining cortex contains densely packed, small, immature lymphocytes, which overshadow the sparse epithelial cell population (Figure 9), and a transient bone-marrow derived population of predominantly phagocytic macrophages. Large, mitotically active lymphoblasts, may be found in the subcapsular cortex. These cells have a round to oval nucleus with one or two prominent nuclei and relatively abundant, strongly basophilic cytoplasm. A gradient of small, less mitotically active cells occurs from the outer cortex to the corticomedullary junction. In the subcapsular region and deep cortex large numbers of rapidly dividing lymphocytes are short-lived and undergo apoptosis therefore, prominent cortical apoptotic bodies are a normal background finding. Apoptotic bodies are phagocytosed by macrophages and are visible within their cytoplasm resulting in the name "tingible-body macrophages" (Figure 10).

View larger version (837K): [in this window] [in a new window]   Figure 9 Thymic cortex from a normal 50-day-old Sprague–Dawley rat. The sparce epithelial cells (arrows) are overshadowed by the abundant small lymphocytes that normally populate the cortex. 10.—Thymic cortex from a young mouse. The predominant cell is the small lymphocyte. In a normally active thymus, occasional lymphocytes are removed by negative selection after undergoing apoptosis and becoming phagocytized by macrophages. The phagocytized lymphocytes are seen in "tingible body macrophages" (arrows) in the thymic cortex.

Medulla
The medulla, is continuous between adjacent lobules (Haley, 2003) and can form small buds that reach deep into the cortex that in some places reach the capsule (Figure 11). The medulla is paler staining, less densely cellular than the cortex, and contains more mature T-cells, prominent epithelial cells (Figure 12), Hassalls corpuscles, admixed macrophages, dendritic cells (non-phagocytic, bone marrow-derived cells), B lymphocytes and rarely myoid cells. The medullary T-lymphocytes are larger, paler-staining and have more cytoplasm than cortical lymphocytes.

View larger version (267K): [in this window] [in a new window]   Figure 11 Thymus from a normal 6-week-old BALB/c mouse shown as an example of the occasional extension of the medulla into the cortex. (A) Medullary tissue (arrow) has extended into the cortex and up to the thin connective tissue capsule. (B) Higher magnification of A. The very thin connective tissue capsule of the mouse thymus is evident at this magnification.

View larger version (948K): [in this window] [in a new window]   Figure 12 This photomicrograph of the thymus of a 3-month-old B6C3F1 mouse shows the distinct difference in cellular density between the cortex in the upper half of (A) and the medulla in the lower half of (A). The darker staining of the cortex is due to more numerous small lymphocytes. (B) This high magnification of the medulla from a mouse was sectioned at 3 microns and shows more cellular detail than is typically seen in standard 5- to 6-micron sections. Prominent epithelial cells (arrows) are readily apparent while other cell types such as macrophages and dendritic cells are more difficult to identify in standard hematoxylin and eosin-stained sections. While small lymphocytes are present in the normal thymic medulla, they are less dense than in the cortex.

View larger version (662K): [in this window] [in a new window]   Figure 13 Hassall’s corpuscles are epithelial cells in the thymic medulla that generally have a large nucleus, degenerative changes in the cytoplasm, and cytoplasmic keratinization in some species. Hassall’s corpuscles are rare in rodents compared to humans. (A) This equivocal Hassall’s corpuscle (arrow) from a B6C3F1 mouse has granular cytoplasm and contains necrotic debris. It is shown to demonstrate the difficulty in clearly recognizing Hassall’s corpuscles in the rodent. Without a special stain, such as a keratin stain, one cannot identify rodent Hassall’s corpuscles with certainty. This cell could very easily represent a macrophage phagocytizing apoptotic lymphocytes. (B) This B6C3F1 mouse has a more distinctly obvious Hassall’s corpuscle (arrow) in which the granular cytoplasm contains a small whorl of keratin appearing material. (C) Two adjacent more characteristic Hassall’s corpuscles are present in the thymic medulla in the genetically engineered knock-out mouse on a C57BL/6 background. The mouse was 6 weeks old and exhibited severely retarded growth. The thymic tissue surrounding the Hassall’s corpuscles contains an increased number of small lymphocytes. (D) Higher magnification of C.

Neuroendocrine cells occur in low numbers. Their physiological function is not understood but they can give rise to carcinoid tumors. Mast cells and eosinophils are also variably present.

The Corticomedullary Ratio
The ratio between the cortex and medulla is typically determined subjectively from a low to medium magnification of the thymus and is frequently part of an enhanced histopathological evaluation of the thymus (Elmore, 2006). Since this ratio can vary depending upon the orientation of the thymus at trimming, it is recommended that a standardized trimming procedure be followed (see Figure 7). Tryphonas et al. (2004) provided morphometric measurements of histological sections of the thymus in control Sprague–Dawley rats. By their method, the average cortico-medullary ratio was determined to be 4.4 to 4.7 (30 and 90 day-old males) and 3.9 to 6.3 (30-and 60 day-old females).

	Electron Microscopy

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On electron microscopy, cortical epithelial cells have elongated cytoplasmic processes connected by desmosomes to adacent cells. Processes are covered in a basal lamina. Medullary epithelial cells are more voluminous and oval-shaped with short cytoplasmic extensions and many secretory organelles. DeWaal et al. (1997) discuss the ultrastructural details of the thymic component cells. Kato (1997) provides ultrastructural details of the mouse thymic microvascular system.

	Normal Function

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The thymus is a primary lymphoid organ, viz. bone marrow derived progenitor cells undergo differentiation/maturation, within the thymic microenvironment, to form the functional T cell repertoire. For an excellent overview of the functional aspects of the immune system one should consult: Abbas (2005), Brown et al. (2002), Tizard (2004), and Lebish et al. (1986).

Prothymocytes migrate from the bone marrow, enter the thymus via the vasculature at the corticomedullary junction, and undergo 4 stages of maturation, as they pass from the sub-capsular zone through the cortex to the medulla and finally enter the circulation as mature peripheral T cells. During intrathymic migration, developing T cells (thymocytes) proliferate and differentiate, resulting in changes in cell size and expression of differentiation antigens and interleukin receptors (van Ewijk et al., 1988). Phenotypic change is accompanied by T cell receptor (TCR) gene rearrangement: necessary for expression of surface T cell receptors and the generation of T cell competence. T cell receptor gene rearrangement is reviewed by Perryman (2004).

Transitional stages of thymocyte maturation can be characterized on the basis of the immunological phenotype of the cells as judged by the expression of the T cell receptor (TCR)-CD3 complex and its coreceptors CD4 and CD8 (differentiation antigens) (Kuper et al., 2002). Thymocytes differentiate from an immature double negative (CD4–/CD8–) phenotype, to an intermediate double positive phenotype (CD4+/CD8+), found on the majority of cortical thymocytes. CD4+/CD8+ thymocytes express a diverse repertoire of TCR specificities. Successful engagement of TCR with major histocompatibility complex (MHC) class I molecules, leads to differentiation into precursors of cytotoxic/suppressor T cells (CD4–/CD8+ phenotype). Engagement of TCR with major histocompatibility complex (MHC) class II molecules leads to differentiation into precursors of helper T cells (CD4+/CD8– phenotype). These single positive, mature phenotypes are located predominantly in the medulla. (De Waal et al., 1997).

The thymus also controls the specificity of T cells entering the circulation by means of positive and negative selection. Positive selection involves major histocompatibility complex (MHC) restriction, in which there is clonal expansion only of those T cells capable of recognizing antigen in the context of host MHC 1 and 2. The thymic nurse cells, express MHC class I and II and play a major role in positive selection. In negative selection, developing T cells, which bear receptors to self-antigens (autoreacive cells) undergo apoptosis, thereby causing clonal deletion of potentially harmful cells.

Thus, there are many more cortical lymphocytes than those entering the medulla, and eventually released by thymus into the general circulation. Apoptotic bodies and tingible body macrophages are therefore a normal histological feature of the cortex, particularly in young animals. The vast majority of apoptotic cells in the thymus is thought to be a reflection of failure to undergo positive selection. (De Waal et al., 1997)

Epithelium-Free Areas (or "Holes")
These areas contain occasional phagocytic macrophages and abundant lymphocytes, (predominantly CD4+/CD8+) with a high rate of proliferation (Figure 14). They are thought to offer a separate intrathymic pathway for T-lymphocytes, whereby immature lymphocytes can move between the cortex, corticomedullary zone and medulla without coming into contact with the stromal elements concerned with selection (Bruijntjes et al., 1993). A summary of thymic function by region is presented in Table 2.

View larger version (617K): [in this window] [in a new window]   Figure 14 Epithelial-free areas (EFAs) are sometimes observed in the cortex of some strains/stocks of rats. This example is from a Wistar rat. EFAs are characteristically located at the capsular surface (arrows) and are comprised of a higher than normal density of small lymphocytes due to the absence of the epithelial cell component normally present in the thymic cortex. Tingible-body macrophages that have phagocytized apoptotic lymphocytes are evident in these EFAs as awell as elsewhere in the normal cortex. Photomicrograph courtesy of Dr. C. Frieke Kuper.

	Genetically Modified Animals

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A symbiotic interaction exists between the thymic microenvironment and developing T cells. Various mouse models have been developed to demonstrate the role of thymic microenvironment in positive and negative selection of T cells and the potential influence of T cells on the development of thymic microenvironments (van Ewijk, 1991; De Waal et al., 1997).

SCID Mouse
Severe Combined Immunodefficiency Syndrome (SCID) is a genetic disorder characterized by failure of B and T lymphocyte differentiation. An important aspect of T lymphocyte differentiation requires rearrangement and expression of genes encoding T lymphocyte antigen-specific receptors (and B lymphocyte surface immunoglobulin receptors). Failure to properly complete these gene rearrangement events results in the elimination of lymphocyte precursors and near absence of mature, functional T and B lymphocytes. In mice the enzyme DNA-dependent protein kinase (DNA-PK) is required for gene rearrangement. Lack of this enzyme occurs as a spontaneous autosomal recessive mutation in C.B-17 BALB/c mice. Animals homozygous for the SCID mutation are severely deficient in functional B and T lymphocytes.

Since T lymphocyte development is necessary for the maintenance of thymic stromal integrity, and the development of a distinct cortex and medulla, the thymus is difficult to identify in these animals. Van Ewijk (1991) demonstrated that the thymic microenvironment was also abnormal in SCID mice. Stromal elements in these mice have a cortical phenotype and low numbers of medullary epithelial cells are scattered throughout the entire thymus. Histologically, the thymus consists of small dysplastic lobules, in which there is a marked paucity of lymphocytes (Figure 15). Hassall’s corpuscles may be evident. In some mice, known as "leaky SCIDS," T cell differentiation may be partially restored over time and in these animals there is patchy re-organisation of the medullary epithelium.

View larger version (341K): [in this window] [in a new window]   Figure 15 Thymus from a female SCID mouse on a BALB/c background. (A) There is no clearly delineated cortex and medulla in this low magnification of the thymus from a 6-week-old SCID mouse. (B) This higher magnification of A shows a mixture of stromal/epithelial cells and a paucity of lymphocytes.

Athymic/Nude Mouse
In the homozygous nude (nu) mouse, there is failure of haircoat development and dysgenisis of the thymus, which does not develop beyond a rudimentary stage of epithelial delineated canaliculi, lacking in lymphoid cells (Hansen, 1978).

	Footnotes

 
This research was supported in part by the Intramural Research Program of the NIH, National Institute of Environmental Health Sciences.

	References

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This Article Abstract Free Full Text (Free PDF) Free Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Saved Citations Download to citation manager Request Permissions Request Reprints Add to My Marked Citations Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Pearse, G. Search for Related Content PubMed PubMed Citation Articles by Pearse, G. Social Bookmarking                   What's this?