|Gray's||subject #274 1273|
Each T cell attacks a foreign substance which it identifies with its receptor. T cells have receptors which are generated by randomly shuffling gene segments. Each T cell attacks a different antigen. T cells that attack the body's own proteins are eliminated in the thymus. Thymic epithelial cells express major proteins from elsewhere in the body. First, T cells undergo "Positive Selection" whereby the cell comes in contact with self-MHC expressed by thymic epithelial cells; those with no interaction are destroyed. Second, the T cell undergoes "Negative Selection" by interacting with thymic dendritic cell whereby T cells with high affinity interaction are eliminated through apoptosis (to avoid autoimmunity), and those with intermediate affinity survive.
Histologically, each lobe of the thymus can be divided into a central medulla and a peripheral cortex which is surrounded by an outer capsule. The cortex and medulla play different roles in the development of T-cells. Cells in the thymus can be divided into thymic stromal cells and cells of hematopoietic origin (derived from bone marrow resident hematopoietic stem cells). Developing T-cells are referred to as thymocytes and are of hematopoietic origin. Stromal cells include thymic cortical epithelial cells, thymic medullary epithelial cells, and dendritic cells.
The thymus provides an inductive environment for development of T-lymphocytes from hematopoietic progenitor cells. In addition, thymic stromal cells allow for the selection of a functional and self-tolerant T-cell repertoire. Therefore, one of the most important roles of the thymus is the induction of central tolerance.
The thymus is largest and most active during the neonatal and pre-adolescent periods. By the early teens, the thymus begins to atrophy and thymic stroma is mostly replaced by adipose (fat) tissue. Nevertheless, residual T lymphopoiesis continues throughout adult life.
- 1 History
- 2 Development
- 3 Anatomy
- 4 Structure
- 5 Function
- 6 Disease associations
- 7 Thymectomy
- 8 Second thymus
- 9 In other animals
- 10 Gallery
- 11 References
- 12 External links
The thymus was known to the ancient Greeks, and its name comes from the Greek word θυμός (thumos), meaning "anger", or "heart, soul, desire, life", possibly because of its location in the chest, near where emotions are subjectively felt; or else the name comes from the herb thyme (also in Greek θύμος or θυμάρι), which became the name for a "warty excrescence", possibly due to its resemblance to a bunch of thyme.
Additionally, the thymus closely resembles the shape of the letter "T." This may also be a possibility for the origin of the name of the organ.
Due to the large numbers of apoptotic lymphocytes, the thymus was originally dismissed as a "lymphocyte graveyard", without functional importance. The importance of the thymus in the immune system was discovered in 1961 by Jacques Miller, by surgically removing the thymus from three day old mice, and observing the subsequent deficiency in a lymphocyte population, subsequently named T-cells after the organ of their origin. Recently, advances in immunology have allowed the function of the thymus in T-cell maturation to be more fully understood.
The two main components of the thymus, the lymphoid thymocytes and the thymic epithelial cells, have distinct developmental origins. The thymic epithelium is the first to develop, and appears in the form of two flask-shape endodermal diverticula, which arise, one on either side, from the third branchial pouch (pharyngeal pouch), and extend lateralward and backward into the surrounding mesoderm and neural crest-derived mesenchyme in front of the ventral aorta.
Here the thymocytes and epithelium meet and join with connective tissue. The pharyngeal opening of each diverticulum is soon obliterated, but the neck of the flask persists for some time as a cellular cord. By further proliferation of the cells lining the flask, buds of cells are formed, which become surrounded and isolated by the invading mesoderm. Additional portions of thymus tissue are sometimes developed from the fourth branchial pouches.
During the late stages of the development of the thymic epithelium, hematopoietic bone-marrow precursors migrate into the thymus. Normal thymic development thereafter is dependent on the interaction between the thymic epithelium and the hematopoietic thymocytes.
The thymus continues to grow between birth and puberty and then begins to atrophy; this thymic involution is directed by the high levels of circulating hormones. Proportional to thymic size, thymic activity (T-cell output) is most active before puberty. Upon atrophy, the size and activity are dramatically reduced, and the organ is primarily replaced with fat (a phenomenon known as "organ involution"). The atrophy is due to the increased circulating level of sex hormones, and chemical or physical castration of an adult results in the thymus increasing in size and activity. Patients with the autoimmune disease Myasthenia gravis commonly (70%) are found to have thymic hyperplasia or malignancy. The reason or order of these circumstances has yet to be determined.
|birth||about 15 grams;|
|puberty||about 35 grams|
|twenty-five years||25 grams|
|sixty years||less than 15 grams|
|seventy years||as low as 5 grams|
The thymus is of a pinkish-gray color, soft, and lobulated on its surfaces. At birth it is about 5 cm in length, 4 cm in breadth, and about 6 mm in thickness. The organ enlarges during childhood, and atrophies at puberty. Unlike the liver, kidney and heart, for instance, the thymus is at its largest in children. The thymus reaches maximum weight (20 to 37 grams) by the time of puberty. The thymus of older people is scarcely distinguishable from surrounding fatty tissue. As one ages the thymus slowly shrinks, eventually degenerating into tiny islands of fatty tissue. By the age of 75 years, the thymus weighs only 6 grams. In children the thymus is grayish-pink in colour and in adults it is yellow.
The thymus will, if examined when its growth is most active, be found to consist of two lateral lobes placed in close contact along the middle line, situated partly in the thorax, partly in the neck, and extending from the fourth costal cartilage upward, as high as the lower border of the thyroid gland. It is covered by the sternum, and by the origins of the sternohyoidei and sternothyreoidei. Below, it rests upon the pericardium, being separated from the aortic arch and great vessels by a layer of fascia. In the neck, it lies on the front and sides of the trachea, behind the sternohyoidei and sternothyreoidei. The two lobes differ slightly in size and may be united or separated.
Each lateral lobe is composed of numerous lobules held together by delicate areolar tissue; the entire organ being enclosed in an investing capsule of a similar but denser structure. The primary lobules vary in size from that of a pin's head to that of a small pea, and are made up of a number of small nodules or follicles.
The follicles are irregular in shape and are more or less fused together, especially toward the interior of the organ. Each follicle is from 1 to 2 mm in diameter and consists of a medullary and a cortical portion, and these differ in many essential particulars from each other.
The cortical portion is mainly composed of lymphoid cells, supported by a network of finely-branched epithelial reticular cells, which is continuous with a similar network in the medullary portion. This network forms an adventitia to the blood vessels.
In the medullary portion, the reticulum is coarser than in the cortex, the lymphoid cells are relatively fewer in number, and there are concentric, nest-like bodies called Hassall's corpuscles. These concentric corpuscles are composed of a central mass, consisting of one or more granular cells, and of a capsule formed of epithelioid cells. They are the remains of the epithelial tubes, which grow out from the third branchial pouches of the embryo to form the thymus. Each follicle is surrounded by a vascular plexus, from which vessels pass into the interior, and radiate from the periphery toward the center, forming a second zone just within the margin of the medullary portion. In the center of the medullary portion there are very few vessels, and they are of minute size.
The medulla is the location of the latter events in thymocyte development. Thymocytes that reach the medulla have already successfully undergone T cell receptor gene rearrangement and positive selection, and have been exposed to a limited degree of negative selection. The medulla is specialised to allow thymocytes to undergo additional rounds of negative selection to remove auto-reactive T-cells from the mature repertoire. The gene AIRE is expressed by the thymic medullary epithelium, and drives the transcription of organ-specific genes such as insulin to allow maturing thymocytes to be exposed to a more complex set of self-antigens than is present in the cortex.
The nerves are exceedingly minute; they are derived from the vagi and sympathetic nervous system. Branches from the descendens hypoglossi and phrenic reach the investing capsule, but do not penetrate into the substance of the organ.
In the two thymic lobes, hematopoietic precursors from the bone-marrow, referred to as thymocytes, mature into T-cells. Once mature, T-cells emigrate from the thymus and constitute the peripheral T-cell repertoire responsible for directing many facets of the adaptive immune system. Loss of the thymus at an early age through genetic mutation (as in DiGeorge Syndrome) results in severe immunodeficiency and a high susceptibility to infection.
The stock of T-lymphocytes is built up in early life, so the function of the thymus is diminished in adults. It is largely degenerated in elderly adults and is barely identifiable, consisting mostly of fatty tissue, but it continues its endocrine function. Involution of the thymus has been linked to loss of immune function in the elderly, susceptibility to infection and to cancer.
The ability of T-cells to recognize foreign antigens is mediated by the T cell receptor. The T cell receptor undergoes genetic rearrangement during thymocyte maturation, resulting in each T-cell bearing a unique T-cell receptor, specific to a limited set of peptide:MHC combinations. The random nature of the genetic rearrangement results in a requirement of central tolerance mechanisms to remove or inactivate those T cells which bear a T cell receptor with the ability to recognise self-peptides.
- A rare population of hematopoietic progenitor cells enter the thymus from the blood, and expands by cell division to generate a large population of immature thymocytes.
- Immature thymocytes each make distinct T-cell receptors by a process of gene rearrangement. This process is error-prone, and some thymocytes fail to make functional T-cell receptors, whereas other thymocytes make T-cell receptors that are autoreactive.
- Immature thymocytes undergo a process of selection, based on the specificity of their T-cell receptors. This involves selection of T-cells that are functional (positive selection), and elimination of T-cells that are autoreactive (negative selection). The medulla of the thymus is the site of T Cell maturation.
|type:||functional (positive selection)||autoreactive (negative selection)|
In order to be positively-selected, thymocytes will have to interact with several cell surface molecules, MHC/HLA, to ensure reactivity and specificity.
Positive selection eliminates (apoptosis) weak binding cells and only takes high medium binding cells. (Binding refers to the ability of the T-cell receptors to bind to either MHC class I/II or peptide molecules.)
Negative selection is not 100% complete. Some autoreactive T-cells escape thymic censorship, and are released into the circulation.
Cells that pass both levels of selection are released into the bloodstream to perform vital immune functions.
The immune system is a multicomponent interactive system. It effectively protects the host from various infections. An improperly functioning immune system can cause discomfort, disease or even death. The type of malfunction falls into one or more of the following major groups: hypersensitivity or allergy, auto-immune disease, or immunodeficiency.
Allergy results from an inappropriate and excessive immune response to common antigens. Substances that trigger an allergic response are called allergens. Allergies involve mainly IgE, antibodies, and histamine. Mast cells release the histamine. Sometimes an allergen may cause a sudden and severe, possibly fatal reaction in a sensitive individual; this is called anaphylaxis.
As the thymus is the organ of T-cell development, any congenital defect in thymic genesis or a defect in thymocyte development can lead to a profound T cell deficiency in primary immunodeficiency disease. Defects that affect both the T cell and B cell lymphocyte lineages result in Severe Combined Immunodeficiency Syndrome (SCIDs). Acquired T cell deficiencies can also affect thymocyte development in the thymus.
DiGeorge syndrome is a genetic disorder caused by the deletion of a small section of chromosome 22. This results in a midline congenital defect including thymic aplasia, or congenital deficiency of a thymus. Patients may present with a profound immunodeficiency disease, due to the lack of T cells. No other immune cell lineages are affected by the congenital absence of the thymus. DiGeorge syndrome is the most common congenital cause of thymic aplasia in humans. In mice, the nude mouse strain are congenitally thymic deficient. These mice are an important model of primary T cell deficiency.
Severe combined immunodeficiency syndromes (SCID) are group of rare congenital genetic diseases that result in combined T lymphocyte and B lymphocyte deficiencies. These syndromes are caused by defective hematopoietic progenitor cells which are the precursors of both B- and T-cells. This results in a severe reduction in developing thymocytes in the thymus and consequently thymic atrophy. A number of genetic defects can cause SCID, including IL-7 receptor deficiency, common gamma chain deficiency, and recombination activating gene deficiency. The gene for the disease called ADA (adenine deaminase) is located on chromosomes 20.
The HIV virus causes an acquired T-cell immunodeficiency syndrome (AIDS) by specifically killing CD4+ T-cells. Whereas the major effect of the virus is on mature peripheral T-cells, HIV can also infect developing thymocytes in the thymus, most of which express CD4.
Autoimmune diseases are caused by a hyperactive immune system that instead of attacking foreign pathogens reacts against the host organism (self) causing disease. One of the primary functions of the thymus is to prevent autoimmunity through the process of central tolerance, immunologic tolerance to self antigens.
Autoimmune polyendocrinopathy-candidiasis-ectodermal dystrophy (APECED) is an extremely rare genetic autoimmune syndrome. However, this disease highlights the importance of the thymus in prevention of autoimmunity. This disease is caused by mutations in the Autoimmune Regulator (AIRE) gene. AIRE allows for the ectopic expression of tissue-specific proteins in the thymus medulla, such as proteins that would normally only be expressed in the eye or pancreas. This expression in the thymus, allows for the deletion of autoreactive thymocytes by exposing them to self-antigens during their development, a mechanism of central tolerance. Patients with APECED develop an autoimmune disease that affects multiple endocrine tissues.
Myasthenia gravis is an autoimmune disease caused by antibodies that block acetylcholine receptors. Myasthenia gravis is often associated with thymic hypertrophy. Thymectomy may be necessary to treat the disease.
Two primary forms of tumours originate in the thymus.
Tumours originating from the thymic epithelial cells are called thymomas, and are found in about 10-15% of patients with myasthenia gravis. Symptoms are sometimes confused with bronchitis or a strong cough because the tumour presses on the recurrent laryngeal nerve. All thymomas are potentially cancerous, but they can vary a great deal. Some grow very slowly. Others grow rapidly and can spread to surrounding tissues. Treatment of thymomas often requires surgery to remove the entire thymus.
People with an enlarged thymus, particularly children, were treated with intense radiation in the years before 1950. There is an elevated incidence of thyroid cancer and leukemia in treated individuals.
Cervical thymic cyst
Cervical thymus is a rare malformation. Thymic tissue containing cysts are rarely described in the literature, ectopic glandular tissue included in the wall of cystic formation can trigger a series of problems similar to those of thymus.
Thymic cysts are uncommon lesions, about 150 cases being found. While thymic cyst and ectopic cervical thymus are identified most frequently in childhood, the mean age at which thymoma is diagnosed is 45 years. However, studies have shown the existence necroptic thymic tissue masses in the neck (asymptomatic intravital) more frequently, the incidence reaching nearly 30%. These observations may mean absence of clinical observation.
Thymectomy is the surgical removal of the thymus. The most common reason for thymectomy in the United States is to gain surgical access to the heart in surgeries to correct congenital heart defects that are performed in the neonatal period. In neonates, but not older children or adults, the relative size of the thymus obstructs surgical access to the heart. Removal of the thymus in infancy results in immunodeficiency by some measures, although T cells develop compensating function and it remains unknown whether disease incidence in later life is significantly greater. This is because sufficient T cells are generated during fetal life prior to birth. These T cells are long-lived and can proliferate by homeostatic proliferation throughout the lifetime of the patient. However, there is evidence of premature immune aging in patients thymectomized during early childhood.
Other indications for thymectomy include the removal of thymomas and the treatment of myastenia gravis. Thymectomy is not indicated for the treatment of primary thymic lymphomas. However, a thymic biopsy may be necessary to make the pathologic diagnosis.
The thymus is also present in most vertebrates, with similar structure and function as the human thymus. Some animals have multiple secondary (smaller) thymi in the neck; this phenomenon has been reported for mice  and also occurs in 5 out of 6 human fetuses. As in humans, the Guinea pig's thymus naturally atrophies as the animal reaches adulthood, but the athymic hairless guinea pig (which arose from a spontaneous laboratory mutation) possesses no thymic tissue whatsoever, and the organ cavity is replaced with cystic spaces.
In other animals
The thymus is present in all jawed vertebrates, where it undergoes the same shrinkage with age and plays the same immunological function as in human beings. Recently, a discrete thymus-like lympho-epithelial structure, termed the thymoid, was discovered in the gills of larval lampreys. Hagfish possess a protothymus associated with the pharyngeal velar muscles, which is responsible for a variety of immune responses. Little is known about the immune mechanisms of tunicates or of Amphioxus.
When used for consumption, animal thymic tissue is known as (one of the kinds of) sweetbread.
- "Translation of Greek word "θυμός" in English". Retrieved 5 October 2012.
- θυμός, Henry George Liddell, Robert Scott, A Greek-English Lexicon, on Perseus
- Online Etymology Dictionary
- Nishino M, Ashiku SK, Kocher ON, Thurer RL, Boiselle PM, Hatabu H (2006). "The thymus: a comprehensive review". Radiographics 26 (2): 335–48. doi:10.1148/rg.262045213. PMID 16549602.
- Miller JF (2002). "The discovery of thymus function and of thymus-derived lymphocytes". Immunol. Rev. 185: 7–14. doi:10.1034/j.1600-065X.2002.18502.x. PMID 12190917.
- Miller JF (2004). "Events that led to the discovery of T-cell development and function--a personal recollection". Tissue Antigens 63 (6): 509–17. doi:10.1111/j.0001-2815.2004.00255.x. PMID 15140026.
- Swiss embryology (from UL, UB, and UF) qblood/lymphat03
- Sutherland, J. S. (2005). "Activation of thymic regeneration in mice and humans following androgen blockade". J Immunol 175 (4): 2741–53. PMID 16081852.
- Kumar, Parveen, Michael Clark (2002). Clinical Medicine (5th ed.). Saunders. p. 1222. ISBN 0-7020-2606-9.
- Gray, H. (1918). (bartleby.com) "4c. The Thymus". Anatomy of the Human Body. Philadelphia: Lea & Febiger.
- BU Histology Learning System: 07403loa
- BU Histology Learning System: 07401loa
- Hussain, I., P.H. Win and S. Guduri (February 2, 2006). "DiGeorge Syndrome". eMedicine. Retrieved 2008-09-29.
- Miller, J. F. (2002). "The discovery of thymus function and of thymus-derived lymphocytes". Immunol Rev 185 (1): 7–14. doi:10.1034/j.1600-065X.2002.18502.x.
- "Thymus". Retrieved 2007-12-03.
- Schwarz, B. A.; Bhandoola, A. (2006). "Trafficking from the bone marrow to the thymus: a prerequisite for thymopoiesis". Immunol Rev 209 (1): 47. doi:10.1111/j.0105-2896.2006.00350.x.
- Sleckman, B. P. (2005). "Lymphocyte antigen receptor gene assembly: multiple layers of regulation". Immunol Res 32 (1–3): 253–258. doi:10.1385/IR:32:1-3:253.
- Baldwin, T. A.; Hogquist, K. A.; Jameson, S. C. (2004). "The fourth way? Harnessing aggressive tendencies in the thymus". J Immunol 173 (11): 6515–20. PMID 15557139.
- Peterson, P. R.; Org, T. N.; Rebane, A. (2008). "Transcriptional regulation by AIRE: Molecular mechanisms of central tolerance". Nature Reviews Immunology 8 (12): 948–957. doi:10.1038/nri2450. PMC 2785478. PMID 19008896.
- Huete-Garin, A.; S.S. Sagel (2005). "Chapter 6: "Mediastinum", Thymic Neoplasm". In J.K.T. Lee, S.S. Sagel, R.J. Stanley and J.P. Heiken. Computed Body Tomography with MRI Correlation. Philadelphia: Lippincott Williams & Wilkins. pp. 311–324. ISBN 0-7817-4526-8.
- Shore, R. E.; Woodward, E.; Hildreth, N.; et al. (1985). "Thyroid Tumors Following Thymus Irradiation". J Natl Cancer Inst 74 (6): 1177–1184. doi:10.1093/jnci/74.6.1177. PMID 3858590.
- Octavian Dincă, Cristina Pădurariu, Alexandru Bucur (Oct 2011). "A rare entity — cervical thymic cyst". Rev. chir. oro-maxilo-fac. implantol. (in (Romanian)) 2 (3): 1–5. ISSN 2069-3850. 38. Retrieved 2012-06-06.(webpage has a translation button)
- Sauce, D.; et al. (2009). "Evidence of premature immune aging in patients thymectomized during early childhood". J Clin Invest 119 (10): 3070–3078. doi:10.1172/JCI39269. PMID 19770514.
- PMID 16907907 (PubMed)
- Eysteinsdottir, J. H.; et al. (2004). "The influence of partial or total thymectomy during open heart surgery in infants on the immune function later in life". Clin Exp Immunol 136 (2): 349–355. doi:10.1111/j.1365-2249.2004.02437.x. PMC 1809033. PMID 15086401.
- http://www.jacionline.org/article/S0091-674[full citation needed]
- Journal of Clinical Investigation. "Evidence of premature immune aging in patients thymectomized during early childhood". JCI. Retrieved 2012-06-11.
- Terszowski G et al. (2006) Evidence for a Functional Second Thymus in Mice. Science. 2 March 2006. PMID 16513945
- Surprise organ discovered in mice, Nature News, 2 March 2006
- Bajoghli; et al. (2011). "A thymus candidate in lampreys". Nature 470 (7332): 90–94. doi:10.1038/nature09655.
- Riviere; et al. (1975). "In Search of the Hagfish Thymus". American Zoologist 15 (1): 39–49. JSTOR 3882269.
- Sawada (1992). "Tunicates and Their Immune Mechanism". Bull. Yamaguchi Med. Sch. 39 (3–4): 83–88.