STAT3 gain-of function (GOF) is a rare genetic disorder of the immune system, leading to early-onset autoimmunity and a variety of multi-organ disorders. The condition is progressive and manifests through a broad spectrum of clinical symptoms, including lymphadenopathy, autoimmune cytopenias, growth delays, enteropathy, lung disease, endocrine disorders, arthritis, autoimmune hepatitis, neurological diseases, vasculopathy, eczema, infections, and multiorgan autoimmunity. Patients experience recurring infections.
STAT3 GOF | |
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Other names | STAT3 Gain of Function [1] disease |
STAT3 GOF syndrome was first described in 2014. In recent years new research has provided understanding and insight in treatment options.[2]
Presentation
editClinically, the STAT3 GOF-associated phenotype is very diverse. It is characterized by prominent lymphoproliferation, including lymphadenopathy and/or hepatosplenomegaly, as well as early-onset multisystem autoimmunity. Hematologic autoimmunity is most prevalent including autoimmune hemolytic anemia, neutropenia, and/or thrombocytopenia. Others exhibited arthritis, lung disease consistent with lymphocytic interstitial pneumonia, hepatitis, atopic dermatitis, alopecia, and/or scleroderma. Several patients also have recurrent, severe infections and fungal infections with hypogammaglobulinemia. Postnatal short stature, with some exhibiting profound growth failure, is commonly seen. Early-onset type 1 diabetes was also noted in several of these patients.[3][4][5]
The stereotyped clinical phenotype of STAT3 GOF patients differs distinctly from that associated with germline STAT3 mutations shown to confer a loss-of-function (LOF). STAT3 loss-of-function mutations are responsible for hyperimmunoglobulin E syndrome, also called Job's syndrome, which is characterized by recurrent infections, unusual eczema-like skin rashes, and susceptibility to severe lung infections. While both LOF and GOF of STAT3 result in immune deficiency, GOF exhibit infections quite distinct from those observed with LOF, along with far more common connective tissue abnormalities.[3]
Furthermore, somatic gain-of-function STAT3 mutations are reported in association with solid and hematologic cancers. Therefore, one would have expected that germline STAT3 GOF mutations would have a similar increase the risk of cancer. However, only 1 patient presented with large granular lymphocytic leukemia and 1 parent with Hodgkin lymphoma.[3] The germline and somatic gain-of-function STAT3 mutations appear to result in distinctly different phenotypes.
Genetics
editThese gain-of-function mutations have been identified as germline mutations, meaning variations in the lineage of germ cells. Most mutations identified were de novo, meaning originating in the symptomatic patient and not inherited from either parent.[4][5] However, multiple cases of inheritance have also been identified. In 2 families, family members carrying a STAT3 mutation were asymptomatic or had a less severe phenotype, indicating that there are carriers of these mutations who display autosomal dominant inheritance with incomplete penetrance.[3] Children of a parent who carries a STAT3 GOF mutation has a 50% chance of inheriting the mutation. Within a family, each child’s risk of inheriting the mutated STAT3 gene is independent of whether other siblings have the mutation. In other words, if the first three children a family have the mutation, the fourth child has the same 50% risk of inheriting the mutation. Children who do not inherit the abnormal gene will not develop this syndrome or pass on the mutation.
Mechanism
editSTAT3 GOF is caused by germline gain-of-function mutations in the gene STAT3. STAT3 maps to human chromosome 17q21.2, has 24 exons, and encodes for the 770 amino acid protein, STAT3.[6][7] STAT3 is part of a family of proteins known as the STAT protein. These proteins play an essential role in chemical signaling pathways within cells. STAT3 is a transcription factor that once activated, moves into the nucleus and binds to specific areas of DNA. By binding to regulatory regions near genes, STAT3 mediates the expression of a variety of genes and is therefore necessary for many cellular processes including cell proliferation, inflammation, differentiation, and survival.[8]
STAT3 GOF patients were found to have germline heterozygous variants. Various missense mutations have been identified in multiple domains of the protein, including the all-alpha, DNA-binding, SH2, and C-terminal transactivation domains (Milner et al, 2014). The genetic model for this disease is gain-of-function. This means that for people with STAT3 GOF disease, the gene STAT3 is hyperactive, leading to an intrinsic increase of transcriptional activity [3][5]
While the consequences of STAT3 hyperactivity are not yet fully understood, some insights into the underlying mechanisms have been identified. Researchers have identified an increase of suppressor of cytokine signaling 3 (SOCS3) in a large number of STAT GOF patients.[3] SOCS3 negatively regulates STAT3 and inhibits other STAT proteins like STAT5 and STAT1. STAT5 is important for regulatory T cell (Treg) differentiation and function, which may explain why many STAT GOF patients have low Tregs. These Treg abnormalities likely play a major role in autoimmunity, although some patients with normal Tregs also presented with autoimmunity disorders.[3] Additionally, a partial decrease of STAT1 activation likely participates in immune deficiencies. Data suggest the upregulation of STAT3 transcriptional activity may have consequences for other cytokine signaling pathways as well.[3]
Notably, there has been no correlation between STAT3 hyperactivity and the severity of the phenotype, in addition to an absence of any genotype-phenotype correlation. This indicates that more research must be done to further understand the role that environmental or other genetic factors may play.[3][4][5]
Diagnosis and inheritance
editA definitive diagnosis for STAT3 GOF diseases currently consists of genetic testing and confirmation with functional tests.[9] STAT3 GOF patients show moderate T-cell lymphopenia, hypogammaglobulinemia, and elevated double negative CD4/CD8 T cells (DNTs). More studies are required to understand the discrepancy associated with many laboratory manifestations, including an impaired Th17 differentiation among patients.[3][4][5]
Variants in STAT3 genes that cause gain-of-function can be inherited in an autosomal dominant manner. However STAT3 GOF variants can also occur as a de novo mutation (spontaneously) in individuals in which a parent is not affected.
Treatment
editResearch shows that in treating STAT3 GOF syndrome, clinical symptoms dramatically improved if patients are treated with JAK-inhibitors, while a variety of other immunomodulatory treatments had less effect.[10] STAT3 is activated in the cell after activation of specific proteins called janus kinases (JAK). JAK-inhibitors like ruxolitinib and tofacitinib specifically inhibit JAK-induced activation of STAT proteins. These JAK-inhibitors have been used off-label and have been successful at improving or resolving symptoms.[9] [11]
References
edit- ^ "STAT3 Gain of Function disease" (PDF). NIH. Retrieved 24 October 2019.
- ^ Leiding, Jennifer W.; Vogel, Tiphanie P.; Santarlas, Valentine G.J.; Mhaskar, Rahul; Smith, Madison R.; Carisey, Alexandre; Vargas-Hernández, Alexander; Silva-Carmona, Manuel; Heeg, Maximilian; Rensing-Ehl, Anne; Neven, Bénédicte; Hadjadj, Jérôme; Hambleton, Sophie; Ronan Leahy, Timothy; Meesilpavikai, Kornvalee (April 2023). "Monogenic early-onset lymphoproliferation and autoimmunity: Natural history of STAT3 gain-of-function syndrome". Journal of Allergy and Clinical Immunology. 151 (4): 1081–1095. doi:10.1016/j.jaci.2022.09.002. ISSN 0091-6749. PMC 10081938. PMID 36228738.
- ^ a b c d e f g h i j k Milner, Joshua D.; Vogel, Tiphanie P.; Forbes, Lisa; Ma, Chi A.; Stray-Pedersen, Asbjørg; Niemela, Julie E.; Lyons, Jonathan J.; Engelhardt, Karin R.; Zhang, Yu (2015-01-22). "Early-onset lymphoproliferation and autoimmunity caused by germline STAT3 gain-of-function mutations". Blood. 125 (4): 591–599. doi:10.1182/blood-2014-09-602763. ISSN 0006-4971. PMC 4304103. PMID 25359994.
- ^ a b c d Haapaniemi, Emma M.; Kaustio, Meri; Rajala, Hanna L. M.; Adrichem, Arjan J. van; Kainulainen, Leena; Glumoff, Virpi; Doffinger, Rainer; Kuusanmäki, Heikki; Heiskanen-Kosma, Tarja (2015-01-22). "Autoimmunity, hypogammaglobulinemia, lymphoproliferation, and mycobacterial disease in patients with activating mutations in STAT3". Blood. 125 (4): 639–648. doi:10.1182/blood-2014-04-570101. ISSN 0006-4971. PMC 4304109. PMID 25349174.
- ^ a b c d e Flanagan, Sarah E; Haapaniemi, Emma; Russell, Mark A; Caswell, Richard; Allen, Hana Lango; Franco, Elisa De; McDonald, Timothy J; Rajala, Hanna; Ramelius, Anita (2014-01-01). "Activating germline mutations in STAT3 cause early-onset multi-organ autoimmune disease". Nature Genetics. 46 (8): 812–814. doi:10.1038/ng.3040. PMC 4129488. PMID 25038750.
- ^ "OMIM Entry - * 102582 - SIGNAL TRANSDUCER AND ACTIVATOR OF TRANSCRIPTION 3; STAT3". www.omim.org. Retrieved 2015-09-15.
- ^ Database, GeneCards Human Gene. "STAT3 Gene - GeneCards | STAT3 Protein | STAT3 Antibody". www.genecards.org. Retrieved 2015-09-15.
- ^ Haddad, Elie (2015-01-22). "STAT3: too much may be worse than not enough!". Blood. 125 (4): 583–584. doi:10.1182/blood-2014-11-610592. ISSN 0006-4971. PMID 25614633.
- ^ a b "STAT1 and STAT3 gain of function | Immune Deficiency Foundation". primaryimmune.org. Retrieved 2024-04-07.
- ^ Leiding, Jennifer W.; Vogel, Tiphanie P.; Santarlas, Valentine G.J.; Mhaskar, Rahul; Smith, Madison R.; Carisey, Alexandre; Vargas-Hernández, Alexander; Silva-Carmona, Manuel; Heeg, Maximilian; Rensing-Ehl, Anne; Neven, Bénédicte; Hadjadj, Jérôme; Hambleton, Sophie; Ronan Leahy, Timothy; Meesilpavikai, Kornvalee (April 2023). "Monogenic early-onset lymphoproliferation and autoimmunity: Natural history of STAT3 gain-of-function syndrome". Journal of Allergy and Clinical Immunology. 151 (4): 1081–1095. doi:10.1016/j.jaci.2022.09.002. ISSN 0091-6749. PMC 10081938. PMID 36228738.
- ^ Forbes, Lisa R.; Vogel, Tiphanie P.; Cooper, Megan A.; Castro-Wagner, Johana; Schussler, Edith; Weinacht, Katja G.; Plant, Ashley S.; Su, Helen C.; Allenspach, Eric J.; Slatter, Mary; Abinun, Mario; Lilic, Desa; Cunningham-Rundles, Charlotte; Eckstein, Olive; Olbrich, Peter (November 2018). "Jakinibs for the treatment of immune dysregulation in patients with gain-of-function signal transducer and activator of transcription 1 (STAT1) or STAT3 mutations". Journal of Allergy and Clinical Immunology. 142 (5): 1665–1669. doi:10.1016/j.jaci.2018.07.020. ISSN 0091-6749. PMC 6322659. PMID 30092289.