Cancer The antiproliferative effects of sirolimus may have a role in treating cancer. When dosed appropriately, sirolimus can enhance the immune response to tumor targeting or otherwise promote tumor regression in clinical trials. Sirolimus seems to lower the cancer risk in some transplant patients. Sirolimus was shown to inhibit the progression of dermal
Kaposi's sarcoma in patients with renal transplants. Other
mTOR inhibitors, such as
temsirolimus (CCI-779) or
everolimus (RAD001), are being tested for use in cancers such as
glioblastoma multiforme and
mantle cell lymphoma. However, these drugs have a higher rate of fatal adverse events in cancer patients than control drugs. A
combination therapy of
doxorubicin and sirolimus has been shown to drive
Akt-positive lymphomas into
remission in mice. Akt signalling promotes cell survival in Akt-positive lymphomas and acts to prevent the
cytotoxic effects of
chemotherapy drugs, such as doxorubicin or
cyclophosphamide. Sirolimus blocks Akt signalling and the cells lose their resistance to the chemotherapy.
Bcl-2-positive lymphomas were completely resistant to the therapy;
eIF4E-expressing lymphomas are not sensitive to sirolimus.
Tuberous sclerosis complex Sirolimus also shows promise in treating
tuberous sclerosis complex (TSC), a congenital disorder that predisposes those afflicted to benign tumor growth in the brain, heart, kidneys, skin, and other organs. After several studies conclusively linked mTOR inhibitors to remission in TSC tumors, specifically subependymal giant-cell astrocytomas in children and
angiomyolipomas in adults, many US doctors began prescribing sirolimus (Wyeth's Rapamune) and
everolimus (Novartis's RAD001) to TSC patients off-label. Numerous clinical trials using both rapamycin analogs, involving both children and adults with TSC, are underway in the United States.
Effects on longevity mTOR, specifically mTORC1, was first shown to be important in aging in 2003, in a study on worms; sirolimus was shown to inhibit and slow aging in worms, yeast, and flies, and then to improve the condition of
mouse models of various diseases of aging. Sirolimus was first shown to extend lifespan in wild-type mice in a study published by NIH investigators in 2009; the studies have been replicated in mice of many different genetic backgrounds. The results are further supported by the finding that genetically modified mice with impaired mTORC1 signalling live longer. This led to many in the anti-aging community self-experimenting with the compound. However, because of the different biochemical properties of sirolimus, the dosing is potentially very different from that of everolimus. Ultimately, due to known side-effects of sirolimus, as well as inadequate evidence for optimal dosing, it was concluded in 2016 that more research was required before sirolimus could be widely prescribed for this purpose. Two human studies on the effects of sirolimus (rapamycin) on longevity did not show statistically significant benefits. However, due to limitations in the studies, further research is needed to fully assess its potential in humans. Sirolimus has complex effects on the immune system—while
IL-12 goes up and
IL-10 decreases, which suggests an immunostimulatory response,
TNF and
IL-6 are decreased, which suggests an immunosuppressive response. The duration of the inhibition and the exact extent to which mTORC1 and mTORC2 are inhibited play a role, but were not yet well understood according to a 2015 paper.
Topical administration When applied as a topical preparation, researchers showed that rapamycin can regenerate collagen and reverse clinical signs of aging in elderly patients. The concentrations are far lower than those used to treat angiofibromas.
SARS-CoV-2 Rapamycin has been proposed as a treatment for
severe acute respiratory syndrome coronavirus 2 insofar as its
immunosuppressive effects could prevent or reduce the
cytokine storm seen in very serious cases of COVID-19. Moreover, inhibition of
cell proliferation by rapamycin could reduce
viral replication. Oxidized LDL cholesterol is a major contributor to atherosclerosis.
Lupus As of 2016, studies in cells, animals, and humans have suggested that mTOR activation is a process underlying
systemic lupus erythematosus and that inhibiting mTOR with rapamycin may be a disease-modifying treatment. As of 2016 rapamycin had been tested in small clinical trials in people with lupus.
Graft-versus-host disease Due to its immunosuppressant activity, rapamycin has been assessed as prophylaxis or treatment agent of
graft-versus-host disease (GVHD), a complication of
hematopoietic stem cell transplantation. While contrasted results were obtained in clinical trials, pre-clinical studies have shown that rapamycin can mitigate GVHD by increasing the proliferation of regulatory T cells, inhibiting cytotoxic T cells and lowering the differentiation of effector T cells.
Applications in biology research Rapamycin is used in biology research as an agent for
chemically induced dimerization. In this application, rapamycin is added to cells expressing two fusion constructs, one of which contains the rapamycin-binding FRB domain from mTOR and the other of which contains an FKBP domain. Each fusion protein also contains additional domains that are brought into proximity when rapamycin induces binding of FRB and FKBP. In this way, rapamycin can be used to control and study protein localization and interactions.
Neurodegenerative disorders As suppression of autophagy has been indicated as a contributing factor in a variety of neurodegenerative disorders, including
Alzheimer's Disease, rapamycin has been proposed as a potential treatment for these conditions, although results suggest it may not be effective in all cases. == Veterinary uses ==