Developing Sphingosine-1-Phosphate (Spns2) Inhibitors for the Treatment of Multiple Sclerosis

Shrader, Christopher Wayne

29 February 2024

Doctor of Philosophy / Autoimmune diseases are caused when a person's immune system attacks its own healthy cells. In a person with multiple sclerosis, their immune system becomes sensitized to the myelin sheath that covers their neurons in the central nervous system. This results in the degradation of the myelin sheath and irreversible degradation of the nerve cell axons. This damage leads to the development of several neurological impairments, such as pain, fatigue, mobility problems, and numbness. While there is no cure for multiple sclerosis, disease-modifying therapies are typically taken by patients to suppress their immune system and slow disease progression. Sphingsoine-1-phosphate (S1P) is a lipid that is important for the trafficking of lymphocytes into a person's central nervous system. This trafficking is largely due to the natural gradient of S1P which is high levels in blood but low in tissues. Lymphocytes will follow this gradient from areas of low S1P concentration (lymphatic tissue) to areas with higher S1P concentrations. Modulation of S1P levels is the mechanism of action for several FDA approved drugs as they target primarily S1P1 receptors to achieve lower levels of circulating lymphocytes. However, targeting this receptor also results in cardiovascular side effects such as first-dose bradycardia. The transporter for S1P, spinster homolog 2 (Spns2), which is upstream of the S1P receptors, is another viable target that our lab has recently been targeting. Spns2 inhibition decreases extracellular S1P levels and result in reduced lymphocytes in mice models. In this dissertation, several inhibitors were developed and assessed for their in vitro and in vivo ability to inhibit Spns2.

sphingosine-1-phosphate

s1p

spns2

structure-activity relationship study

spinster homolog 2

multiple sclerosis

Quantitative structure activity relationship study of anti-Mycobacterium avium agents and the calculation of some physico-chemical properties of organic compounds

Wang, Shaomeng

January 1993

No description available.

Development of Potent Inhibitors of the Sphingosine-1-Phosphate Transporter Spns2 for the Treatment of Multiple Sclerosis

Foster, Daniel John

07 July 2022

Sphingosine-1-phosphate (S1P) is an amino-alcohol signaling molecule produced from the intracellular phosphorylation of the lipid sphingosine. Despite possessing several identified intracellular targets, the predominant signaling functionality of S1P is derived from its activation of membrane-bound G-protein coupled receptors (GPCRs). The binding of S1P to these receptors (S1P1-5) is closely associated with immune cell development and recruitment. As such, the modulation of S1P-related pathways is of particular interest for the development of immunomodulating agents. To reach its native GPCRs, S1P must be released from the cell. This process is facilitated by the transmembrane transport protein Spinster homolog 2 (Spns2) in most vertebrates. Studies in murine species have demonstrated that the protein plays a key role in directing immune cell chemotaxis and the progression of autoimmune diseases. Consequently, Spns2 represents an attractive target for the pharmaceutical induction of immunosuppression. While several drugs that act through the modulation of S1P receptor signaling have received FDA approval for the treatment of autoimmune disorders (fingolimod, siponimod, ozanimod, and ponesimod), they typically manifest on-target cardiovascular side-effects. Therefore, the development of novel Spns2 inhibitors is a prudent alternative approach to achieve S1P-mediated lymphopenia. In this dissertation, the design, synthesis, and activities of highly potent Spns2 inhibitors are disclosed. These structures spanned several scaffolds and culminated in the discovery of a phenylurea derivative 4.11i. In vitro assessment of 4.11i demonstrated that the compound possessed an IC50 value of 92 nM, making it the most potent inhibitor of Spns2 disclosed to date. Intraperitoneal administration of 4.11i (10 mg/kg dose) into mice reduced circulating lymphocyte counts and impaired the progression of experimental autoimmune encephalomyelitis (a murine model of multiple sclerosis). Taken together, these data validated the target of 4.11i in vivo and represented the first reported instance of Spns2 inhibition as a viable multiple sclerosis treatment. Additional work is currently being undertaken to further improve in vivo activity and pharmacokinetic properties of 4.11i. / Doctor of Philosophy / White blood cells comprise a significant portion of the body's natural defense mechanisms. In healthy individuals, these white blood cells identify and destroy foreign materials and organisms. However, in patients with multiple sclerosis, immune cells can become sensitized to protein fragments lining the myelin sheath of neurons. These autoreactive immune cells recognize the body's natural neuronal proteins as antigens. Damage exerted by autoreactive cells leads to the development of neurological impairments (i.e., fatigue, muscle weakness, and slurred speech) as nerve impulses are disrupted before reaching their target. First-line treatment of multiple sclerosis often centers on the administration of immunosuppressive drugs to curtail the progression of the disease and mitigate immune cell-directed demyelination. A driving factor in white blood cell localization is the lipid sphingosine-1-phosphate (S1P). Concentrations of S1P are often not static in the body, with different tissue types and fluids possessing variable levels. Immune cells, and lymphocytes in particular, use this natural S1P gradient to dictate their movement within the body. Lymphocytes will track with the S1P gradient, going from areas of lower S1P concentration (lymph tissue) to areas of higher S1P concentration where synthetic enzyme expression is upregulated (multiple sclerosis lesions). Consequently, the development of drugs that can alter this S1P gradient represents an ideal avenue to achieve immunosuppression. One key mediator of S1P release is the transmembrane transport protein Spinster homolog 2 (Spns2). This protein directs the secretion of intracellular S1P into the extracellular space and is necessary for lymphocytes to enter circulation. However, little effort has been devoted to the development of Spns2 inhibitors. As such, the inhibition of this protein represents a novel and underexplored target for the treatment of autoimmune disorders. In this disclosure, the structures of several highly potent Spns2 inhibitors are revealed. The work around these structures led to the discovery of 4.11i. This compound proved highly potent in biological assays and animal models. Mice treated with 4.11i experienced a reduction in circulating lymphocyte counts and demonstrated less symptom manifestation in multiple sclerosis disease models.

sphingosine-1-phosphate

spinster homolog 2

multiple sclerosis

structure-activity relationship study

Improving Potency and Oral Bioavailability of Spinster Homolog 2 (Spns2) Inhibitor: A Structure-Activity Relationship Study

Dunnavant, Kyle Jacob

13 June 2024

Doctor of Philosophy / In healthy individuals, the autoimmune system is the body's natural defense against foreign materials and organisms. The main tools utilized for this defense mechanism are immune cells. However, in patients suffering from autoimmune diseases, the autoimmune system is overactive resulting in its attack on healthy cells, which leads to reduced or eliminated function of the targeted organs. To suppress these overreactive immune responses, pharmaceutical intervention is needed. An integral part of autoimmune response is the lipid sphingosine-1-phosphate (S1P). Interactions of S1P with its response-inducing receptors prompts the release of immune cells, lymphocytes in particular, from lymph tissue to migrate and participate in the invoked immune response. The pharmaceutical industry has produced five FDA approved drugs that disrupt this S1P-receptor interaction by blocking the receptor to reduce the autoimmune response in patients suffering from autoimmune diseases such as multiple sclerosis and ulcerative colitis. However, these treatments had adverse side effects on the cardiovascular system due to the presence of S1P receptors in the heart. Due to this, there is attraction to target a different node of the S1P signaling pathway to avoid these side effects while still suppressing the immune response. A node that is a viable target for therapeutic target that has recently become the focus of medicinal chemistry campaigns is the transporter protein spinster homolog 2 (Spns2). This protein is responsible for the transport of S1P from intracellular space to extracellular space to interact with its receptors and induce the immune response. Recently, our group has developed several effective inhibitors of Spns2. In this dissertation, several improvements of previously reported inhibitors are revealed. The pinnacle of this work is the development of 4.22v that is optimized to have drug-like properties for testing in mice. Administration of 4.22v to mice resulted in reduced circulating lymphocytes and without showing signs of toxicity following chronic dosing for 14 days. These results suggest that 4.22v is a potential drug candidate and is currently undergoing further biological evaluation.

Sphingosine-1-phosphate

S1P

Spns2

transporter inhibitor

lymphopenia

autoimmune disease

multiple sclerosis

ulcerative colitis

renal fibrosis

structure-activity relationship study

Syntéza polysubstituovaných pyrimidinů s potenciálními protizánětlivými vlastnostmi / Synthesis of polysubstituted pyrimidines with potential anti-inflammatory properties

Kalčic, Filip

January 2017

This thesis is engaged in the synthesis of polysubstituted pyrimidines with anti- inflammatory properties. Such molecules can inhibit production of prostaglandin E2 (PGE2). The aim of this study was to enhance water-solubility and anti-inflammatory efficacy of such derivatives via structural modifications of the lead scaffold. Among applied synthetic tools, the Suzuki-Miyaura cross-coupling was the prevalent reaction, however, many other synthetic procedures (Heck reaction, condensation, borylation, ozonolysis, nucleophilic substitution, etc.) were utilized as well. Overall, 43 final products were prepared. The anti-inflammatory efficacy (inhibition of PGE2 production) was successfully increased as the most potent compound achieved three orders of magnitude higher activity compared to the current lead structure WQE-134. Furthermore, no general influence of the length of the substituent in the C5 position of pyrimidine (C5pyr) on the anti-inflammatory efficacy of synthesized compounds was observed. Significant bioavailability obstacle in future development of the current lead WQE-134 is its poor solubility which was successfully enhanced by introduction of heteroatom bearing moieties to C5pyr. The most water-soluble compound achieved two orders of magnitude higher solubility than WQE-134 while...

Identification of novel scaffolds for Monoamine oxidase B inhibitors

Odhar, Hasanain

21 March 2014

No description available.

Biomedical Research

Neurosciences

Pharmaceuticals

Pharmacology

Pharmacy Sciences

Parkinsonism

Monoamine oxidase

Scaffold

High throughput screening

Drug design

structure-activity relationship study

Thiazolidine

8-hydroxyquinoline

L-alanine

Inhibition of monoamine oxidase by derivatives of piperine, an alkaloid from the pepper plant Piper nigrum, for possible use in Parkinson’s disease

Al-Baghdadi, Osamah Basim Khalaf

27 October 2014

No description available.

Pharmacology

Biomedical Research

Parkinsonism

Monoamine oxidase

High throughput screening

Drug design

structure-activity relationship study

Piperine

docking

Bovine serum albumin

Parkinson disease