The Effects of SOCS1 and SOCS3 Peptide Mimetics on Macrophage Phagocytosis of Malignant Cells

Madkhali, Tahirah M.

14 May 2019

No description available.

Microbiology

Immunology

SOCS1

SOCS3

Cytokine Signal

Peptide Mimetics

Macrophage

Phagocytosis

Malignant Cells

Calreticulin

NOVEL CARRIER PROTEIN AND ITS APPLICATION TO A RESPIRATORY SYNCYTIAL VIRUS ANTIVIRAL PEPTIDE / DEVELOPMENT OF AN ALBUMIN-BINDING DOMAIN CARRIER AND A NOVEL PEPTIDE MIMETIC ANTIVIRAL FOR RESPIRATORY SYNCYTIAL VIRUS

Mihalco, Samantha P.

January 2018

Background: Respiratory syncytial virus (RSV) is the leading cause of acute lower respiratory tract infection and hospitalization in children worldwide. With no vaccine or antivirals available for the routine prevention or treatment of RSV, an effective RSV antiviral is required. Previous studies have shown that the RSV nucleocapsid complex (NC), phosphoprotein (P), and large polymerase (L) are essential for the replication and survival of RSV since they form the core of the RNA-dependent RNA polymerase (RdRp) complex. Thus, these proteins are viable targets for novel RSV antivirals. Objective: The Mahony laboratory has previously shown that 20 µM of a peptide mimetic composed of the 21 terminal amino acids of the RSV phosphoprotein (RSVP220-241) fused to an HIV-1 Tat cell penetrating peptide (CPP), a hexa-histidine (His) tag, and the Escherichia coli (E. coli) maltose binding protein carrier (MBP) molecule was sufficient to attenuate RSV A and B replication in vitro by approximately 90 and 80%, respectively. We evaluated the fusion of this His-MBP-Tat-RSVP220-241 mimetic to a more suitable carrier molecule, an albumin-binding domain (ABD), for future use in vivo. In addition, we designed a novel antiviral mimetic composed of the 30 terminal amino acids of the RSV A P protein (RSVP212-241), which are involved in binding both L polymerase and NC complexes, fused to a CPP consisting of Tat or nine arginine residues (Arg9), a His-tag, and the MBP carrier. We evaluated the activity of His-MBP-Tat-RSVP212-241, Tat-His-MBP-Tat-RSVP212-241, and His-Arg9-MBP-RSVP212-241 mimetics in vitro and hypothesized that a mimetic designed to target both L and NC interactions would be a more effective RSV antiviral than the original His-MBP-Tat-RSVP220-241 mimetic. Methods and Results: The Gateway® Cloning System was used to create expression vectors containing His-, GST-, or His-MBP-ABD-Tat-RSVP220-241 and His-MBP-Tat-RSVP212-241, whereas inverse PCR and both the In-Fusion® and Gateway® Cloning systems were used to generate expression vectors containing Tat-His-MBP-Tat-RSVP212-241 and His-Arg9-MBP-RSVP212-241. The fusion proteins were expressed, purified by affinity chromatography, and evaluated in vitro. No soluble protein was obtained for the ABD constructs. His-MBP-Tat-RSVP212-241 was toxic and not internalized by LLC-MK2 cells, whereas only 0.26 mg of Tat-His-MBP-Tat-RSVP212-241 was purified. We were able to show that His-Arg9-MBP-RSVP212-241 was non-toxic, internalized, and interacted with the RSV nucleoprotein (N) in a GST pull-down experiment. Furthermore, His-Arg9-MBP-RSVP212-241 attenuated RSV A replication and progeny production by 94.8 and 93.33% at 200 µM, respectively. We demonstrated 50.7 and 49% inhibition of RSV A replication and progeny production at 20 µM, respectively. We showed that inhibition of viral replication by 25 µM His-Arg9-MBP-RSVP212-241 was not significantly different from inhibition by 20 µM His-MBP-Tat-RSVP220-241. Thus, in this thesis we were unable to show that His-Arg9-MBP-RSVP212-241 was a more effective RSV antiviral. Conclusion: The ABD was not a suitable carrier molecule for use with our fusion protein mimetics. However, RSV P protein mimetics that target interactions with the NC complexes and L polymerase are a novel and viable antiviral strategy. We showed that a His-Arg9-MBP-RSVP212-241 mimetic was non-toxic, internalized, and interacted with the RSV N protein in vitro. Furthermore, we showed that at 200 µM this novel mimetic could attenuate RSV A replication and progeny production in vitro by 94.8 and 93.3%, respectively. Further studies are required to characterize the construct, increase its bioactivity, and identify a suitable human carrier molecule for future evaluation in vivo. / Thesis / Master of Science (MSc) / Worldwide, respiratory syncytial virus is a leading cause of lower respiratory infection and hospitalization in children. Nearly all children are infected with the virus by the young age of two. However, respiratory syncytial virus also causes a significant amount of illness and death in the elderly and in immunocompromised individuals. Furthermore, repeated infections by the virus are common throughout life in all populations. With the lack of a vaccine or treatment for this viral infection, an effective antiviral against RSV is required. In this thesis, we developed and evaluated a novel RSV antiviral therapeutic peptide that targets proteins of the viral replication machinery. Since the replication machinery is required for respiratory syncytial virus survival, we hypothesized that infection could be attenuated by preventing formation of the replication machinery. Furthermore, since small protein therapeutics are often cleared quickly from the human body, we investigated human carrier molecules that could be attached to the antiviral protein for stabilization within the body.

Respiratory Syncytial Virus

Peptide Mimetics

RNA-Dependent RNA-Polymerase

Human Carrier Molecules