Your search keyword '"Maxwell Bannister"' showing total 5 results

1. An ADPRS variant disrupts ARH3 stability and subcellular localization in children with neurodegeneration and respiratory failure

Author

Maxwell Bannister, Sarah Bray, Anjali Aggarwal, Charles Billington, Jr., and Hai Dang Nguyen

Subjects

CONDSIAS, ADPRS, ARH3, ADPr, ADP-ribose, PAR, Genetics, QH426-470

Abstract

Summary: ADP-ribosylation is a post-translational modification involving the transfer of one or more ADP-ribose units from NAD+ to target proteins. Dysregulation of ADP-ribosylation is implicated in neurodegenerative diseases. In this study, genetic testing via exome sequencing was used to identify the underlying disease in two siblings with developmental delay, seizures, progressive muscle weakness, and respiratory failure following an episodic course. This identified a novel homozygous variant in the ADPRS gene (c.545A>G, p.His182Arg) encoding the mono(ADP-ribosyl) hydrolase ARH3, confirming the diagnosis of childhood-onset neurodegeneration with stress-induced ataxia and seizures (CONDSIAS) in these two children. Mechanistically, the ARH3H182R variant affects a highly conserved residue in the active site of ARH3, leading to protein instability, degradation, and, subsequently, reduced protein expression. The ARH3H182R mutant additionally fails to localize to the nucleus, which further resulted in accumulated mono-ADP ribosylated species in cells. The children’s clinical course combined with the biochemical characterization of their genetic variant develops our understanding of the pathogenic mechanisms driving CONDSIAS and highlights a critical role for ARH3-regulated ADP-ribosylation in nervous system integrity.

Published

2025

2. Saracatinib synergizes with enzalutamide to downregulate AR activity in CRPC

Author

Ralph E. White, Maxwell Bannister, Abderrahman Day, Hannah E. Bergom, Victor M. Tan, Justin Hwang, Hai Dang Nguyen, and Justin M. Drake

Subjects

prostate cancer, enzalutamide, SRC kinase inhibitor, Synergy, androgen receptor, phosphorylation, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Prostate cancer (PCa) remains the most diagnosed non-skin cancer amongst the American male population. Treatment for localized prostate cancer consists of androgen deprivation therapies (ADTs), which typically inhibit androgen production and the androgen receptor (AR). Though initially effective, a subset of patients will develop resistance to ADTs and the tumors will transition to castration-resistant prostate cancer (CRPC). Second generation hormonal therapies such as abiraterone acetate and enzalutamide are typically given to men with CRPC. However, these treatments are not curative and typically prolong survival only by a few months. Several resistance mechanisms contribute to this lack of efficacy such as the emergence of AR mutations, AR amplification, lineage plasticity, AR splice variants (AR-Vs) and increased kinase signaling. Having identified SRC kinase as a key tyrosine kinase enriched in CRPC patient tumors from our previous work, we evaluated whether inhibition of SRC kinase synergizes with enzalutamide or chemotherapy in several prostate cancer cell lines expressing variable AR isoforms. We observed robust synergy between the SRC kinase inhibitor, saracatinib, and enzalutamide, in the AR-FL+/AR-V+ CRPC cell lines, LNCaP95 and 22Rv1. We also observed that saracatinib significantly decreases AR Y534 phosphorylation, a key SRC kinase substrate residue, on AR-FL and AR-Vs, along with the AR regulome, supporting key mechanisms of synergy with enzalutamide. Lastly, we also found that the saracatinib-enzalutamide combination reduced DNA replication compared to the saracatinib-docetaxel combination, resulting in marked increased apoptosis. By elucidating this combination strategy, we provide pre-clinical data that suggests combining SRC kinase inhibitors with enzalutamide in select patients that express both AR-FL and AR-Vs.

Published

2023

3. Prescribing Syringes to People Who Inject Drugs: Advancing Harm Reduction in Primary Care

Author

Avik Chatterjee, Maxwell Bannister, Lucas G. Hill, and Corey S. Davis

Subjects

Internal Medicine

Abstract

Access to new syringes can reduce the risk of HIV and hepatitis C transmission, skin and soft tissue infections, and infectious endocarditis for people who inject drugs (PWID). Syringe service programs (SSPs) and other harm reduction programs are a good source of syringes. However, they are sometimes not accessible due to limited hours, geographic barriers, and other factors. In this perspective, we argue that when PWID faces barriers to syringes physicians and other providers should prescribe, and pharmacists should dispense, syringes to decrease health risks associated with syringe re-use. This strategy is endorsed by professional organizations and is legally permissible in most states. Such prescribing has numerous benefits, including insurance coverage of the cost of syringes and the sense of legitimacy conveyed by a prescription. We discuss these benefits as well as the legality of prescribing and dispensing syringes and address practical considerations such as type of syringe, quantity, and relevant diagnostic codes, if required. In the face of an unprecedented overdose crisis with many associated health harms, we also make the case for advocacy to change state and federal laws to make access to prescribed syringes uniform, smooth, and universal as part of a suite of harm reduction efforts.

Published

2023

4. Therapeutic Targeting of Spliceosome Mutant Myeloid Neoplasms Via PARP1 Inhibition

Author

Sayantani Sinha, Zhiyan Silvia Liu, Maxwell Bannister, Erica Arriaga-Gomez, Axia Song, Dawei Zong, Martina Sarchi, Elizabeth Bonner, Victor Corral, Cassandra Leibson, Wannasiri Chiraphapphaiboon, Derek Stirewalt, Joachim Deeg, Sumit Rai, Matthew J Walter, Timothy A. Graubert, Sergei Doulatov, Dang Hai Nguyen, and Stanley Chun-Wei Lee

Subjects

Immunology, Cell Biology, Hematology, Biochemistry

Published

2022

5. Spliceosome Mutant Myeloid Malignancies Are Preferentially Sensitive to PARP Inhibition

Author

Maxwell Bannister, Victor M. Corral, Cassandra Leibson, Zhiyan Silvia Liu, Axia Song, Timothy A. Graubert, Sayantani Sinha, Erica Arriaga-Gomez, Sumit Rai, Dang Hai Nguyen, Dawei Zong, and Stanley Chun-Wei Lee

Subjects

Spliceosome, Myeloid, medicine.anatomical_structure, Chemistry, Poly ADP ribose polymerase, Immunology, Mutant, Cancer research, medicine, Cell Biology, Hematology, Biochemistry

Abstract

Somatic heterozygous mutations in spliceosome genes SRSF2, U2AF1, and SF3B1 commonly occur in patients with myeloid malignancies such as myelodysplastic syndromes (MDS) and acute myeloid leukemia (AML). Moreover, SRSF2 and U2AF1 mutations associate with poor survival and high risk of progression to AML, representing a unique genetic vulnerability for targeted therapy. We and others previously found that R-loops, a group of transcription intermediates containing RNA:DNA hybrids and displaced single-stranded DNA, are a source of genomic instability induced by different spliceosome mutants. We further showed that inhibition of ATR kinase activity preferentially kills spliceosome mutant cells in an R-loop-dependent manner. Inspired by ATR inhibition results, we performed a focused drug screen with inhibitors targeting additional DNA damage response pathways to identify novel therapeutic vulnerabilities generated by spliceosome mutations. We generated a murine leukemia model by overexpressing the MLL-AF9 fusion oncogene on an Srsf2 P95H/+background, a mutational combination that is found in ~10% of MLL-rearranged leukemias. Surprisingly, we found that Srsf2 P95H/+cells are more sensitive to five inhibitors targeting ADP-ribosyltransferases or PARP (olaparib, talazoparib, rucaparib, niraparib, veliparib) (Figs 1A-B). Olaparib (PARPi)-treated Srsf2 P95H/+cells exhibited increased apoptosis compared to Srsf2 +/+ cells as determined by AnnexinV (Fig 1C). PARPi sensitivity was also observed in isogenic murine MLL-AF9 U2af1 S34F/+cells compared to MLL-AF9 U2af1 +/+ cells (Fig 1D). These data highlight that both SRSF2 P95H and U2AF1 S34F mutations create a common vulnerability that is dependent on PARP activity for survival. To evaluate PARP activity in cells, we used isogenic K562 leukemia cells expressing SRSF2 P95H and U2AF1 S34F mutations from their endogenous loci and monitored PAR (poly(ADP-ribose)) chain levels, a marker of PARP activity. Both SRSF2 P95H and U2AF1 S34F cells exhibited elevated PAR levels compared to wildtype cells (Figs 1E-F). PARPi treatment significantly suppressed PAR signals in SRSF2 P95H and U2AF1 S34F cells. PARP inhibitors target both PARP1 and PARP2 enzymes, of which PARP1 plays a key role in DNA damage response. We used CRISPR-Cas9 to knockout PARP1 gene to determine the major PARP responsible for elevated PAR level in these leukemia cells. PARP1 deletion abrogated elevated PAR levels in U2AF1 S34F (Fig 1G) and SRSF2 P95H cells (data not shown). Altogether, we demonstrated that SRSF2 P95H and U2AF1 S34F cells trigger a PARP1 response critical for cell survival. To test whether increased PAR level arises from U2AF1 S34F-induced R-loops, we generated U2AF1 S34F cells that inducibly express RNaseH1, an enzyme that specifically cleaves the RNA moiety within RNA:DNA hybrids. Induction of RNaseH1 in U2AF1 S34F cells significantly reduced PAR levels, showing that U2AF1 S34F-induced PAR chains is R-loop-dependent (Fig 1H). Moreover, RNaseH1 overexpression suppressed the growth inhibition of PARPi-treated U2AF1 S34F cells (Fig 1I). Collectively, these results suggest that U2AF1 S34F mutants induce R-loop accumulation and elicit an R-loop-associated PARP1 signaling to promote cell survival. We next tested whether combining ATR inhibitor (ATRi) can further exacerbate PARPi sensitivity in spliceosome mutant cells. To examine ATR activity, we monitored phosphorylated RPA (Replication Protein A, or pRPA), a known ATR substrate. pRPA level was enhanced in PARPi-treated SRSF2 P95H cells compared to PARPi-treated SRSF2 WT cells but was suppressed when treated with ATRi (Fig 1J), suggesting that splicing factor mutant cells are more reliant on ATR function in the context of PARPi. Importantly, the combination of PARPi with ATRi, but not with ATMi, significantly promoted cell growth inhibition in SRSF2 P95H cells compared to SRSF2 WT cells or to SRSF2 P95H cells treated with individual compounds alone (Fig 1K). Collectively, these data provide a pre-clinical rationale that splicing factor mutant leukemias are preferentially sensitive to PARP1 modulation compared to their wildtype counterpart. Moreover, combining PARPi and ATRi may further sensitize spliceosome mutant cells and could represent a new therapeutic strategy in myeloid leukemia patients harboring these mutations (Fig 1L). Figure 1 Figure 1. Disclosures Graubert: Calico: Research Funding; Janssen: Research Funding; astrazeneca: Research Funding.

Published

2021