Bidirectional regulation of synaptic SUMOylation by Group 1 metabotropic glutamate receptors

Mechanistic insights into SENP1 and OCT4 interaction in promoting drug resistance and stem cell features in colon cancer

This study explores the molecular mechanism by which sentrin/SUMO-specific protease 1 (SENP1) promotes cisplatin (Cis) resistance and tumor stem cell characteristics in colon adenocarcinoma (COAD) through deSUMOylation-mediated modification of octamer-binding transcription factor 4 (OCT4). By analyzing single-cell and transcriptome sequencing datasets, we identified key genes and regulatory pathways in both resistant and sensitive COAD cells. Malignant cells were isolated and evaluated for stemness using the infercnv package, and differential genes between Cis-resistant and -sensitive groups were identified. Machine learning algorithms highlighted essential genes, and databases predicted interaction sites between OCT4 and SENP1. In vitro experiments using enriched HCT116 stem cells revealed that SENP1 and OCT4 expression significantly elevated CD44 and CD133 levels, enhancing stemness. Functional assays showed that SENP1's deSUMOylation of OCT4 intensified Cis resistance, migration, and invasion in cisplatin-resistant cell line 116 (Cis-116) cells. In vivo, SENP1 knockdown reduced tumor growth and stem cell markers, whereas OCT4 overexpression escalated tumor metastasis and structural damage. These findings demonstrate that SENP1's modulation of OCT4 is central to COAD's resistance and stem cell properties, offering a novel target for COAD therapy.NEW & NOTEWORTHY This study uncovers the critical role of SENP1 in regulating OCT4 through deSUMOylation, driving Cis resistance and tumor stemness in COAD. Targeting this pathway may provide novel therapeutic strategies for COAD management.

Genetic and pharmacologic enhancement of SUMO2 conjugation prevents and reverses cognitive impairment and synaptotoxicity in a preclinical model of Alzheimer's disease

INTRODUCTION

Amyloid beta oligomers (Aβos) are toxic to synapses and key to the progression of Alzheimer's disease (AD) and amyloid pathology, representing a target for therapeutic strategies.

METHODS

Amyloid and small ubiquitin modifier 2 (SUMO2) transgenics were analyzed by electrophysiology and behavioral testing. A recombinant analogue of SUMO2, SBT02, was generated and assessed for brain penetration and the ability to mitigate amyloid pathology.

RESULTS

Elevated SUMO2 expression prevents cognitive and synaptic impairment in a mouse model of AD amyloid pathology. Systemic administration of SBT02 resulted in high brain bioavailability and prophylactically halted the progression of AD-associated deficits. SBT02 also restored cognition and synaptic function in late-stage amyloid load. Mechanistically, SUMO2 and SBT02 do not alter amyloid processing or clearance and mitigate synaptotoxicity in the presence of high amyloid loads.

DISCUSSION

SBT02 is a promising therapeutic strategy to counteract and reverse the toxic effects of Aβos in AD.

HIGHLIGHTS

Genetic overexpression of human SUMO2 prevents the long-term potentiation (LTP) impairments and cognitive deficits in amyloid precursor protein (APP) transgenics without affecting amyloid pathology. A recombinant analogue of human SUMO2, termed SBT02, when administered systemically, displays high brain bioavailability and has no adverse effects at high doses. Prophylactic treatment of APP transgenics with SBT02 prior to the development of amyloid pathology results in the prevention of synaptic and behavioral dysfunction. SBT02 also reverses pre-existing LTP and cognitive impairments when administered to APP transgenics with advanced and severe pathology. SBT02 has no impact on amyloid pathology, indicating a mechanism of action on synaptic resistance to Aβ toxicity.

SUMOylation and DeSUMOylation: Tug of War of Pain Signaling

SUMOylation is a post-translational modification that attaches a small ubiquitin-like modifier (SUMO) group to a target protein via SUMO ligases, while deSUMOylation refers to the removal of this SUMO group by sentrin-specific proteases (SENPs). Although the functions of these processes have been well described in the nucleus, the role of SUMOylation and deSUMOylation in regulating ion channels is emerging as a novel area of study. Despite this, their contributions to pain signaling remain less clear. Therefore, this review consolidates the current evidence on the link(s) between SUMOylation, deSUMOylation, and pain, with a specific focus on ion channels expressed in the sensory system. Additionally, we explore the role of SUMOylation in the expression and function of kinases, vesicle proteins, and transcription factors, which result in the modulation of certain ion channels contributing to pain. Altogether, this review aims to highlight the relationship between SUMOylation and deSUMOylation in the modulation of ion channels, ultimately exploring the potential therapeutic role of these processes in chronic pain.

Molecular Organization and Regulation of the Mammalian Synapse by the Post-Translational Modification SUMOylation

Neurotransmission occurs within highly specialized compartments forming the active synapse where the complex organization and dynamics of the interactions are tightly orchestrated both in time and space. Post-translational modifications (PTMs) are central to these spatiotemporal regulations to ensure an efficient synaptic transmission. SUMOylation is a dynamic PTM that modulates the interactions between proteins and consequently regulates the conformation, the distribution and the trafficking of the SUMO-target proteins. SUMOylation plays a crucial role in synapse formation and stabilization, as well as in the regulation of synaptic transmission and plasticity. In this review, we summarize the molecular consequences of this protein modification in the structural organization and function of the mammalian synapse. We also outline novel activity-dependent regulation and consequences of the SUMO process and explore how this protein modification can functionally participate in the compartmentalization of both pre- and post-synaptic sites.