Recent developments in PARP14 research

Knockdown of YTHDF2 mitigates OGD-induced microglial inflammation by preventing m6A-dependent PARP14 degradation

Neuroinflammation is a key pathological factor in ischemic brain diseases, contributing to the initiation and progression of these conditions. The function of the m6A reader protein YTHDF2 in regulating neuroinflammation across various neurological contexts. To elucidate the role and regulatory mechanism of YTHDF2 in inflammation under ischemic-like conditions, this study employed an in vitro model, exposing microglia to oxygen-glucose deprivation (OGD) to mimic the stress environment. And through YTHDF2 knockdown, we investigated its effect on OGD-induced inflammation. The results demonstrated that YTHDF2 knockdown significantly suppressed the expression of pro-inflammatory cytokines, including tumor necrosis factor-α (TNF-α), interleukin-1β (IL-1β), and interleukin-6 (IL-6), in OGD-treated microglia. Mechanistic analysis revealed that YTHDF2 interacts with Parp14 mRNA under OGD conditions, reducing its RNA stability via m6A-dependent mechanisms, which in turn decreases Poly (ADP-ribose) polymerase family, member 14 (PARP14) protein expression. Additionally, YTHDF2 knockdown after OGD promoted a PARP14-driven phenotypic switch in microglia from the pro-inflammatory M1 state to the anti-inflammatory M2 state, resulting in diminished inflammation. These findings offer new insights into the regulatory function of YTHDF2 in OGD-induced microglial inflammation and propose m6A modification as a potential therapeutic target for alleviating neuroinflammation.

Parps in immune response: Potential targets for cancer immunotherapy

Immunotherapy in clinical application faces numerous challenges pertaining to both effectiveness and safety. Poly(ADP-ribose) polymerases (PARPs) exhibit multifunctional characteristics by transferring ADP-ribose units to target proteins or nucleic acids. In recent years, more and more attention has been paid to the biological function of PARPs in immune response. This article reviews the relationship between PARP family members and immune response. PARP1 and PARP2 inhibit anti-tumor immune activity by regulating immune checkpoint expression and the cGAS/STING signaling pathway. PARP7 and PARP11 play an important role in promoting immunosuppressive tumor microenvironment. PARP9 promotes the production of Type I interferon and the infiltration of macrophages. PARP13 is a key tumor suppressor that promotes anti-tumor immune response. PARP14 plays a crucial role in promoting the differentiation of macrophages towards the M2 pro-tumor phenotype. Summarizing the molecular mechanisms of PARP7, PARP9, PARP11, PARP13 and PARP14 in regulating immune response is helpful to deepen our comprehension of the role of PARPs in immune function regulation. This provides a reference and basis for targeted PARP-based cancer treatment strategies and drug development. PARP1, PARP7 inhibitors or other PARP inhibitors in combination with immune checkpoint inhibitors or other immunotherapy strategies may be a more effective cancer therapy.

PARP15 Is a Susceptibility Locus for Clarkson Disease (Monoclonal Gammopathy-Associated Systemic Capillary Leak Syndrome)

BACKGROUND

Vascular leakage is a deadly complication of severe infections, ranging from bacterial sepsis to malaria. Worldwide, septicemia is among the top 10 causes of lethality because of the shock and multiorgan dysfunction that arise from the host vascular response. In the monoclonal gammopathy-associated capillary leak syndrome (MG-CLS), even otherwise mundane infections induce recurrent septic-like episodes of profound microvascular hyperpermeability and shock. There are no defined genetic risk factors for MG-CLS or effective treatments for acute crises.

METHODS

We characterized predicted loss-of-function mutations in PARP15 (poly[ADP-ribose] polymerase 15), a protein of unknown function that is absent in mice, in patients with MG-CLS. We analyzed barrier function in PARP15-deficient vascular endothelial cells and vascular leakage in mice engineered to express wild-type or loss-of-function variant human PARP15.

RESULTS

We discovered several loss-of-function PARP15 variants associated with MG-CLS. These mutations severely reduced PARP15 enzymatic function. The presence of the most frequently detected variant (G628R) correlated with clinical markers of severe vascular leakage. In human microvascular endothelial cells, PARP15 suppressed cytokine-induced barrier disruption by ADP-ribosylating the scaffold protein JIP3 (c-Jun N-terminal kinase-interacting protein 3) and inhibiting p38 MAP (mitogen-activated protein) kinase activation. Mice expressing enzymatically inactive human PARP15(G628R) were significantly more prone to inflammation-associated vascular leakage than mice expressing wild-type PARP15 in a p38-dependent fashion.

CONCLUSIONS

PARP15 represents a previously unrecognized genetic susceptibility factor for MG-CLS. PARP15-mediated ADP ribosylation is an essential and genetically determined mechanism of the human vascular response to inflammation.

Exploration of glycosyltransferases mutation status in cervical cancer reveals PARP14 as a potential prognostic marker

This study investigates the potential role of Glycosyltransferases (GTs) in the glycosylation process and their association with malignant tumors. Specifically, the study focuses on PARP14, a member of GTs, and its potential as a target for tumors in the diagnosis and treatment of cervical cancer. To gather data, the study used somatic mutation data, gene expression data and clinical information from TCGA-CESE dataset as well as tissue samples from cervical cancer patients. Further verification was conducted through RT-qPCR and immunohistochemistry staining on cervical cancer tissues to confirm the expression of PARP14. The study utilized Kaplan-Meier for survival analysis of cervical cancer patient and found significant mutational abnormalities in GTs. The high frequency mutated gene was identified as PARP14. RT-qPCR revealed significantly higher mRNA expression of PARP14 compared to precancerous tissue. Using IHC combined with Kaplan-Meier,patients in the PARP14 high expression group had a better prognosis than the low expression group. The study identified PARP14 as a frequently mutated gene in cervical cancer and proposed its potential role in diagnosis and treatment.

Functional roles of ADP-ribosylation writers, readers and erasers

ADP-ribosylation is a reversible post-translational modification (PTM) tightly regulated by the dynamic interplay between its writers, readers and erasers. As an intricate and versatile PTM, ADP-ribosylation plays critical roles in various physiological and pathological processes. In this review, we discuss the major players involved in the ADP-ribosylation cycle, which may facilitate the investigation of the ADP-ribosylation function and contribute to the understanding and treatment of ADP-ribosylation associated disease.

N,N'-Diphenyldithiomalonodiamide: Structural Features, Acidic Properties, and In Silico Estimation of Biological Activity

The spectral characteristics of dithiomalondianilide (N,N'-diphenyldithiomalonodiamide) were studied, and the dissociation constant was determined by potentiometric titration. Quantum-chemical methods at the B3LYP-D3BJ/6-311+G (2d,p) level were used to calculate the molecular geometry and vibrational spectra of the most stable tautomeric forms of dithiomalondianilide. The bioavailability parameters were calculated, and possible protein targets were predicted by the protein ligand docking method.

Mono(ADP-ribosyl)ation Enzymes and NAD+ Metabolism: A Focus on Diseases and Therapeutic Perspectives

Mono(ADP-ribose) transferases and mono(ADP-ribosyl)ating sirtuins use NAD+ to perform the mono(ADP-ribosyl)ation, a simple form of post-translational modification of proteins and, in some cases, of nucleic acids. The availability of NAD+ is a limiting step and an essential requisite for NAD+ consuming enzymes. The synthesis and degradation of NAD+, as well as the transport of its key intermediates among cell compartments, play a vital role in the maintenance of optimal NAD+ levels, which are essential for the regulation of NAD+-utilizing enzymes. In this review, we provide an overview of the current knowledge of NAD+ metabolism, highlighting the functional liaison with mono(ADP-ribosyl)ating enzymes, such as the well-known ARTD10 (also named PARP10), SIRT6, and SIRT7. To this aim, we discuss the link of these enzymes with NAD+ metabolism and chronic diseases, such as cancer, degenerative disorders and aging.

Design, synthesis and evaluation of potential inhibitors for poly(ADP-ribose) polymerase members 1 and 14

Poly(ADP-ribose) polymerase (PARP) members PARP1 and PARP14 belong to an 18-member superfamily of post-translational modifying enzymes. A library of 9 novel non-NAD analog amine compounds was designed, synthesized and evaluated for inhibitory activity against PARP1 and PARP14. Both in silico studies and in vitro assays identified compound 2 as a potential PARP1 inhibitor, inhibiting activity by 93 ± 2% (PARP14 inhibition: 0 ± 6%), and 7 as a potential PARP14 inhibitor, inhibiting activity by 91 ± 2% (PARP1 inhibition: 18 ± 4%), at 10-μm concentration. Key in silico interactions with TYR907 in PARP1 and TYR1620 and TYR1646 in PARP14 have been identified. Compound 2 and compound 7 have been identified as potential leads for the development of selective PARP inhibitors.

In silico family-wide profiling and 3D modelling of the poly(ADP-ribose) polymerase superfamily

Background: Due to the conserved nature of the poly(ADP-ribose) polymerase (PARP) catalytic domain, the identification of unique residues is critical for the design of selective inhibitors. With inhibitors of the DNA-dependent PARP members already clinically approved, new efforts lie in discovering selective inhibitors for PARP5a and beyond. Targeting the noncatalytic domains, such as the macro2 and WWE domains may also provide a way to achieve selectivity. Methodology & results: This paper details the in silico profiling of x-ray crystal structures and homology models of the PARP catalytic, WWE and macro2 domains. PARP10 was the least conserved catalytic domain, with the macro2 and WWE domains possessing more unique residues than their catalytic counterparts. Conclusion: Overall, we identify unique residues to target when designing selective PARP inhibitors including HIS1610, TYR1620, ALA1627 and ARG1658 of the PARP14 catalytic domain, along with multiple unique residues across the PARP WWE and macro2 domains.