Last update 01 Nov 2024

AcpS

Last update 01 Nov 2024

Basic Info

Synonyms

4'-phosphopantetheinyl transferase, AASD-PPT, AASDHPPT

+ [8]

Introduction

Catalyzes the post-translational modification of target proteins by phosphopantetheine. Can transfer the 4'-phosphopantetheine moiety from coenzyme A, regardless of whether the CoA is presented in the free thiol form or as an acetyl thioester, to a serine residue of a broad range of acceptors including the acyl carrier domain of FASN.

Drugs associated with AcpS

SCH 538415

Target

AcpS

Mechanism

AcpS inhibitors

Active Org.

Schering-Plough Corp.

Originator Org.

Schering-Plough Corp.

Active Indication

Bacterial Infections

Inactive Indication-

Drug Highest PhasePreclinical

First Approval Ctry. / Loc.-

First Approval Date20 Jan 1800

ML-267

Target

AcpS

Mechanism

AcpS inhibitors

Active Org.

National Center for Advancing Translational Sciences

Originator Org.

National Center for Advancing Translational Sciences

Active Indication

Bacterial Infections

Inactive Indication-

Drug Highest PhasePreclinical

First Approval Ctry. / Loc.-

First Approval Date20 Jan 1800

100 Clinical Results associated with AcpS

100 Translational Medicine associated with AcpS

0 Patents (Medical) associated with AcpS

700

Literatures (Medical) associated with AcpS

10 Oct 2024·British Journal of Nursing

The role of ACPs in recognising and treating diabetic ketoacidosis and hyperosmolar hyperglycaemic state

Review

Author: Alsararatee, Hasan Hazim

Diabetic ketoacidosis (DKA) and hyperosmolar hyperglycaemic state (HHS) are both diabetic emergencies that require immediate identification and intervention. Advanced clinical practitioners (ACPs) play a crucial role in the early detection, management and co-ordination of care for patients with these conditions, although some may feel less confident in handling such complex cases. This clinical review explores the role of ACPs in managing DKA and HHS, focusing on their responsibilities in diagnosis, treatment initiation, and communication within multidisciplinary teams. It also examines the epidemiology, pathogenesis, risk factors, and causes of these conditions, alongside diagnostic criteria and management strategies. In addition, the review highlights the importance of minimising risks and preventing recurrence to ultimately enhance patient outcomes.

01 Sep 2024·Journal of Molecular Biology

mACPpred 2.0: Stacked Deep Learning for Anticancer Peptide Prediction with Integrated Spatial and Probabilistic Feature Representations

Article

Author: Wei, Leyi ; Sangaraju, Vinoth Kumar ; Manavalan, Balachandran ; Pham, Nhat Truong ; Yu, Xue

Anticancer peptides (ACPs), naturally occurring molecules with remarkable potential to target and kill cancer cells. However, identifying ACPs based solely from their primary amino acid sequences remains a major hurdle in immunoinformatics. In the past, several web-based machine learning (ML) tools have been proposed to assist researchers in identifying potential ACPs for further testing. Notably, our meta-approach method, mACPpred, introduced in 2019, has significantly advanced the field of ACP research. Given the exponential growth in the number of characterized ACPs, there is now a pressing need to create an updated version of mACPpred. To develop mACPpred 2.0, we constructed an up-to-date benchmarking dataset by integrating all publicly available ACP datasets. We employed a large-scale of feature descriptors, encompassing both conventional feature descriptors and advanced pre-trained natural language processing (NLP)-based embeddings. We evaluated their ability to discriminate between ACPs and non-ACPs using eleven different classifiers. Subsequently, we employed a stacked deep learning (SDL) approach, incorporating 1D convolutional neural network (1D CNN) blocks and hybrid features. These features included the top seven performing NLP-based features and 90 probabilistic features, allowing us to identify hidden patterns within these diverse features and improve the accuracy of our ACP prediction model. This is the first study to integrate spatial and probabilistic feature representations for predicting ACPs. Rigorous cross-validation and independent tests conclusively demonstrated that mACPpred 2.0 not only surpassed its predecessor (mACPpred) but also outperformed the existing state-of-the-art predictors, highlighting the importance of advanced feature representation capabilities attained through SDL. To facilitate widespread use and accessibility, we have developed a user-friendly for mACPpred 2.0, available at https://balalab-skku.org/mACPpred2/.

01 Aug 2024·International Journal of Biological Macromolecules

Novel ApeC-containing protein mediates the recognition and internalization of Vibrio splendidus in Apostichopus japonicus

Article

Author: Li, Chenghua ; Sun, Lianlian ; Liang, Weikang ; Xiang, Yangxi ; Shi, Yue ; Chen, Kaiyu

Pattern recognition receptors (PRRs) mediate the innate immune responses and play a crucial role in host defense against pathogen infections. Apextrin C-terminal (ApeC)-containing proteins (ACPs), a newly discovered class of PRRs specific to invertebrates, recognize pathogens through their ApeC domain as intracellular or extracellular effectors. However, the other immunological functions of ACPs remain unclear. In this study, a membrane-localized ACP receptor was identified in the sea cucumber Apostichopus japonicus (denoted as AjACP1). The ApeC domain of AjACP1, which was located outside of its cell membrane, exhibited the capability to recognize and aggregate Vibrio splendidus. AjACP1 was upregulated upon V. splendidus infection, internalizing into the cytoplasm of coelomocytes. AjACP1 overexpression enhanced the phagocytic activity of coelomocytes against V. splendidus, while knockdown of AjACP1 by RNA interfere inhibited coelomocyte endocytosis. Inhibitor experiments indicated that AjACP1 regulated coelomocyte phagocytosis through the actin-dependent endocytic signaling pathway. Further investigation revealed that AjACP1 interacted with the subunit of the actin-related protein 2/3 complex ARPC2, promoting F-actin polymerization and cytoskeletal rearrangement and thereby affecting the coelomocyte phagocytosis of V. splendidus via the actin-dependent endocytic signaling pathway. As a novel membrane PRR, AjACP1 mediates the recognition and phagocytic activity of coelomocytes against V. splendidus through the AjACP1-ARPC2-F-actin polymerization and cytoskeletal rearrangement pathway.

News (Medical) associated with AcpS

13 Oct 2022

·www.sciencedaily.com

The missing link: Fatty acid metabolism impacts plant immunity

A recent study reveals a new dimension to the role of FA biosynthesis in plants by providing a direct link to the plant defense mechanism. That healthy salad you ate for lunch contains fatty acids -- surprised? Fatty acids, lipids, and fats in our food may sound undesirable, but they are foundational to human life and to the plants we consume. Their interaction with certain proteins helps regulate plant growth. Plant fatty acids (FAs) serve as structural constituents of cell membranes and are building blocks for certain hormones, among other things. Fatty acids are stabilized during synthesis by acyl carrier proteins (ACPs), found throughout all branches of life, which support and elongate the growing FA chains. A recent study, by Zhenzhen Zhao (of The Ohio State University) and colleagues, reveals a new dimension to the role of FA biosynthesis in plants by providing a direct link to the plant defense mechanism. Published in Molecular Plant-Microbe Interactions (MPMI), the study found that the Arabidopsis plants lacking the Acyl Carrier Protein 1 (ACP1) were more resistant to the bacterial pathogen, Pseudomonas syringae, indicating that FA metabolism plays a critical role in plant immunity. Corresponding author Ye Xia comments, "Our research provided a direct link between FA metabolism and plant immunity and unraveled the potential role of ACP1 in plant defense across economically important crops." The study shows that ACP1 is essential to maintaining the homeostasis of hormones that affect a variety of plant stress responses. This effect on hormone signaling creates a broad arena for ACP1 to influence other biotic and abiotic stresses, an area ripe for further exploration. In addition, this research emphasizes the importance of studying individual members of gene families that may have discrete functions, since ACP1 plays a role in plant resistance -- distinct from that of its close family member, ACP4. ACP1 homologs are currently present in a variety of economically important crops. In the future, genetically engineering these important crops to modulate the expression of ACP1 is an exciting avenue to create disease-resistant varieties that withstand bacterial and other pathogen infections.

Analysis

Perform a panoramic analysis of this field.

view full example data

Chat with Hiro

Get started for free today!

Accelerate Strategic R&D decision making with Synapse, PatSnap’s AI-powered Connected Innovation Intelligence Platform Built for Life Sciences Professionals.

Start your data trial now!

Synapse data is also accessible to external entities via APIs or data packages. Empower better decisions with the latest in pharmaceutical intelligence.

Bio

Bio Sequences Search & Analysis

Chemical

Chemical Structures Search & Analysis

AcpS

Basic Info

Related

Analysis