Perilipins: Lipid droplet coat proteins adapted for tissue-specific energy storage and utilization, and lipid cytoprotection

ABSTRACTProcollagen requires COPII coat proteins for export from the endoplasmic reticulum (ER). SEC24 is the major component of the COPII proteins that selects cargo during COPII vesicle assembly. There are four paralogs (A to D) of SEC24 in mammals, which are classified into two subgroups. Pathological mutations in SEC24D cause osteogenesis imperfecta with craniofacial dysplasia in humans and sec24d mutant fish also recapitulate this phenotypes. Consistent with the skeletal phenotypes, the secretion of collagen was severely defective in mutant fish, emphasizing the importance of SEC24D in collagen secretion. However, SEC24D patient-derived fibroblasts show only a mild secretion phenotype, suggesting tissue-specificity in the secretion process. To explore this possibility, we generated Sec24d knockout (KO) mice. Homozygous KO mice died prior to bone development. When we analyzed embryonic and extraembryonic tissues of mutant animals, we observed tissue-dependent defects of procollagen processing and ER export. The spacial patterns of these defects mirrored with SEC24B deficiency. By systematically knocking down the expression of Sec24 paralogs, we determined that, in addition to SEC24C and SEC24D, SEC24A and SEC24B also contribute to collagen secretion. In contrast, fibronectin 1 preferred either SEC24C or SEC24D. On the basis of our results, we propose that procollagen interacts with multiple SEC24 paralogs for efficient export from the ER, and that this is the basis for tissue-specific phenotypes resulting from SEC24 paralog deficiency.

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High-performance metal–iodine batteries enabled by a bifunctional dendrite-free Li–Na alloy anode

Journal of Materials Chemistry A ◽

10.1039/d0ta08072a ◽

2021 ◽

Vol 9 (1) ◽

pp. 538-545

Author(s):

Donglin Yu ◽

Dong Liu ◽

Lei Shi ◽

Jieshan Qiu ◽

Liming Dai

Keyword(s):

Energy Storage ◽

Energy Density ◽

Alkali Metal ◽

Specific Energy ◽

High Performance ◽

Alloy Anode ◽

Specific Energy Density ◽

High Theoretical Capacity ◽

Storage Technologies

Rechargeable aprotic alkali metal (Li and Na)–iodine (AM–I2) batteries with high theoretical capacity and specific energy density have emerged as one of the promising energy storage technologies.

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Effects of electrode pattern on thermal runaway of lithium-ion battery

International Journal of Damage Mechanics ◽

10.1177/1056789516660176 ◽

2016 ◽

Vol 27 (1) ◽

pp. 74-81 ◽

Cited By ~ 2

Author(s):

Meng Wang ◽

Anh V Le ◽

Daniel J Noelle ◽

Yang Shi ◽

Hyojung Yoon ◽

...

Keyword(s):

Energy Storage ◽

Temperature Profile ◽

Lithium Ion Battery ◽

Heat Generation ◽

Specific Energy ◽

Storage Systems ◽

Lithium Ion ◽

Thermal Runaway ◽

Cathode Layer ◽

High Specific Energy

In the current study, through a set of nail penetration and impact tests on modified lithium-ion battery coin half-cells, we examine the effects of electrode pattern on the heat generation behaviors associated with internal shorting. The results show that the temperature profile is quite insensitive to the openings in cathode layer, which may be attributed to the high specific energy as well as the secondary conductive paths. This finding will considerably influence the study in the area of thermal runaway mitigation of energy storage systems.

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Recent Progress on Pristine Metal/Covalent-Organic Frameworks and Their Composites for Lithium–Sulfur Batteries

Energy & Environmental Science ◽

10.1039/d0ee03181j ◽

2021 ◽

Author(s):

Zijian Zheng ◽

Huan Ye ◽

Zaiping Guo

Keyword(s):

Energy Storage ◽

Specific Energy ◽

Recent Progress ◽

Covalent Organic Frameworks ◽

Energy Storage Devices ◽

Practical Applications ◽

Storage Devices ◽

Lithium Sulfur Batteries ◽

Lithium Sulfur

Lithium–sulfur (Li–S) batteries have emerged as promising energy storage devices due to their high theoretical specific energy densities; their practical applications, however, have been restricted due to their poor cycling...

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A Simple Method for Identifying the Thermodynamic Limits to the Specific Energy of Electrochemical Energy Storage Systems

10.26434/chemrxiv.8799188 ◽

2019 ◽

Author(s):

Roland Hermann Pawelke

Keyword(s):

Energy Storage ◽

Specific Energy ◽

Storage Systems ◽

Electrochemical Energy Storage ◽

Energy Storage Systems ◽

Nernst Equation ◽

Battery Cell ◽

Simple Method ◽

Global Understanding ◽

Thermodynamic Limits

This article outlines a simple method for identifying the thermodynamic limits to electrochemical reversible energy storage systems based on the Nernst equation and previous results obtained from work on reversible chemical hydrogen sorption. The model is successfully validated for seven reversible battery cell examples. The findings of this work substantiate the idea of a general thermodynamic principle limiting reversible chemical energy storage and suggest a change of paradigm towards a global understanding of the matter.

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Modeling Ionic Liquid Based Electrolytes for Lithium Batteries

Volume 6A: Energy ◽

10.1115/imece2013-66497 ◽

2013 ◽

Author(s):

Soumik Banerjee

Keyword(s):

Ionic Liquids ◽

Energy Storage ◽

Ionic Conductivity ◽

Lithium Ion Batteries ◽

Specific Energy ◽

Lithium Salt ◽

Lithium Ion ◽

Ionic Species ◽

Specific Power ◽

Energy Storage Devices

Based on ever-growing societal demand for stable energy supply, recent times have witnessed an increasing emphasis on developing energy storage devices such as batteries with improved specific energy and specific power. Among the myriad energy-storage technologies, rechargeable lithium ion batteries are widely used as energy sources for a range of portable electronic devices because of their relatively high specific energy storage capabilities [1]. However, the highest energy storage capacity achieved by a state-of-the-art lithium ion battery is too low to meet current demands in larger applications such as in the automotive industry [1]. The limitation is due, in part, to the limited ionic conductivity of currently used organic electrolytes coupled with their volatility, electrochemical instability and flammability, which raises safety concerns. The development of new generation of lithium ion batteries with significantly improved energy storage would require the selection of novel electrolyte materials with improved performance without compromising on safety standards. In recent years, there has been growing interest in the development of room temperature ionic liquids because they have extremely low vapor pressure, are stable at high temperatures, are highly resistant to oxidation and reduction, possess high ionic conductivity and have tunable electrochemical properties. However, the ionic conductivity of ionic liquids doped with lithium salt is extremely sensitive to the molecular structure of the ions as well as the extent of coordination between neighboring ionic species. In an effort to understand how atomistic interactions determine transport properties of ionic liquids, in the current study, we simulated lithium salt doped pyrrolidinium based ionic liquids using fundamental atomistic simulations. Properties such as density and self-diffusion coefficients were determined from molecular dynamics simulations and compared to experimental data to validate our model. Our simulations indicate that the mobility of lithium ions is limited due to association with multiple salt anions.

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Minireview: Lipid Droplets in Lipogenesis and Lipolysis

Endocrinology ◽

10.1210/en.2007-1713 ◽

2008 ◽

Vol 149 (3) ◽

pp. 942-949 ◽

Cited By ~ 318

Author(s):

Nicole A. Ducharme ◽

Perry E. Bickel

Keyword(s):

Lipid Droplet ◽

Lipid Droplets ◽

Cytoskeletal Proteins ◽

Lipid Storage ◽

Model Organisms ◽

Coat Proteins ◽

Specific Expression ◽

Interacting Protein ◽

Cytoplasmic Inclusions ◽

Protein Receptors

Organisms store energy for later use during times of nutrient scarcity. Excess energy is stored as triacylglycerol in lipid droplets during lipogenesis. When energy is required, the stored triacylglycerol is hydrolyzed via activation of lipolytic pathways. The coordination of lipid storage and utilization is regulated by the perilipin family of lipid droplet coat proteins [perilipin, adipophilin/adipocyte differentiation-related protein (ADRP), S3-12, tail-interacting protein of 47 kilodaltons (TIP47), and myocardial lipid droplet protein (MLDP)/oxidative tissues-enriched PAT protein (OXPAT)/lipid storage droplet protein 5 (LSDP5)]. Lipid droplets are dynamic and heterogeneous in size, location, and protein content. The proteins that coat lipid droplets change during lipid droplet biogenesis and are dependent upon multiple factors, including tissue-specific expression and metabolic state (basal vs. lipogenic vs. lipolytic). New data suggest that proteins previously implicated in vesicle trafficking, including Rabs, soluble N-ethylmaleimide sensitive factor attachment protein receptors (SNAREs), and motor and cytoskeletal proteins, likely orchestrate the movement and fusion of lipid droplets. Thus, rather than inert cytoplasmic inclusions, lipid droplets are now appreciated as dynamic organelles that are critical for management of cellular lipid stores. That much remains to be discovered is suggested by the recent identification of a novel lipase [adipocyte triglyceride lipase (ATGL)] and lipase regulator [Comparative Gene Identification-58 (CGI-58)], which has led to reconsideration of the decades-old model of lipolysis. Future discovery likely will be driven by the exploitation of model organisms and by human genetic studies.

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