Subcellular Particles Research Articles

Determinants in the HTLV-1 Capsid Major Homology Region that are Critical for Virus Particle Assembly

The Gag protein of retroviruses is the primary driver of virus particle assembly. Particle morphologies among retroviral genera are distinct, with intriguing differences observed relative to human immunodeficiency virus type 1 (HIV-1), particularly that of human T-cell leukemia virus type 1 (HTLV-1). In contrast to HIV-1 and other retroviruses where the capsid (CA) carboxy-terminal domain (CTD) possesses the key amino acid determinants involved in driving Gag-Gag interactions, we have previously demonstrated that the amino-terminal domain (NTD) encodes the key residues crucial for Gag multimerization and immature particle production. Here in this study, we sought to thoroughly interrogate the conserved HTLV-1 major homology region (MHR) of the CACTD to determine whether this region harbors residues important for particle assembly. In particular, site-directed mutagenesis of the HTLV-1 MHR was conducted, and mutants were analyzed for their ability to impact Gag subcellular distribution, particle production and morphology, as well as the CA-CA assembly kinetics. Several key residues (i.e., Q138, E142, Y144, F147 and R150), were found to significantly impact Gag multimerization and particle assembly. Taken together, these observations imply that while the HTLV-1 CANTD acts as the major region involved in CA-CA interactions, residues in the MHR can impact Gag multimerization, particle assembly and morphology, and likely play an important role in the conformation the CACTD that is required for CA-CA interactions.

Evidence that keratinocyte microvesicle particles carrying Platelet-activating factor mediate the widespread multi-organ damage associated with intoxicated thermal burn injury.

Thermal burn injuries can result in significant morbidity and mortality. The combination of ethanol intoxication with thermal burn injury results in increased morbidity through an exaggerated inflammatory response involving many organs. Recent studies have linked involvement of the lipid mediator Platelet-activating factor (PAF) in the pathology associated with intoxicated thermal burn injury (ITBI). The present studies tested the roles of PAF and the elevated levels of subcellular microvesicle particles (MVP) generated in response to ITBI in the subsequent multi-organ toxicity. First, thermal burn injury of HaCaT keratinocytes preincubated with ethanol resulted in augmented MVP release, which was blocked by inhibiting the PAF-generating enzyme cytosolic phospholipase A2 and the PAF receptor (PAFR). Second, ITBI of mice resulted in increased pro-inflammatory cytokine production and neutrophilic inflammation in multiple organs which were not present in mice deficient in PAFRs nor the MVP-generating enzyme acid sphingomyelinase (aSMase). Moreover, the increased bacterial translocation from the gut to mesenteric lymph nodes previously reported in murine ITBI was also dependent upon PAFR and aSMase. MVP released from ITBI-treated keratinocytes contained high levels of PAFR agonistic activity. Finally, use of topical aSMase inhibitor imipramine following ITBI attenuated the widespread organ inflammatory response of ITBI, suggesting a potential therapeutic for this condition. These studies provide evidence for PAF-enriched MVP generated in skin, which then act upon the gut PAFR resulting in bacterial translocation as the mechanism for the multi-organ dysfunction associated with ITBI. Inasmuch as aSMase inhibitors are widely available, these studies could result in effective treatments for ITBI.

Evidence for the involvement of keratinocyte-derived microvesicle particles in the photosensitivity associated with xeroderma pigmentosum type A deficiency.

Photosensitivity can be due to numerous causes. The photosensitivity associated with deficiency of xeroderma pigmentosum type A (XPA) has been previously shown to be associated with excess levels of the lipid mediator platelet-activating factor (PAF) generated by the keratinocyte. As PAF has been reported to trigger the production of subcellular microvesicle particles (MVP) due to the enzyme acid sphingomyelinase (aSMase), the goal of these studies was to discern if PAF and aSMase could serve as therapeutic targets for the XPA deficiency photosensitivity. HaCaT keratinocytes lacking XPA generated greater levels of MVP in comparison to control cells. Mice deficient in XPA also generated enhanced MVP levels in skin and in plasma in response to UV radiation. Use of a genetic strategy with mice deficient in both XPA and PAF receptors revealed that these mice generated less MVP release as well as decreased skin erythema and cytokine release compared to XPA knockout mice alone. Finally, the aSMase inhibitor imipramine blocked UV-induced MVP release in HaCaT keratinocytes, as well as XPA knockout mice. These studies support the concept that the photosensitivity associated with XPA involves PAF- and aSMase-mediated MVP release and provides a potential pharmacologic target in treating this form of photosensitivity.

Subcellular particles for characterization of host-parasite interactions

Parasitic diseases remain a major global health problem for humans. Parasites employ a variety of strategies to invade and survive within their hosts and to manipulate host defense mechanisms, always in the pathogen's favor. Extracellular vesicles (EVs), membrane-bound nanospheres carrying a variety of bioactive compounds, were shown to be released by the parasites during all stages of the infection, enabling growth and expansion within the host and adaptation to frequently changing environmental stressors. In this review, we discuss how the use of existing nanotechnologies and high-resolution imaging tools assisted in revealing the role of EVs during parasitic infections, enabling the quantitation, visualization, and detailed characterization of EVs. We discuss here the cases of malaria, Chagas disease and leishmaniasis as examples of parasitic neglected tropical diseases (NTDs). Unraveling the EVs' role in the NTD pathogenesis may enormously contribute to their early and reliable diagnostic, effective treatment, and prevention.

Mitochondrial bioenergetics and cytometric characterization of a synaptosomal preparation from mouse brain cortex

Mitochondrial function at synapses can be assessed in isolated nerve terminals. Synaptosomes are structures obtained in vitro by detaching the nerve endings from neuronal bodies under controlled homogenization conditions. Several protocols have been described for the preparation of intact synaptosomal fractions. Herein a fast and economical method to obtain synaptosomes with optimal intrasynaptic mitochondria functionality was described.Synaptosomal fractions were obtained from mouse brain cortex by differential centrifugation followed by centrifugation in a Ficoll gradient. The characteristics of the subcellular particles obtained were analyzed by flow cytometry employing specific tools.Integrity and specificity of the obtained organelles were evaluated by calcein and SNAP-25 probes. The proportion of positive events of the synaptosomal preparation was 75 ± 2 % and 48 ± 7% for calcein and Synaptosomal-Associated Protein of 25 kDa (SNAP-25), respectively.Mitochondrial integrity was evaluated by flow cytometric analysis of cardiolipin content, which indicated that 73 ± 1% of the total events were 10 N-nonylacridine orange (NAO)-positive. Oxygen consumption, ATP production and mitochondrial membrane potential determinations showed that mitochondria inside synaptosomes remained functional after the isolation procedure. Mitochondrial and synaptosomal enrichment were determined by measuring synaptosomes/ homogenate ratio of specific markers. Functionality of synaptosomes was verified by nitric oxide detection after glutamate addition.As compared with other methods, the present protocol can be performed briefly, does not imply high economic costs, and provides an useful tool for the isolation of a synaptosomal preparation with high mitochondrial respiratory capacity and an adequate integrity and function of intraterminal mitochondria.

Radiation Therapy Generates Release of Microvesicle Particles in Keratinocytes

Ionizing radiation (IR) exerts both tissue and systemic effects. However, the exact mechanism by which radiation therapy to skin results in local and systemic effects is incompletely defined. Previously our group has reported that IR of tumors results in the generation of the lipid mediator Platelet-activating factor (PAF) which resulted in systemic immunosuppressive effects via activation of regulatory T cells. Since PAF acting on the PAF receptor (PAFR) has been demonstrated to generate high levels of subcellular microvesicle particles (100-1000nm; MVP), and MVP are known to be able to signal systemically, the current studies seek to define whether IR of keratinocyte cells generates MVP, and to define the role of the PAFR in this process. Thus, we examine MVP release in the human keratinocyte cell line HaCaT. Moreover, the PAFR-dependency of IR-generated MVP is assessed by use of PAFR-positive KBP and PAFR-negative KBM cells. HaCaT cells (human keratinocytes), KBM cells (PAFR-negative), and KBP cells (PAFR-positive) were grown in 10cm dishes and treated with IR at either no treatment 0 Gy (NT), 4 Gy and 10 Gy. IR was delivered utilizing a technology company's medical linear accelerator radiotherapy system set up with dosimetry verified by nanodot optical stimulated luminescence (Landauer, Glenwood, IL). Some cell lines were treated with PAFR agonist N-methyl carbamoyl PAF (CPAF) and a phorbol ester TPA, known inducers of MVP release. A set of cells were treated with only 90% DMSO/10% ethanol vehicle in HBSS with BSA. After treatments, cells were incubated for 4 hours prior to extraction of MVPs. MVPs were isolated through centrifuging at 2000G for 20, supernatant was collected, transferred into different tubes, and centrifuged at 20,000 G for 70 mins. MVP was detected using a NanoSight NS300 instrument. MVP concentrations were recorded, and the data was statistically analyzed using Student's t-test (JMP, Cary, NC). IR treatment of HaCaT cells at various fluences exhibited statistically significant increases in MVP generation when compared to NT. Of note, 4 Gy resulted in the most fluence for MVP release but was not significant. IR treatment of KB cells resulted in MVP release in both KBM and KBP cells at both 4 and 10Gy. Augmented levels of MVP release were noted in KBP over KBM cells with any IR dose suggesting that the presence of the PAFR is involved in MVP release. Testing of inhibitors of the MVP generating enzyme acid sphingomyelinase (aSMase) also revealed involvement of this lipid metabolizing enzyme. The present studies indicate that RT can generates MVP production in epithelial cells. The mechanism for IR-generated MVP appears to involve aSMase and the PAFR. Target cell MVP release may provide a mechanism for RT effects, including the release of cytokines that influence systemic and local inflammation. Elucidation of this novel pathway may provide insights into IR effects on skin along with new therapeutic strategies.

A Review on Formulation and Evaluation of Liposomal Drugs

A liposome is the drug delivery system used for the administration of various types of drugs or active substances essential for the treatment of various types of diseases. They play a major role in the target delivery of the drug to particular tissue without affecting the other body parts. Hence it is also called targeted drug delivery system. The term liposome means lipid body. It has been derived on the basis of name of subcellular particles, ribosome. Liposomes were first made by the British scientist Alec Bangham and colleagues at Babraham Cambridge in the mid- 1960s and they first published the structure of liposomes in 1964.Their size ranges from 25 to 500 nm. In this present review, we discussed about liposomes formulation, evaluation and their mechanism of action in the biological system.

Mapping optical scattering properties to physical particle information in singly and multiply scattering samples.

Optical coherence tomography (OCT) leverages light scattering by biological tissues as endogenous contrast to form structural images. Light scattering behavior is dictated by the optical properties of the tissue, which depend on microstructural details at the cellular or sub-cellular level. Methods to measure these properties from OCT intensity data have been explored in the context of a number of biomedical applications seeking to access this sub-resolution tissue microstructure and thereby increase the diagnostic impact of OCT. Most commonly, the optical attenuation coefficient, an analogue of the scattering coefficient, has been used as a surrogate metric linking OCT intensity to subcellular particle characteristics. To record attenuation coefficient data that is accurately representative of the underlying physical properties of a given sample, it is necessary to account for the impact of the OCT imaging system itself on the distribution of light intensity in the sample, including the numerical aperture (NA) of the system and the location of the focal plane with respect to the sample surface, as well as the potential contribution of multiple scattering to the reconstructed intensity signal. Although these considerations complicate attenuation coefficient measurement and interpretation, a suitably calibrated system may potentiate a powerful strategy for gaining additional information about the scattering behavior and microstructure of samples. In this work, we experimentally show that altering the OCT system geometry minimally impacts measured attenuation coefficients in samples presumed to be singly scattering, but changes these measurements in more highly scattering samples. Using both depth-resolved attenuation coefficient data and layer-resolved backscattering coefficients, we demonstrate the retrieval of scattering particle diameter and concentration in tissue-mimicking phantoms, and the impact of presumed multiple scattering on these calculations. We further extend our approach to characterize a murine brain tissue sample and highlight a tumor-bearing region based on increased scattering particle density. Through these methods, we not only enhance conventional OCT attenuation coefficient analysis by decoupling the independent effects of particle size and concentration, but also discriminate areas of strong multiple scattering through minor changes to system topology to provide a framework for assessing the accuracy of these measurements.

Plasma extracellular vesicle test sample to standardize flow cytometry measurements

BackgroundExtracellular vesicles (EVs) in body fluids are explored as disease biomarkers, but EV concentrations measured by flow cytometers (FCMs) are incomparable. ObjectivesTo improve data comparability, new reference materials with physical properties resembling EVs and reference procedures are being developed. The validation of new reference materials and procedures requires biological test samples. We developed a human plasma EV test sample (PEVTES) that i) resembles subcellular particles in plasma, ii) is ready-to-use, iii) is flow cytometry–compatible, and iv) is stable. MethodsThe PEVTES was prepared from human plasma of 3 fasting donors. EVs were immunofluorescently stained with antibodies against platelet-specific (CD61) and erythrocyte-specific (CD235a) antigens or lactadherin. To reduce the concentration of soluble proteins, lipoproteins, and unbound reagents, stained EVs were isolated from plasma by size-exclusion chromatography. After isolation, the PEVTES was filtered to remove remnant platelets. PEVTESs were diluted in cryopreservation agents, dimethyl sulfoxide, glycerol, or trehalose and stored at −80 °C for 12 months. After thawing, stained EV concentrations were measured with a calibrated FCM (Apogee A60-Micro). ResultsWe demonstrate that the developed PEVTES resembles subcellular particles in human plasma when measured using FCM and that the concentrations of prestained platelet-derived, erythrocyte-derived, and lactadherin+ EVs in the PEVTES are stable during storage at −80 °C for 12 months when stored in trehalose. ConclusionThe PEVTES i) resembles subcellular particles in plasma, ii) is ready-to-use, iii) is flow cytometry–compatible, and iv) is stable. Therefore, the developed PEVTES is an ideal candidate to validate newly developed reference materials and procedures.

Extracorporeal Photopheresis Suppresses Transplant Fibrosis by Inducing Decorin Expression in Alveolar Macrophages.

Extracorporeal Photopheresis Suppresses Transplant Fibrosis by Inducing Decorin Expression in Alveolar Macrophages.

Abstract 1812: ROS-dependent activation of immunogenic glioblastoma cell death & release of immunogenic particles by an autologous cell-based immunotherapeutic platform

Abstract Background: Imvax is developing a novel personalized immunotherapy platform that combines whole-tumor derived cells with an antisense oligonucleotide against insulin-like growth factor 1-receptor in implantable biodiffusion chambers (BDCs; 0.1 μm pore-size). The lead product, IGV-001, was evaluated in newly diagnosed glioblastoma (GBM) patients in a phase 1b clinical trial. Median overall survival of highest exposure IGV-001-treated ‘Stupp-eligible patients (n=10) was 38.2 months compared with 16.2 months in current standard-of-care-treated patients (p=0.044) (Andrews 2021). Imvax also reported anti-tumor activity of the murine variant of this product, mIGV-001, in the GL261 GBM mouse model and detected mIGV-001-induced immune responses in BDC-draining lymph nodes. Since reactive oxygen species (ROS) overproduction can result in immunogenic cell death, we investigated the role of ROS formation as a mediator of cell death in mIGV-001 as well as the generation of subcellular particles that, when released from the BDCs, may provide a tumor antigen payload with potential anti-tumor activity. Methods: Mouse (m) or human (h) variants of IGV-001 were prepared using mouse GL261 or human T98G GBM cells, respectively, and BDCs were incubated for 24-48 h. ROS levels were detected by flow cytometry and fluorescence microscopy via oxidation of H2DCF (a fluorescein analog used to quantify ROS in cells) in the presence or absence of the antioxidant N-acetyl-cysteine (NAC). m/hIGV-001 viability was assessed by flow cytometry using Annexin V/7-AAD staining. Particle size distribution in hIGV-001 BDC contents was analyzed using a Nanosight NS300. The transport of subcellular particles (25-90 nm) across the BDC membrane was modeled under dynamic and static conditions using MATLAB® 2022a and confirmed by in vitro studies. Results: After 24 h in vitro, ROS levels in mIGV-001 were significantly increased along with overt cell death. ROS scavenging with NAC resulted in a cell viability rescue of approximately 50% (from ~40% to ~60% viable cells). Similar trends, although of reduced magnitude, were observed in hIGV-001. Particle analysis within hIGV-001 BDCs showed that after 48 h in culture, dead cells produced particles small enough to diffuse through the BDC membrane. Computational models corroborated that under static conditions, particle equilibrium inside and outside BDCs was achieved after 40 h, 80 h, and 260 h for 25 nm, 50 nm, and 90 nm particles, respectively. Under dynamic conditions, equilibrium was reached in less than 5 h irrespective of particle size. Conclusions: The use of a surgically implantable drug-device combination product induces ROS-associated immunogenic cell death and generation of a tumor-derived immunogenic payload that can be taken up by local DCs, which travel to the proximal draining lymph nodes to activate anti-tumor T cells. Citation Format: Christopher Cultrara, Kenneth Kirby, Essam Elrazaq, Christopher Uhl, Amelia Zellander, Lorenzo Galluzzi, Mark Exley, Jenny Zilberberg. ROS-dependent activation of immunogenic glioblastoma cell death & release of immunogenic particles by an autologous cell-based immunotherapeutic platform [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 1812.

Topical Photodynamic Therapy Generates Bioactive Microvesicle Particles: Evidence for a Pathway Involved in Immunosuppressive Effects

Although effective in treating actinic damage, topical photodynamic therapy (PDT) has been shown to be immunosuppressive through unknown mechanisms, which could potentially limit its effectiveness. Multiple types of environmental stressors, including PDT, can produce the immunosuppressive lipid mediator platelet-activating factor (PAF). Because PAF can produce subcellular microvesicle particles (MVPs), these studies tested whether PDT can generate PAF and MVP release and whether these are involved in PDT-induced immunosuppression. Previously, topical PDT using blue light and 5-aminolevulinic acid was found to be a potent stimulus for PAF production in mice and human skin explants and human patients, and we show that experimental PDT also generates high levels of MVP. PDT-generated MVPs were independent of the PAF receptor but were dependent on the MVP-generating enzyme acid sphingomyelinase. Patients undergoing topical PDT treatment to at least 10% of body surface area showed local and systemic immunosuppression as measured by inhibition of delayed-type hypersensitivity reactions. Finally, using a murine model of contact hypersensitivity, PDT immunosuppression was blocked by genetic and pharmacologic inhibition of acid sphingomyelinase and genetic inhibition of PAF receptor signaling. These studies describe a mechanism involving MVP through which PDT exerts immunomodulatory effects, providing a potential target to improve its effectiveness.

Platelet-activating factor and microvesicle particles as potential mediators for the toxicity associated with intoxicated thermal burn injury.

Thermal burn injuries (TBIs) in patients who are alcohol-intoxicated result in greater morbidity and mortality. The systemic toxicity found in human patients, which includes both immediate systemic cytokine generation with multiple organ failure and a delayed systemic immunosuppression, has previously been replicated in mouse models combining ethanol and localized TBI. Though considerable insights have been provided with these models, the exact mechanisms for these pathologic effects are unclear. In this review, we highlight the roles of the lipid mediator platelet-activating factor (PAF) and subcellular microvesicle particle (MVP) release in response to intoxicated thermal burn injury (ITBI) as effectors in the pathology. Particularly, MVP is released from keratinocytes in response to PAF receptor (PAFR) activation due to excess PAF produced by ITBI. These subcellular particles carry and thus protect the metabolically labile PAF which enable binding of this potent lipid mediator to several key sites. We hypothesize that PAF carried by MVP can bind to PAFR within the gut, activating myosin light chain kinase (MLCK). The subsequent gut barrier dysfunction in response to MLCK activation then allows bacteria to invade the lymphatic system and, eventually, the bloodstream, resulting in sepsis and resultant dysregulated inflammation in multiple organs. PAF in MVP also activate the skin mast cell PAFR resulting in migration of this key effector cell to the lymph nodes to induce immunosuppression. This review thus provides a mechanism and potential therapeutic approaches for the increased toxicity and immunosuppressive outcomes of TBI in the presence of acute ethanol exposure.

UVB-Induced Microvesicle Particle Release and Its Effects on the Cutaneous Microenvironment.

Ultraviolet B radiation (UVB) has profound effects on human skin that results in a broad spectrum of immunological local and systemic responses and is the major cause of skin carcinogenesis. One important area of study in photobiology is how UVB is translated into effector signals. As the skin is exposed to UVB light, subcellular microvesicle particles (MVP), a subtype of bioactive extracellular vesicles, are released causing a variety of local and systemic immunological effects. In this review, we highlight keratinocyte MVP release in keratinocytes in response to UVB. Specifically, Platelet-activating factor receptor agonists generated by UVB result in MVP released from keratinocytes. The downstream effects of MVP release include the ability of these subcellular particles to transport agents including the glycerophosphocholine-derived lipid mediator Platelet-activating factor (PAF). Moreover, even though UVB is only absorbed in the epidermis, it appears that PAF release from MVPs also mediates systemic immunosuppression and enhances tumor growth and metastasis. Tumor cells expressing PAF receptors can use this mechanism to evade chemotherapy responses, leading to treatment resistance for advanced cancers such as melanoma. Furthermore, novel pharmacological agents provide greater insight into the UVB-induced immune response pathway and a potential target for pharmacological intervention. This review outlines the need to more clearly elucidate the mechanism linking UVB-irradiation with the cutaneous immune response and its pathological manifestations. An improved understanding of this process can result in new insights and treatment strategies for UVB-related disorders from carcinogenesis to photosensitivity.

Loading of cell cultures with cholesterol‐dextran particles as a new functional test for Niemann–Pick type C disease

Deuterium-labeled cholesterol-dextran particles (d4-CholDex), prepared by co-precipitation, were internalized by cultured human skin fibroblasts and HEK293 cells. Subcellular particles from d4-CholDex-treated HEK293 cells were fractionated on iodixanol gradients. More than 60% of d4-cholesterol (d4-UC) in the gradient co-fractionated with lysosomal markers and NPC1. This and formation of d4-cholesteryl esters (d4-CE) in the cells suggests that d4-CholDex is lysosomally processed. In accordance with these findings, we observed an increase in lysosomal cholesterol content by fluorescence microscopy in CholDex-loaded cells. Fibroblast cultures including 13 NPC1-deficient, four heterozygous and six control lines were treated with d4-CholDex at final d4-UC concentration of 0.05 mg/ml (127.98μmol/L) for 3h and chased for 48 h in medium without d4-CholDex. Concentrations of d4-UC and d4-CE in harvested cells were measured by tandem mass spectrometry (MS/MS). d4-UC/d4-CE ratios were elevated in NP-C lines compared to controls (n=6, mean=4.36, range=1.89-8.91), with the highest ratios in severe NP-C1 phenotypes and the lowest in adolescent/adult type patients. There were overlaps between NP-C1 forms: early infantile (n=1, mean=48.6), late infantile (n=4, mean=36.3, range=20.6-54.0), juvenile (n=5, mean=24.7, range=13.4-38.3), adolescent/adult (n=3, mean=14.5, range=11.7-19.8). The ratios in NP-C1 heterozygotes were mildly elevated (n=4, mean=16.4, range=14.9-17.4) and comparable to patients with adolescent/adult NP-C1. The test can be useful in evaluation of suspected NP-C patients with inconclusive results of biomarker or molecular tests. Its advantages include standardized preparation of particles with longer shelf life at 4°C, quantitative results, and no requirement for radioactive chemicals.

Apoptosis Detection by Quantification of Cell Debris in Bright-Field Microscopy Images.

We describe a simple protocol for quantification of apoptosis by counting subcellular debris particles in bright-field microscopy images of cell culture media samples. The only necessary equipment is a bright-field microscope (fitted with a digital camera) and a computer for image processing and analysis. The method gives comparable results to established fluorescence markers in several different applications and is, in principle, compatible with any culture format. Given its simplicity, accessibility, and inexpensive nature, the method can complement or provide an alternative to other methods for apoptosis detection.

Automated Quantification of Subcellular Particles in Myogenic Progenitors.

Fluorescence microscopy is a powerful tool enabling the visualization of protein localization within cells. In this article, we outline an automated and non-biased way to detect and quantify subcellular particles using immunocytochemistry, fluorescence microscopy, and the program CellProfiler. We discuss the examination of two types of subcellular particles: messenger ribonucleoprotein (mRNP) granules, namely processing bodies and stress granules, and autophagosomes. Fluorescent microscopy Z-stacks are acquired and deconvolved, and maximum intensity images are generated. The number of subcellular particles per cell is then quantified using the described CellProfiler pipeline. We also explain how to isolate primary myoblast progenitor cells from mice, which were used to obtain the presented results. Last, we discuss the critical parameters to be considered for each of these techniques. Both mRNP granules and autophagosomes play important roles in sequestering intracellular cargo, such as messenger RNAs and RNA-binding proteins for mRNP granules and cytoplasmic waste for autophagosomes. The methods outlined in this article are widely applicable for studies relating to subcellular particle formation, localization, and flux during homeostasis, following stimuli, and during disease. © 2021 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Immunofluorescence microscopy of messenger ribonucleoprotein granules in primary myoblasts Alternate Protocol: Immunofluorescence microscopy of autophagosomes in primary myoblasts Support Protocol: Isolation of primary myoblasts from mice Basic Protocol 2: Automated quantification of subcellular particles.

Evidence for Systemic Reactive Oxygen Species in UVB-mediated Microvesicle Formation.

Recent studies have implicated subcellular microvesicle particles (MVP) in the ability of ultraviolet B radiation to exert both local and systemic effects. Indeed, UVB generates MVP (UVB-MVP) in human skin and systemically following phototherapy. The current studies were designed to test the hypothesis that the ability of UVB to generate MVP was dependent upon reactive oxygen species (ROS). To that end, we tested urine samples from subjects undergoing UVB phototherapy for the presence of isoprostanes as well as the oxidized guanosine derivative 8OHdG. We also conducted a clinical study in which volar forearms of subjects were treated with localized UVB and erythema/MVP measured. The same cohort was then treated with 7 days of vitamin C (2 g day-1 ) and vitamin E (1000 IU day-1 ), and UVB-induced MVPs tested on the contralateral forearm. Urine specimens from subjects undergoing phototherapy were found to have increased levels of isoprostanes and 8OHdG, with maximal levels noted 8-16 h post-treatment. Treatment with antioxidant vitamins resulted in diminished UVB-generated skin MVP to baseline levels. These studies suggest that whole-body UVB generates a systemic pro-oxidative response, and that antioxidants can attenuate localized skin UVB-MVPs.

Low UVB Fluences Augment Microvesicle Particle Generation in Keratinocytes.

Microvesicle particles (MVP) are bioactive subcellular particles which have been recently implicated in the keratinocyte response to many environmental stressors including ultraviolet B radiation (UVB). Previous studies have demonstrated that UVB generates high levels of MVP in a process involving the platelet-activating factor receptor (PAFR) and the enzyme acid sphingomyelinase (aSMase). Yet the fluences of UVB needed to generate MVP are usually above those commonly encountered. Using models including human epithelial cell lines invitro, human skin explants exvivo and murine studies invivo, the present studies indicate that pretreatment of epithelial cells/skin with PAFR agonist/phorbol ester can synergize with low fluences of UVB to generate high levels of MVP. These studies indicate the possibility that MVP could play a role in combinatorial pathologic processes involving UVB.

203 Heightened levels of microvesicle particles resulting from combination of ethanol and thermal burn injury

Ethanol, in combination with thermal burn injury, is a clinically significant problem resulting in an increase in morbidity and mortality due to acute multi-organ toxicity from excess systemic cytokine release. Moreover, murine models of intoxicated burn injury replicate the acute toxic effects as well as a delayed systemic immunosuppression. Almost half of the admitted hospital patients with burn injuries were alcohol intoxicated at the time of admission. Our group has demonstrated that the lipid mediator Platelet-activating factor (PAF) plays an important role in the delayed immunosuppressive effects of intoxicated thermal burn injury. As PAF receptor signaling causes generation of subcellular microvesicle particles (MVP), the objective of the present studies is to define the role of MVP in the toxicity associated with EtOH + burn injury. Using HaCaT keratinocyte-derived cell line, we demonstrate that both thermal burn injury and EtOH alone generate increased release of MVP into the supernatant. Combining the two agents results in an increased generation of MVP in at least an additive fashion. These studies suggest that MVP might play a role in the augmented toxicity of intoxicated thermal burn injury.