Cell Biology

Recordings of electric potential changes on plant surfaces have been utilized to identify the components and mechanisms involved in the formation and transmission of systemic signals elicited by stimuli such as herbivory, wounding, or burning. The recorded responses, commonly referred to as slow wave or variation potentials, exhibit striking variability in their waveform. The extent to which this variability is due to differences in experimental procedures or plant biological variability remains unclear. Here, we provide a detailed and robust protocol refined from years of experience in conducting leaf surface potential recordings of Arabidopsis thaliana in response to mechanical wounding. This protocol serves as a comprehensive tutorial covering plant growth, procedures for reproducible mechanical wounding, critical aspects of electrophysiological recordings, and statistical analysis of surface potential recordings. It particularly emphasizes the construction and maintenance of electrodes, placement of the reference or ground electrode, mechanisms for wounding, and data analysis. This protocol aims to promote and facilitate the adoption, standardization, and interoperability of plant surface potential recordings among research groups, thereby increasing the reproducibility and comparability of data within the field.

Human immunodeficiency virus (HIV) remains a global health challenge with major research efforts being directed toward the unmet needs for a vaccine and a safe and scalable cure. Antiretroviral therapy (ART) suppresses viral replication but does not cure infection and so requires lifelong adherence. HIV-specific CD8+ T-cell responses play a crucial role in long-term HIV control as demonstrated in elite controllers, highlighting their potential in HIV cure strategies. Various HIV mouse models—including the human-hematopoietic stem cell (Hu-HSC) mouse, the bone marrow, liver, and thymus (BLT) mouse, and the human peripheral blood leukocyte (Hu-PBL) mouse—have deepened the understanding of HIV dynamics and facilitated the development of therapeutics. We developed the HIV participant-derived xenograft (HIV PDX) mouse model to enable long-term in vivo evaluation of bona fide autologous T-cell mechanisms of HIV control, including the antiviral activity of primary memory CD8+ (mCD8+) T cells taken directly from people with or without HIV, as well as testing potential immunotherapies. Additionally, this model faithfully recapitulates virus escape mutations in response to sustained CD8+ T-cell pressure, enabling the assessment of strategies to curb virus escape. In this model, NSG mice are engrafted with purified memory CD4+ (mCD4+) cells and infected with HIV; then, they receive autologous CD8+ T cells or T-cell products. Key advantages of this model include the minimization of graft-versus-host disease (GvHD), which severely limits peripheral blood mononuclear cell (PBMC) or total CD4-engrafted mice, the ability to evaluate long-term natural donor-specific T-cell responses in vivo, and the lack of use of human fetal tissues required for most humanized mouse models of HIV.

With the advancement of liquid chromatography–mass spectrometry (LC–MS/MS), the quantification of glycerophospholipid (PL) molecules has become more accessible, leading to the discovery of numerous enzymes responsible for determining the acyl groups attached to these molecules. Metabolic tracer experiments using radioisotopes and stable isotopes are powerful tools for defining the function of metabolic enzymes and metabolic flux. We have established an ex vivo muscle experimental system using stable isotope–labeled fatty acids to evaluate fatty acid incorporation into PL molecules. Here, we describe a method to incorporate fatty acids with stable isotope labels into excised skeletal muscle and detect the PL molecules containing labeled acyl chains by LC–MS/MS.

Matrix vesicles (MVs) represent a heterogeneous group of spherical membrane-bound extracellular vesicles in the range of 100–200 nm in diameter secreted by mineralizing osteoblasts. The initial synthesis of the amorphous calcium phosphate occurs within the confines of the intracellular MVs, which are capable of transporting P_i and Ca²⁺ into the MV lumen. Thus, understanding the initial process of MV-mediated mineralization is critical in developing better therapeutic strategies for various bone-related disorders such as osteoporosis and addressing ectopic calcification of soft tissues. Although various techniques and commercially available kits are now available for isolating MVs, isolating a pure population of MVs is challenging mainly because of their variable size and lack of consensus protein markers. This ultracentrifugation-based protocol ensures high purity of isolated MVs by removing other contaminated extracellular vesicles and cellular debris through sequential centrifugation steps but also allows downstream functional mineralization assays of the isolated MVs.

Homologous recombination (HR) is a major pathway to repair DNA double-strand breaks. Hereditary breast and ovarian cancer syndrome (HBOC) is caused by germline pathogenic variants of HR-related genes, such as BRCA1 and BRCA2 (BRCA1/2). Cancer cells with HR deficiency are sensitive to poly(ADP-ribose) polymerase (PARP) inhibitors. Therefore, accurate evaluation of HR activity is helpful to diagnose HBOC and predict the effects of PARP inhibitors. The direct-repeat GFP (DR-GFP) assay has been utilized to evaluate cellular HR activity. However, evaluation by the DR-GFP assay tends to be qualitative and requires the establishment of stable cell lines. Therefore, we developed an assay to quantitatively measure HR activity called Assay for Site-Specific HR Activity (ASHRA), which can be performed by transiently transfecting two plasmids. In ASHRA, we use Cas9 endonuclease to create DNA double-strand breaks at specific sites in the genome, enabling the targeting of any endogenous loci. Quantification of HR products by real-time PCR using genomic DNA allows HR activity evaluated at the DNA level. Thus, ASHRA is an easy and quantitative method to evaluate HR activity at any genomic locus in various samples. Here, we present the protocols for adherent cells, suspension cells, and tumor tissues.

Pathological conditions of the cervix ranging from cervical cancer to structural dysfunction associated with preterm labor all have limited treatment options. Thus, there is a need for physiologically relevant preclinical models that recapitulate the structure and function of this human organ. Here, we describe a protocol for engineering and studying a highly functional in vitro model of the human cervix that is composed of a commercially available, dual-channel, microfluidic, organ-on-a-chip (Organ Chip) device lined by primary cervical epithelial (CE) cells interfaced across a porous membrane with cervical stromal cells. The provision of dynamic and customized media flow through both the epithelial and stromal compartments results in cell growth and differentiation, including the accumulation of a thick mucus layer overlying the epithelium. The resulting model closely mimics the structure, epithelial barrier, mucus composition and structure, and biochemical properties of the in vivo human cervix, as well as its responsiveness to female hormones, pH, and microbiome. This Cervix Chip protocol also includes noninvasive techniques for longitudinal monitoring of the live 3D tissue model. The Cervix Chip offers a powerful preclinical platform for replicating in vivo cervical physiology, studying disease mechanisms, and facilitating the development of new therapeutics and diagnostics.

The endothelial barrier is a semipermeable cell layer covering the inside of blood vessels that regulates the flux of ions, macromolecules, and plasma from blood to tissues. Inflammation promotes an increase in vascular permeability, which can contribute to disease if not controlled properly. Thus, it is important to understand in detail the molecular mechanisms underlying inflammatory vascular hyperpermeability. While endothelial permeability can be measured in vitro, these assays do not recapitulate precisely the in vivo vasculature. Thus, in vivo assays are required to understand the full picture of vascular permeability regulation. Here, we describe an established assay that involves injection of Evans blue dye followed by intradermal injection of agents inducing vascular permeability. This assay is relatively easy to perform and provides reliable data on permeability regulation in vivo.

Daphnia magna is a well-established model organism in ecotoxicology, environmental monitoring, and genetics due to its sensitivity to pollutants, its pivotal role in freshwater ecosystems, and its well-characterized genome. Despite its extensive use in these fields, there is a notable lack of established protocols for developing primary cell culture systems and conducting transgenic studies in Daphnia spp. This study addresses these gaps by optimizing a medium and standardizing protocols for primary cell culture and transgenic experiments in D. magna. Primary cell cultures were established from both D. magna embryos and whole organisms, with medium optimization verified using XTT assay. Cell viability was sustained for over two months using a modified Schneider’s insect medium enriched with FBS, glucose, MEM vitamin mix, and selenium. DNA replication and cell proliferation were confirmed through BrdU labeling. Both mechanical and enzymatic passaging methods were compared, resulting in 20% and 10% cell attachment, respectively. For transgenic applications, this study successfully standardized plasmid-mediated lipofection and baculovirus-mediated transduction, achieving success rates of 52% and 45%. These findings represent a pioneering effort in D. magna embryonic cell culture, offering a reliable in vitro platform for future biological research, including ecotoxicological and epigenetic investigations. The established protocols and optimized cell culture medium have significant implications for advancing crustacean cell line research and transgenic model development, enhancing our understanding of biological processes in controlled laboratory environments.

The masseter muscle, a key orofacial muscle, demonstrates unique anatomical and functional properties, including sexual dimorphism in myosin heavy chain (MyHC) expression and complex fiber architecture. Despite its importance in mastication and relevance to various disorders, phenotypic characterization of the masseter remains limited. Conventional fluorescence microscopy has been a cornerstone in muscle fiber typing, reliably identifying MyHC isoforms and measuring fiber cross-sectional areas. Building on this foundation, confocal microscopy offers complementary advantages, such as enhanced resolution, increased flexibility for multiplexing, and the ability to visualize complex structures in three dimensions. This study presents a detailed protocol for using confocal microscopy to achieve high-resolution imaging and molecular characterization of masseter muscle cryosections. By leveraging advanced technologies such as white light lasers and extended z-length imaging, this method ensures precise spectral separation, simultaneous multichannel fluorescence detection, and the ability to capture muscle architecture in three dimensions. The protocol includes tissue preparation, immunostaining for MyHC isoforms, and postprocessing for fiber segmentation and quantification. The imaging setup was optimized for minimizing signal bleed through, improving the signal-to-noise ratio, and enabling detailed visualization of muscle fibers and molecular markers. Image postprocessing allows for quantification of the cross-sectional area of individual fibers, nuclei location measurements, and identification of MyHC isoforms within each fiber. This confocal microscopy–based protocol provides similar resolution and contrast compared to conventional techniques, enabling robust multiplexed imaging and 3D reconstruction of muscle structures. These advantages make it a valuable tool for studying complex muscle architecture, offering broad applications in muscle physiology and pathology research.

Confocal microscopy is integral to molecular and cellular biology, enabling high-resolution imaging and colocalization studies to elucidate biomolecular interactions in cells. Despite its utility, challenges in handling large datasets, particularly in preprocessing Z-stacks and calculating colocalization metrics like the Manders coefficient, limit efficiency and reproducibility. Manually processing large numbers of imaging data for colocalization analysis is prone to observer bias and inefficiencies. This study presents an automated workflow integrating Python-based preprocessing with Fiji ImageJ's BIOP-JACoP plugin to streamline Z-stack refinement and colocalization analysis. We generated an executable Windows application and made it publicly available on GitHub (https://github.com/weiyue99/Yue-Colocalization), allowing even those without Python experience to directly run the Python code required in the current protocol. The workflow systematically removes signal-free Z-slices that sometimes exist at the beginning and/or end of the Z-stacks using auto-thresholding, creates refined substacks, and performs batch analysis to calculate the Manders coefficient. It is designed for high-throughput applications, significantly reducing human error and hands-on time. By ensuring reproducibility and adaptability, this protocol addresses critical gaps in confocal image analysis workflows, facilitating efficient handling of large datasets and offering broad applicability in protein colocalization studies.