Disclosed are compositions and methods for promoting survival of or axon regeneration in neurons by increasing mitochondrial motility in the neuron. Also disclosed are methods to treat neuronal injury and disease and disorders characterized by neuronal injury. Agents that increase Armcx1 activity, such as Armcx1 polypeptide or vectors comprising nucleic acid encoding Armcx1 polypeptide, are proposed for use in the methods. Pharmaceutical composition comprising the agents, and methods for identifying additional agents are also disclosed.

The present disclosure provides, among other things, compositions (e.g., autoantibodies) that inhibit the growth, viability, or mobility of (invasion by) a cancer cell. Also provided are applications, such as therapeutic and diagnostic methods, in which the agents are useful, as well as screening methods for identifying autoantibodies useful in the applications.

A method of screening a test compound, e.g., a fibrosis or IPF inhibitor, for induction of an unjammed-to-jammed transition (UJT) in fibrotic primary human bronchial epithelial cells (HBECs) isolated from a subject with a fibrotic lung disease includes culturing the fibrotic primary HBECs at an air-liquid interface for a time sufficient to provide a differentiated pseudostratified epithelium contacting the cultured cells with the test compound; and monitoring the motility of the cultured cells to identify the cultured cells as moving or stationary; wherein stationary cultured cells indicate that the test compound induces the UJT. Also included are methods of identifying lung fibrosis biomarkers.

Disclosed herein are methods of treating, reducing the incidence of, or preventing one or more activities in or of a cancer cell, methods of treating, reducing the incidence of, or preventing migration or metastasis of a cancer cell, methods of treating, reducing the incidence of, or preventing a cancer by reducing tumor associated macrophages (TAMs) or their migration, and methods of treating, reducing the incidence of, or preventing a cancer (including metastatic cancer), for example, with an inhibitor of Motile Sperm Domain containing Protein 2 (MOSPD2). Also disclosed are inhibitors of MOSPD2 (e.g., anti-MOSPD2 antibodies or antigen binding fragments thereof) and pharmaceutical compositions containing MOSPD2 inhibitors. Also disclosed are methods for the prediction, diagnosis, or prognosis of cancer, cancer metastasis, tumor progression, or tumor invasiveness in a subject.

The present invention describes an integrated apparatus that enables identification of invasive tumor cells directly from a specimen. The methods using the apparatus can be used to prognose or predict the survivability of the cancer in a subject and the risk of recurrence of the cancer in the subject after treatment. The methods disclosed herein can be used to determine which chemotherapeutic or other therapies most strongly inhibit the tumor cells invasiveness as a form of personalized therapy.

Systems and methods are provided for simultaneously assaying cell adhesion or cell rolling for multiple cell specimens. One embodiment provides a system for assaying adhesion or cell rolling of multiple cell specimens that includes a confocal imaging system containing a parallel plate flow chamber, a pump in fluid communication with the parallel plate flow chamber via a flow chamber inlet line and a cell suspension in fluid communication with the parallel plate flow chamber via a flow chamber outlet line. The system also includes a laser scanning system in electronic communication with the confocal imaging system, and a computer in communication with the confocal imaging system and laser scanning system. In certain embodiments, the laser scanning system emits multiple electromagnetic wavelengths simultaneously it cause multiple fluorescent labels having different excitation wavelength maximums to fluoresce. The system can simultaneously capture real-time fluorescence images from at least seven cell specimens in the parallel plate flow chamber.

The present disclosure relates to a method of diagnosing metastatic cancer or taxane-based drug-resistant cancer, including: measuring an LMCD1 expression level from a complex formed by bringing, into contact with a sample isolated from a subject, an antibody, peptide, protein, or combination thereof that specifically binds to an LMCD1 protein or a fragment thereof; or a probe, primer, nucleotide, or combination thereof that specifically binds to a nucleotide sequence encoding the LMCD1 protein; and comparing the measured LMCD1 expression level of the sample with a measured LMCD1 expression level of a control, and a kit for diagnosing metastatic cancer or taxane-based drug-resistant cancer, including a composition for diagnosing metastatic cancer or taxane-based drug-resistant cancer.

A cell analysis system according to the present disclosure includes a motion information extracting unit and a motion characteristics calculating unit. The motion information extracting unit extracts motion information arising from a movement of ions or molecules across a cell membrane, out of a cell image obtained from imaging a cell in time series. The motion characteristics calculating unit calculates motion characteristics of the motion information.

The present invention relates to a novel use of an antibody biding specifically to the N-terminus of lysyl-tRNA synthetase and, more particularly, to a pharmaceutical composition comprising an antibody biding specifically to an epitope including the sequence of SEQ ID NO: 117 in the N-terminal domain of lysyl-tRNA synthetase (KRS) or a functional fragment thereof as an effective ingredient for preventing and treating an immune cell migration-related disease. A KRS N-terminus-specific antibody provided by the present invention can regulate the migration of immune cells, thereby exhibiting very remarkable effects in the prevention, alleviation, and treatment of immune cell migration-related diseases.

High-throughput co-culture models, for example, relevant to the cell barrier interface, are disclosed that employ under-side cell seeding in a miniaturized and automated system and process. The seeding method, which can be implemented in a scalable and low-cost manner, can eliminate the need for an inversion process by adjusting/optimizing the density of the cell suspension medium to float cells of interest so they can attach under a membrane.