The present invention aims at providing a specific antibody that can simply and rapidly detect Mycoplasma pneumoniae which is a causative bacterium of mycoplasma pneumonia, with high sensitivity, and also an immunological detection method and a kit containing the same antibody. The present invention makes it possible to diagnose infection with Mycoplasma pneumoniae more rapidly and specifically than the conventional method, by producing an antibody recognizing a specific epitope of P30 protein of Mycoplasma pneumoniae and performing an immunological detection using the antibody. Also, the present invention enables easy and rapid detection of Mycoplasma pneumoniae and diagnosis of infection with the same at a hospital or the like without need of specialized instruments or skilled techniques.

Provided are a method of efficiently producing an sIL-2R antigen in an amount necessary for antibody generation, and a method of producing an anti-sIL-2R antibody using the antigen. Specifically, provided are a method of producing soluble interleukin-2 receptor, including culturing SCC-3 cells and recovering soluble interleukin-2 receptor from a culture of the cells, and a method of producing an anti-soluble interleukin-2 receptor antibody, including immunizing an animal with sIL-2R produced by the method.

Provided are a method of efficiently producing an sIL-2R antigen in an amount necessary for antibody generation, and a method of producing an anti-sIL-2R antibody using the antigen. Specifically, provided are a method of producing soluble interleukin-2 receptor, including culturing SCC-3 cells and recovering soluble interleukin-2 receptor from a culture of the cells, and a method of producing an anti-soluble interleukin-2 receptor antibody, including immunizing an animal with sIL-2R produced by the method.

The present invention provides compositions, systems, kits, and methods for combining a. single myeloma cell and a single B-cell (e.g., from an animal exposed to a desired antigen) via discrete entity (e.g., droplet) microfluidics. In certain embodiments, a microfluidic device is used to merge a discrete entity containing a B-cell, and a discrete entity containing a myeloma cell, and a discrete entity containing gellable material, at a merger region via a trapping element in order to generate a combined discrete entity. In further embodiments, the combined discrete entity is treated such that a gelled discrete entity is formed.

The present invention provides compositions, systems, kits, and methods for combining a. single myeloma cell and a single B-cell (e.g., from an animal exposed to a desired antigen) via discrete entity (e.g., droplet) microfluidics. In certain embodiments, a microfluidic device is used to merge a discrete entity containing a B-cell, and a discrete entity containing a myeloma cell, and a discrete entity containing gellable material, at a merger region via a trapping element in order to generate a combined discrete entity. In further embodiments, the combined discrete entity is treated such that a gelled discrete entity is formed.

The present invention aims at providing a specific antibody that can simply and rapidly detect Mycoplasma pneumoniae which is a causative bacterium of mycoplasma pneumonia, with high sensitivity, and also an immunological detection method and a kit containing the same antibody. The present invention makes it possible to diagnose infection with Mycoplasma pneumoniae more rapidly and specifically than the conventional method, by producing an antibody recognizing a specific epitope of P30 protein of Mycoplasma pneumoniae and performing an immunological detection using the antibody. Also, the present invention enables easy and rapid detection of Mycoplasma pneumoniae and diagnosis of infection with the same at a hospital or the like without need of specialized instruments or skilled techniques.

The present invention aims at providing a specific antibody that can simply and rapidly detect Mycoplasma pneumoniae which is a causative bacterium of mycoplasma pneumonia, with high sensitivity, and also an immunological detection method and a kit containing the same antibody. The present invention makes it possible to diagnose infection with Mycoplasma pneumoniae more rapidly and specifically than the conventional method, by producing an antibody recognizing a specific epitope of P30 protein of Mycoplasma pneumoniae and performing an immunological detection using the antibody. Also, the present invention enables easy and rapid detection of Mycoplasma pneumoniae and diagnosis of infection with the same at a hospital or the like without need of specialized instruments or skilled techniques.

The present disclosure describes the fusogenic activity of the Myomaker protein. This polypeptide, when expressed in non-muscle cells, is able to drive fusion of the cell with a muscle cell, but not with other non-muscle cells. The use of this protein and cell expressing it in the delivery of exogenous genetic material to muscle cells also is described.

The present disclosure describes the fusogenic activity of the Myomaker protein. This polypeptide, when expressed in non-muscle cells, is able to drive fusion of the cell with a muscle cell, but not with other non-muscle cells. The use of this protein and cell expressing it in the delivery of exogenous genetic material to muscle cells also is described.

Methods of producing a hybrid organism. The methods include providing a first organism, providing a second organism, providing a fusing medium, combining the first organism and the second organism in or on the fusing medium to define a fusion environment, and initiating somatic fusion between the first organism and the second organism in the fusion environment to produce the hybrid organism. The first organism is either a plant organism or a fungus organism. The second organism is either a plant organism or a fungus organism. In some examples, the first organism is Tuber melanosporum . In certain examples, the second organism is either Panaeolus cambodginiensis or Panaeolus cyanescens . In some examples, the methods include incubating the hybrid organism, regenerating cell walls of the hybrid organism, and/or replicating the hybrid organism.