The invention provides non-human cells and mammals having a genome encoding chimeric antibodies and methods of producing transgenic cells and mammals. Certain aspects of the invention include chimeric antibodies, humanized antibodies, pharmaceutical compositions and kits. Certain aspects of the invention also relate to diagnostic and treatment methods using the antibodies of the invention.

The present invention provides a method of bioluminescence-driven optogenetic control of excitable cells. The excitable cell expresses a light-gated ion channel, and a luminescent protein can be expressed either in the excitable cell or in another cell proximal to the excitable cell. The methods of the invention can be used to desynchronize local activity of excitable cells in a mammalian tissue. The methods of the invention can be used to treat a disease or condition in a mammal, the disease or condition being related to bursting. The disease or condition can be Parkinson's disease, epilepsy, a sleep disorder, or a sensory-related disease or condition (e.g., attention deficit disorder or pain). The invention also provides a conjugate of containing a voltage-gated ion channel and a luminescent protein.

Mice comprising a transgene encoding a peptide (iBox) inhibitor of Group B p21-activated kinase are provided. Also provided are cells, tissue, and organs obtained from such transgenic mice. Also provided are methods for producing mice comprising an iBox-encoding transgene.

Provided are a method and use of microRNA MiR-2911 in regulating an ebola virus. Particularly provided are a method and use of isolated microRNA MiR-2911 in regulating an ebola virus protein gene.

The skin is one of first lines of defense against external threats. Tissue-resident macrophages have pivotal functions in tissue-barrier integrity and homeostasis. Upon skin inflammation, a functional crosstalk between the sensory nervous system and tissue-resident immune cells can regulate cutaneous immune responses. However, depending on the pathological context, sensory neurons display pro- or anti-inflammatory regulatory properties. Here the inventors identify, in a model of ultraviolet (UV)-induced skin N damage, a regulatory role for type C low-threshold mechanoreceptor (C-LTMR) sensory neurons on the dynamic of dermal macrophage replacement by inflammatory monocytes through the neuropeptide TAFA4. Tafa4-KO mice present an unresolved fibrotic dermis after UV irradiation. Increased fibrotic score correlates with the upstream persistency of inflammatory monocytes and their MHC-II.sup.+ macrophage progeny. Bone marrow chimera revealed that inflammatory monocyte differentiation towards CD206+ dermal macrophage is increased in Tafa4KO recipient. Finally, intradermal injection of TAFA4 at the site of UV irradiation reduces inflammatory monocytes accumulation and skin inflammation in Tafa4-KO mice. The results provide new insight about tissue-resident macrophages dynamic during the resolution of skin fibrosis and thus renders credible the use of TAFA4 for the treatment of skin inflammation.

Described herein are donor vectors and systems for use in dual recombinase-mediated cassette exchange. Also described herein are animal models and human cells for consistent, rigorous, and facile investigation of transgene expression. Further described herein are methods of screening for therapeutic drugs using these animal models, and methods of treatment.

Non-human animals, cells, methods and compositions for making and using the same are provided, wherein the non-human animals and cells comprise a humanized a proliferation-inducing ligand gene. Non-human animals and cells that express a human or humanized a proliferation-inducing ligand protein from an endogenous a proliferation-inducing ligand locus are described.

The present invention is transgenic chickens obtained from long-term cultures of avian PGCs and techniques to produce and transgenic birds derived from prolonged PGC cultures. In some embodiments, these PGCs can be transfected with genetic constructs to modify the DNA of the PGC, specifically to introduce a transgene encoding an exogenous protein. When combined with a host avian embryo by known procedures, those modified PGCs are transmitted through the germline to yield transgenic offspring. This invention includes compositions comprising long-term cultures of PGCs and offspring derived from them that are genetically modified. The genetic modifications introduced into PGCs to achieve the gene inactivation may also include, but are not restricted to, random integrations of transgenes into the genome, transgenes inserted into the promoter region of genes, transgenes inserted into repetitive elements in the genome, site specific changes to the genome that are introduced using integrase, site specific changes to the genome introduced by homologous recombination, and conditional mutations introduced into the genome by excising DNA that is flanked by lox sites or other sequences that are substrates for site specific recombination.

The inventive technology is directed to the generation of a novel transgenic mammalian model for the study of Laing distal myopathy. The novel animal model of the invention may include a transgenic animal, and preferably a transgenic mouse, expressing the β-myosin R1500P mutation transgene that produces one or more phenotypes associated with MPD1. The β-myosin R1500P mutation transgene may further be selectively expressed in fast muscle tissue of the transgenic animal.

The present invention describes transgenic animals with human(ized) immunoglobulin loci and transgenes encoding human(ized) Igα and/or Igβ sequences. Of particular interest are animals with transgenic heavy and light chain immunoglobulin loci capable of producing a diversified human(ized) antibody repertoire that have their endogenous production of Ig and/or endogenous Igα and/or Igβ sequences suppressed. Simultaneous expression of human(ized) immunoglobulin and human(ized) Igα and/or Igβ results in normal B-cell development, affinity maturation and efficient expression of human(ized) antibodies.