Provided is a method for preparing genetically-modified T cells expressing chimeric antigen receptor, comprising: (i) a step of preparing non-proliferative cells holding a viral peptide antigen, which are obtained by stimulating a group of cells comprising T cells using an anti-CD3 antibody and an anti-CD28 antibody followed by culturing in the presence of the viral peptide antigen and a treatment for causing the cells to lose their proliferation capability; (ii) a step of obtaining genetically-modified T cells into which a target antigen-specific chimeric antigen receptor gene has been introduced using a transposon method; (iii) a step of mixing the non-proliferative cells prepared by step (i) with the genetically-modified T cells obtained by step (ii), and co-culturing the mixed cells; and (iv) a step of collecting the cells after culture.

Provided is a method for preparing genetically-modified T cells expressing chimeric antigen receptor, comprising: (i) a step of preparing non-proliferative cells holding a viral peptide antigen, which are obtained by stimulating a group of cells comprising T cells using an anti-CD3 antibody and an anti-CD28 antibody followed by culturing in the presence of the viral peptide antigen and a treatment for causing the cells to lose their proliferation capability; (ii) a step of obtaining genetically-modified T cells into which a target antigen-specific chimeric antigen receptor gene has been introduced using a transposon method; (iii) a step of mixing the non-proliferative cells prepared by step (i) with the genetically-modified T cells obtained by step (ii), and co-culturing the mixed cells; and (iv) a step of collecting the cells after culture.

Provided herein are modified AAV capsid proteins, particles, nucleic acid vectors, and compositions thereof, as well as methods of their use.

Disclosed herein include methods and compositions comprising variant AAV capsids. Variant capsid proteins, including variant capsid proteins with structure-guided deletion/substitution, tandem multimers, and/or variant capsid proteins with structure-guided deletion and C-terminal insertion, are provided in some embodiments. The variant capsid proteins disclosed herein are capable of assembling into a variant AAV capsid with an expanded size (e.g., diameter) and/or genetic cargo capacity. Methods of treating diseases and disorders using said rAAV are also disclosed.

Disclosed herein include methods and compositions comprising variant AAV capsids. Variant capsid proteins, including variant capsid proteins with structure-guided deletion/substitution, tandem multimers, and/or variant capsid proteins with structure-guided deletion and C-terminal insertion, are provided in some embodiments. The variant capsid proteins disclosed herein are capable of assembling into a variant AAV capsid with an expanded size (e.g., diameter) and/or genetic cargo capacity. Methods of treating diseases and disorders using said rAAV are also disclosed.

The present invention relates to variant AAV capsid polypeptides, wherein the variant AAV capsid polypeptides exhibit increased transduction and/or tropism in human pancreatic tissue or human islets as compared non-variant parent capsid polypeptides.

The present invention relates to variant AAV capsid polypeptides, wherein the variant AAV capsid polypeptides exhibit increased transduction and/or tropism in human pancreatic tissue or human islets as compared non-variant parent capsid polypeptides.

In alternative embodiments, provided are methods for increasing levels of and/or upregulating the expression of ApoA-I Binding Protein (APOA1BP, AIBP, or AI-BP) to treat, ameliorate, prevent, reverse, decrease the severity or duration of: a neuropathic pain, including an inflammation-induced neuropathic pain, a nerve or CNS inflammation, a, a post nerve injury pain, a post-surgical pain, a chemotherapeutic-induced peripheral neuropathy (CIPN) (e.g., cisplatin-induced allodynia) a neurodegeneration or neurodegenerative disease or condition, a migraine, and/or a hyperalgesia. In alternative embodiments, provided are methods comprising administering formulations and pharmaceutical compositions comprising an APOA1BP polypeptide or protein that is a human or a mammalian APOA1BP, or an AIBP1 or an AIBP2, or a recombinant, peptidomimetic or a synthetic APOA1BP, or a bioisostere of an ApoA-I Binding Protein to treat, ameliorate prevent, reverse, decrease the severity of a neuropathic pain, a TLR4-mediated allodynia and/or a hyperalgesia.

In alternative embodiments, provided are methods for increasing levels of and/or upregulating the expression of ApoA-I Binding Protein (APOA1BP, AIBP, or AI-BP) to treat, ameliorate, prevent, reverse, decrease the severity or duration of: a neuropathic pain, including an inflammation-induced neuropathic pain, a nerve or CNS inflammation, a, a post nerve injury pain, a post-surgical pain, a chemotherapeutic-induced peripheral neuropathy (CIPN) (e.g., cisplatin-induced allodynia) a neurodegeneration or neurodegenerative disease or condition, a migraine, and/or a hyperalgesia. In alternative embodiments, provided are methods comprising administering formulations and pharmaceutical compositions comprising an APOA1BP polypeptide or protein that is a human or a mammalian APOA1BP, or an AIBP1 or an AIBP2, or a recombinant, peptidomimetic or a synthetic APOA1BP, or a bioisostere of an ApoA-I Binding Protein to treat, ameliorate prevent, reverse, decrease the severity of a neuropathic pain, a TLR4-mediated allodynia and/or a hyperalgesia.

The disclosure relates to compositions and methods for rAAV-mediated delivery of a transgene to a subject. In some embodiments, the rAAV transduces the prostate tissue of a subject. In some embodiments, the methods are useful for treatment of prostate disease (e.g., prostatitis, BPH, prostate cancer).