Provided herein are compounds that inhibit a binding interaction between a integrin and a G protein subunit, as well as compositions, e.g., pharmaceutical compositions, comprising the same, and related kits. In some embodiments, the compound is an antibody or antibody analog, and, in other embodiments, the compound is a peptide or peptide analog. Also provided are methods of using the compounds, including methods of treating or preventing a medical condition, such as stroke, heart attack, cancer, or inflammation.

The present disclosure provides peptides and constructs that inhibit mitochondrial fission, and compositions comprising the peptides or constructs. The present disclosure provides methods of reducing abnormal mitochondrial fission in a cell. Also provided are methods for designing and validating mitochondrial fission inhibitor constructs and peptides, including but not limited to, evaluating the effects of the constructs and peptides on binding of dynamin-1-related protein (Drp1) GTPase activity, Drp1 to mitochondrial fission 1 protein (Fis1), reduction of mitochondrial damage, reduction in cell death, inhibition of mitochondrial fragmentation in a cell under pathological conditions, and reduced loss of neurites in primary dopaminergic neurons in a Parkinsonism cell culture.

Disclosed is a composition for treating a neurological disease caused by nerve injury, including an isolated polynucleotide of a 5-untranslated region (5UTR) of a Gpr151 gene or a variant thereof. Also disclosed are a novel variant polynucleotide of 5UTR of a Gpr151 gene and a vector including the polynucleotide.

The design and generation of a number of chimeric VSV-G (or VSV-G variants) proteins are used as transfer vehicles to enhance delivery of nucleic acids like plasmid DNA, single and double stranded DNA and RNA, and antisense oligonucleotides into human and animal cells. These chimeric VSV-G protein-nucleic acid transfer vehicles have widespread applications to deliver nucleic acids for exon skipping and gene delivery for gene replacement in human and animals.

A pharmaceutical composition comprises a GPCR agonist fusion protein in which a GPCR agonist peptide is covalently coupled to albumin via a linker in a manner that is resistant to a retro-Michael addition. Advantageously, compositions presented herein avoid decoupling of the agonist form the albumin while retaining the agonist in a steric relationship to the albumin that allows for effective binding and activation of the GPCR while also enabling gp60-mediated transcytosis and FcRn-mediated albumin recycling. These properties enable ultra-low dosages for the GPCR agonist fusion protein to give a therapeutic effect while substantially reducing or even entirely avoiding adverse effects otherwise commonly associated with unbound agonists. Such retro-Michael resistant composition is generally achieved by conformational modification of the albumin, resulting in stereoselective coupling of the linker to the albumin.

Methods, compositions and kits for regulating complement activity or treating a complement activity disorder in a subject using soluble, membrane-independent CD59 protein, methods of assaying human macular degeneration (MD), and methods and kits for assaying potential therapeutic agents for treatment of human MD are provided herein.

The present disclosure provides peptides and constructs that inhibit mitochondrial fission, and compositions comprising the peptides or constructs. The present disclosure provides methods of reducing abnormal mitochondrial fission in a cell. Also provided are methods for designing and validating mitochondrial fission inhibitor constructs and peptides, including but not limited to, evaluating the effects of the constructs and peptides on binding of dynamin-1-related protein (Drp1) GTPase activity, Drp1 to mitochondrial fission 1 protein (Fis1), reduction of mitochondrial damage, reduction in cell death, inhibition of mitochondrial fragmentation in a cell under pathological conditions, and reduced loss of neurites in primary dopaminergic neurons in a Parkinsonism cell culture.

The present disclosure relates to the field of G protein coupled receptor (GPCR) structural biology and signaling. In particular, the present disclosure relates to binding domains directed against and/or specifically binding to GPCR:G protein complexes. Also provided are nucleic acid sequences encoding such binding domains and cells expressing or capable of expressing such binding domains. The binding domains of the present disclosure can be used as universal tools for the structural and functional characterization of G-protein coupled receptors in complex with downstream heterotrimeric G proteins and bound to various natural or synthetic ligands, for investigating the dynamic features of G protein activation, as well as for screening and drug discovery efforts that make use of GPCR:G protein complexes.

The present invention relates to the field of G protein coupled receptor (GPCR) structural biology and signaling. In particular, the present invention relates to binding domains directed against and/or specifically binding to GPCR:G protein complexes. Also provided are nucleic acid sequences encoding such binding domains and cells expressing or capable of expressing such binding domains. The binding domains of the present invention can be used as universal tools for the structural and functional characterization of G-protein coupled receptors in complex with downstream heterotrimeric G proteins and bound to various natural or synthetic ligands, for investigating the dynamic features of G protein activation, as well as for screening and drug discovery efforts that make use of GPCR:G protein complexes.

The present invention is directed to methods and compositions comprising G-protein-coupled receptor kinase interacting protein-1 (GIT1) inhibitors that are suitable for inhibiting angiogenesis in a subject and treating related conditions.