The present disclosure provides compositions and methods for treating or preventing ulcers in subjects having low red blood cell levels and/or hemoglobin levels (e.g, anemia). In some embodiments, the compositions of the disclosure may be used to treat or prevent ulcers associated with anemia.

Described herein are novel compositions comprising, for example, PDCL3 polypeptides having VEGFR-2 inhibitory activity, inhibitory PDCL3 antibodies and PDCL3-binding fragments thereof, or PDCL3 inhibitory nucleic acid molecules, and methods of their use in anti-angiogenesis and anti-tumor proliferation and invasiveness therapies, such as the treatment of cancer, as well as the treatment of those vascular diseases where pathological angiogenesis plays a role, such as in carotid artery disease, macular degeneration, and plaque neovascularization. Also described herein are novel compositions comprising engineered PDCL3 polypeptides having enhanced chaperone activity, recombinant cells comprising such engineered PDCL3 polypeptides having enhanced chaperone activity, and methods thereof for therapeutic protein production and in vitro protein synthesis.

Cell-targeted cytotoxic agents, including sortase serine protease constructs, are provided. Such compounds can be used in methods for targeted cell killing such as for treatment cell of proliferative diseases (e.g., cancer). In some aspects, recombinant sortase serine proteases, such as Granzyme B polypeptides, are provided that exhibit improved stability and cell toxicity.

The present invention provides a humanized monoclonal antibody against extracellular domain of human death receptor 5, comprising a light chain variable region, whose amino acid sequence has at least 90% identity with the amino acid sequence shown as SEQ ID NO: 1, a heavy chain variable region, whose amino acid sequence has at least 90% identity with the amino acid sequence shown as SEQ ID NO: 2, and constant region derived from human antibody. The present invention also provides nucleotide sequence encoding said humanized monoclonal antibody, a recombinant eukaryotic expression vector, a process for preparing the humanized monoclonal antibody, and the composition and use therefore. Said humanized monoclonal antibody of the present invention shows specific apoptosis-inducing activity against various cancer cells both in vivo and in vitro, and thus it can be used alone or in combination with natural ligand of DR5, apoptosis-inducing ligand associated with tumor nerosis factor or other medicaments for the treatment of a variety of cancers as well as other diseases associated with high DR5 expression.

The present disclosure provides synthetic collagen and methods of making and using synthetic collagen that include a synthetic collagen that facilitates wound closure comprising an isolated and purified triple helical backbone protein that facilitates wound closure comprising one or more alteration in a triple helical backbone protein sequence, that stabilize the isolated and purified triple helical backbone protein and does not disrupt an additional collagen ligand interaction; and one or more integrin binding motifs, wherein the isolated and purified triple helical backbone protein facilitates wound closure.

Disclosed are compositions and methods related to the construction and use of universal synthetic notch (synNotch) receptors and chimeric antigen receptor (CAR) T cells.

The present invention relates to a method for increasing the sialylation of an Fc fragment, including a mutation step of at least one amino acid selected from among the amino acids in positions 240 to 243, 258 to 267 and 290 to 305 of the Fc fragment, the numbering being that of the EU index or equivalent in Kabat. The present invention also relates to a method for producing a variant of a parent polypeptide including an Fc fragment, the variant having improved sialylation of the Fc fragment relatively to the parent polypeptide, which includes a mutation step of at least one amino acid selected from among the amino acids in positions 240 to 243, 258 to 267 and 290 to 305 of the Fc fragment, the numbering being that of the EU index or equivalent in Kabat.

The present disclosure relates to pharmaceutical compositions comprising a non-naturally occurring fusion molecule and one or more pharmaceutically acceptable carriers, formulated for oral delivery to a subject, and designed to provide for improved, effective therapies for treatment of, e.g., inflammatory diseases, autoimmune diseases, cancer, metabolic disorders, and growth deficiency disorders. The present disclosure relates to a non-toxic mutant form of the Vibrio cholera Cholix gene (ntCholix), a variant of Cholix truncated at amino acid A.sup.386 (Cholix.sup.386) and the use of other various Cholix-derived polypeptide sequences to enhance intestinal delivery of biologically-active therapeutics. The systems and methods described herein provide for: the ability to deliver macromolecule doses without injections; the ability to deliver cargo such as siRNA or antisense molecules into intracellular compartments where their activity is required; and the delivery of nanoparticles and dendrimer-based carriers across biological membranes.

Cell-targeted cytotoxic agents, including sortase serine protease constructs, are provided. Such compounds can be used in methods for targeted cell killing such as for treatment cell of proliferative diseases (e.g., cancer). In some aspects, recombinant sortase serine proteases, such as Granzyme B polypeptides, are provided that exhibit improved stability and cell toxicity.

The present disclosure relates to pharmaceutical compositions comprising a non-naturally occurring fusion molecule and one or more pharmaceutically acceptable carriers, formulated for oral delivery to a subject, and designed to provide for improved, effective therapies for treatment of, e.g., inflammatory diseases, autoimmune diseases, cancer, metabolic disorders, and growth deficiency disorders. The present disclosure relates to a non-toxic mutant form of the Vibrio cholera Cholix gene (ntCholix), a variant of Cholix truncated at amino acid A.sup.386 (Cholix.sup.386) and the use of other various Cholix-derived polypeptide sequences to enhance intestinal delivery of biologically-active therapeutics. The systems and methods described herein provide for: the ability to deliver macromolecule doses without injections; the ability to deliver cargo such as siRNA or antisense molecules into intracellular compartments where their activity is required; and the delivery of nanoparticles and dendrimer-based carriers across biological membranes.