Abstract: A method for modulating angiogenesis in a cancer or tumor refractory to anti-VEGF, including identifying a cancer cell as being referactory to anti-VEGF, and then contacting the cancer cell refractory to anti-VEGF with an effective amount of an agent that modulates interaction between Gal1 or a Gal1 fragment and the natural binding partner of Gal1 or the Gal1 fragment to thereby modulate angiogenesis.

Abstract: A method for modulating angiogenesis in a cancer or tumor refractory to anti-VEGF, including identifying a cancer cell as being referactory to anti-VEGF, and then contacting the cancer cell refractory to anti-VEGF with an effective amount of an agent that modulates interaction between Gal1 or a Gal1 fragment and the natural binding partner of Gal1 or the Gal1 fragment to thereby modulate angiogenesis.

Abstract: A method for modulating angiogenesis in a cancer or tumor refractory to anti-VEGF, including identifying a cancer cell as being referactory to anti-VEGF, and then contacting the cancer cell refractory to anti-VEGF with an effective amount of an agent that modulates interaction between Gal1 or a Gal1 fragment and the natural binding partner of Gal1 or the Gal1 fragment to thereby modulate angiogenesis.

Abstract: Galectin-1 polypeptide variants that include a mutation of the histidine residue corresponding to position 52 of the full-length amino acid sequence of native human Gal-1 as shown in SEQ ID NO: 1, the mutation being a substitution of the histidine to tyrosine or asparagine, providing resistance to acidosis otherwise resulting in deactivation of the native human Gal-1. The Galectin-1 polypeptide variants may include one or more additional mutation(s) of the cysteine residue corresponding to a position selected from 2, 16, 88, or combinations thereof of the full-length amino acid sequence of native human Gal-1 as shown in SEQ ID NO: 1, the additional mutation being a substitution of the cysteine to serine, and providing resistance to oxidation.

Abstract: Galectin-1 polypeptide variants that include a mutation of the histidine residue corresponding to position 52 of the full-length amino acid sequence of native human Gal-1 as shown in SEQ ID NO: 1, the mutation being a substitution of the histidine to tyrosine or asparagine, providing resistance to acidosis otherwise resulting in deactivation of the native human Gal-1. The Galectin-1 polypeptide variants may include one or more additional mutation(s) of the cysteine residue corresponding to a position selected from 2, 16, 88, or combinations thereof of the full-length amino acid sequence of native human Gal-1 as shown in SEQ ID NO: 1, the additional mutation being a substitution of the cysteine to serine, and providing resistance to oxidation.

Abstract: A method for modulating angiogenesis in a cancer or tumor refractory to anti-VEGF, including identifying a cancer cell as being referactory to anti-VEGF, and then contacting the cancer cell refractory to anti-VEGF with an effective amount of an agent that modulates interaction between Gal1 or a Gal1 fragment and the natural binding partner of Gal1 or the Gal1 fragment to thereby modulate angiogenesis.

Abstract: In spite of their pivotal role in orchestrating immunity, dendritic cells (DCs) may be licensed by immunosuppressive signals to become tolerogenic. Here we show that ligation of cell surface glyco-receptors by Galectin-1, an endogenous glycan-binding protein, can drive the differentiation of regulatory DCs with tolerogenic potential in vivo. Galectin-1-differentiated DCs acquired a tolerogenic phenotype characterized by IL-27-dependent, STAT3-mediated and CD45RB+IL-10+ regulatory signatures. Adoptive transfer of galectin-1-conditioned DCs induced T-cell tolerance in inflammatory and neoplastic settings and dampened TH1- and TH-17-mediated autoimmune neuroinflammation. Consistent with a negative regulatory function of endogenous galectin-1, DCs from galectin-1-deficient (Lgals1?/?) mice had greater immunogenic capacity compared with their wild-type counterparts.