Sulfated Lewis A Trisaccharide on Oviduct Membrane Glycoproteins Binds Bovine Sperm and Lengthens Sperm Lifespan

Overview

Journal J Biol Chem

Specialty Biochemistry

Date 2019 Jul 25

PMID 31337705

Citations 10

Authors

Sudipta Dutta

Kazuhiro Aoki

Kankanit Doungkamchan

Michael Tiemeyer

Nicolai Bovin

David J Miller

Affiliations

Soon will be listed here.

Abstract

A fraction of sperm deposited at mating or insemination reaches the oviduct isthmus, where sperm are retained and thereby form a reservoir. This reservoir delays capacitation, prevents polyspermy, selects a fertile population of sperm, and, foremost, increases sperm lifespan. The molecular interactions underlying the formation of a sperm reservoir are becoming clearer in mammals. Sperm lectins bind to oviductal glycans to form the reservoir. Herein, we found that the highest percentage of bovine sperm bound to the 3'--sulfated form of Lewis A (suLe) trisaccharide and sialylated Lewis A and that fluoresceinated versions of each localized to receptors on the anterior head of the sperm. Following capacitation, binding to suLe decreased significantly, a potential explanation for sperm release from the reservoir. MS and immunohistochemistry analyses indicated that suLe motifs were present predominantly on -linked glycans initiated by GalNAc residues, but no sialylated Lewis A was detected. To determine whether sperm binding to isolated suLe could mimic sperm binding to oviduct cells and increase sperm longevity, we immobilized suLe and incubated it with sperm. Using free-swimming sperm and sperm bound to immobilized laminin as controls, we observed that over 96 h, the viability of free-swimming sperm decreased to 10%, and that of sperm bound to immobilized laminin decreased to about 50%, whereas viability of sperm bound to immobilized suLe was highest throughout the incubation and 60% at 96 h. These results indicate that bovine sperm binding to oviduct suLe retains sperm for reservoir formation and extends sperm lifespan.

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