The Influence of Hen Aging on Eggshell Ultrastructure and Shell Mineral Components

Salmonella Enteritidis (SE) has been the major cause of the food-borne salmonellosis pandemic in humans over the last 20 years, during which contaminated hen's eggs were the most important vehicle of the infection. Eggs can be contaminated on the outer shell surface and internally. Internal contamination can be the result of penetration through the eggshell or by direct contamination of egg contents before oviposition, originating from infection of the reproductive organs. Once inside the egg, the bacteria need to cope with antimicrobial factors in the albumen and vitelline membrane before migration to the yolk can occur. It would seem that serotype Enteritidis has intrinsic characteristics that allow an epidemiological association with hen eggs that are still undefined. There are indications that SE survives the attacks with the help of antimicrobial molecules during the formation of the egg in the hen's oviduct and inside the egg. This appears to require a unique combination of genes encoding for improved cell wall protection and repairing cellular and molecular damage, among others.

Background In Gallus gallus, eggshell formation takes place daily in the hen uterus and requires large amounts of the ionic precursors for calcium carbonate (CaCO3). Both elements (Ca2+, HCO3 -) are supplied by the blood via trans-epithelial transport. Our aims were to identify genes coding for ion transporters that are upregulated in the uterine portion of the oviduct during eggshell calcification, compared to other tissues and other physiological states, and incorporate these proteins into a general model for mineral transfer across the tubular gland cells during eggshell formation. Results A total of 37 candidate ion transport genes were selected from our database of overexpressed uterine genes associated with eggshell calcification, and by analogy with mammalian transporters. Their uterine expression was compared by qRTPCR in the presence and absence of eggshell formation, and with relative expression levels in magnum (low Ca2+/HCO3 - movement) and duodenum (high rates of Ca2+/HCO3 - trans-epithelial transfer). We identified overexpression of eleven genes related to calcium movement: the TRPV6 Ca2+ channel (basolateral uptake of Ca2+), 28 kDa calbindin (intracellular Ca2+ buffering), the endoplasmic reticulum type 2 and 3 Ca2+ pumps (ER uptake), and the inositol trisphosphate receptors type 1, 2 and 3 (ER release). Ca2+ movement across the apical membrane likely involves membrane Ca2+ pumps and Ca2+/Na+ exchangers. Our data suggests that Na+ transport involved the SCNN1 channel and the Na+/Ca2+ exchangers SLC8A1, 3 for cell uptake, the Na+/K+ ATPase for cell output. K+ uptake resulted from the Na+/K+ ATPase, and its output from the K+ channels (KCNJ2, 15, 16 and KCNMA1). We propose that the HCO3 - is mainly produced from CO2 by the carbonic anhydrase 2 (CA2) and that HCO3 - is secreted through the HCO3 -/Cl- exchanger SLC26A9. HCO3 - synthesis and precipitation with Ca2+ produce two H+. Protons are absorbed via the membrane’s Ca2+ pumps ATP2B1, 2 in the apical membrane and the vacuolar (H+)-atpases at the basolateral level. Our model incorporate Cl- ions which are absorbed by the HCO3 -/Cl- exchanger SLC26A9 and by Cl- channels (CLCN2, CFTR) and might be extruded by Cl-/H+ exchanger (CLCN5), but also by Na+ K+ 2 Cl- and K+ Cl- cotransporters. Conclusions Our Gallus gallus uterine model proposes a large list of ion transfer proteins supplying Ca2+ and HCO3 - and maintaining cellular ionic homeostasis. This avian model should contribute towards understanding the mechanisms and regulation for ionic precursors of CaCO3, and provide insight in other species where epithelia transport large amount of calcium or bicarbonate.

The secretory cells in the epithelium of mammalian oviducts produce and release various secretory materials into the lumen. Secretions from such cells provide a suitable environment for the events that occur in the oviductal lumen. This review focuses on the regional differentiation of the secretory cells in mammalian oviducts. Many histological studies have demonstrated regional variations in both the morphological and ultrastructural features of the secretory cells in the oviductal epithelium. Regional differences have been found, for example, in the number of putative secretory granules in the oviductal secretory cells. Histochemical and immunocytochemical studies have also revealed regional differences in the localization of various materials in the oviductal epithelium, suggesting the possibility of regional specificity in the production of various secretory materials by the oviductal epithelial cells. Recent biochemical and immunoelectron microscopical studies have shown that biosynthesis of specific proteins or glycoproteins is associated with region-specific variations in epithelial cells in different oviductal segments. In particular, certain oviduct-specific glycoproteins are produced by secretory cells in specific regions of the oviduct and these glycoproteins may affect fertilization, embryonic development, and sperm functions. The oviductal epithelial cell also provide physiological support to gametes and embryos. The interactions of oviductal epithelial cells with gametes support the development of embryos and the maintenance of sperm functions in vitro. Some studies using coculture systems have suggested regional differences associated with such physiological support by oviductal epithelial cells. Moreover, the expression of functional proteins, such as growth factors, show segmental variations within the oviduct. The regional variations demonstrated in these studies may reflect distinct functional differences among the various segments of the mammalian oviduct. The proposal is presented that despite the fact that the mammalian oviductal tissue is not very complex in terms of structure, the oviductal secretory cells may be highly differentiated along the length of the oviduct.