Dynamics of the interaction of human IgG subtype immune complexes with cells expressing R and H allelic forms of a low-affinity Fc gamma receptor CD32A.

CD32A, the major phagocytic FcgammaR in humans, exhibits a polymorphism in the ligand binding domain. Individuals homozygous for the R allelic form of CD32A (CD32A(R) allele) are more susceptible to bacterial infections and autoimmune diseases as compared with H allelic CD32A (CD32A(H)) homozygous and CD32A(R/H) heterozygous individuals. To understand the mechanisms behind this differential susceptibility, we have investigated the dynamics of the interaction of these allelic forms of CD32A when they are simultaneously exposed to immune complexes (IC). Binding studies using Ig fusion proteins of CD32A alleles showed that the R allele has significantly lower binding not only to human IgG2, but also to IgG1 and IgG3 subtypes. Competition assays using purified molecules demonstrated that CD32A(H)-Ig outcompetes CD32A(R)-Ig for IC binding when both alleles simultaneously compete for the same ligand. CD32A(H)-Ig blocked the IC binding mediated by both the allelic forms of cell surface CD32A, whereas CD32A(R)-Ig blocked only CD32A(R) and was unable to cross-block IC binding mediated by CD32A(H). Two-dimensional affinity measurements also demonstrated that CD32A(R) has significantly lower affinity toward all three subtypes as compared with CD32A(H). Our data suggest that the lower binding of CD32A(R) not only to IgG2 but also to IgG1 and IgG3 might be responsible for the lack of clearance of IC leading to increased susceptibility to bacterial infections and autoimmune diseases. Our data further suggests that in humans, inflammatory cells from CD32A(R/H) heterozygous individuals may predominantly use the H allele to mediate Ab-coated target cell binding during phagocytosis and Ab-dependent cellular cytotoxicity, resulting in a phenotype similar to CD32A(H) homozygous individuals.

Cloning, expression, and functional characterization of relaxin receptor (leucine-rich repeat-containing g protein-coupled receptor 7) splice variants from human fetal membranes.

The relaxin receptor [leucine-rich repeat-containing G protein-coupled receptor 7 (LGR7)] belongs to the leucine-rich repeat containing G protein-coupled receptors subgroup C. Three new LGR7 splice variants have been cloned from the human fetal membranes and shown to be truncated versions of the full-length receptor, encoded by different lengths of the extracellular domain. The expression of their mRNAs has been confirmed by both qualitative and quantitative PCR and shown to be higher in the chorion and decidua before, compared with after, spontaneous labor. When HEK293 cells were transfected with each LGR7 splice variant, their proteins were retained within the endoplasmic reticulum. However, the protein for the shortest variant was also secreted into the medium. We have characterized the intracellular functions and effects of these LGR7 variants on the function of the wild-type (WT)-LGR7. In coexpression studies, each splice variant interacted directly with the WT-LGR7 and exerted a dominant-negative effect on cAMP accumulation by the WT-LGR7 after relaxin treatment. This interaction resulted in the sequestration of the WT-LGR7 inside the cells by down-regulation of its maturation and cell surface delivery. The constitutive homodimerization of WT-LGR7 has been shown here to take place in the endoplasmic reticulum, and the presence of any one of the splice variants decreased this by the formation of heterodimers with the WT-LGR7, supporting the view that homodimerization is a prerequisite for receptor trafficking to the cell surface. These data suggest that the dominant-negative effects of the LGR7 splice variants expressed in the chorion and decidua could be functionally significant in the peripartal period by inhibiting the function of WT-LGR7 and dampening the responsiveness of these tissues to endogenous relaxin.

Human decidual relaxin and preterm birth.

Relaxin in human pregnancy is both a systemic hormone from the corpus luteum and an autocrine/paracrine hormone at the maternal-fetal interface formed by the decidua/placenta and fetal membranes. We have focused our studies on the autocrine/paracrine roles of relaxin, especially in the preterm premature rupture of the fetal membranes, which causes 30-40% of preterm births. By using different techniques and different tissue collections, our laboratory has shown that expression of the relaxin genes and proteins in the decidua and placenta is increased in patients with preterm premature rupture of the fetal membranes. Relaxin binding and the expression of LGR7 are primarily in the chorion and decidua and are downregulated after spontaneous labor and delivery both at term and preterm. However, expression of LGR7 in the fetal membranes is significantly greater in all clinical situations at preterm than term, suggesting an important role for relaxin in these tissues at that time. The roles of the relaxin system in three potential causes of preterm birth are discussed: in the growth and proliferation of the membranes important for fetal membrane accommodation to fetal and placental growth, in acute infection, and in the inflammatory response leading to the initiation of labor.