The inflammation paradox in the evolution of mammalian pregnancy: turning a foe into a friend.

A widely discussed physiological puzzle of mammalian pregnancy is the immunological paradox, which asks: why is the semi-allogenic fetus not attacked by the mother's adaptive immune system? Here, we argue that an additional, and perhaps more fundamental paradox is the question: why is embryo implantation so similar to inflammation while inflammation is also the greatest threat to the continuation of pregnancy? Equally puzzling is the question of how this arose during evolution. We call this the inflammation paradox. We argue that acute endometrial inflammation was ancestrally a natural maternal reaction to the attaching blastocyst, a situation still observed in the opossum. Eutherian implantation arose through a transformation of the acute inflammation into a process essential for implantation by causing vascular permeability and matrix reorganization as well as by suppressing the effects deleterious to the fetus. We propose that this model allows us to understand the differences between 'good inflammation' and 'bad inflammation'. Further, it allows us to understand the influence of inflammation on the outcome of pregnancy and maternal health.

Repressor domain and nuclear localization signal of the murine Hoxa-11 protein are located in the homeodomain: no evidence for role of poly alanine stretches in transcriptional repression.

Hoxa-11 is a member of the homeodomain class of transcription factors, which play important roles in metazoan development. Hoxa-11 is particularly interesting because it is involved in a major mammalian innovation, uterus development and gestation. We are interested in the molecular changes underlying this evolutionary innovation. Although phenotypes resulting from loss of functions are well investigated (e.g., female sterility), little is known about the domains contributing to Hoxa-11 protein function. We therefore mapped the domains mediating two essential transcription factor functions, nuclear localization and transcriptional activity in the mouse Hoxa-11 protein. Our results show that the mammal-specific alanine repeat does not contribute to repressor activity, as has been hypothesized based on amino acid composition and analogy with other repressor domains. Interestingly, both the repressor domain as well as the nuclear localization signal (NLS) are located within the homeodomain, adding to the growing evidence that the homeodomain is a multifunctional domain which fulfills essential transcription factor functions beyond DNA binding. It is proposed that the high degree of conservation of the homeodomain is due to the multiple functional constraints that result from the various conserved functions accommodated in the homeodomain.