Morphology and development of the placentae in Eulamprus quoyii group skinks (Squamata: Scincidae).

Frequent evolutionary changes in reproductive mode have produced a wide range of placental structures in viviparous squamate reptiles. Closely related species with different placental structures and resolved phylogenetic relationships are particularly useful for reconstructing how placentae might have transformed during the evolutionary process. We used light microscopy to study placental morphology in mid- to late stage embryos of four closely related species of Eulamprus, a genus of viviparous scincid lizards that we had reason to suspect may display significant interspecific variation in placental morphology. Embryos from all four species possess a chorioallantoic placenta, an omphaloplacenta and an interomphalopleuric membrane, characteristics present in other viviparous skinks. However, unlike other viviparous skinks but characteristic of oviparous skinks, the allantois expands to surround the yolk sac in each species, supplanting the omphalopleure with a larger area of chorioallantois until a chorioallantoic placenta surrounds the entire egg in one specimen that is only a few days from birth. All four Eulamprus species share the same extraembryonic membrane morphology, but the cellular morphology of the uterine epithelium in the chorioallantoic placenta and omphaloplacenta varies between species. We determined that the interomphalopleuric membrane is a shared derived character of the Eulamprus quoyii species group. New phylogenetic information indicates that variation in the chorioallantoic placenta is a result of two independent transitions, but that variation in the omphaloplacenta can be explained using a single change within the species studied. Our results indicate that E. quoyii group skinks are a valuable model for investigating the evolution of viviparity, as extraembryonic membrane development in these species shows features characteristic of both oviparous and viviparous skinks.

Placentation in the eastern water skink (Eulamprus quoyii): a placentome-like structure in a lecithotrophic lizard.

The eastern water skink (Eulamprus quoyii) has lecithotrophic embryos and was previously described as having a simple Type I chorioallantoic placenta. Indeed, it was the species upon which the definition of a Type I placenta was thought to be based, although we had cause to question that assumption. Hence we have described the morphology of the uterus of E. quoyii and found it to be more complex than previously supposed. The mesometrial pole of the uterus in E. quoyii displays a vessel-dense elliptical structure (the VDE) with columnar uterine epithelial cells. As pregnancy proceeds, the uterine epithelium near the mesometrial pole becomes folded and glands become hypertrophied, so that the morphology of VDE resembles that of a placentome, characteristic of Type III placentae. Unlike species with a Type III placenta, the apposing chorioallantoic membrane of E. quoyii is lined with squamous cells and interdigitates with the folded uterine epithelium. The remainder of the uterus is thin with a squamous uterine epithelium throughout pregnancy. Immunohistochemical localisation of blood vessels reveals a dense network of small capillaries directly beneath the folded epithelium of the VDE, while blood vessels are larger and sparser at the abembryonic pole of the uterus. Alkaline phosphatase (AP) activity is present in the uterine epithelium and sub-epithelial blood vessels in newly ovulated females. AP activity disappears from the epithelium between stages 27 and 29 of embryonic development and from the blood vessels after stage 34, but appears in the uterine glands at stage 35, where it remains until the end of pregnancy. Although the VDE is structurally similar to the placentomes found in other viviparous lizards, different distributions of AP activity in the uterus of E. quoyii and Pseudemoia spenceri suggest that the VDE may be functionally different from the placentome of the latter species. Our description of uterine morphology in E. quoyii provides evidence that, at least in some lineages, the evolution of a placentome may not occur in concert with the evolution of microlecithal eggs and obligate placentotrophy.

Evolution of viviparity and uterine angiogenesis: vascular endothelial growth factor (VEGF) in oviparous and viviparous skinks.

During pregnancy, uterine vasculature of live-bearing lizards proliferates to support embryonic growth and development. Vascular endothelial growth factor (VEGF) is the most potent of a suite of growth factors responsible for uterine vascularization in mammals. We have sequenced VEGF mRNA transcripts expressed in the uterus of oviparous and viviparous Australian skinks, and compared uterine VEGF expression in nonreproductive and late-reproductive Saiphos equalis, a fossorial viviparous skink. VEGF sequences differed between phylogenetic groups of skinks, rather than oviparous and viviparous skinks. Two transcripts were identified in the uterus of each species that had the same splice sites as human VEGF(165) and VEGF(189). A third transcript, found only in uterine and testis tissue from S. equalis, had the same splice sites as human VEGF(111). This is the first natural expression of VEGF(111), previously found only in human cultured cells subjected to environmental stress. All the three VEGF transcripts identified showed higher expression in uterus from late-reproductive S. equalis than nonreproductive females. The different angiogenic properties of VEGF transcripts provide a mechanism that may produce the variety of placental complexities observed in viviparous skinks. The presence of VEGF(111) in S. equalis may be an opportunity to investigate the function of this unique transcript in a whole animal system.

Angiogenesis of the uterus and chorioallantois in the eastern water skink Eulamprus quoyii.

We have discovered a modification of the uterus that appears to facilitate maternal-fetal communication during pregnancy in the scincid lizard Eulamprus quoyii. A vessel-dense elliptical area (VDE) on the mesometrial side of the uterus expands as the embryo grows, providing a large vascular area for physiological exchange between mother and embryo. The VDE is already developed in females with newly ovulated eggs, and is situated directly adjacent to the chorioallantois of the embryo when it develops. It is likely that signals from the early developing embryo determine the position of the VDE, as the VDE is off-centre in cases where the embryo sits obliquely in the uterus. The VDE is not a modification of the uterus over the entire chorioallantoic placenta, as the VDE is smaller than the chorioallantois after embryonic stage 33, but expansion of the VDE and growth of the chorioallantois during pregnancy are strongly correlated. The expansion of the VDE is also strongly correlated with embryonic growth and increasing embryonic oxygen demand (Vo2). We propose that angiogenic stimuli are exchanged between the VDE and the chorioallantois in E. quoyii, allowing the simultaneous growth of both tissues.

A review of the evolution of viviparity in squamate reptiles: the past, present and future role of molecular biology and genomics.

Squamate reptiles (lizards and snakes) offer a unique model system for testing hypotheses about the evolutionary transition from oviparity (egg-laying) to viviparity (live-bearing) in amniote vertebrates. The evolution of squamate viviparity has occurred remarkably frequently (>108 times) and has resulted in major changes in reproductive physiology. Such frequent changes in reproductive strategy pose two questions: (1) what are the molecular mechanisms responsible for the evolution of squamate viviparity? (2) Are these molecular mechanisms the same for separate origins of viviparity? Molecular approaches, such as RT-PCR, in situ hybridisation, Western blotting and immunofluorescence, have been invaluable for identifying genes and proteins that are involved in squamate placental development, materno-foetal immunotolerance, placental transport, placental angiogenesis, hormone synthesis and hormone receptor expression. However, the candidate-gene or -protein approach that has been used until now does not allow for de novo gene/protein discovery; results to date suggest that the reproductive physiologies of mammals and squamate reptiles are very similar, but this conclusion may simply be due to a limited capacity to study the subset of genes and proteins that are unique to reptiles. Progress has also been slowed by the lack of appropriate molecular and genomic resources for squamate reptiles. The advent of next-generation sequencing provides a relatively inexpensive way to conduct rapid high-throughput sequencing of genomes and transcriptomes. We discuss the potential use of next-generation sequencing technologies to analyse differences in gene expression between oviparous and viviparous squamates, provide important sequence information for reptiles, and generate testable hypotheses for the evolution of viviparity.