Comparative study on ovarian structures in scorpaenids: possible evolutional process of reproductive mode

The reproductive modes of the Scorpaenidae are extremely varied: oviparity, viviparity, and even spawning of internally fertilized eggs or embryos (zygoparity or embryoparity), as in Helicolenus, are known. The ovarian structure of this family is divided into two types by the arrangement of the stroma and the ovarian cavity. One type is the ovary in which the lamella-like stroma develops from the ovarian hilus located on the dorsal side and where the ovarian cavity is located on the ventral side of ovary, classified as “cystovarian type II-1” by Takano (1989). In the other type, the stroma in the ovary develops radially around the blood circulatory system that traverses the center of the ovary, and then the ovarian cavity surrounds all the ovary, classified as “cystovarian type II-3” by Takano (1989). In the present analysis, previous reports about ovarian structure and the relationship to the reproductive mode of scorpaenids were described, and the ovarian structure of eight genera of Scorpaenidae was examined. The ovary of cystovarian type II-1 is seen only in viviparous genera and is not seen in oviparous genera. However, the cystovarian type II-1 is a general structure in other families of Scorpaeniformes, and this structure could be considered a primitive type of ovary rather than that acquired by the process of evolution from oviparity to viviparity. The ovary of cystovarian type II-3 is seen in all six oviparous genera and the one zygoparous genus examined. The ovary of this type is not found in any other family of teleosts, so it could be a structure originally divided in Scorpaenidae. In the genera having the cystovarian type II-3 ovary, there is a common feature of spawning: a floating egg mass encompassed by the gelatinous material. We postulate that the evolution of reproductive mode in the scorpaenid fishes is as follows: Sebastes and Sebastiscus have a primitive ovary in which viviparity has developed, whereas the genera that spawn a floating egg mass evolved the ovarian structure from primitive type to cystovarian type II-3, and further zygoparity, such as in Helicolenus, evolved from them.     

Distribution and Biology of the New Zealand Endemic Catshark, Halaelurus dawsoni

Synopsis Halaelurus dawsoni has a restricted geographic range, occurring only in south-eastern New Zealand. It is primarily a demersal inhabitant of the upper continental slope, plateaus, and ridges at 250–800 m depth. Halaelurus dawsoni is a voracious carnivore that feeds on a wide variety of crustaceans and fishes. Maximum recorded length is 418 mm total length, and males and females grow to similar maximum lengths. Length at 50% maturity is about 340–350 mm for males and 330–360 mm for females. The reproductive mode of H. dawsoni is single oviparity, with one leathery egg case being carried per uterus. It appears that most embryonic development occurs after egg cases are deposited on the seabed. The reproductive mode of species of Halaelurus in the subgenus Halaelurus is multiple oviparity, whereas for those in the subgenus Bythaelurus it is single oviparity or aplacental viviparity. It has been suggested that single oviparity is a primitive reproductive mode, and that aplacental viviparity evolved from it via the intermediate stage of multiple oviparity. However, the relationship between reproductive mode and Halaelurus subgenus suggests that aplacental viviparity may have evolved directly from single oviparity in the subgenus Bythaelurus without passing through a multiple oviparous stage.     

Effects of Incubation Temperature on Crocodiles and the Evolution of Reptilian Oviparity

Crocodylus porosus is a mound-nesting crocodilian in which incubationtemperature influences the rate of embryonic development, theprobability that embryos will survive to hatching, post-hatchinggrowth rates and the probability of hatchlings surviving to2 yr of age. Similar responses have been described in Alligatormississippiensis (Joanen et al., 1987) and C. niloticus (Hutton,1987), and they reflect a suite of "non-sexual" effects of incubationtemperature. Temperature-dependent sex determination allocatessex on the basis of these "non-sexual" effects. In C. porosus,it results in maleness being assigned to embryos with high probabilitiesof surviving and good potential for post-hatching growth. Withinthe limits of survival, effects of the moisture environmenton embryological development rate and hatchling fitness seemminor relative to those of the temperature environment. Reptilian orders have either obligate oviparity (chelonians,crocodilians and rhynchocephalians) or facultative oviparity(squamates), depending on the extent of embryonic developmentwithin the oviducts. The distinction is equally one betweenembryos which are buffered from thermal effects within a female'sbody (facultative oviparity) and those that are not (obligateoviparity). Facultative oviparity and internal thermal bufferingmay be the primitive condition within the Class Reptilia, andthe "shell-less" eggs of extant squamates may reflect the originalamniote egg. Obligate oviparity, which also exists in birds,appears to have been a specialized development, and is a blindend in the evolution of viviparity among vertebrates. The significanceof thermal buffering being lost in obligate oviparous reptilesremains unclear.     

Superfoetative viviparity in a Carboniferous chondrichthyan and reproduction in early gnathostomes

Chondrichthyan fishes have an evolutionary history spanning over 400 million years and are characterized, in part, by internal fertilization. Traditionally, oviparity has been assumed to be the primitive birthing mode for these fishes and for vertebrates in general, with viviparity and matrotrophic nutrition being derived. The fossilized remains of two specimens of Harpagofututor volsellorhinus from the Upper Mississippian of Montana now provide the first direct evidence of matrotrophic live birth in a Palaeozoic chondrichthyan and of superfoetation in an extinct fish. Each female exhibits multiple foetuses of two size groups, indicating simultaneous gestation of multiple litters. There is no evidence of yolk sacs, only preserved organic pigments enveloping the young, suggesting matrotrophically derived material. Young were born large, as head lengths of the largest embryos measured up to 66 per cent of the mother's head length. Comparison of in utero embryos to isolated specimens suggests, unlike all extant chondrichthyans, the absence of a juvenile stage and rapid maturity. These new data suggest the advantages of superfoetative viviparity for a small bodied fish in a 318 Myr old species‐ and predator‐rich marine bay. In the greater view of gnathostome evolution, this finding combines with other recent discoveries to document that multiple, and not necessarily closely related, species of both placoderms and chondrichthyans exhibited viviparity by the Upper Devonian and the Upper Mississippian. The capacity for internal fertilization probably predisposed members of these lineages to develop viviparity so early in gnathostome history. Yet, the surprising range of viviparity exhibited at this stage of vertebrate evolution emphasizes that derived reproductive strategies had evolved in gnathostomes by 380–318 million years ago. © 2011 The Linnean Society of London, Zoological Journal of the Linnean Society, 2011, 161 , 587–594.     

Matrotrophy in the cave molly: an unexpected provisioning strategy in an extreme environment

Maternal provisioning of animal embryos may be entirely through yolk deposited in the unfertilized egg (lecithotrophy) or may include post-fertilization nutrient transfer (matrotrophy) in varying degrees. Current theory suggests that the extent of post-fertilization provisioning is resource-dependent, with higher levels of matrotrophy being advantageous in more productive environments. In this study, we investigated post-fertilization embryo provisioning in a livebearing fish, Poecilia mexicana, from two different habitats (a toxic cave and a non-toxic surface habitat) that impose different energetic demands and therefore differ in resources available for reproduction. We predicted that fish in the benign habitat would be more matrotrophic than those from the toxic cave. We used two different techniques for this assay: (1) the matrotrophy-index analysis (MI) for field-collected fish and (2) both MI and radio-tracer assay for laboratory-reared females. According to the interpretation of the matrotrophy index, both populations are purely lecithotrophic, while the radio-tracer assay found females from both populations to actively transfer nutrients to developing embryos at approximately the same rate. Our results suggest that P. mexicana, which was traditionally classified as lecithotrophic, is capable of incipient matrotrophy, and that matrotrophy can contribute to embryo provisioning even in populations from resource-limited environments. Furthermore, the analysis of laboratory-reared animals provides evidence for a genetic component to the large offspring size in cave mollies, which had so far only been described from the field. Specifically, our results suggest matrotrophy occurs in species interpreted as lecithotrophic using the MI approach. Hence, to avoid misclassification, both techniques should ideally be employed in concert, rather than individually. Finally, our results provide further insights into the possible evolutionary pathway from lecithotrophic oviparity to matrotrophic viviparity.     

TESTS FOR ANCIENT SPECIES FLOCKS BASED ON MOLECULAR PHYLOGENETIC APPRAISALS OF SEBASTES ROCKFISHES AND OTHER MARINE FISHES

The concept of species flocks has been central to previous interpretations of patterns and processes of explosive species radiations within several groups of freshwater fishes. Here, molecular phytogenies of species-rich Sebastes rockfishes from the northeastern Pacific Ocean were used to test predictions of null theoretical models that assume random temporal placements of phylogenetic nodes. Similar appraisals were conducted using molecular data previously published for particular cichlid fishes in Africa that epitomize, by virtue of a rapid and recent radiation of species, the traditional concept of an intralacustrine “species flock.” As gauged by the magnitudes of genetic divergence in cytochrome b sequences from mitochondrial DNA, as well as in allozymes, most speciation events in the Sebastes complex were far more ancient than those in the cichlids. However, statistical tests of the nodal placements in the Sebastes phylogeny suggest that speciation events in the rockfishes were temporally nonrandom, with significant clustering of cladogenetic events in time. Similar conclusions also apply to an ancient complex of icefishes (within the Notothenioidei) analyzed in the same fashion. Thus, the rockfishes (and icefishes) may be interpreted as ancient species flocks in the marine realm. The analyses exemplified in this report introduce a conceptual and operational approach for extending the concept of species flocks to additional environmental settings and evolutionary timescales.     

MITOCHONDRIAL DNA SEQUENCE-BASED PHYLOGENY AND THE EVOLUTION OF VIVIPARITY IN THE SCELOPORUS SCALARIS GROUP (REPTILIA,SQUAMATA)

The lizard genus Sceloporus contains both oviparous and viviparous species. The scalaris complex is the only monophyletic group within the genus that includes both reproductive modes, thus it is particularly well suited for studies of the evolution of viviparity. Approximately 874 nucleotides of mtDNA sequence data, collected from 38 specimens, comprising 25 populations of all five recognized species within the group, were used in a phylogenetic analysis of the origin of viviparity. Viviparity appears to have evolved twice in this group: once in S. goldmani, included in a clade formed by a northern group consisting of S. scalaris, S. chaneyi, and S. goldmani, and one more time in S. bicanthalis, included in the southern group formed by S. bicanthalis and S. aeneus. An oviparous population of S. bicanthalis nested within that viviparous clade, indicates that reversal from viviparity to oviparity may be possible. Degree of sequence divergence among several S. bicanthalis individuals pertaining to a population in which both parity modes occur, was no larger between oviparous and viviparous lizards than among viviparous lizards. This suggests that this population is a single species, and it may represent a transition from oviparity to viviparity or vice-versa.     

Immunochemical identification and partial characterization of female-specific serum proteins in white-edged rockfish,Sebastes taczanowskii

Synopsis Female-specific serum proteins (FSSPs) in white-edged rockfish,Sebastes taczanowskii, were identified and partially characterized by immunochemical procedures. Two FSSPs, which clearly reacted with antiserum against egg proteins, were confirmed in the serum of mature females, and estrogen treatment induced similar FSSPs in the serum of mature males. Hence, the FSSPs were considered to be vitellogenin. The vitellogenin concentration in female fish was high during the vitellogenic period and low during gestation, parturition and the recovery period, indicating that vitellogenin is used only for yolk formation in the oocytes and not as a direct nutritional source for developing embryos during gestation. On the other hand, an FSSP (FS3), which was considered not to be vitellogenin, was also identified in the sera of mature females and males after estradiol-17β administration by using an antiserum (a-FS3) that removed the components of the male serum and egg extracts from the anti-mature female serum antiserum. Moreover, immunohistochemical observation with a-FS3 illustrated that FS3 was a major constituent of the ovarian fluid but not of vitellogenic oocytes. The cross-reactivities of these FSSPs among seven viviparous rockfishes demonstrated that vitellogenin existed in the sera of all rockfishes studied belonging to the generaSebastes andSebastiscus, whereas FS3 was not present in several species ofSebastes.     

Embryonic development and nourishment in the viviparous fish Poecilia vivipara (Cyprinodontiformes: Poeciliidae)

While viviparity confers protection to the embryos during gestation, it increases energetic costs for the mother, which acquires new relations to its offspring. Maternal–fetal transfer of nutrients can occur in different patterns: as lecithotrophy (nourished by yolk) or matrotrophy (nourished by the mother). The development of Poecilia vivipara embryos was described macroscopically and microscopically, and the form of nutritional provisioning was identified. Embryonic development was divided into three prefertilization and seven postfertilization stages. The first organ to appear is the notochord, followed by the nervous, digestive and cardiovascular systems, and then by muscles and eyes. Embryonic nutritional provisioning was lecithotrophic, with yolk persisting until the last developmental stages and rich in proteins and polysaccharides. This kind of embryonic nutrition confirms the pattern found in the family Poeciliidae.     

Energy utilization by embryos during gestation in viviparous copper rockfish,Sebastes caurinus

Synopsis The energy utilized by developing copper rockfishSebastes caurinus embryos was measured through direct respirometry (0.408 cal embryo⁻¹) and compared with the change in energy content of embryos from fertilization to birth (0.361 cal embryo⁻¹). The difference between the energy consumed and energy lost during gestation indicates that 0.047 cal embryo⁻¹ or 11.5% of the energy utilized during gestation is contributed by the mother after fertilization. Available information on other membres of the genusSebastes suggests that matrotrophic viviparity may be the common mode of reproduction, but energy contribution varies greatly between species.     

DID EGG‐LAYING BOAS BREAK DOLLO'S LAW? PHYLOGENETIC EVIDENCE FOR REVERSAL TO OVIPARITY IN SAND BOAS (ERYX: BOIDAE)

Re-evolution of lost complex morphological characters has been proposed for several characters, including insect wings, limbs, eyes in snakes, and digits in lizards, among others. There has also been much interest in whether the transition from oviparity to viviparity is reversible, particularly in squamate reptiles where the transition to viviparity has occurred more times than in any other lineage. Here, we present a phylogenetic analysis of boid snakes based on a concatenated multigene study of all genera of erycines, New and Old World boines, plus other groups thought to be closely related with boines such as monotypic species Calabaria and Casarea . We reconstruct ancestral parity mode on this phylogeny and present statistical evidence that oviparity reevolved in a species of Old World sand boa in the genus Eryx nearly 60 million years after the initial boid transition to viviparity. Remarkably, like other viviparous boas hatchlings of oviparous Eryx lack an egg-tooth providing independent evidence that oviparity is a derived state in these species.     

REPTILIAN VIVIPARITY AND DOLLO'S LAW

It has been suggested repeatedly that the evolutionary transition from oviparity (egg-laying) to viviparity (live-bearing) in reptiles is irreversible. However, these adaptive arguments have yet to be tested by detailed examination of the phylogenetic distribution of oviparity and viviparity across a broad range of taxa. Using available data on reproductive modes and phylogenetic relationships within reptiles, we here quantify the numbers and directions of evolutionary transitions between oviparity and viviparity. Phylogenetic relationships among three diverse squamate groups (scincid lizards, colubrid snakes, elapid snakes) are currently inadequately known for inclusion in this study Among the remaining reptiles, oviparity has given rise to viviparity at least 35 times. Five possible instances of reversals (from viviparity to oviparity) are identified, but closer examination indicates that all have weak empirical support (i.e., they could be “unreversed” with little loss in parsimony, and/or are based on poorly substantiated phylogenetic hypotheses). Viviparity is clearly more frequently (and presumably easily) gained than lost in several disparate groups so far examined (reptiles, fishes, polychaete worms); this evolutionary bias should be considered when reproductive mode is optimized on a phylogeny or employed in phylogenetic reconstruction.     

Plasticity and limitations of extended egg retention in oviparous Zootoca vivipara (Reptilia: Lacertidae)

The transition between oviparity and viviparity in reptiles is generally accepted to be a gradual process, the result of selection for increasingly prolonged egg retention within the oviduct. We examined egg retention plasticity in an oviparous strain of the lacertid lizard Zootoca vivipara, a species having both oviparous and viviparous populations. We forced a group of female Z. vivipara to retain their clutch in utero by keeping them in dry substrata, and assessed the effect on embryonic development and hatching success, along with offspring phenotype and locomotor performance. Forced egg retention for one additional week affected the developmental stage of embryos at oviposition, as well as hatchling robustness and locomotor performance. However, embryos from forced clutch retention treatment reached one stage unit more than control embryos at oviposition time. Embryos from control eggs were more developed than embryos from experimental eggs after approximately the same period of external incubation, showing that embryonic development is retarded during the period of extended egg retention, despite the high temperature inside the mother's body. Significant differences in external incubation time were only found in one of the two years of study. Hatching success was much lower in the experimental group with forced egg retention (21.1%) than in the control group (95.4%). Therefore, we conclude that there are limitations that hinder the advance of intrauterine embryonic development beyond the normal time of oviposition, and that extended egg retention does not represent clear advantages in this population of Z. vivipara. Nevertheless, the fact that some eggs are successful after forced egg retention could be advantageous for the females that are able to retain their clutch under unfavourable climatic conditions. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2011, 102 , 75–82.     

Live birth in Cretaceous marine lizards (mosasauroids).

Although live-bearing (viviparity) has evolved around 100 times within reptiles, evidence of it is almost never preserved in the fossil record. Here, we report viviparity in mosasauroids, a group of Cretaceous marine lizards. This is the only known fossil record of live-bearing in squamates (lizards and snakes), and might represent the oldest occurrence of the trait in this diverse group; it is also the only known fossil record of viviparity in reptiles other than ichthyosaurs. An exceptionally preserved gravid female of the aigialosaur Carsosaurus (a primitive mosasauroid) contains at least four advanced embryos distributed along the posterior two-thirds of the long trunk region (dorsal vertebrae 9-21). Their orientation suggests that they were born tail-first (the nostrils emerging last) to reduce the possibility of drowning, an adaptation shared with other highly aquatic amniotes such as cetaceans, sirenians and ichthyosaurs; the orientation of the embryos also suggests that they were not gut contents because swallowed prey are usually consumed head-first. One embryo is located within the pelvis, raising the possibility that the adult died during parturition. Viviparity in early medium-sized amphibious aigialosaurs may have freed them from the need to return to land to deposit eggs, and permitted the subsequent evolution of gigantic totally marine mosasaurs.     

Thermoregulation during gravidity in the children's python (Antaresia childreni): a test of the preadaptation hypothesis for maternal thermophily in snakes

Pregnant squamate reptiles (i.e. lizards and snakes) often maintain higher and more stable body temperatures than their nonpregnant conspecifics, and this maternal thermophily enhances developmental rate and can lead to increased offspring quality. However, it is unclear when this behaviour evolved relative to the evolution of viviparity. A preadaptation hypothesis suggests that maternal thermophily was a preadaptation to viviparity. Oviparous squamates are unique among oviparous reptiles for generally retaining their eggs until the embryos achieve one fourth of their development. As a result, maternal thermophily by gravid squamates may provide the same thermoregulatory benefits, at least during early development, that have been associated with viviparity. Thus, the evolution of viviparity in squamates may reflect an expanded duration of a pre-existing maternal thermoregulatory behaviour. Despite its evolutionary relevance, thermoregulation during gravidity in oviparous squamates has not yet been explored in depth. In the present study, we examined whether gravidity was associated with thermoregulatory changes in the oviparous children's python, Antaresia childreni . First, we discovered that, compared to most snakes, A. childreni is at an advanced stage of embryonic development at oviposition. Second, using surgically implanted temperature loggers, we detected a significant influence of reproductive status on thermoregulation. Reproductive females maintained higher and less variable body temperatures than nonreproductive females and this difference was most pronounced during the last 3 weeks of gravidity. Overall, these results highlight the continuum between oviparity and viviparity in squamate reptiles and emphasize the importance of thermal control of early embryonic development independent of reproductive mode.  © 2008 The Linnean Society of London, Biological Journal of the Linnean Society , 2008, 93 , 499–508.     

Matrotrophic viviparity constrains microbiome acquisition during gestation in a live‐bearing cockroach,Diploptera punctata

The vertical transmission of microbes from mother to offspring is critical to the survival, development, and health of animals. Invertebrate systems offer unique opportunities to conduct studies on microbiome‐development‐reproduction dynamics since reproductive modes ranging from oviparity to multiple types of viviparity are found in these animals. One such invertebrate is the live‐bearing cockroach, Diploptera punctata. Females carry embryos in their brood sac, which acts as the functional equivalent of the uterus and placenta. In our study, 16S rRNA sequencing was used to characterize maternal and embryonic microbiomes as well as the development of the whole‐body microbiome across nymphal development. We identified 50 phyla and 121 classes overall and found that mothers and their developing embryos had significantly different microbial communities. Of particular interest is the notable lack of diversity in the embryonic microbiome, which is comprised exclusively of Blattabacteria, indicating microbial transmission of only this symbiont during gestation. Our analysis of postnatal development reveals that significant amounts of non‐Blattabacteria species are not able to colonize newborn D. punctata until melanization, after which the microbial community rapidly and dynamically diversifies. While the role of these microbes during development has not been characterized, Blattabacteria must serve a critical role providing specific micronutrients lacking in milk secretions to the embryos during gestation. This research provides insight into the microbiome development, specifically with relation to viviparity, provisioning of milk‐like secretions, and mother–offspring interactions during pregnancy.     

Multiple origins of viviparity,or reversal from viviparity to oviparity? The European common lizard (Zootoca vivipara,Lacertidae) and the evolution of parity

The evolution of viviparity in squamates has been the focus of much scientific attention in previous years. In particular, the possibility of the transition from viviparity back to oviparity has been the subject of a vigorous debate. Some studies have suggested this reversal is more frequent than previously thought. However, none of them provide conclusive evidence. We investigated this problem by studying the phylogenetic relationships between oviparous and viviparous lineages of the reproductively bimodal lizard species Zootoca vivipara . Our results show that viviparous populations are not monophyletic, and that several evolutionary transitions in parity mode have occurred. The most parsimonious scenario involves a single origin of viviparity followed by a reversal back to oviparity. This is the first study with a strongly supported phylogenetic framework supporting a transition from viviparity to oviparity.  © 2006 The Linnean Society of London, Biological Journal of the Linnean Society , 2006, 87 , 1–11.     

Ionic and osmotic environment of developing elasmobranch embryos

Synopsis The elasmobranchs display a variety of ionic and osmotic environments for developing embryos. Oviparous species protect their eggs with a tough, fibrous capsule which is highly permeable to ions and urea even at oviposition. Thus the embryonic tissues are bathed by a solution ionically similar to sea water. In the more advanced reproductive style ofSqualus acanthias (a lecithotrophic live bearer) early embryos in egg capsules are retained in utero and bathed in a solution osmotically similar to maternal plasma. Several months into the 22 month gestation period the embryos can iono- and osmoregulate in a uterine solution resembling sea water. Embryos of more advanced viviparous species develop in a solution that is ionically and osmotically similar to maternal plasma. Iono- and osmoregulation by these embryos would appear to be unnecessary. Clearly, in the oviparous elasmobranchs, the ability of the embryo to regulate salts and urea is present at the earliest stage of development. The need for elasmobranch embryos to regulate osmolytes was reduced or delayed as viviparity evolved.     

Assessment of habitat and predator effects on dwarf rockfishes (<Emphasis Type="Italic">Sebastes</Emphasis> spp.) using multi model inference

Habitat associations and the effect of predators on dwarf rockfishes (Sebastes spp.) were investigated in two large marine protected areas (MPAs) off southern California. Using data from submersible surveys, the occurrence and abundance of dwarf rockfishes were modeled using substrata types and the biomass of predators as predictor variables. The occurrence and abundance of dwarf rockfishes generally were positively associated with rock, boulder, and cobble substrata. The association between predators and occurrence of dwarf rockfishes differed substantially between species. Predator density and biomass levels were much lower in the southern California MPAs than in a de facto MPA off central California. Better inference about predator effects on dwarf rockfishes will be possible if the predator biomass and densities of southern California MPAs increase to that observed in the de facto MPA.