Arrested embryonic development: a review of strategies to delay hatching in egg-laying reptiles

(i) Causes of pre-ovipositional arrest

There are several morphological and physiological constraints likely to have given rise to pre-ovipositional arrest and the need to lay eggs at specific, mostly early, stages of development. In turtles, crocodilians and the tuatara, limited oxygen exchange might occur in the oviduct as a result of shell calcification and the shell pores filling with oviducal fluid [21]. Pre-ovipositional calcification of turtle eggs becomes complete when the embryos reach gastrulae and enter pre-ovipositional arrest approximately 7 days after ovulation [31]. Similarly, calcification of the eggshell is extended in squamate species that arrest during late developmental stages and completes just prior to arrest [65]. Eggshell calcification may infer a restriction on respiratory gas exchange needed for further growth of the embryo [32,33]. A reduction in eggshell thickness has been associated with extended egg retention and advanced embryonic development in reptiles, presumably because the availability of O₂ to the embryo is enhanced [31,66]. However, instances of eggshell thickening associated with extended egg retention in turtles have also been reported [67]. Additionally, the eggshell provides a source of calcium for developing turtle embryos and reducing the degree of eggshell calcification in order to achieve greater O₂ exchange may decrease embryo fitness [21,68].

The embryonic vitelline membrane and inner shell membranes of the egg must adhere to one another after calcification of turtle and crocodilian eggs to allow gas diffusion and embryonic growth. Membrane fusion can only occur after oviposition because it is likely that the connection would rupture when eggs are jostled during oviposition, leading to embryonic mortality [21,69]. Vertical or horizontal movement of turtle eggs after membrane adhesion can cause movement-induced mortality [69–71], which has also been demonstrated in crocodilian embryos between 2 and 9 days after oviposition [22,61]. The presence of viscous oviducal secretions surrounding the egg and filling its pores inhibits formation of a respiratory surface that allows efficient gas diffusion [34,72].

Currently, there are no published data supporting the suggestion that hypoxia within the reptilian oviduct induces pre-ovipositional arrest [21,35,36]. Intra-oviducal oxygen tensions also remain unknown in reptiles, although there have been studies that estimated the oxygen tension in utero of the eastern fence lizard, Sceloporus undulatus, to be hypoxic [37,38]. Hypoxia is known to induce developmental arrest in budding yeast, Saccharomyces cerevisiae, and embryos of the nematode Caenorhabditis elegans, zebrafish, Danio rerio, and mouse, Mus musculus [73–76]. Hypoxia also maintains arrest in several species of short-lived fishes [77]. Oviducal oxygen tension has been measured at 37 mm Hg (5.3% O₂) during the formation of pre-implantation blastocysts in pregnant hamsters [78]. These comparative findings suggest that a hypoxic environment within the oviduct of oviparous reptiles is likely and that a lack of oxygen may induce and/or maintain pre-ovipositional arrest.

Hypoxia causes the upregulation of the insulin-like growth factor binding protein (IGFBP-1) [79–81] that binds to insulin-like growth factors (IGFs) and inhibit their activity. IGFs are greatly involved in embryonic metabolic activities and regulate all aspects of development and growth [82]. Altered expression of IGF proteins affects embryonic development in guinea pigs [83] and binding of IGFBP-1 to IGFs during hypoxia inhibits growth and causes developmental arrest in zebrafish embryos [84]. It is unknown whether this occurs in reptilian embryos that experience pre-ovipositional arrest, but it is plausible that oviducal hypoxia may cause expression of IGFBP-1 during certain developmental stages, leading embryos to arrest in the oviducts. After oviposition, increased oxygen levels or natural degradation of IGFBP-1 may then allow IGF activity and resumption of development.

IGF-I and IGF-II have been discovered in the albumin of shelled eggs present in the oviducts of the American alligator, A. mississippiensis [85], and peak IGF levels have been recorded in gravid females of this species [19,86]. The maternal influence over developmental arrest is widely reported in mammals [6], but is a topic that is relatively unexplored in reptiles. Maternal effects, defined as the underlying pressure exerted by the maternal genotype or phenotype that influences the offspring phenotype [87], have been linked to hatching success, hatchling growth rate and righting response in the snapping turtle, Chelydra serpentina, despite the absence of the mother during incubation [88,89]. In addition, some female leatherback turtles, Dermochelys coriacea, are more successful mothers than others [90,91] and it is therefore plausible that female reptiles directly influence the development of their embryos inside the oviduct with such influence possibly persisting after oviposition.

(i) Post-ovipositional arrest

Both eggshell type and geographic location have been used to predict the likelihood of a species possessing developmental arrest after oviposition [4,11,41]. Eggshell thickness is a primary focus in the debate surrounding the evolution of developmental arrest and viviparity in reptiles, and it is known to affect aspects of embryonic physiology [98]. Species that lay thinner-shelled pliable eggs typically do not use developmental arrest after oviposition and as a result they have shorter incubation periods than those laying thicker, more rigid, brittle-shelled eggs that do use it [11]. In addition, seasonal climatic effects influence the occurrence of developmental arrest in different geographic locations and it is likely to occur in reptilian species nesting in regions with distinct seasons and locations that are characterized by a warm temperate or tropical climate [30].

In sub-tropical and tropical regions, arrested development in chameleons is closely related to seasonal temperature fluctuations [4]. This is also the case for turtle species that nest during temperate autumn, although embryonic development does not appear to arrest during egg incubation when nesting occurs during temperate spring and summer in ephemerally suitable habitats [42]. On the other hand, developmental arrest in turtle species that nest in tropical and sub-tropical regions is most likely dictated by the seasonality of rainfall rather than temperature [4,11,42]. For example, pre-ovipositional arrest persists in embryos of the northern long-necked turtle, Chelodina rugosa, when eggs are laid underwater during the wet season. Embryos remain as gastrulae in response to underwater hypoxia until they are exposed to atmospheric oxygen when the nests dry out during the dry season [43]. A modified vitelline membrane in the eggs of this species prevents excessive water uptake during submersion [39]. The entire ontogeny of C. rugosa can be linked to environmental parameters with rainfall and hypoxia being involved in not just pre-ovipositional arrest in early embryos [99].

(ii) Post-ovipositional embryonic diapause

Embryos from several chelonian and chamaeleonid lizard lineages undergo a period of post-ovipositional embryonic diapause while they are still gastrulae [42,100]. Embryonic diapause is observed in the common chameleon, C. chamaeleon, the veiled chameleon, C. calyptratus and the Indian chameleon, C. zeylanicus, which lay eggs during temperate and subtropical autumn that take up to a year after oviposition to hatch because they arrest during cold winter months [40,44,101]. Embryos of the jewelled chameleon, Furcifer lateralis and the panther chameleon, F. pardalis, may also experience periods of embryonic diapause during the cooler dry season because they are laid during the warm wet season and do not hatch until the following wet season [45,46,47,102]. Embryonic diapause is an obligate part of the life cycle for each of these species, although resumption of development is facultative and does not appear to be linked to a mandatory environmental cue like those needed during embryonic diapause in some turtle species [29]. However, the length of time that embryonic diapause persists after oviposition has been linked to temperature in some chameleon species [29,40,101].

Australian broad-shelled turtle, Chelodina expansa, embryos also typically remain arrested after oviposition for several weeks before recommencing development briefly and entering a secondary state of embryonic diapause prior to somite and vitelline development, which persists throughout the winter period [29,42]. This type of embryonic diapause occurs after white spot development and is seen in healthy embryos that are in an environment which would normally promote active development [4]. Embryos in this state need to be exposed to an obligatory trigger to recommence development and in the absence of this cue, embryos remain arrested and eventually die [4].

Freshwater turtle embryos that show embryonic diapause take longer to reach specific development stages than those that do not when incubated at the same temperature [4]. The occurrence of embryonic diapause can be identified by comparing the developmental schedules of siblings or embryos of closely related species and recognizing whether pre-somite development is extended in relation to the remainder of development (i.e. whether development occurs in the expected timeframe) [4]. Five developmental stages are used to draw comparisons based on a determined developmental series [103]. These include the appearance of blood islands (stage 5), development of the haemodisc (vitelline circulation at stage 8), pigmentation of the eye (stage 12), pigmentation of the body (stage 20) and hatching (stage 26). The appearance of the white spot has also been used as a defining developmental stage [72,100]. These aforementioned stages can be observed in many species through non-destructive candling techniques and so make development in viable eggs relatively simple to assess [104].

In warm temperate regions, where oviposition generally occurs in autumn, embryos enter a state of embryonic diapause during the winter months and for some species such as the striped mud turtle, Kinosternon baurii, it has been described as seasonally dependent [4,42]. Kinosternon baurii females nest twice yearly during both spring and autumn, but embryos from the same females that are laid during both seasons only express embryonic diapause during autumn, suggesting that the occurrence of this reproductive characteristic is dependent on some external cue [42]. These embryos require a period of chilling to terminate embryonic diapause and resume development to hatching. Unchilled eggs of D. reticularia, the ornate wood turtle, Rhinoclemmys pulcherrim, and the Indian black turtle, Melanochelys trijuga, also require this stimulus, and they will remain arrested and subsequently die in its absence [11,25]. The same is true for C. expansa embryos, which require a chilling period during their developmental cycle in order for eggs to recommence development after embryonic diapause [29].

The ‘decision’ of whether or not an embryo expresses embryonic diapause is thought to occur during late oogenesis (between ovulation and fertilization) in K. baurii [42]. If females underwent chilling during this period, their embryos did not express embryonic diapause post-oviposition, but the embryos of unchilled females did [42]. This suggests that expression of embryonic diapause in embryos is determined by the temperature that mothers experience during late oogenesis, supporting the theory that maternal experience may influence the phenotype of their young [88,89].

The presence of embryonic diapause is characterized by annual wet–dry seasonality rather than by the temperature in sub-tropical and tropical locations [41]. These regions have seasonal rainfall patterns with minimal annual variation in temperature. In these areas, early incubation is spent in embryonic diapause during the wet season and the beginning of the dry season with hatching occurring the following wet season. In Pacific coastal regions of Mexico and Central America, turtle species including Kinosternon, Staurotypus and Rhinoclemmys express embryonic diapause in relation to seasonal rainfall, the same is also true for the north Australian snapping turtle, Elseya dentata, that lays its eggs during the austral wet season [42,105]. By laying eggs during the wet season, reptilian females may free themselves from the burden of carrying eggs for extended periods until suitable nesting environments are available. Additionally, it may also allow them to exploit the abundant food resources existing during these periods and thereby to produce subsequent clutches, assuming that successive clutches are not ovulated immediately after oviposition [43]. Likewise, hatching emergence during wet seasons may infer an advantage for the hatchlings because prey abundance is greater [48].

(iii) Cold torpor

Cold torpor is the facultative suspension of development that embryos use to survive brief periods during temperatures that are too low to support developmental requirements [4,11,50]. The embryos of most species of bird and reptile are capable of using this type of arrest at any stage during incubation, although others such as the montane lizard, Acritoscincus duperreyi, can only enter cold torpor when they are full-term embryos and not during earlier stages of development [49]. It is a direct response to unfavourable weather and in many cases, it protects embryos for varying durations at below-critical temperatures, although the chances of mortality increase with increased duration spent in torpor [4,51]. Avian species can typically only endure several days in torpor, whereas reptile embryos can withstand weeks [4]. Cold torpor can maintain pre-ovipositional arrest in turtle embryos [52] and in avian species that do not use pre-ovipositional arrest, torpor can prevent development of embryos after oviposition until all eggs in the clutch have been laid [8]. This allows the synchronization of development and hatching of the clutch [7].

(iv) Delayed hatching and embryonic aestivation

Delayed hatching and embryonic aestivation are strategies employed to prolong the residence of an embryo within the egg in response to adverse environmental conditions [4,42]. During both forms of arrest, the embryo is in the final stages of development and typically remains within an unpipped egg, although some species of bird may pip the egg before delaying hatching for up to a week [4,106]. Delayed hatching and aestivation differ only in the duration and degree of metabolic downregulation, so they are generally not distinguished in the literature. Delayed hatching occurs in avian, crocodilian, squamate and chelonian groups and although it may persist for several weeks in reptile eggs, it is usually brief in birds [4,55]. In contrast, aestivation is a late-embryonic dormancy that may last for weeks or months and empirical evidence of its occurrence has only been documented in turtles, although it may also occur in crocodiles and lizards [55,56,57,107]. Both delayed hatching and aestivation allow protection of young during unfavourable conditions and also permit synchronization of hatching when environmental surroundings promote optimum survival [4,53,57].

Generally, approximately 2 days before a turtle embryo pips the shell, the amnion ruptures inside the egg and the chorio-allantois moves posterior to the embryo, revealing the head and forelimbs and so freeing the embryo to pip the shell [11]. At the time of hatching, a yolk sac will also be external to the plastron [4,108]. However, when an embryo delays hatching, there is usually a greater delay in pipping after rupture of the amnion and movement of the chorio-allantois, in addition to internalization of the yolk reserve. Yolk absorption and final assimilation of any blood from the chorio-allantois signal the completion of embryonic development in turtles and crocodilians.

Turtle species including the pig-nosed turtle, Carettochelys insculpta, K. scorpioides and K. flavescens gradually enter aestivation after the chorio-allantois parts and migrates, such that it no longer covers the body of the turtle inside the eggshell [4]. Aestivation is sometimes considered an extension of delayed hatching if optimal conditions for hatching do not arise. The prolonged incubation period associated with aestivation generally involves the downregulation of metabolic processes and the subsequent decline in oxygen consumption rates to extremely low but steady levels [4]. Aestivation can extend for periods up to 116 days in K. scorpioides and 232 days in K. flavescens embryos if a stimulus to pip remains absent. In the former species, oxygen consumption can decrease to approximately 22 per cent of the peak rate [4]. Oxygen consumption rates of C. insculpta can decline to one-third of the peak rate when experiencing delayed hatching and aestivation at 30°C [109]. During these periods, the fully developed mature hatchlings of C. insculpta can remain within the egg for up to 59 days, after which the yolk reserve becomes depleted [57,109]. Extended aestivation periods potentially result in the weakening of the embryo and increase the likelihood of mortality if all energetic reserves have been exhausted and a stimulus to pip is still absent [4,41]. Not all species of turtle are capable of aestivation and when late-term embryos of the painted turtle, Chrysemys picta and C. serpentina are exposed to conditions that induce aestivation in other aestivating species, development and hatching are hastened because of the unfavourable conditions [4].

The proximate mechanisms associated with the metabolic changes observed during delayed hatching and aestivation, which appear to be actively regulated independent of temperature, are poorly understood. However, a possible factor involved in the process may be thyroid hormone [54,110]. Thyroid hormone is vital for the growth and function of most vertebrate tissues and is capable of acting on both metabolic and non-metabolic pathways to influence embryonic tissue accretion and differentiation [111]. Thyroid hormone is also involved in energy metabolism and has been linked to the hatching process in chickens [112,113]. Increased thyroid hormone levels are known to stimulate hatching, and production of this hormone is induced in hypoxic conditions [112]. Hypoxia is the proximal cue known to trigger aestivating C. insculpta eggs to rapidly hatch, although whether this process involves thyroid hormone remains to be tested [57].

Environmentally induced cues have been explained to terminate delayed hatching and aestivation. Both processes were originally thought to occur in response to hot environments, although recent research suggests that delayed hatching and aestivation are more likely strategies to coincide hatching with wet season productivity [41,57]. In doing so, delayed hatching and aestivation allow hatchlings to exploit early wet-season productivity to promote growth and survival rather than to avoid any embryonic stress that might be caused by late dry-season conditions [4,106,109]. As mentioned previously, hypoxia induced by complete water inundation of C. insculpta eggs is the trigger that induces explosive hatching during periods of heavy rainfall [57,109]. Eggs of hole-nesting crocodilians may also undergo this process based on similar nesting and hatching patterns, but more research is needed to confirm this [107]. Additionally, heavy rainfall at the onset of the wet season may trigger hatching in the Fiji-crested iguana, Brachylophus vitiensis, but it has not yet been determined whether extended incubation periods are associated with delayed hatching and aestivation, or embryonic diapause in this species [55,114].

Evidence is also emerging which suggests that there are additional mechanisms, other than fluctuations in nest gas concentration, that trigger eggs to hatch synchronously after undergoing a period of quiescence. Vibration-induced hatching, triggered by the vibrations of some eggs hatching earlier than others, has been proposed [55]. In addition, audible triggers such as the pipping of eggs or vocalizations by embryos is plausible considering that sibling communication has been identified in eggs of both crocodilian and some avian species [54,58]. However, all of these hypotheses remain to be fully tested.