Autocrine embryotropins revisited: how do embryos communicate with each other in vitro when cultured in groups?

In the absence of the maternal genital tract, preimplantation embryos can develop in vitro in culture medium where all communication with the oviduct or uterus is absent. In several mammalian species, it has been observed that embryos cultured in groups thrive better than those cultured singly. Here we argue that group‐cultured embryos are able to promote their own development in vitro by the production of autocrine embryotropins that putatively serve as a communication tool. The concept of effective communication implies an origin, a signalling agent, and finally a recipient that is able to decode the message. We illustrate this concept by demonstrating that preimplantation embryos are able to secrete autocrine factors in several ways, including active secretion, passive outflow, or as messengers bound to a molecular vehicle or transported within extracellular vesicles. Likewise, we broaden the traditional view that inter‐embryo communication is dictated mainly by growth factors, by discussing a wide range of other biochemical messengers including proteins, lipids, neurotransmitters, saccharides, and microRNAs, all of which can be exchanged among embryos cultured in a group. Finally, we describe how different classes of messenger molecules are decoded by the embryo and influence embryo development by triggering different pathways. When autocrine embryotropins such as insulin‐like growth factor‐I (IGF‐I) or platelet activating factor (PAF) bind to their appropriate receptor, the phosphatidylinositol‐4,5‐bisphosphate 3‐kinase (PI3K) pathway will be activated which is important for embryo survival. On the other hand, the mitogen‐activated protein kinase (MAPK) pathway is activated when compounds such as hyaluronic acid and serotonin bind to their respective receptors, thereby acting as growth factors. By activating the peroxisome‐proliferator‐activated receptor family (PPAR) pathway, lipophilic autocrine factors such as prostaglandins or fatty acids have both survival and anti‐apoptotic functions. In conclusion, considering different types of messenger molecules simultaneously will be crucial to understanding more comprehensively how embryos communicate with each other in group‐culture systems. This approach will assist in the development of novel media for single‐embryo culture.     

小鼠着床前胚胎发育中调控因子的时序表达及功能

哺乳动物着床前胚胎发育最基本的问题之一是高度分化的卵母细胞如何过渡到全能性的卵裂球。这一转换过程受到了多种调控因子正或负的调控作用,这些特定调控因子在着床前胚胎发育过程中呈现出较为显著的时空表达特征,它们对早期胚胎的进一步正常发育有重要的作用。研究这些调控因子在着床前胚胎发育中的表达模式和调控机制,将有助于我们对早期胚胎发育机制的进一步了解。作者主要对近些年来有关生长因子与细胞因子（如：PAF、IL－1、IGF、MIF）以及特定转录因子（如：SP1、TBP、mTEF、eIF、myc、c-jun等）在小鼠着床前胚胎发育中的时空表达及其相应功能的研究做一简要介绍。     

Changes in requirements and utilization of nutrients during mammalian preimplantation embryo development and their significance in embryo culture

Along with the transition from maternal to embryonic genome control the mammalian preimplantation embryo undergoes significant changes in its physiology during development. Concomitant with these changes are altering patterns of nutrient uptake and differences in the subsequent fate of such nutrients. The most significant nutrients to the developing mammalian preimplantation embryo are carbohydrates and amino acids, which serve not only to provide energy but also to maintain embryo function by preventing cellular stress induced by suboptimal culture conditions in vitro. It is subsequently proposed that optimal development of the mammalian embryo in culture requires the use of two or more media, each designed to cater for the changing requirements of the embryo. Importantly, culture conditions that maintain the early embryo are not ideal for the embryo post-compaction, and conditions that support excellent development and differentiation of the blastocyst can actually be inhibitory to the zygote. A marker of in vitro-induced cellular stress to the embryo is the relative activity of the metabolic pathways used to generate energy for development. Quantification of embryo energy metabolism may therefore serve as a valuable marker of embryo development and viability.     

Characterization of an immortalized oviduct cell line from the cynomolgus monkey (Macaca fascicularis)

To establish reproductive biological techniques in mammals, it is important to understand the growth environment of the embryo. Oviduct epithelial cells are in close proximity to the embryo during pre-implantation development. We, therefore, established an immortalized oviduct epithelial cell line from the cynomolgus monkey, evaluated the usefulness of these cells as feeder cells for embryo culture, and investigated the gene expression of several growth factors and cytokines in the cells. The immortalized cells were positive for the anti-cytokeratin antibody, as determined by immunocytochemistry, indicating that they are epithelial. They also expressed oviductin, which is specific to oviduct epithelial cells, glyceraldehyde-3-phosphate dehydrogenase (control), leukemia inhibitory factor, vascular endothelial growth factor, epidermal growth factor, insulin-like growth factor 1, transforming growth factor beta-2, and interleukin 4. Mouse embryo development was improved when the immortalized cells were used as feeder cells. This cell line is also useful for studying the factors secreted by oviduct epithelial cells.     

Cytoskeleton in preimplantation mouse development

This paper reviews the constituents of the cytoskeleton in the cells of the preimplantation mouse embryo and how they change as the development proceeds. The cytoskeleton can be divided into two distinct groups, that in the cytosplasm and that associated with the membrane. The first and better-known group contains microfilaments, microtubules and intermediate filaments, the second such components of the cell and nuclear membrane as spectrin-like protein and nuclear lamin. The filamentous components of the cytoplasmic cytoskeleton adhere to the nuclear and cell membrane at attachment points where specific proteins such as vinculin may mediate the interaction. Each cell of the early embryo has all of these components, but their morphological organization and molecular constitution alter as the embryo develops. These modifications are especially pronounced when the cleavage-stage embryo compacts and when the blastocysts forms and differentiates. These events represent the most critical stages of morphogenesis and cytodifferentiation in the preimplantation embryo. The cytoskeleton may thus have an important role in the control of the early mammalian development.     

To be or not to be--determinants of embryonic survival following heat shock

Elevated temperature can reduce developmental competence of the preimplantation embryo. Whether an embryo survives elevated temperature depends on its genotype, stage of development, exposure to regulatory molecules and redox status. Following fertilization, the embryo is very sensitive to heat shock. By Days 4-5 after insemination, however, the embryo has acquired increased resistance to elevated temperature. One system that may potentiate embryonic survival at later stages of embryonic development is the apoptosis response-inhibition of apoptosis responses at Day 4 exacerbated effects of heat shock on development. Embryo responses to heat shock at Days 4-5 also depend upon genotype because Bos indicus embryos are more resistant than embryos from non-adapted B. taurus. Some experiments (although not all) indicate that survival following heat shock can be increased by reducing oxygen tension, suggesting involvement of reactive oxygen species or hypoxia-induced factors. Embryonic responses to heat shock are also affected by regulatory molecules that act to modify cellular physiology and improve cell survival. The best characterized of these is insulin-like growth factor-1 (IGF-1). Actions of IGF-1 to allow development following heat shock are independent of its anti-apoptotic actions because inhibition of the phosphatidylinositol-3 kinase pathway through which IGF-1 blocks apoptosis does not prevent thermoprotective effects of IGF-1 on development. Identification of specific determinants of embryonic survival creates the opportunity for new strategies to improve pregnancy rates in animals exposed to heat stress. Many environmental perturbations activate similar cellular responses. Therefore, molecular and cellular systems that improve embryonic survival to heat shock may confer protection from other embryotoxic conditions.     

Rethinking in vitro embryo culture: new developments in culture platforms and potential to improve assisted reproductive technologies

The preponderance of research toward improving embryo development in vitro has focused on manipulation of the chemical soluble environment, including altering basic salt composition, energy substrate concentration, amino acid makeup, and the effect of various growth factors or addition or subtraction of other supplements. In contrast, relatively little work has been done examining the physical requirements of preimplantation embryos and the role culture platforms or devices can play in influencing embryo development within the laboratory. The goal of this review is not to reevaluate the soluble composition of past and current embryo culture media, but rather to consider how other controlled and precise factors such as time, space, mechanical interactions, gradient diffusions, cell movement, and surface interactions might influence embryo development. Novel culture platforms are being developed as a result of interdisciplinary collaborations between biologists and biomedical, material, chemical, and mechanical engineers. These approaches are looking beyond the soluble media composition and examining issues such as media volume and embryo spacing. Furthermore, methods that permit precise and regulated dynamic embryo culture with fluid flow and embryo movement are now available, and novel culture surfaces are being developed and tested. While several factors remain to be investigated to optimize the efficiency of embryo production, manipulation of the embryo culture microenvironment through novel devices and platforms may offer a pathway toward improving embryo development within the laboratory of the future.     

Serotonin localization and its functional significance during mouse preimplantation embryo development

Serotonin is a neurotransmitter functioning also as a hormone and growth factor. To further investigate the biological role of serotonin during embryo development, we analysed serotonin localization as well as the expression of specific serotonin 5-HT1D receptor mRNA in mouse oocytes and preimplantation embryos. The functional significance of serotonin during the preimplantation period was examined by studying the effects of serotonin on mouse embryo development. Embryo exposure to serotonin (1 microM) highly significantly reduced the mean cell number, whereas lower concentrations of serotonin (0.1 microM and 0.01 microM) had no significant effects on embryo cell numbers. In all serotonin-treated groups a significant increase in the number of embryos with apoptotic and secondary necrotic nuclei was observed. Expression of serotonin 5-HT1D receptor mRNA in mouse oocytes and preimplantation embryos was confirmed by in situ hybridization showing a clearly distinct punctate signal. Immunocytochemistry results revealed the localization of serotonin in oocytes and embryos to the blastocyst stage as diffuse punctate cytoplasmic labelling. It appears that endogenous and/or exogenous serotonin in preimplantation embryos could be involved in complex autocrine/paracrine regulations of embryo development and embryo-maternal interactions.     

The role of nutrients, peptide growth factors and co-culture cells in development of preimplantation embryos in vitro

Our knowledge of the control of preimplantation embryo development and growth is deficient in many aspects as is evidenced by the great difficulty there is in growing embryos of many species in vitro while maintaining viability. This review discusses recent findings on the roles of nutrients, peptide growth factors and co-culture cells in embryo growth and development in vitro.     

未性成熟雌性小鼠孕前砷暴露导致植入前胚胎体外发育阻滞

目前研究发现妊娠期环境砷暴露可以导致其后代发育异常如不孕不育、流产、早产、胎儿生长受限、子代先天畸形及性别比例失调等生殖健康问题,而对孕前砷暴露对植入前胚胎发育的影响的研究还不充分.我们选用3-5周龄雌性未性成熟小鼠,按8mg/Kg亚砷酸钠（NaAsO2）剂量隔日腹腔注射一次,共注射8次.结果显示：孕前砷暴露导致小鼠排卵能力明显下降,植入前胚胎大部分阻滞在1-2细胞期.同时发现这些阻滞的胚胎活性氧（ROS）水平明显升高,细胞色素C明显释放,细胞凋亡率明显升高.这些结果说明孕前砷暴露十分危害随后植入前胚胎的发育,这也预示着孕前砷暴露将有可能导致育龄妇女受孕困难.     

Coats of preimplantation mammalian embryos as a target of reproductive technologies

The structure and function of the mammalian oocyte and preimplantation embryo coverings are described in this review. The integrity of embryonic coverings is the main prerequisite for the success of such technology as preimplantation embryo freezing and, especially, for successful rederivation. On the other hand, results of in vitro fertilization and, sometimes, the results of embryo freezing are improved after perforation of the oocyte/embryonic coverings. Modern reproductive technologies focusing on oocyte/embryonic coverings, such as preimplantation embryo freezing/cryopreservation, in vitro fertilization, intracytoplasmic sperm injection, assisted hatching, immunocontraception, and rederivation, are reviewed. Application of these technologies to different mammalian species is discussed with a special emphasis on the oocytes/preimplantation embryos coverings.     

The culture of zygotes to the blastocyst stage changes the postnatal expression of an epigentically labile allele, agouti viable yellow, in mice

Restricting the growth of the embryo can cause adverse whole-of-life changes in an organism's homeostasis. Such adverse long-term consequences may occur even when growth restriction occurs only during the preimplantation period. The molecular basis for these long-term effects has not been defined, although an epigenetic mechanism is suspected. Some loci seem to be more sensitive to epigenetic perturbation than others, and the agouti viable yellow allele (A(vy)) is the best studied example of this. It has active (hypomethylated) and inactive (hypermethylated) epialleles. This study used the A(vy) model to show that growth restriction of preimplantation embryos, as provided by culture of zygotes, induced persistent epigenetic changes that resulted in altered postnatal phenotype. C57BL/6 A(vy)/a males were mated to ovulation-induced FVB/N females, and then either zygotes were collected and cultured for 96 h and the resulting blastocysts were transferred to pseudopregnant recipient females, blastocysts were collected from females and transferred without embryo culture, or pregnancy was allowed to proceed after mating without intervention. Culture was in a commercial human in vitro fertilization media. The proportion of pups expressing the active (hypomethylated) epiallele and yellow coat was significantly higher following zygote culture compared to embryos that were transferred without culture (P = 0.014) or natural matings (P < 0.001). There was no difference in expression of the active epiallele in pups resulting from embryo transfer (without culture) compared to natural matings. These results show for the first time that the preimplantation embryo's growth environment can affect the postnatal expression of a defined epigenetically sensitive allele.