Mature Embryos Research Articles

Epigenetic memory of temperature sensed during somatic embryo maturation in 2-year-old maritime pine trees

Abstract Embryogenesis is a brief but potentially critical phase in the tree life cycle for adaptive phenotypic plasticity. Using somatic embryogenesis in maritime pine (Pinus pinaster Ait.), we found that temperature during the maturation phase affects embryo development and post-embryonic tree growth for up to three years. We examined whether this somatic stress memory could stem from temperature- and/or development-induced changes in DNA methylation. For this, we developed a 200 Mb custom sequence capture bisulfite analysis of genes and promoters to identify differentially methylated cytosines (DMCs) between temperature treatments (18, 23, and 28°C) and developmental stages (immature and cotyledonary embryos, shoot apical meristem of 2-year-old plants) and investigate if these differences can be mitotically transmitted from embryonic to post-embryonic development (epigenetic memory). We revealed a high prevalence of temperature-induced DMCs in genes (8-14%) compared to promoters (less than 1%) in all 3 cytosine contexts. Developmental DMCs showed a comparable pattern but only in the CG context and with a strong trend towards hypomethylation, particularly in the promoters. A high percentage of DMCs induced by developmental transitions were found memorized in genes (up to 45-50%) and promoters (up to 90%). In contrast, temperature-induced memory was lower and confined to genes after both embryonic (up to 14%) and post-embryonic development (up to 8%). Using stringent criteria, we identified ten genes involved in defense responses and adaptation, embryo development, and chromatin regulation that are candidates for the establishment of a persistent epigenetic memory of temperature sensed during embryo maturation in maritime pine. Here, we provide evidence that DNA methylation marks established during the embryonic phase are transmitted to the post-embryonic plant development phase.

LED lighting affects maturation, conversion and metabolic profile of somatic embryos derived from Kelussia odoratissima Mozaff

LED lighting affects maturation, conversion and metabolic profile of somatic embryos derived from Kelussia odoratissima Mozaff

Histological Analysis of Somatic Embryogenesis from Immature Zygotic Embryo of Wild Banana Musa acuminata ssp. malaccensis

Somatic embryogenesis, a crucial plant regeneration method, has become indispensable for crop improvement, particularly for species reliant on somatic cell manipulation techniques. Optimization of this process necessitates an understanding of the developmental stages involved. This study investigates the histological aspects of somatic embryogenesis in Musa acuminata ssp. malaccensis derived from immature zygotic embryos. Through detailed histological analysis, we aimed to elucidate the morphological changes and cellular organization occurring during the various stages of somatic embryogenesis, from induction, culture proliferation, and somatic embryo development to plantlet conversion. The initial stages of embryogenesis, characterized by nodules, were primarily composed of meristematic cells with high cell division activity. These cells contained tetrad-like structures that could develop into distinct two- and four-celled proembryoids or proembryogenic aggregates. Our histo-anatomical analysis revealed that embryogenic cultures proliferated through multiple pathways simultaneously: somatic embryo budding, proembryo formation, and pro-embryonic mass formation from both internal and peripheral cells. At the stage of somatic embryo development, embryos with a well-defined protoderm layer, containing cells with prominent nuclei and dense cytoplasm, potentially regenerate into plantlets. Furthermore, histological examination revealed the presence of procambium within mature somatic embryos, which subsequently developed into the vascular system of the complete plantlet

Induction and maturation of somatic embryogenesis in mangaba tree a multipurpose Apocynaceae

This study reported the first results of in vitro somatic embryogenesis induction in Hancornia speciosa Gomes (mangaba tree, Apocynaceae). To induce callus, the TC accession leaf and nodal segments were cultivated in culture medium I (Murashige and Skoog; MS salts, putrescine, 45 µM 2,4-dichlorophenoxyacetic acid; 2,4-D and 22.19 µM 6-benzylaminopurine; BA). For the next stage (multiplication), the callus masses were sub-cultured into a culture medium II (MS salts, 22.62 µM 2,4-D and 22.19 µM BA). After 90 days, embryogenic calluses were inoculated to somatic embryo maturation medium culture III (MS salts, polyethylene glycol; PEG (0 and 2%) and BA (44.39 and 66.58 µM). Pro-embryos and somatic embryos in the maturation stage were assessed after 60 days. The rstatix package from R software with non-parametric tests (p < 0.05) were used to analysis data of experiments I and II. The Tukey’s test (p < 0.05) was performed on the data of experiment III. To induce and multiply embryogenic callus, 45 µM 2,4-D and 22.19 µM BA were efficient. More pro- and somatic embryo development were seen in the nodal explant cultured in the presence of 44.39 and 66.58 µM BA and 2% PEG. Putrescine does not promote the embryogenic masses of callus derived from leaf explants in the TC accession. Keywords: Hancornia speciosa Gomes, micropropagation, somatic embryo.

A transcriptome atlas of zygotic and somatic embryogenesis in Norway spruce.

Somatic embryogenesis (SE) is a powerful model system for studying embryo development and an important method for scaling up availability of elite and climate-adapted genetic material of Norway spruce (Picea abies L. Karst). However, there are several steps during the development of the somatic embryo (Sem) that are suboptimal compared to zygotic embryo (Zem) development. These differences are poorly understood and result in substantial yield losses during plant production, which limits cost-effective large-scale production of SE plants. This study presents a comprehensive data resource profiling gene expression during zygotic and somatic embryo development to support studies aiming to advance understanding of gene regulatory programmes controlling embryo development. Transcriptome expression patterns were analysed during zygotic embryogenesis (ZE) in Norway spruce, including separated samples of the female gametophytes and Zem, and at multiple stages during SE. Expression data from eight developmental stages of SE, starting with pro-embryogenic masses (PEMs) up until germination, revealed extensive modulation of the transcriptome between the early and mid-stage maturing embryos and at the transition of desiccated embryos to germination. Comparative analysis of gene expression changes during ZE and SE identified differences in the pattern of gene expression changes and functional enrichment of these provided insight into the associated biological processes. Orthologs of transcription factors known to regulate embryo development in angiosperms were differentially regulated during Zem and Sem development and in the different zygotic embryo tissues, providing clues to the differences in development observed between Zem and Sem. This resource represents the most comprehensive dataset available for exploring embryo development in conifers.

Sound and vibration control crocodile hatching

Abstract The birth of a baby or the hatching of an egg are moments when the risk of predation is particularly high. In oviparous species where clutches contain many eggs, one strategy for limiting predation is based on mechanisms that synchronise hatching, which reduces the individual risk of being targeted and may allow hatchlings to emerge under parental protection. These mechanisms involve communication signals between eggs and between eggs and parents. While previous studies in various species have shown the importance of sound and vibration signals in these exchanges, how embryos integrate this information remains poorly understood. Here we show that crocodile embryos respond differently to calls emitted by siblings (hatching calls) and to vibrations mimicking parental intervention (rubbing and scratching the shell) or the presence of a predator, suggesting that these two stimuli carry different information. Through playback experiments, we confirm that hatching calls elicit vocal responses and synchronous hatching in mature embryos, while embryos hatch earlier when they perceive vibrations. Our study underlines that the control of hatching by external factors can rely on differential apprehension of multiple sensory inputs by embryos.

Knockout mutation in TaD27 enhances number of productive tillers in hexaploid wheat.

Recent advances allow the deployment of cluster regularly interspaced short palindromic repeats (CRISPR)-associated endonucleases (Cas) system for the targeted mutagenesis in the genome with accuracy and precision for trait improvement in crops. CRISPR-Cas systems have been extensively utilized to induce knockout or frameshift mutations in the targeted sequence of mostly negative regulating genes for wheat improvement. However, most of the reported work has been done in non-commercial varieties of wheat and introgression of edited alleles into breeding population comes with the penalty of unwanted linkage-drag. Wheat yield is controlled by various genes such as positive and negative regulators. The TaD27 gene is described as a negative regulator of shoot branching or tillering and involved in the biosynthesis of strigolactones. In this study, we developed Tad27 knockout mutant lines of an elite wheat cultivar that showed a twofold increase in the number of tillers and 1.8-fold increase in the number of grains per plant. Subsequently, enhancing the grain yield without any morphological penalty in the architecture of the plants. The co-transformation of regeneration enhancing growth regulator, Growth Regulating Factor 4 (GRF4) and its cofactor GRF-Interacting Factor 1 (GIF1), under single T-DNA cassette improved the regeneration efficiency up to 6% of transgenic events from mature embryos of wheat. Our results indicate that the CRISPR-mediated targeted mutagenesis confers the potential to knockout yield-related negative regulators in elite cultivars of wheat that can substantially enhance grain yield per plant and this strategy can be harnessed for the improvement of future wheat.

Gene expression levels in cumulus cells are correlated with developmental competence of bovine oocytes

The generation of mammalian embryos by in vitro culture is hampered by the failure of many of the embryos to develop to the blastocyst stage. This problem occurs even when cumulus–oocyte complexes (COCs) with good morphology are visually selected and used for culture. Because cumulus cells are important for oocyte maturation and subsequent embryo development, here we compared gene expression patterns in cumulus cells of COCs that developed in vitro to the blastocyst stage with those of COCs that failed to develop. Cumulus cells were aspirated from bovine COCs selected for in vitro culture. Oocyte developmental competence was evaluated by screening for cleavage and development to the blastocyst stage. The collected cumulus cells were used to quantify mRNA levels of FSH receptor (FSHR), insulin-like growth factor-1 receptor (IGF-1R), anti-Müllerian hormone (AMH), AMH receptor II (AMHRII), epidermal growth factor receptor (EGFR), estrogen receptor β (ERβ), B cell lymphoma/leukemia-2 associated X (Bax), and cysteine-aspartic acid protease-3 (Caspase-3). We found that the expression levels of FSHR, IGF-1R, AMH, and EGFR were higher in cumulus cells from COCs that developed to blastocysts as compared with those that failed to develop, whereas expression levels of Bax and Caspase-3 were lower in cumulus cells of COCs that matured to the blastocyst stage. Positive correlations were found between FSHR and IGF-1R expression (r = 0.59) and between ERβ and EGFR expression (r = 0.43) in cumulus cells from COCs that developed to the blastocyst stage. Our findings indicate that gene expression levels in cumulus cells are correlated with the developmental competence of bovine oocytes. Measurement of gene expression in cumulus cells therefore offers a non-invasive means of predicting oocyte developmental competence.

New Insights on In Vitro Maturation of Oocytes for Fertility Preservation

In the last decade, the evolution of oncofertility has sparked a resurgence of interest in in vitro maturation (IVM) due to its suitability in certain oncological scenarios where controlled ovarian hyperstimulation may not be feasible. The retrieval of immature cumulus–oocyte complexes from small antral follicles, regardless of the menstrual cycle phase, presents a swift opportunity to vitrify mature oocytes or embryos post-IVM in urgent situations or when stimulation is not advisable. Harvesting immature cumulus–oocyte complexes and immature oocytes can be achieved transvaginally or directly in the laboratory from extracorporeal ovarian tissue. Although IVM has transitioned from an experimental status due to safety validations, it relies on the intricate process of oocyte maturation. Despite successful live births resulting from IVM in fertility preservation contexts, the comparatively lower developmental competence of in vitro matured oocytes highlights the necessity to enhance IVM culture systems. Recent advancements in IVM systems hold promise in bolstering oocyte competence post-IVM, thereby narrowing the gap between IVM and outcomes from ovarian stimulation. Additionally, for optimizing the chances of conception in cancer survivors, the combination of IVM and ovarian tissue cryopreservation stands as the favored choice when ovarian stimulation is unfeasible.

Determination of phosphinothricin and paromomycin selective concentrations for obtaining transgenic spelt plants

Aim. To determine the selective concentrations of phosphinothricin and paromomycin for the selection of transgenic plants of spelt wheat. Methods. Shoot apical meristem culture, mature embryo culture, Agrobacterium-mediated genetic transformation. Results. Isolation and cultivation of shoot apical meristems of seedlings from three spelt genotypes and mature embryos from three other genotypes were carried out. A high frequency (from 80 to 100 %) of callus induction from explants was observed. It was shown that the addition of 5 mg/l of phosphinothricin or 100 mg/l of paromomycin to the culture medium almost completely inhibited plant regeneration compared to the control. After Agrobacterium-mediated genetic transformation of calli with a vector containing the phosphinothricin-N-acetyltransferase gene, regeneration of spelt shoots for one genotype was observed on a selective medium with 5 mg/l phosphinothricin. Conclusions. The selective concentrations of herbicide and antibiotic for obtaining transgenic spelt wheat plants with the corresponding marker genes are 5 mg/l for phosphinothricin and 100 mg/l for paromomycin.

The efficacy of orally administered L-carnitine in alleviating ovarian dysfunctions has laid the foundation for targeted in vivo use: a study employing self-control and propensity score matching.

This study aimed to evaluate the effectiveness of oral L-carnitine administration in patients after treatment failure to lay the groundwork for targeted in vivo use. A total of 515 In Vitro Fertilization (IVF) patients undergoing subsequent cycles were included after applying exclusion criteria. They were divided into a control group of 362 patients and a study group of 153 patients who received oral L-carnitine until oocyte retrieval.140 patients were matched according to maternal age, infertility duration, body mass index (BMI), day three top-quality embryos rate, by propensity score matching (PSM). The study investigated the relationship between L-carnitine treatment and in vivo oocyte maturation, normal fertilization, and subsequent embryo development. Following PSM, initial differences in BMI and Day3 top-quality embryo rate between groups were nullified, we created two comparable cohorts with highly similar characteristics. In the subsequent cycles, the study group showed significant improvements in in vivo oocyte maturation rate at retrieval (p=0.002), normal in vitro fertilization rate (p=0.003), blastocyst formation rate (p=0.003), and usable blastocyst rate compared to controls. Although there was no significant difference in the top-quality embryo rate on Day 3, the study group showed a 10% increase in the upper quartile (55.35% vs. 66.67%). The cumulative clinical pregnancy and live birth rates showed a significant improvement (59.82% vs. 68.42%,p=0.004, 47.41% vs. 59.80%, p=0.002). Furthermore, self-control analysis revealed substantial enhancements (p<0.001) in all outcome measures following L-carnitine administration, resulting in the birth of 74 healthy neonates without congenital anomalies. We theorized that daily oral intake of L-carnitine before oocyte retrieval could boost oocyte quality and embryonic development, thus improving IVF outcomes. Ongoing investigations hold the potential to offer valuable insights into the applications and mechanisms underlying the therapeutic effectiveness of L-carnitine.

The Integrated Analysis of miRNome and Degradome Sequencing Reveals the Regulatory Mechanisms of Seed Development and Oil Biosynthesis in Pecan (Carya illinoinensis).

Pecan seed oil is a valuable source of essential fatty acids and various bioactive compounds; however, the functions of microRNAs and their targets in oil biosynthesis during seed development are still unknown. Here, we found that the oil content increased rapidly in the three early stages in three cultivars, and that oleic acid was the predominant fatty acid component in the mature pecan embryos. We identified, analyzed, and validated the expression levels of miRNAs related to seed development and oil biosynthesis, as well as their potential target genes, using small RNA sequencing data from three stages (120, 135, and 150 days after flowering). During the seed development process, 365 known and 321 novel miRNAs were discovered. In total, 91 known and 181 novel miRNAs were found to be differentially expressed, and 633 target genes were further investigated. The expression trend analysis revealed that the 91 known miRNAs were classified into eight groups, approximately two-thirds of which were up-regulated, whereas most novel miRNAs were down-regulated. The qRT-PCR and degradome sequencing data were used to identify five miRNA- target pairs. Overall, our study provides valuable insights into the molecular regulation of oil biosynthesis in pecan seeds.

Novel mechanism of MicroRNA408 in callus formation from rice mature embryo.

Mature embryos are the main explants of tissue culture used in rice transgenic technology. However, the mechanism of mature embryo callus formation remains unclear. In this study, a microRNA-mediated gene regulatory network of rice calli was established using degradome sequencing. We identified a microRNA, OsmiR408, that regulates the formation of the callus derived from the mature rice embryo. OsUCLACYANIN 30 (OsUCL 30), a target gene of OsmiR408, was the most abundant cleavage mRNA in rice callus. OsUCL17 was verified as a target gene of OsmiR408 using RNA ligase-mediated 5'-RACE. In analysis of the OsmiR408 promoter reporter line and pri-miR408 transcript level, the promoter activity and transcript level of MIR408 were increased dramatically during callus formation. In phenotypic observations, OsmiR408 knockout caused severe defects in mature embryo callus formation, whereas OsmiR408 overexpression promoted callus formation. Transcriptome analysis demonstrated that OsUCLs and certain genes related to the plant hormone signal transduction and phenylpropanoid-flavonoid biosynthesis pathway had different differential expression patterns between OsmiR408 knockout and overexpression calli. Thus, OsmiR408 may regulate callus formation mainly by affecting plant hormone signal transduction and phenylpropanoid-flavonoid biosynthesis pathway. Our findings provide insight into OsmiR408/UCLs module function in callus formation.

Embryonic Genome Activation (EGA) Occurred at 1-Cell Stage of Embryonic Development in the Mud Crab, Scylla paramamosain, Revealed by RNA-Seq.

As a prerequisite for the success of embryo development, embryonic genome activation (EGA) is an important biological event in which zygotic gene products in the embryo are activated to replace maternal-derived transcripts. Although EGA has been extensively studied in a large number of vertebrates and invertebrates, there is a lack of information regarding this event in crustacean crab. In this study, the timing of EGA was confirmed by examining a transcriptomic dataset of early embryonic development, including mature oocytes and embryos through six early developmental stages, and signaling pathways associated with EGA were identified in the mud crab, S. paramamosain. The comprehensive transcriptomic data identified a total of 53,915 transcripts from these sequencing samples. Notable transcriptomic change was evident at the 1-cell stage, indicated by a 36% transcript number shift and a reduction in transcript fragment length, compared to those present in the mature oocytes. Concurrently, a substantial increase in the expression of newly transcribed transcripts was observed, with gene counts reaching 3485 at the 1-cell stage, indicative of the onset of EGA. GO functional enrichment revealed key biological processes initiated at the 1-cell stage, such as protein complex formation, protein metabolism, and various biosynthetic processes. KEGG analysis identified several critical signaling pathways activated during EGA, including the "cell cycle," "spliceosome," "RNA degradation", and "RNA polymerase", pathways. Furthermore, transcription factor families, including zinc finger, T-box, Nrf1, and Tub were predominantly enriched at the 1-cell stage, suggesting their pivotal roles in regulating embryonic development through the targeting of specific DNA sequences during the EGA process. This groundbreaking study not only addresses a significant knowledge gap regarding the developmental biology of S. paramamosain, especially for the understanding of the mechanism underlying EGA, but also provides scientific data crucial for the research on the individual synchronization of seed breeding within S. paramamosain aquaculture. Additionally, it serves as a reference basis for the study of early embryonic development in other crustacean species.

Integrated ultrasensitive metabolomics and single-cell transcriptomics identify crucial regulators of sheep oocyte maturation and early embryo development in vitro

IntroductionDevelopmental competence of oocytes matured in vitro is limited due to a lack of complete understanding of metabolism and metabolic gene expression during oocyte maturation and embryo development. Conventional metabolic analysis requires a large number of samples and is not efficiently applicable in oocytes and early embryos, thereby posing challenges in identifying key metabolites and regulating their in vitro culture system. ObjectivesTo enhance the developmental competence of sheep oocytes, this study aimed to identify and supplement essential metabolites that were deficient in the culture systems. MethodsThe metabolic characteristics of oocytes and embryos were determined using ultrasensitive metabolomics analysis on trace samples and single-cell RNA-seq. By conducting integrated analyses of metabolites in cells (oocytes and embryos) and their developmental microenvironment (follicular fluid, oviductal fluid, and in vitro culture systems), we identified key missing metabolites in the in vitro culture systems. In order to assess the impact of these key missing metabolites on oocyte development competence, we performed in vitro culture experiments. Furthermore, omics analyses were employed to elucidate the underlying mechanisms. ResultsOur findings demonstrated that betaine, carnitine and creatine were the key missing metabolites in vitro culture systems and supplementation of betaine and L-carnitine significantly improved the blastocyst formation rate (67.48% and 48.61%). Through in vitro culture experiments and omics analyses, we have discovered that L-carnitine had the potential to promote fatty acid oxidation, reduce lipid content and lipid peroxidation level, and regulate spindle morphological grade through fatty acid degradation pathway. Additionally, betaine may participate in methylation modification and osmotic pressure regulation, thereby potentially improving oocyte maturation and early embryo development in sheep. ConclusionTogether, these analyses identified key metabolites that promote ovine oocyte maturation and early embryo development, while also providing a new viewpoint to improve clinical applications such as oocyte maturation or embryo culture.

The Effect of Seminal Plasma on the Equine Endometrial Transcriptome.

The establishment of pregnancy involves a fine-tuned balance between protection and tolerance within the maternal immune system, as the female needs to accept a foreign antigen (the semi-allogenic fetus) while still being able to combat pathogens from the uterus. In the horse, the first uterine exposure to paternal antigens is during mating when sperm is introduced to the tissue and draining lymphatics of the uterus. Additionally, it has been suggested that seminal plasma and its proteins within it play an essential role in preparing the female tract for a suitable immunologic environment but this has not been confirmed in the horse. Therefore, the objective of this study was to evaluate the endometrial transcriptome following insemination either with seminal plasma or with reduced seminal plasma. We hypothesised that reduced seminal plasma would alter the endometrial transcriptome and affect transcripts relating to immunotolerance, antigen presentation and embryo growth and development. To do so, six (n = 6) mares were inseminated in a randomised switch-back design over the course of four oestrous cycles. Mares were rectally palpated and scanned via ultrasonography for the detection of a pre-ovulatory follicle (>35 mm) alongside increasing uterine oedema and relaxed cervix, and then treated with one of four treatment groups including (1) 30 mL lactated Ringers solution (LRS; NegCon), (2) 500 × 106 spermatozoa in conjunction with 30 mL seminal plasma (SP+), (3) 30 mL lactated Ringers solution (LRS; wash out) and (4) 500 × 106 spermatozoa with seminal plasma reduced via gradient centrifugation and resuspended in 30 mL LRS (SP-). Human chorionic gonadotropin (hCG) was administered to standardise the time to ovulation and endometrial biopsies were collected 7 days after insemination. RNA was isolated utilising Trizol, and RNA-Seq was performed by Novogene, with 97.79% total mapping and 40 million read depth. p value was set to <0.05. When comparing SP+ to SP-, 158 differentially expressed genes (DEGs) were identified. Biological processes impacted included antigen processing and regulation, cholesterol synthesis, and immune/inflammatory response. Gene ontology (GO) enrichment analysis using DAVID v6.8 revealed that many of these DEGs were involved in biological process such as antigen presentation (HLA-DM beta chain, HLA-DRB, HLA-DQA and RASGRP1), immune cell signalling (CXCL9, CXCL1, DEFB1 and MIP-2B), embryo growth and development (INHA, KLF2, RDH10, LAMA3 and SLC34A2) and embryo metabolism (ABCA1, ABCA2, APOA1, LDL, INSR, IGFBP2 and IGFBP3). Overall, reduction of seminal plasma from the insemination dose impacted the endometrial transcriptome at the time of early embryonic exposure to the uterine environment. Further work is justified to evaluate these alterations impact on embryo maturation, placental development, pregnancy outcome and development of offspring.

Melatonin partially rescues defects induced by tranexamic acid exposure during oocyte maturation in mice.

Tranexamic acid (TXA) is widely used among young women because of its ability to whiten skin and treat menorrhagia. Nevertheless, its potential effects on oocyte maturation and quality have not yet been clearly clarified. Melatonin (MT) is an endogenous hormone released by the pineal gland and believed to protect cells from oxidative stress injury. In the present study, we used an in vitro maturation model to investigate the toxicity of TXA and the protective role of MT in mouse oocytes. Compared with the control group, the TXA-exposed group had significantly lower nuclear maturation (57.72% vs. 94.08%, P < 0.001) and early embryo cleavage rates (38.18% vs. 87.66%, P < 0.001). Further study showed that spindle organization (52.56% vs. 18.77%, P < 0.01) and chromosome alignment (33.23% vs. 16.66%, P < 0.01) were also disrupted after TXA treatment. Mechanistically, we have demonstrated that TXA induced early apoptosis of oocytes (P < 0.001) by raising the level of reactive oxygen species (P < 0.001), which was consistent with an increase in mitochondrial damage (P < 0.01). Fortunately, all these effects except the spindle defect were successfully rescued by an appropriate level of MT. Collectively, our findings indicate that MT could partially reverse TXA-induced oocyte quality deterioration in mice by effectively improving mitochondrial function and reducing oxidative stress-mediated apoptosis.NEW & NOTEWORTHY Tranexamic acid is increasingly used to whiten skin, reverse dermal damages, and treat heavy menstrual bleeding in young women. However, its potential toxicity in mammalian oocytes is still unclear. Our study revealed that tranexamic acid exposure impaired the mouse oocyte quality and subsequent embryo development. Meanwhile, melatonin has been found to exert beneficial effects in reducing tranexamic acid-induced mitochondrial dysfunction and oxidative stress.

In vitro maturation using porcine follicular fluid-derived exosomes as an alternative to the conventional method

Extracellular vesicles, also known as exosomes, influence numerous cellular functions by regulating different signaling pathways. However, their role in animal reproduction remains understudied. This study aimed to evaluate the effects of porcine follicular fluid-derived exosomes (pff-Exos) on porcine oocyte in vitro maturation and parthenogenetic embryo development. We obtained pff-Exos through mixed-method ultracentrifugation and size-exclusion chromatography. Transmission electron microscopy revealed an increase in the expression of exosome markers in the first four of thirteen fractions. The number of pff-Exo was 2.2 × 106 particles per microliter. The highest maturation rate of porcine oocytes treated with pff-Exo was observed with 1.1 × 107 particles of pff-Exo in the absence of porcine follicular fluid (pFF) culture conditions. Moreover, increased expression of Gdf9 and Bmp15 was observed. The developmental rate was the highest upon treatment with 1.1 × 107 particles of pff-Exo, which increased the total cell number in blastocysts. Embryonic development to the 2-cell stage was similar between the control and pff-Exo groups; however, development to the 4-cell stage and blastocyst was significantly increased in the pff-Exo group (61.6 ± 6.08 % and 29.72 ± 1.41 %, respectively; P < 0.05) compared with that in the control group (42.0 ± 5.19 % and 18.14 ± 1.78 %, respectively). The expression levels of Oct4, Sox2, Bcl2, Elf4, and Gcn5 significantly increased at the pff-Exo 2-cell stage, whereas those of Bax, Hdac1, Hdac6, and Sirt6 decreased. Specifically, the Oct4, Sox2, Elf4, Gcn5, and Hdac6 levels remained stable in pff-Exo 4-cell embryos, whereas those of p53 and Hat1 were reduced and increased, respectively. Treatment with pffExos significantly increased H3K9 and H3K14 acetylation levels. These results demonstrate that pff-Exo affects the in vitro maturation of porcine oocytes and early embryonic development by regulating gene expression.

Ce2O3 nanoparticle synthesis, characterization, and application to callus formation and plant regeneration from mature embryo culture of wheat (Triticum aestivum L.)

Ce2O3 nanoparticle synthesis, characterization, and application to callus formation and plant regeneration from mature embryo culture of wheat (Triticum aestivum L.)

Cryopreservation of zygotic embryos derived from BBTV resistant accessions of wild banana Musa acuminata

The wild banana species Musa acuminata encompasses numerous subspecies, some of which serve as ancestors of edible bananas. Preserving these subspecies is critical for food security, especially in regions where bananas are staple crops. While cryopreservation of M. acuminata subsp. burmanicoides zygotic embryos using air dehydration have shown high success rates, this method has not been effective for other subspecies. With at least 15 subspecies displaying various morphological traits, including seed morphology, alternative cryopreservation methods warrant exploration. In a recent study, successful cryopreservation using the droplet-vitrification method was achieved for mature zygotic embryos of accession of M. acuminata subspecies tomentosa, rutilifes, and malaccensis, all of which are resistant to the Banana bunchy top virus (BBTV). Using this approach, subjecting embryos to dehydration for 20 min in PVS2 solution and employing a regeneration medium comprising MS medium supplemented with benzyladenine and thidiazuron resulted in a success rate of 77.4 % (86 % survival rate × 90 % regrowth rate) for subsp. tomentosa and 50.4 % (70 % survival rate × 72 % regrowth rate) for subsp. malaccensis. Conversely, for subsp. rutilifes, dehydration for 10 min led to a success rate of 15.6 % (30 % survival rate × 52 % regrowth rate). Subspecies emerged as the primary factor influencing embryo regrowth, suggesting the need for protocol optimizations tailored to other subspecies. These findings highlight the potential of droplet-vitrification as a long-term preservation method for certain subspecies, while underscoring the necessity for further optimization for the other subspecies of M. acuminata.