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.     

Biology of LPA in health and disease

The functions of lysophosphatidic acid (LPA) can be broadly divided into two classes: (1) physiological and (2) pathological roles. The role of LPA in embryonic development can be seen as early as oocyte formation. It continues in postnatal homeostasis, through its ability to impart a level of protection from both stress and local injury, by regulating cellular proliferation, apoptosis, and the reorganization of cytoskeletal fibers. LPA may function as a double-edged sword. While it helps maintain homeostasis against stress and insult, it may also augment the development and spread of pathological processes, including cancers.     

Stress tolerance of misfolded carboxypeptidase Y requires maintenance of protein trafficking and degradative pathways

The accumulation of aberrantly folded proteins can lead to cell dysfunction and death. Currently, the mechanisms of toxicity and cellular defenses against their effects remain incompletely understood. In the endoplasmic reticulum (ER), stress caused by misfolded proteins activates the unfolded protein response (UPR). The UPR is an ER-to-nucleus signal transduction pathway that regulates a wide variety of target genes to maintain cellular homeostasis. We studied the effects of ER stress in budding yeast through expression of the well-characterized misfolded protein, CPY*. By challenging cells within their physiological limits to resist stress, we show that the UPR is required to maintain essential functions including protein translocation, glycosylation, degradation, and transport. Under stress, the ER-associated degradation (ERAD) pathway for misfolded proteins is saturable. To maintain homeostasis, an "overflow" pathway dependent on the UPR transports excess substrate to the vacuole for turnover. The importance of this pathway was revealed through mutant strains compromised in the vesicular trafficking of excess CPY*. Expression of CPY* at levels tolerated by wild-type cells was toxic to these strains despite retaining the ability to activate the UPR.     

A role of trophoblastic cells in regulation of mouse blastocyst survival in vitro after microinjection and osmotic stress

We have evaluated the morphology of the mouse preimplantation embryos at developmental stages from morula to late blastocyst after two different impacts: microinjection of modified Witten’s medium and osmotic stress in physiological osmolarity (310 mOsM), in 5% glucose (560 mOsM) at high concentration of NaCl (614 mOsM). Results of our research showed that these stresses caused similar changes in embryo morphology: volume was reduced followed by its recovery in culture medium (osmolality was less than a physiological value, 260 mOsM). The ability of embryos to recover the volume and morphology up to the initial level depends on a stage of embryo development and consequently competence of TB cells. In this study it was revealed that a key role in regulation of volume homeostasis after microinjection and after short-time (30–60 min) osmotic stress belongs to TB cells. Both physical effects induce the further embryo development in vitro up to the formation of primary colonies of embryonic and trophoblastic cells. These data could be used to develop the morphological criteria for a prediction of blastocyst-stage embryonic implantation potential.     

植物HKT蛋白耐盐机制研究进展

盐害是限制植物生长发育的重要环境因素, 对植物造成渗透胁迫和离子毒害。维持细胞及整株水平的Na⁺/K⁺平衡是植物重要的耐盐机制。目前, 已报道的高亲和性钾离子转运蛋白(HKT)具有钠、钾离子转运特性, 在植物体钠、钾离子长距离运输及分配过程中发挥重要作用。该文重点总结了淡土植物和盐土植物HKT蛋白的结构、功能及耐盐机理, 并对其在植物耐盐改良育种中的前景做出了展望。     

The control of histone methylation and gene expression by oxidative stress, hypoxia, and metals

The harmful consequences of carcinogenic metals, such as nickel, arsenic, and chromium, are thought to be in part due to their ability to induce oxidative stress. The ubiquity of oxidative stress in biological systems has made it a fairly obvious culprit in causing cellular damage and/or development of disease. However, the full extent of oxidative stress-induced damage is not limited to its direct effects on cellular components, such as lipids, proteins, and DNA, but may extend to its ability to alter gene expression. Gene expression regulation is an important component of cellular and/or tissue homeostasis, and its alteration can have detrimental consequences. Therefore, a growing amount of interest is being paid to understanding how oxidative stress can influence gene expression. Oxidative stress-induced epigenetic dysregulation in the form of posttranslational histone modifications, in particular, is a popular topic of research. This review will therefore primarily focus on discussing the role of oxidative stress and hypoxia on histone methylation and/or gene expression alterations. The sources of oxidative stress discussed here are carcinogenic metals, such as, nickel, arsenic, and chromium.     

Membrane transport, sensing and signaling in plant adaptation to environmental stress

Plants are generally well adapted to a wide range of environmental conditions. Even though they have notably prospered in our planet, stressful conditions such as salinity, drought and cold or heat, which are increasingly being observed worldwide in the context of the ongoing climate changes, limit their growth and productivity. Behind the remarkable ability of plants to cope with these stresses and still thrive, sophisticated and efficient mechanisms to re-establish and maintain ion and cellular homeostasis are involved. Among the plant arsenal to maintain homeostasis are efficient stress sensing and signaling mechanisms, plant cell detoxification systems, compatible solute and osmoprotectant accumulation and a vital rearrangement of solute transport and compartmentation. The key role of solute transport systems and signaling proteins in cellular homeostasis is addressed in the present work. The full understanding of the plant cell complex defense mechanisms under stress may allow for the engineering of more tolerant plants or the optimization of cultivation practices to improve yield and productivity, which is crucial at the present time as food resources are progressively scarce.     

Metal ion resistance in fungi: molecular mechanisms and their regulated expression

One stress response in cells is the ability to survive in an environment containing excessive concentrations of metal ions. This paper reviews current knowledge about cellular and molecular mechanisms involved in the response and adaptation of various fungal species to metal stress. Most cells contain a repertoire of mechanisms to maintain metal homeostasis and prevent metal toxicity. Roles played by glutathione, related (gamma-EC)nG peptides, metallothionein-like polypeptides, and sulfide ions are discussed. In response to cellular metal stress, the biosynthesis of some of these molecules are metalloregulated via intracellular metal sensors. The identify of the metal sensors and the role of metal ions in the regulation of biosynthesis of metallothionein and (gamma-EC)nG peptides are subjects of much current attention and are discussed herein.     

Myosin Vb Mediated Plasma Membrane Homeostasis Regulates Peridermal Cell Size and Maintains Tissue Homeostasis in the Zebrafish Epidermis

The epidermis is a stratified epithelium, which forms a barrier to maintain the internal milieu in metazoans. Being the outermost tissue, growth of the epidermis has to be strictly coordinated with the growth of the embryo. The key parameters that determine tissue growth are cell number and cell size. So far, it has remained unclear how the size of epidermal cells is maintained and whether it contributes towards epidermal homeostasis. We have used genetic analysis in combination with cellular imaging to show that zebrafish goosepimples/myosin Vb regulates plasma membrane homeostasis and is involved in maintenance of cell size in the periderm, the outermost epidermal layer. The decrease in peridermal cell size in Myosin Vb deficient embryos is compensated by an increase in cell number whereas decrease in cell number results in the expansion of peridermal cells, which requires myosin Vb (myoVb) function. Inhibition of cell proliferation as well as cell size expansion results in increased lethality in larval stages suggesting that this two-way compensatory mechanism is essential for growing larvae. Our analyses unravel the importance of Myosin Vb dependent cell size regulation in epidermal homeostasis and demonstrate that the epidermis has the ability to maintain a dynamic balance between cell size and cell number.     

Endoplasmic reticulum stress and lipids in health and diseases

The endoplasmic reticulum (ER) is a complex and dynamic organelle that regulates many cellular pathways, including protein synthesis, protein quality control, and lipid synthesis. When one or multiple ER roles are dysregulated and saturated, the ER enters a stress state, which, in turn, activates the highly conserved unfolded protein response (UPR). By sensing the accumulation of unfolded proteins or lipid bilayer stress (LBS) at the ER, the UPR triggers pathways to restore ER homeostasis and eventually induces apoptosis if the stress remains unresolved. In recent years, it has emerged that the UPR works intimately with other cellular pathways to maintain lipid homeostasis at the ER, and so does at cellular levels. Lipid distribution, along with lipid anabolism and catabolism, are tightly regulated, in part, by the ER. Dysfunctional and overwhelmed lipid-related pathways, independently or in combination with ER stress, can have reciprocal effects on other cellular functions, contributing to the development of diseases. In this review, we summarize the current understanding of the UPR in response to proteotoxic stress and LBS and the breadth of the functions mitigated by the UPR in different tissues and in the context of diseases.     

ATM at the crossroads of reactive oxygen species and autophagy

Reactive oxygen species (ROS) are generally small, short-lived and highly reactive molecules, initially thought to be a pathological role in the cell. A growing amount of evidence in recent years argues for ROS functioning as a signaling intermediate to facilitate cellular adaptation in response to pathophysiological stress through the regulation of autophagy. Autophagy is an essential cellular process that plays a crucial role in recycling cellular components and damaged organelles to eliminate sources of ROS in response to various stress conditions. A large number of studies have shown that DNA damage response (DDR) transducer ataxia-telangiectasia mutated (ATM) protein can also be activated by ROS, and its downstream signaling pathway is involved in autophagy regulation. This review aims at providing novel insight into the regulatory mechanism of ATM activated by ROS and its molecular basis for inducing autophagy, and revealing a new function that ATM can not only maintain genome homeostasis in the nucleus, but also as a ROS sensor trigger autophagy to maintain cellular homeostasis in the cytoplasm.     

翻译后修饰对转录因子NF-E2相关因子2功能的调控

抗氧化反应组件（AREs）普遍存在于编码抗氧化和/或解毒酶基因的启动子区域,为这些基因的转录启动所必需;而这些基因的表达对维持细胞内氧化还原稳态,抵抗活性氧类（ROS）引起的细胞损伤发挥重要作用。转录因子NF E2相关因子2(nuclear factor erythroid 2 related factor 2, NRF2)作为抗氧化反应中的关键转录因子,可以与ARE结合,启动其下游靶基因,在氧化应激及亲电子剂应激中发挥重要的调控作用,广泛参与炎症、增殖、凋亡、细胞分化、组织再生和代谢等过程;因此,激活NRF2有望成为治疗肿瘤及其他与氧化、炎症相关疾病的新策略。蛋白质的翻译后修饰,对蛋白质空间构象、稳定性及其与其他蛋白质间相互作用具有重要作用。因此,探究NRF2的翻译后修饰如磷酸化、乙酰化和泛素化的修饰过程等,对深入了解NRF2的功能及调控机制至关重要,并与某些疾病的发生发展密切相关。本文对近年来翻译后修饰对NRF2的活性及功能的调控进行综述。     

益生菌冷冻干燥高活性保护机制研究进展

摄取足量益生菌有助于维持肠道微生物群落的稳态,对维持人体肠道健康具有重要意义。然而,在工业化应用中,益生菌抗逆能力较弱且对储存条件要求高,导致益生菌产品对运输和活性维持条件要求较高,这些产业需求对高活力益生菌的制备工艺提出了挑战。干燥处理常应用于保持益生菌活性和稳定性,其中冷冻干燥技术应用最广泛,但冻干过程中益生菌会受到各类环境压力的刺激,引起细胞损伤甚至死亡。因此,可以显著提高益生菌存活率的冻干保护剂成为目前益生菌工业应用的研究热点。本文从益生菌常用及新发现的冻干保护剂种类及其作用机制进行了系统归纳,对菌株冻干后细胞存活率的影响因素进行全面综述,并对冻干保护剂研究方向进行了展望,旨在为高活力益生菌冻干菌粉的研制提供理论支持。     

Adverse impact of heat stress on embryo production: causes and strategies for mitigation

The production of embryos by superovulation is often reduced in periods of heat stress. The associated reduction in the number of transferable embryos is due to reduced superovulatory response, lower fertilization rate, and reduced embryo quality. There are also reports that success of in vitro fertilization procedures is reduced during warm periods of the year. Heat stress can compromise the reproductive events required for embryo production by decreasing expression of estrus behavior, altering follicular development, compromising oocyte competence, and inhibiting embryonic development. While preventing effects of heat stress can be difficult, several strategies exist to improve embryo production during heat stress. Among these strategies are changing animal housing to reduce the magnitude of heat stress, utilization of cows with increased resistance to heat stress (i.e., cows with lower milk yield or from thermally-adapted breeds), and manipulation of physiological and cellular function to overcome deleterious consequences of heat stress. Effects of heat stress on estrus behavior can be mitigated by use of estrus detection aids or utilization of ovulation synchronization treatments to allow timed embryo transfer. There is some evidence that embryonic survival can be improved by antioxidant administration and that pharmacological treatments can be developed that reduce the degree of hyperthermia experienced by cows exposed to heat stress.     

Reactive oxygen species regulation of autophagy in cancer: Implications for cancer treatment

Reactive oxygen species (ROS) are important in regulating normal cellular processes, but deregulated ROS contribute to the development of various human diseases including cancers. Autophagy is one of the first lines of defense against oxidative stress damage. The autophagy pathway can be induced and upregulated in response to intracellular ROS or extracellular oxidative stress. This leads to selective lysosomal self-digestion of intracellular components to maintain cellular homeostasis. Hence, autophagy is the survival pathway, conferring stress adaptation and promoting viability under oxidative stress. However, increasing evidence has demonstrated that autophagy can also lead to cell death under oxidative stress conditions. In addition, altered autophagic signaling pathways that lead to decreased autophagy are frequently found in many human cancers. This review discusses the advances in understanding of the mechanisms of ROS-induced autophagy and how this process relates to tumorigenesis and cancer therapy.     

Heat Shock Protein Reports on Proteome Stress

Proper regulation of protein homeostasis (proteostasis) is essential to maintain cellular fitness. Proteome stress causes imbalance of the proteostasis, leading to various diseases represented by neurodegenerative diseases, cancers, and metabolic disorders. The biosensor community recently embarked on the development of proteome stress sensors to report on the integrity of proteostasis in live cells. While most of these sensors are based on metastable mutants of specific client proteins, a recent sensor takes advantage of the specific association of heat shock protein 27 with protein aggregates and exhibits a diffusive to punctate fluorescent change in cells that are subjected to stress conditions. Thus, heat shock proteins can be also used as a family of sensors to monitor proteome stress.     

Epithelial to mesenchymal transition (EMT) of feto-maternal reproductive tissues generates inflammation: a detrimental factor for preterm birth

Human pregnancy is a delicate and complex process where multiorgan interactions between two independent systems, the mother, and her fetus, maintain pregnancy. Intercellular interactions that can define homeostasis at the various cellular level between the two systems allow uninterrupted fetal growth and development until delivery. Interactions are needed for tissue remodeling during pregnancy at both fetal and maternal tissue layers. One of the mechanisms that help tissue remodeling is via cellular transitions where epithelial cells undergo a cyclic transition from epithelial to mesenchymal (EMT) and back from mesenchymal to epithelial (MET). Two major pregnancy-associated tissue systems that use EMT, and MET are the fetal membrane (amniochorion) amnion epithelial layer and cervical epithelial cells and will be reviewed here. EMT is often associated with localized inflammation, and it is a well-balanced process to facilitate tissue remodeling. Cyclic transition processes are important because a terminal state or the static state of EMT can cause accumulation of proinflammatory mesenchymal cells in the matrix regions of these tissues and increase localized inflammation that can cause tissue damage. Interactions that determine homeostasis are often controlled by both endocrine and paracrine mediators. Pregnancy maintenance hormone progesterone and its receptors are critical for maintaining the balance between EMT and MET. Increased intrauterine oxidative stress at term can force a static (terminal) EMT and increase inflammation that are physiologic processes that destabilize homeostasis that maintain pregnancy to promote labor and delivery of the fetus. However, conditions that can produce an untimely increase in EMT and inflammation can be pathologic. These tissue damages are often associated with adverse pregnancy complications such as preterm prelabor rupture of the membranes (pPROM) and spontaneous preterm birth (PTB). Therefore, an understanding of the biomolecular processes that maintain cyclic EMT-MET is critical to reducing the risk of pPROM and PTB. Extracellular vesicles (exosomes of 40-160 nm) that can carry various cargo are involved in cellular transitions as paracrine mediators. Exosomes can carry a variety of biomolecules as cargo. Studies specifically using exosomes from cells undergone EMT can carry a pro-inflammatory cargo and in a paracrine fashion can modify the neighboring tissue environment to cause enhancement of uterine inflammation.