瓦氏效应——哺乳动物生殖过程中的有氧糖酵解

糖代谢是生物体赖以生存的基本生化过程之一.哺乳动物体内不同细胞对葡萄糖的利用方式不同.摄氧充足时,细胞通过氧化磷酸化在线粒体中进行有氧呼吸;缺氧的细胞则选择抑制氧化磷酸化,通过糖酵解产生乳酸.但有些细胞在有氧条件下也能进行糖酵解,从而产生大量的乳酸,这种糖酵解途径称为瓦氏效应.以前认为瓦氏效应主要存在于肿瘤细胞中,但近来发现在哺乳动物的生殖过程中也存在瓦氏效应.本文综述了哺乳动物生殖发育过程的瓦氏效应及其与一些生殖疾病的关系.     

Aerobic Glycolysis in the Brain: Warburg and Crabtree Contra Pasteur

Neurochemical Research - Information processing is onerous. Curiously, active brain tissue does not fully oxidize glucose and instead generates a local surplus of lactate, a phenomenon termed...     

A role for the Warburg effect in preimplantation embryo development: metabolic modification to support rapid cell proliferation

In this essay, we propose that embryos express a metabolic phenotype necessarily different from that of differentiated somatic cells and more like that of rapidly proliferating cancer cells. This metabolic adaptation, known as the Warburg effect, supports rapid cell proliferation. One of the hallmarks of the Warburg effect is that pyruvate is directed away from the tri-carboxylic acid cycle and metabolized to lactate, resulting in a buildup of glycolytic intermediates. Although this is a comparatively inefficient way to generate ATP, this adaptation allows the cell to meet other critical metabolic requirements, including biomass production and redox regulation. Thus, utilization of WE gives proliferating cells a selective growth advantage. This model represents a completely new understanding of embryo metabolism in the context of a broad, interconnected network of metabolic mechanisms that influence viability, versus the current dogma of carbohydrate metabolism via oxidative phosphorylation. A more complete understanding of embryo metabolism is critical to better support embryo viability in vitro, and to avoid forcing embryos to adapt to suboptimal culture conditions at a significant cost to future growth and development.     

RBM19 is essential for preimplantation development in the mouse

Background  

RNA-binding motif protein 19 (RBM19, NCBI Accession # NP_083038) is a conserved nucleolar protein containing 6 conserved RNA recognition motifs. Its biochemical function is to process rRNA for ribosome biogenesis, and it has been shown to play a role in digestive organ development in zebrafish. Here we analyzed the role of RBM19 during mouse embryonic development by generating mice containing a mutation in the Rbm19 locus via gene-trap insertion.     

The reverse Warburg Effect: Glycolysis inhibitors prevent the tumor promoting effects of caveolin-1 deficient cancer associated fibroblasts

We and others have previously identified a loss of stromal caveolin-1 (Cav-1) in cancer-associated fibroblasts (CAFs) as a powerful single independent predictor of breast cancer patient tumor recurrence, metastasis, tamoxifen-resistance, and poor clinical outcome. However, it remains unknown how loss of stromal Cav-1 mediates these effects clinically. To mechanistically address this issue, we have now generated a novel human tumor xenograft model. In this two-component system, nude mice are co-injected with i) human breast cancer cells (MDA-MB-231), and ii) stromal fibroblasts (wild-type (WT) versus Cav-1 (-/-) deficient). This allowed us to directly evaluate the effects of a Cav-1 deficiency solely in the tumor stromal compartment. Here, we show that Cav-1-deficient stromal fibroblasts are sufficient to promote both tumor growth and angiogenesis, and to recruit Cav-1 (+) micro-vascular cells. Proteomic analysis of Cav-1-deficient stromal fibroblasts indicates that these cells upregulate the expression of glycolytic enzymes, a hallmark of aerobic glycolysis (the Warburg effect). Thus, Cav-1-deficient stromal fibroblasts may contribute towards tumor growth and angiogenesis, by providing energy-rich metabolites in a paracrine fashion. We have previously termed this new idea the “Reverse Warburg Effect”. In direct support of this notion, treatment of this xenograft model with glycolysis inhibitors functionally blocks the positive effects of Cav-1-deficient stromal fibroblasts on breast cancer tumor growth. Thus, pharmacologically-induced metabolic restriction (via treatment with glycolysis inhibitors) may be a promising new therapeutic strategy for breast cancer patients that lack stromal Cav-1 expression. We also identify the stromal expression of PKM2 and LDH-B as new candidate biomarkers for the “Reverse Warburg Effect” or “Stromal-Epithelial Metabolic Coupling” in human breast cancers.     

m-Calpain is required for preimplantation embryonic development in mice

Background  

μ-calpain and m-calpain are ubiquitously expressed proteases implicated in cellular migration, cell cycle progression, degenerative processes and cell death. These heterodimeric enzymes are composed of distinct catalytic subunits, encoded by Capn1 (μ-calpain) or Capn2 (m-calpain), and a common regulatory subunit encoded by Capn4. Disruption of the mouse Capn4 gene abolished both μ-calpain and m-calpain activity, and resulted in embryonic lethality, thereby suggesting essential roles for one or both of these enzymes during mammalian embryogenesis. Disruption of the Capn1 gene produced viable, fertile mice implying that either m-calpain could compensate for the loss of μ-calpain, or that the loss of m-calpain was responsible for death of Capn4 ^-/- mice.     

Arp3 is required during preimplantation development of the mouse embryo

The role of Arp3 in mouse development was investigated utilizing a gene trap mutation in the Arp3 gene. Heterozygous Arp3(WT/GT) mice are normal, however, homozygous Arp3(GT/GT) embryos die at blastocyst stage. Earlier embryonic stages appear unaffected by the mutation, probably due to maternal Arp3 protein. Mutant blastocysts isolated at E3.5 fail to continue development in vitro, lack outgrowth of trophoblast-like cells in culture and express reduced levels of the trophoblast marker Cdx2, while markers for inner cell mass continue to be present. The recessive embryonic lethal phenotype indicates that Arp3 plays a vital role for early mouse development, possibly when trophoblast cells become critical for implantation.     

Nepro is localized in the nucleolus and essential for preimplantation development in mice

We generated knockout (KO) mice of Nepro, which has been shown to be necessary to maintain neural progenitor cells downstream of Notch in the mouse developing neocortex by using knockdown experiments, to explore its function in embryogenesis. Nepro KO embryos were morphologically indistinguishable from wild type (WT) embryos until the morula stage but failed in blastocyst formation, and many cells of the KO embryos resulted in apoptosis. We found that Nepro was localized in the nucleolus at the blastocyst stage. The number of nucleolus precursor bodies (NPBs) and nucleoli per nucleus was significantly higher in Nepro KO embryos compared with WT embryos later than the 2‐cell stage. Furthermore, at the morula stage, whereas 18S rRNA and ribosomal protein S6 (rpS6), which are components of the ribosome, were distributed to the cytoplasm in WT embryos, they were mainly localized in the nucleoli in Nepro KO embryos. In addition, in Nepro KO embryos, the amount of the mitochondria‐associated p53 protein increased, and Cytochrome c was distributed in the cytoplasm. These findings indicate that Nepro is a nucleolus‐associated protein, and its loss leads to the apoptosis before blastocyst formation in mice.     

HIV-induced T-cell activation/exhaustion in rectal mucosa is controlled only partially by antiretroviral treatment

Peripheral blood T-cells from untreated HIV-1-infected patients exhibit reduced immune responses, usually associated with a hyperactivated/exhausted phenotype compared to HAART treated patients. However, it is not clear whether HAART ameliorates this altered phenotype of T-cells in the gastrointestinal-associated lymphoid tissue (GALT), the main site for viral replication. Here, we compared T-cells from peripheral blood and GALT of two groups of chronically HIV-1-infected patients: untreated patients with active viral replication, and patients on suppressive HAART. We characterized the T-cell phenotype by measuring PD-1, CTLA-4, HLA-DR, CD25, Foxp3 and granzyme A expression by flow cytometry; mRNA expression of T-bet, GATA-3, ROR-γt and Foxp3, and was also evaluated in peripheral blood mononuclear cells and rectal lymphoid cells. In HIV-1+ patients, the frequency of PD-1(+) and CTLA-4(+) T-cells (both CD4+ and CD8+ T cells) was higher in the GALT than in the blood. The expression of PD-1 by T-cells from GALT was higher in HIV-1-infected subjects with active viral replication compared to controls. Moreover, the expression per cell of PD-1 and CTLA-4 in CD4(+) T-cells from blood and GALT was positively correlated with viral load. HAART treatment decreased the expression of CTLA-4 in CD8(+) T cells from blood and GALT to levels similar as those observed in controls. Frequency of Granzyme A(+) CD8(+) T-cells in both tissues was low in the untreated group, compared to controls and HAART-treated patients. Finally, a switch towards Treg polarization was found in untreated patients, in both tissues. Together, these findings suggest that chronic HIV-1 infection results in an activated/exhausted T-cell phenotype, despite T-cell polarization towards a regulatory profile; these alterations are more pronounced in the GALT compared to peripheral blood, and are only partiality modulated by HAART.     

Effect of gossypol on bovine embryo development during the preimplantation period

The purpose of this study was to evaluate the effect of varying doses of gossypol acetic acid on early bovine embryo development in vitro. One hundred and forty-eight excellent and good quality bovine morulae were randomly cultured in 0, 1.0, 5.0, 10.0, 30.0 mug gossypol acetic acid (GAA) in normal steer serum and Ham's F-10 media. Bovine embryo development was assessed at 12-h intervals for 96 h. Sixty-seven percent of embryos developed in 0 mug GAA to the hatched blastocyst stage, while 43, 19, 4 and 0% had comparable development in 1.0, 5.0, 10.0 and 30.0 mug GAA, respectively. Embryos in 5.0 mug GAA had a delayed development to the blastocyst stage compared to embryos in 1.0 mug GAA. Development time to expanded blastocyst stage was longer for 10.0 mug GAA embryos than 0, and 1.0 GAA-treated embryos. No embryo cultured in 30.0 mug GAA advanced past the morula stage. Final developmental scores were highest for embryos in 0 mug GAA (4.06) and lowest for embryos cultured in 10.0 and 30.0 mug GAA (0.44 and -0.02, respectively). Embryos cultured in higher doses of GAA degenerated sooner than embryos cultured in 0 mug GAA. These data show a dose-dependent detrimental action of GAA on early bovine embryo development and suggest a direct action on the embryo itself.     

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.     

Effect of superoxide dismutase on the development of preimplantation mouse embryos

The role of superoxide dismutase (SOD) was tested on preimplantation development of mouse embryos in vitro. The presence of SOD in ovarian antral follicles and in oviductal and uterine secretions was also investigated. Zygotes from superovulated ICR female mice were cultured in modified Whittingham's T6 medium supplemented with SOD (0 to 370 U) or EDTA (100 muM) at 37 degrees C under 5% CO(2) in air. Supplementation of SOD (370 U) significantly promoted the development of zygotes to the blastocyst stage (45%) as compared to that of the controls (1.4%). This favorable effect of SOD was comparable to that of EDTA and completely suppressed by anti-SOD antibody. Blastocysts cultured with SOD consisted of 78.2+/-10.4 blastomeres and possessed as many blastomeres as those (81.6+/-9.3) developing in vivo; blastocysts cultured with EDTA had significantly fewer blastomeres (42.6+/-13.7). These findings suggest that SOD protects embryos against oxidative insults and that it can be an effective substitute for EDTA for supporting mouse embryo development in vitro. The SOD activity was detected in 3 different lumina from mouse reproductive organs, and SOD was identified as a cytosolic Cu,Zn-SOD on photochemically stained polyacrylamide gels. Our results suggest that oxidative injury may be responsible for developmental retardation of preimplantation-stage mouse embryos in vitro and that Cu,Zn-SOD may play a crucial role in protecting embryos against oxygen toxicity in vivo as well as in vitro.