Unusual fast sedimenting mitochondria producing heavy DNA in the cells of aging coleoptiles of wheat seedlings

A fraction of unusual fast sedimenting (10 min at 600-1700g) particles with properties of mitochondria has been detected in wheat seedlings. This fraction conventionally called "heavy" mitochondria amounts (by protein) to about 40% of the total subcellular particle fraction sedimented by 10 min centrifugation at 17,000g. The specific feature of these "heavy" mitochondria in aging tissues is an ability to synthesize and even superproduce heavy (rho = 1.718 g/cm3) mitochondrial DNA (H-mtDNA). The share of "heavy" mitochondria sedimented in the interval between 1000 and 1700g and possessing the maximal H-mtDNA synthesis in aging coleoptiles is about 1.5-fold higher than that in young coleoptiles. Although "heavy" mitochondria are present in young plant organs, they seem to be unable to synthesize H-mtDNA; heavy mtDNA forms only in mitochondria of aging or old cells. Thus, aging in plants is accompanied by a change in population of mitochondria and appearance of the ability for selective H-mtDNA superproduction in a certain mitochondrial fraction. Mitochondria isolated from wheat coleoptiles are practically not stimulated by uncouplers. "Heavy" (600-1700g) and usual (4,300-17,400g) mitochondria are similar in respiration rates, cytochrome compositions, cytochrome c amount (per mg protein) and sensitivities to respiration inhibitors. However, "heavy" mitochondria contain (per mg protein) cytochromes b and aa3 by 10-20% and Ca2+ by 2-3-fold more than normal mitochondria. Ultrastructural analysis showed that the isolated fraction of fast sedimenting mitochondria consists of a suspension of closed membrane vesicles filled with cytoplasm and containing one or a few mitochondria. We observed similar structures in situ in vacuoles of parenchyma cells in the apical part of intact coleoptiles. The process of formation of such structures was detected by serial ultra-thin section analysis. It was shown that tonoplast protrudes into vacuoles, the separate mitochondria translocate into these protrusions, and then these structures separate. As a result, the suspended cytoplasmic bodies containing mitochondria appear in vacuoles. Appearance of these bodies containing mitochondria and, in particular, the superproduction of H-mtDNA in them correlate with processes of aging and cell transition to apoptosis.     

Subcellular reorganization of mitochondria producing heavy DNA in aging wheat coleoptiles.

Unusual closed membrane vesicles containing one or more mitochondria were isolated from homogenates of aging wheat coleoptiles. Very similar (or the same) bodies were shown to exist in situ in vacuoles of undividing cells in the apical part of intact senescent coleoptiles. Vesicles isolated from coleoptile homogenate free of nuclei by 10 min centrifugation at 1700 x g and traditional mitochondria (sedimented at between 4300 x g and 17,400 x g) are similar in respiration rate, composition and content of cytochromes and sensitivity to respiration inhibitors. However, vesicles contain about 2-fold more Ca2+ ions than free mitochondria do. The specific feature of vesicles containing mitochondria in aging coleoptiles is an intensive synthesis of heavy (rho = 1.718 g/cm3) mitochondrial DNA (H-mtDNA). Thus, aging in plants is accompanied by an increased selective H-mtDNA production and change in subcellular organization of mitochondria.     

Necessity of Superoxide Production for Development of Etiolated Wheat Seedlings

It was found that production of superoxide (O₂ ^{– ·}) is crucial for normal morphogenesis of etiolated wheat seedlings in the early stages of plant development. The development of etiolated wheat seedlings was shown to be accompanied with cyclic changes in the rate of O₂ ^{– ·} production both in the entire intact seedling and in its separated organs (leaf, coleoptile). First increase in the rate of O₂ ^{– ·} production was clearly observed in the period from two to four days of seedling development, then the rate of O₂ ^{– ·} production decreased to the initial level, and then it increased again for two days to a new maximum. An increase in O₂ ^{– ·} production in the period of the first four days of seedling development correlates with an increase in DNA and protein contents in the coleoptile. The second peak of increased rate of O₂ ^{– ·} production observed on the sixth or seventh day of seedling development coincides with a decrease in DNA and protein contents and apoptotic internucleosomal nuclear DNA fragmentation in the coleoptile. Incubation of seedlings in the presence of the antioxidant BHT (ionol) strongly affects their development but it does not influence the increase in DNA and protein contents for the initial four days of seedling life, and it slows down the subsequent age-dependent decrease in protein content and fully prevents the age-dependent decrease in DNA content in the coleoptile. A decrease in the O₂ ^{– ·} amount induced by BHT distorts the seedling development. BHT retards seedling growth, presumably by suppression of cell elongation, and it increases the life span of the coleoptile. It seems that O₂ ^{– ·} controls plant growth by cell elongation at the early stages of seedling development but later O₂ ^{– ·} controls (induces) apoptotic DNA fragmentation and protein disintegration.     

Effect of the antioxidant ionol (BHT) on growth and development of etiolated wheat seedlings: control of apoptosis, cell division, organelle ultrastructure, and plastid differentiation

Ionol (BHT), a compound having antioxidant activity, at concentrations in the range 1-50 mg/liter (0.45·10^-5-2.27·10^-4 M), inhibits growth of etiolated wheat seedlings, changes the morphology of their organs, prolongs the coleoptile life span, and prevents the appearance of specific features of aging and apoptosis in plants. In particular, BHT prevents the age-dependent decrease in total DNA content, apoptotic internucleosomal fragmentation of nuclear DNA, appearance in the cell vac-uole of specific vesicles with active mitochondria intensively producing mtDNA, and formation of heavy mitochondrial DNA ( = 1.718 g/cm³) in coleoptiles of etiolated wheat seedlings. BHT induces large structural changes in the organization of all cellular organelles (nucleus, mitochondria, plastids, Golgi apparatus, endocytoplasmic reticulum) and the formation of new unusual membrane structures in the cytoplasm. BHT distorts the division of nuclei and cells, and this results in the appearance of multi-bladed polyploid nuclei and multinuclear cells. In roots of etiolated wheat seedlings, BHT induces intensive synthesis of pigments, presumably carotenoids, and the differentiation of plastids with formation of chloro- or chromoplasts. The observed multiple effects of BHT are due to its antioxidative properties (the structural BHT analog 3,5-di-tert-butyltoluene is physiologically inert; it has no effect similar to that of BHT). Therefore, the reactive oxygen species (ROS) controlled by BHT seem to trigger apoptosis and the structural reorganization of the cytoplasm in the apoptotic cell with formation of specific vac-uolar vesicles that contain active mitochondria intensively producing mtDNA. Thus, the inactivation of ROS by BHT may be responsible for the observed changes in the structure of all the mentioned cellular organelles. This corresponds to the idea that ROS control apoptosis and mitosis including formation of cell wall, and they are powerful secondary messengers that regulate dif-ferentiation of plastids and the Golgi apparatus in plants.     

Brg1 Loss Attenuates Aberrant Wnt-Signalling and Prevents Wnt-Dependent Tumourigenesis in the Murine Small Intestine

Tumourigenesis within the intestine is potently driven by deregulation of the Wnt pathway, a process epigenetically regulated by the chromatin remodelling factor Brg1. We aimed to investigate this interdependency in an in vivo setting and assess the viability of Brg1 as a potential therapeutic target. Using a range of transgenic approaches, we deleted Brg1 in the context of Wnt-activated murine small intestinal epithelium. Pan-epithelial loss of Brg1 using VillinCreER^T2 and AhCreER^T transgenes attenuated expression of Wnt target genes, including a subset of stem cell-specific genes and suppressed Wnt-driven tumourigenesis improving animal survival. A similar increase in survival was observed when Wnt activation and Brg1 loss were restricted to the Lgr5 expressing intestinal stem cell population. We propose a mechanism whereby Brg1 function is required for aberrant Wnt signalling and ultimately for the maintenance of the tumour initiating cell compartment, such that loss of Brg1 in an Apc-deficient context suppresses adenoma formation. Our results highlight potential therapeutic value of targeting Brg1 and serve as a proof of concept that targeting the cells of origin of cancer may be of therapeutic relevance.     

LKB1 loss of function studied in vivo

Recent developments have placed the serine/threonine kinase LKB1 on the crossroads linking energy metabolism, cell structure and cancer progression and that its deletion can affect tumorigenesis, metastasis, cell adhesion and polarity. LKB1 can regulate a host of different functions which all have potential to impact upon the initiation and progression of neoplastic disease. To understand the phenotypic consequences of LKB1 loss in a range of different settings, a number of animal models of loss of function have been generated and analyzed. In this review we summarize recent data generated from a range of these models, which reveal clear tissue specific differences in LKB1 function in vivo and in the consequences of its loss.     

Lkb1 Deficiency Alters Goblet and Paneth Cell Differentiation in the Small Intestine

The Lkb1 tumour suppressor is a multitasking kinase participating in a range of physiological processes. We have determined the impact of Lkb1 deficiency on intestinal homeostasis, particularly focussing on secretory cell differentiation and development since we observe strong expression of Lkb1 in normal small intestine Paneth and goblet cells. We crossed mice bearing an Lkb1 allele flanked with LoxP sites with those carrying a Cyp1a1-specific inducible Cre recombinase. Lkb1 was efficiently deleted from the epithelial cells of the mouse intestine after intraperitoneal injection of the inducing agent β-naphthoflavone. Bi-allelic loss of Lkb1 led to the perturbed development of Paneth and goblet cell lineages. These changes were characterised by the lack of Delta ligand expression in Lkb1-deficient secretory cells and a significant increase in the levels of the downstream Notch signalling effector Hes5 but not Hes1. Our data show that Lkb1 is required for the normal differentiation of secretory cell lineages within the intestine, and that Lkb1 deficiency modulates Notch signalling modulation in post-mitotic cells.     

Lkb1 and Pten synergise to suppress mTOR-mediated tumorigenesis and epithelial-mesenchymal transition in the mouse bladder

The AKT/PI3K/mTOR pathway is frequently altered in a range of human tumours, including bladder cancer. Here we report the phenotype of mice characterised by deletion of two key players in mTOR regulation, Pten and Lkb1, in a range of tissues including the mouse urothelium. Despite widespread recombination within the range of epithelial tissues, the primary phenotype we observe is the rapid onset of bladder tumorigenesis, with median onset of approximately 100 days. Single deletion of either Pten or Lkb1 had no effect on bladder cell proliferation or tumour formation. However, simultaneous deletion of Lkb1 and Pten led to an upregulation of the mTOR pathway and the hypoxia marker GLUT1, increased bladder epithelial cell proliferation and ultimately tumorigenesis. Bladder tissue also exhibited characteristic features of epithelial-mesenchymal transition, with loss of the epithelial markers E-cadherin and the tight junction protein ZO-1, and increases in the mesenchymal marker vimentin as well as nuclear localization of epithelial-mesenchymal transition (EMT) regulator Snail. We show that these effects were all dependent upon mTOR activity, as rapamycin treatment blocked both EMT and tumorigenesis. Our data therefore establish clear synergy between Lkb1 and Pten in controlling the mTOR pathway within bladder epithelium, and show that loss of this control leads to the disturbance of epithelial structure, EMT and ultimately tumorigenesis.     

Putative DNA-(amino)methyltransferases in eucaryotes

By computer analysis of the known data bases, we have established that the open reading frames (ORF) coding for proteins that possess high degree of homology with procaryotic DNA-(amino)methyltransferases are present in the genomes of Leishmania major, Saccharomyces cerevisiae, Schizosaccharomyces pombe, Arabidopsis thaliana, Drosophila melanogaster, Caenorhabditis elegans, and Homo sapiens. Conservative motifs typical for bacterial DNA-(amino)methyltransferases are detected in the amino acid sequences of these putative proteins. The ORF of all putative eucaryotic DNA-(amino)methyl-transferases found are encoded in nuclear DNA. In mitochondrial genomes including a few fully sequenced higher plant mtDNA, nucleotide sequences significantly homologous to genes of procaryotic DNA-(amino)methyltransferases are not found. Thus, ORF homologous to bacterial adenine DNA-methyltransferases are present in nuclei of protozoa, yeasts, insects, nematodes, vertebrates, higher plants, and other eucaryotes. A special search for corresponding proteins and, in particular, adenine DNA-methyltransferases in these organisms and a study of their functions are quite promising.     

The Effects of Phytohormones and 5-Azacytidine on Apoptosis in Etiolated Wheat Seedlings

The development of etiolated wheat (Triticum aestivum L.) seedlings is necessarily accompanied by apoptosis in their coleoptiles and first leaves. Internucleosome DNA fragmentation, which is characteristic of apoptosis, was detected in the coleoptile as soon as six days after germination. After eight days of germination, DNA fragmentation was clearly expressed in the coleoptile and was noticeable in the apical part of the first-leaf blade. Growing of intact seedlings or incubation of their shoots in the presence of such phytohormones as benzyladenine, gibberellin A₃, fusicoccin C, and 2,4-D at the concentration of 10^–5 M did not essentially affect DNA fragmentation in the coleoptile. As distinct from antioxidants, none of the phytohormones used prevented apoptosis in wheat seedlings. In contrast, ABA (10^–5 M) and an ethylene producer, ethrel (2-chloroethylphosphonic acid, 10^–2–10^–3 M), stimulated sharply DNA fragmentation in the coleoptile. An inhibitor of DNA methylation, 5-azacytidine, was very efficient in the stimulation of DNA fragmentation in the coleoptiles of eight-day-old seedlings at its concentration of 100 g/ml. Thus, some phytohormones can regulate apoptosis, and DNA methylation is involved in this process. Our results indicate that apoptosis activation by some phytohormones may be mediated by their regulation of DNA methylation/demethylation, which is responsible for the induction of genes encoding apoptogenic proteins and/or the repression of antiapoptotic genes.