Systemic administration of bone marrow‐derived cells leads to better uterine engraftment than use of uterine‐derived cells or local injection

Stem cells are recruited to the uterus where they differentiate into endometrial cells and have been suggested as potential therapy for uterine injury such as Asherman's syndrome. However, it is unknown whether local intrauterine injection may result in better stem cell engraftment of the uterus compared with systemic administration, and whether uterine‐derived cells (UDCs) may confer an advantage over BM‐derived cells (BMDCs). Mice underwent local injury to a single uterine horn. Green fluorescent protein (GFP)‐expressing BMDCs, UDCs or saline (control) were injected either intravenously or locally (uterine lumen) into wild‐type recipients. Two or 3 weeks post‐transplant, uterine tissues were collected for fluorescence‐activated cell sorting (FACS) and immunohistochemistry/immunofluorescence studies. Mice injected intravenously with BMDCs or UDCs had increased GFP⁺ cells recruitment to the non‐injured or injured uterus compared to those injected locally. No significant differences were noted in GFP⁺ cell recruitment to the injured versus non‐injured horn. In addition, systemic injection of BMDCs led to greater recruitment of GFP⁺ cells at 2 weeks and 3 weeks compared with UDCs. Immunohistochemical staining demonstrated that GFP⁺ cells were found in stroma but not in epithelium or blood vessels. Immunofluorescence analysis revealed that GFP⁺ cells were mostly CD45‐negative, and negative for CD31 and cytokeratin, confirming their stromal identity. In conclusion, the systemic route of administration results in better recruitment of BMDCs or UDCs to the injured uterus than local injection. In addition, BMDCs recruitment to the uterus is greater than UDCs. These findings inform the development of stem cell‐based therapies targeting the uterus.     

Systems-Wide Prediction of Enzyme Promiscuity Reveals a New Underground Alternative Route for Pyridoxal 5’-Phosphate Production in E. coli

Recent insights suggest that non-specific and/or promiscuous enzymes are common and active across life. Understanding the role of such enzymes is an important open question in biology. Here we develop a genome-wide method, PROPER, that uses a permissive PSI-BLAST approach to predict promiscuous activities of metabolic genes. Enzyme promiscuity is typically studied experimentally using multicopy suppression, in which over-expression of a promiscuous ‘replacer’ gene rescues lethality caused by inactivation of a ‘target’ gene. We use PROPER to predict multicopy suppression in Escherichia coli, achieving highly significant overlap with published cases (hypergeometric p = 4.4e-13). We then validate three novel predicted target-replacer gene pairs in new multicopy suppression experiments. We next go beyond PROPER and develop a network-based approach, GEM-PROPER, that integrates PROPER with genome-scale metabolic modeling to predict promiscuous replacements via alternative metabolic pathways. GEM-PROPER predicts a new indirect replacer (thiG) for an essential enzyme (pdxB) in production of pyridoxal 5’-phosphate (the active form of Vitamin B₆), which we validate experimentally via multicopy suppression. We perform a structural analysis of thiG to determine its potential promiscuous active site, which we validate experimentally by inactivating the pertaining residues and showing a loss of replacer activity. Thus, this study is a successful example where a computational investigation leads to a network-based identification of an indirect promiscuous replacement of a key metabolic enzyme, which would have been extremely difficult to identify directly.     

Crucial Roles of Single Residues in Binding Affinity,Specificity, and Promiscuity in the Cellulosomal Cohesin-Dockerin Interface

Interactions between cohesin and dockerin modules play a crucial role in the assembly of multienzyme cellulosome complexes. Although intraspecies cohesin and dockerin modules bind in general with high affinity but indiscriminately, cross-species binding is rare. Here, we combined ELISA-based experiments with Rosetta-based computational design to evaluate the contribution of distinct residues at the Clostridium thermocellum cohesin-dockerin interface to binding affinity, specificity, and promiscuity. We found that single mutations can show distinct and significant effects on binding affinity and specificity. In particular, mutations at cohesin position Asn³⁷ show dramatic variability in their effect on dockerin binding affinity and specificity: the N37A mutant binds promiscuously both to cognate (C. thermocellum) as well as to non-cognate Clostridium cellulolyticum dockerin. N37L in turn switches binding specificity: compared with the wild-type C. thermocellum cohesin, this mutant shows significantly increased preference for C. cellulolyticum dockerin combined with strongly reduced binding to its cognate C. thermocellum dockerin. The observation that a single mutation can overcome the naturally observed specificity barrier provides insights into the evolutionary dynamics of this system that allows rapid modulation of binding specificity within a high affinity background.     

The role of microorganisms in coral health, disease and evolution

Coral microbiology is an emerging field, driven largely by a desire to understand, and ultimately prevent, the worldwide destruction of coral reefs. The mucus layer, skeleton and tissues of healthy corals all contain large populations of eukaryotic algae, bacteria and archaea. These microorganisms confer benefits to their host by various mechanisms, including photosynthesis, nitrogen fixation, the provision of nutrients and infection prevention. Conversely, in conditions of environmental stress, certain microorganisms cause coral bleaching and other diseases. Recent research indicates that corals can develop resistance to specific pathogens and adapt to higher environmental temperatures. To explain these findings the coral probiotic hypothesis proposes the occurrence of a dynamic relationship between symbiotic microorganisms and corals that selects for the coral holobiont that is best suited for the prevailing environmental conditions. Generalization of the coral probiotic hypothesis has led us to propose the hologenome theory of evolution.     

Tissue-specific hypomethylation and expression of rat phosphoenolpyruvate carboxykinase gene induced by in vivo treatment of fetuses and neonates with 5-azacytidine

Rat fetuses of 17-19-day gestation were injected in utero with 5-azacytidine (two to three daily injections of 40 micrograms/fetus). Neonates were injected with seven daily injections (1 mg/kg). DNA samples were isolated from the fetal and neonatal livers and neonatal spleen and subjected to analysis of their methylation status. Overall methylation was analyzed by the nearest-neighbor analysis (at CpG sites) and the pattern of methylation at CCGG sites by Southern blot analysis using phosphoenolpyruvate carboxykinase (PEPCK) sequences as probes. While DNAs from the liver and spleen undergo hypomethylation to the same extent in response to the 5-azacytidine treatment, the changes in the methylation patterns of the PEPCK gene in the two tissues are strikingly different. The changes observed indicate that a decrease in the methylase activity (inhibition by 5-azacytidine) results in site- and tissue-specific hypomethylation. The tissue-specific changes in the methylation pattern are associated with a tissue-specific expression of the PEPCK gene. Although the gene is hypomethylated by azacytidine in both liver and spleen, it is expressed only in the liver. The expression of already active genes (PEPCK in the kidney and albumin in the liver) is not further enhanced by the drug.     

Prenatal diagnosis of familial hypercholesterolemia caused by the “Lebanese” mutation at the low density lipoprotein receptor locus

Summary Here, we report the prenatal diagnosis of familial hypercholesterolemia in a Christian-Arab family that carries the Lebanese mutation, a single base substitution that creates a HinfI restriction site, at the low density lipoprotein (LDL) receptor locus. Polymerase chain reaction amplification and restriction analysis were performed on genomic DNA extracted from a chorionic villus sample. In conjunction with karyotype analysis, the fetus was identified as a heterozygous female. Analysis of LDL receptor restriction fragment length polymorphisms confirmed the presence of a male parent marker and revealed that the fetus inherited the mutant gene from its mother. This technique offers a simple and rapid diagnostic tool that can be carried out at an early stage of gestation. It is recommended for families and population groups with molecularly defined LDL receptor mutations.     

Effect of propionate on lipogenesis in adipose tissue

The metabolism of propionate in adipose tissue and its effect on lipogenesis was investigated. Fasting induced changes in propionate metabolism of adipose tissue, drastically reducing higher fatty acid synthesis and increasing glyceride-glyerol formation from low concentrations of propionate (0.25 mM). Propionate also promoted lipogenesis from acetate-1-(14)C in tissues of fasted rats, while it inhibited lipogenesis and CO(2) formation from acetate in the fed animal. Treatment with actinomycin D or ethionine abolished both the increased glyceride-glycerol formation from propionate and the promoting effect on lipogenesis from acetate. Synthesis of long-chain fatty acids from propionate-1-(14)C was increased by actinomycin treatment. The change in propionate metabolism induced by fasting is, however, not entirely due to its conversion to glyceride-glycerol, since the latter was almost completely blocked by malonate while part of the promoting effect on fatty acid synthesis persisted.     

Effect of propionate on pyruvate metabolism in adipose tissue

Glyceride-glycerol formation in rat adipose tissue from pyruvate-2-(14)C is increased by fasting, while fatty acid synthesis is markedly depressed. In tissues of fasted animals glyceride-glycerol formation is maximal with concentrations of pyruvate exceeding 2.5 mM. With 0.25 mM pyruvate-2-(14)C, glyceride-glycerol formation is increased severalfold by the addition of 0.25 mM propionate. No further increase in synthesis is caused by propionate when pyruvate is supplied in optimal amounts. Addition of equimolar concentrations of acetate or pyruvate does not replace propionate. The effect of propionate on glyceride-glycerol synthesis from pyruvate is also given by a series of even-chain fatty acids. However, only propionate promotes fatty acid synthesis in tissues of fasted and fed animals. Fixation of (14)CO(2) in glyceride-glycerol is dependent on the presence of propionate and is maximal in tissues of fasted rats and when pyruvate is also added. Succinate has no significant effect. Actinomycin treatment blocks glyceride-glycerol synthesis in tissues of fed and fasted animals, in the presence and absence of propionate. At the same time, fatty acid synthesis in tissues of fasted rats is markedly increased.