Experimental diabetes in neonatal mice induces early peripheral sensorimotor neuropathy.

Animal models of diabetes do not reach the severity of human diabetic neuropathy but relatively mild neurophysiological deficits and minor morphometric changes. The lack of degenerative neuropathy in diabetic rodent models seems to be a consequence of the shorter length of the axons or the shorter animal life span. Diabetes-induced demyelination needs many weeks or even months before it can be evident by morphometrical analysis. In mice myelination of the peripheral nervous system starts at the prenatal period and it is complete several days after birth. Here we induced experimental diabetes to neonatal mice and we evaluated its effect on the peripheral nerve 4 and 8 weeks after diabetes induction. Neurophysiological values showed a decline in sensory nerve conduction velocity at both time-points. Morphometrical analysis of the tibial nerve demonstrated a decrease in the number of myelinated fibers, fiber size and myelin thickness at both time-points studied. Moreover, aldose reductase and poly(ADP-ribose) polymerase activities were increased even if the amount of the enzyme was not affected. Thus, type 1 diabetes in newborn mice induces early peripheral neuropathy and may be a good model to assay pharmacological or gene therapy strategies to treat diabetic neuropathy.

Molecular signature of the immune and tissue response to non-coding plasmid DNA in skeletal muscle after electrotransfer.

Electrotransfer of plasmid DNA in skeletal muscle is a common non-viral delivery method for both therapeutic genes and DNA vaccines. Yet, despite the similar approaches, an immune response is detrimental in gene therapy, but desirable for vaccines. However, the full nature of the immune and tissue responses to nucleic acids and electrotransfer in skeletal muscle has not been addressed. Here we used microarray analysis, fluorescence-activated cell sorting and quantitative polymerase chain reaction to obtain the molecular and cellular signature of the tissue and immune response to electrotransfer of saline and non-coding plasmid DNA. Saline electrotransfer resulted in limited infiltration and induction of a moderate damage-repair gene expression pattern not involving innate immune activation. However, plasmid electrotransfer augmented expression of the same genes in addition to inducing a strong innate immune response associated with pro-inflammatory infiltration. In particular, the inflammasome, Toll-like receptor 9 and other pattern recognition receptors able to respond to cytoplasmic DNA were upregulated. Several key differences in the nature of the inflammatory infiltrate and the kinetics of gene expression were also identified when comparing electrotransfer of conventional and CpG-free plasmids. Our data provide insights into the mechanisms of DNA detection and response in muscle that has relevance for non-viral gene therapy and DNA vaccination.

Differential effects of glucose and fructose on hexose metabolism in dog spermatozoa.

Incubation of dog spermatozoa with 10 mmol l(-1) glucose or fructose rapidly increased the intracellular content of glucose 6-phosphate and fructose 6-phosphate, although the effect of fructose was greater. These effects were correlated with increases in ATP, ribose 5-phosphate and glycogen contents, and in the rates of formation of L-lactate and CO2. In all cases, except for ATP and glycogen, the effect of fructose was greater than that of glucose. The total hexokinase activity of the crude extracts of dog spermatozoa was more sensitive to fructose than to glucose at lower concentrations (0.1-3.0 mmol l(-1)). Both monosaccharides induced a fast and intense increase in the overall tyrosine phosphorylation of dog spermatozoa, although their specific induced-phosphorylation patterns differed slightly. Glut 3 and Glut 5 hexose transporters were the main hexose transporters in dog spermatozoa; however, other possible SGLT family-related hexose transporters were also localized. These data indicate that, at concentrations from 1 mmol l(-1) to 10 mmol l(-1), fructose has a stronger effect than glucose on hexose metabolism of dog spermatozoa. These differences appear to be related to variations in the sensitivity of hexokinase activity. Moreover, the differential hexose metabolism induced by the two sugars had distinct effects on the function of dog spermatozoa, as revealed by the diverse patterns of tyrosine phosphorylation.

Expression of glucokinase in skeletal muscle: a new approach to counteract diabetic hyperglycemia.

Chronic hyperglycemia is responsible for diabetes-specific microvascular and macrovascular complications. To reduce hyperglycemia, key tissues may be engineered to take up glucose. To determine whether an increase in skeletal muscle glucose phosphorylation leads to increased glucose uptake and to normalization of diabetic alterations, the liver enzyme glucokinase (GK) was expressed in muscle of transgenic mice. GK has a high Km for glucose and its activity is not inhibited by glucose 6-phosphate. The presence of GK activity in skeletal muscle resulted in increased concentrations of glucose 6-phosphate and glycogen. These mice showed lower glycemia and insulinemia, increased serum lactate levels, and higher blood glucose disposal after an intraperitoneal glucose tolerance test. Furthermore, transgenic mice were more sensitive to injection of low doses of insulin, which led to increased blood glucose disposal. In addition, streptozotocin (STZ)-treated transgenic mice showed lower levels of blood glucose than STZ-treated controls and maintained body weight. Moreover, injection of insulin to STZ-treated transgenic mice led to normoglycemia, while STZ-treated control mice remained highly hyperglycemic. Thus, these results are consistent with a key role of glucose phosphorylation in regulating glucose metabolism in skeletal muscle. Furthermore, this study suggests that engineering skeletal muscle to express GK may be a new approach to the therapy of diabetes mellitus.

Parthenogenetic activation of mouse oocytes by exposure to strontium as a source of cytoplasts for nuclear transfer.

Cell-cycle phase of the donor and recipient cells at the moment of nuclear transfer influences subsequent development of the reconstituted embryo. In order to study this effect, the precise cell-cycle phase of the recipient oocyte at the time of fusion must be known and this depends on reliable activation of oocytes in a protocol that has a low incidence of spontaneous activation. Mouse oocytes recovered before (8-10 hours post-human chorionic gonadotropin [hCG]) and after ovulation (14 and 18 hours post-hCG) were exposed to strontium ions in calcium magnesium-free M16 culture medium. The effect on development of haploid parthenotes of post-hCG age of the oocyte, the duration of exposure, and strontium concentration in the medium was determined. These experiments established a reliable method of parthogenetic activation of recently ovulated mouse oocytes, involving the culture of oocytes for 60 minutes in 25 mM strontium in a calcium magnesium-free M16 medium. This method of activation was also able to induce activation of preovulatory oocytes after a preincubation period in vitro. Only a low incidence of spontaneous activation was observed if oocytes were recovered before or immediately after ovulation (14 hours after hCG).

Cell cycle co-ordination in embryo cloning by nuclear transfer.

Exciting new opportunities in embryo cloning have been made possible by recent studies on the interaction of the donor nucleus with the recipient cytoplasm after embryo reconstruction. This article reviews information regarding the co-ordination of nuclear and cytoplasmic events during embryo reconstruction, in particular the direct and indirect effects of maturation/ meiosis/mitosis-promoting factor (MPF), upon the transferred nucleus. This will be discussed in relation to DNA replication, the maintenance of correct ploidy, the occurrence of chromosomal abnormalities and development of reconstructed embryos. Although this review is primarily concerned with the reconstruction of mammalian embryos, specific examples from amphibians will also be cited.

Transfer of nuclei from 8-cell stage mouse embryos following use of nocodazole to control the cell cycle.

Mouse 2-, 4-, 8-, and 16-cell embryos were exposed to nocodazole in M16 culture medium. The effect of different concentrations and exposure times on the efficiency of cell cycle synchronization and the development of the treated embryos after release from the drug was determined. The minimum effective concentration (> 95% of arrested nuclei) for 4-, 8-, and 16-cell embryos was 5 microM nocodazole. The effect upon subsequent development of mouse embryos depended upon both the stage of development of the embryo at treatment (P < 0.001) and the length of exposure to nocodazole (P < 0.001). Exposure to any concentration of nocodazole within the range 2.5-10 microM for 12 hr caused a reduction in the proportion of embryos that formed blastocysts. As the period of exposure to 5 microM nocodazole increased from 12 to 24 hr, the proportion of embryos developing to the blastocyst stage decreased. The lower proportion of embryos developing to the blastocyst stage and to term (P < 0.01) suggests that the more advanced stages were more susceptible to damage as a result of exposure to nocodazole. The rate of development of 4-cell embryos to blastocysts was not affected when an exposure time of 9 hr was used. Together these results show that it is possible to use nocodazole to arrest mouse embryonic cells in mitosis but that it is not appropriate to culture the embryos in the presence of this drug for prolonged periods. Individual blastomeres completed mitosis at 60-90 min and started DNA synthesis at 120-150 min after release from nocodazole.(ABSTRACT TRUNCATED AT 250 WORDS)