Recovery of Proteolipid Protein in Mice Heterozygous for the Jimpy Gene

We have measured levels and synthesis of proteolipid protein (PLP) and its transport into myelin in female mice heterozygous for the jimpy gene and in their normal female littermates. In both cord and cerebrum, jimpy carriers show deficits in PLP during development followed by compensation in adulthood. Recovery of PLP occurs earlier in cord than in brain. At 13 days levels of PLP in carriers compared to controls are reduced to 0.60 and 0.44, respectively, in cord and cerebrum. By 100 days, normal levels of PLP are attained in cord (1.13) whereas levels of PLP in cerebrum are only 0.78 of control. By 200 days full recovery occurs in cerebrum, with a ratio of 1.21, suggesting a possible over-compensation. The yield of myelin from cerebrum was reduced to 0.78 in carriers compared to controls at 17 days. In brain slices, incorporation of [3H]leucine into homogenate PLP from carriers is the same as in controls, whereas [3H]leucine incorporation into myelin PLP is reduced to 0.68 of control. These results indicate that synthesis of PLP in the carriers is normal at 17 days, but transport of PLP into myelin is reduced. Similarly, acylation of homogenate PLP is normal, whereas acylation of myelin PLP is reduced, as measured by incorporation of [3H]palmitic acid. Transport of PLP into myelin was compared to transport of MBP; transport of both proteins was equally decreased as indicated by the similar ratio of labeled PLP to MBP in myelin from carriers compared to noncarriers.(ABSTRACT TRUNCATED AT 250 WORDS)     

Detection of oligodendrocytes in tissue sections using PCR synthesis of digoxigenin-labeled probes.

Oligodendrocytes, the myelin-forming cells in the central nervous system, were visualized with excellent resolution at the light microscopic level using in situ hybridization (ISH). Digoxigenin (Dig)-tagged probes were synthesized and efficiently labeled by PCR. Specific probes to myelin genes were made by RT from brain total RNAs, followed by PCR with designed specific primers in the presence of Dig-11-dUTP. Probes specific to proteolipid protein (PLP), PLP and its isoform DM20 (PLP/DM20), and myelin oligodendrocyte glycoprotein (MOG) were synthesized and labeled. ISH was then applied on vibratomed tissue sections from mouse brains. Despite a low expression of MOG-specific and PLP-specific mRNAs in adult and newborn mouse brains, an oligodendrocyte population was detected. The specificity of Dig-labeled probes was confirmed with the double labeling of carbonic anhydrase II (CA II) and glial fibrillary acidic protein (GFAP) immunocytochemistry and ISH. This versatile and easy method for synthesis and labeling of specific probes to oligodendrocytes can be also applied to detect many other mRNAs in the nervous system and in other tissues.     

Preferential hemolysis of postnatal calf red cells induced by internal alkanlinization

Red blood cells from neonatal calves, but not from adult cows, rapidly hemolyze in buffered 300 mM solutions of a variety of nonelectrolytes and amino acids. Of these compounds, sucrose is chosen to elucidate the mechanism by which this preferential hemolysis takes place. As in other mammalian red cells, both calf and cow cells are found to be impermeable to sucrose and, in an isosmolar sucrose solution, to undergo volume shrinkage caused by the net loss of chloride ions with concomitant increase in intracellular pH. To test the potential role of intracellular pH change associated with chloride loss in promoting hemolysis, intracellular pH was altered by: (a) a direct addition of fixed acid or base to sucrose solution; (b) the removal of dissolved CO(2) from sucrose solution; and (c) the addition of cells to isotonic NaHCO(3) solution in the absence of sucrose. In all cases, only calf and not cow cells underwent hemolysis. Moreover, 4-acetamido-4’-isothiocyano-2,2’-stilbene disulfonic acid, a potent anion transport inhibitor, completely protected calf cells from hemolysis and caused a nearly total inhibition of both chloride loss and intracellular alkalinization. Furthermore, the hemolytic process is closely related to the integrity of a membrane protein, the band 3 protein, which can be cleaved to varying degrees by the combined treatment of pronase and lipase. Hemolysis is progressively inhibited as the band 3 protein undergoes proteolysis, until a total inhibition of hemolysis takes place when almost all of the band 3 protein is digested into smaller protein components with a mol wt of 65,000 and 35,000 daltons. These results suggest that the intracellular alkalinization process leading to a structural instability of the membrane band 3 protein is responsible for this calf cell hemolysis.     

Pig Reticulocytes. III. Glucose permeability in naturally occurring reticulocytes and red cells from newborn piglets

The loss of facilitated glucose transport of red cells occurring in the newborn pig was monitored in 11 density-separated cells from birth to a 4 wk of age. At birth there was a threefold increase in glucose permeability from the lightest cells to the most dense, suggesting that cells having progressively less glucose permeability are released into the circulation as gestation proceeds. Because of extraordinary stimulation of erythropoietic activity, the uppermost top fraction constituting 2-3 percent of the total cells is composed purely of reticulocytes in the growing animal. The glucose permeability of these reticulocytes which at birth has a slow but significant rate of 3.7 μmol/ml cell x min at 25 degrees C is rapidly decreased within 3-4 days to the level of reticulocytes produced in the adult in response to phenylhydrazine assault. Moreover, reticulocytes themselves discard their membrane permeability to glucose in the course of maturation to red cells. Thus, even though reticulocytes at birth are permeable to glucose, they will become red cells practically impervious to glucose within a few days. These findings suggest that the transition from a glucose- permeable fetal state to a glucose-impermeable postnatal state is brought about by two mechanisms: (a) dilution of fetal cells by glucose-impervious cells produced coincidentally with or shortly after birth; and (b) elimination of fetal cells, which have a shorter half-life, from the circulation.     

Plasticity of Neurons and Glia Following Neonatal Hypoxic-Ischemic Brain Injury in Rats

Periventricular white matter injury in premature infants is linked to chronic neurological dysfunction. Periventricular white matter injury is caused by many mechanisms including hypoxia-ischemia (HI). Animal models of HI in the neonatal rodent brain can replicate some important features of periventricular white matter injury. Most rodent studies have focused upon early cellular and tissue events following unilateral neonatal HI that is elicited by unilateral carotid artery ligation and followed by timed exposure to moderate hypoxia. Milder hypoxic-ischemic insults elicit preferential white matter injury. Little information is available about long-term cellular effects of unilateral HI. One month after unilateral neonatal hypoxia ischemia, we show that all the components for structural reorganization of the brain are present in moderately injured rats. These components in the injured side include extensive influx of neurites, axonal and dendritic growth cones, abundant immature synapses, and myelination of many small axons. Surprisingly, this neural recovery is often found in and adjacent to cysts that have the ultrastructural features of bone extracellular matrix. In contrast, brains with severe hypoxia ischemia one month after injury still undergo massive neuronal degeneration. While massive destruction of neurons and glia are striking events shortly after brain HI, neural cells re-express their intrinsic properties and attempt an anatomical recovery long after injury. Special issue dedicated to Anthony Campagnoni.     

Neonatal endocrine abnormalities in myelin deficient Jimpy-tabby mice.

The Jimpy mouse is a sex-linked recessive mutant characterized by a paucity of myelin in the Central Nervous System. These mice are bred with another sex-linked gene bearing a fur mutation known as Tabby. The endocrine system of these animals was examined for histologic abnormalites because growth hormone and thyroxine play important roles in controlling myelinogenesis. The results of the present study show that the pituitary and thyroid are abnormal in appearance by two days after birth. The number of somatotrophs in the Jimpy-Tabby pituitary is reduced about 30% but the number of granules in these cells is increased 25%. The endoplasmic reticulum of the thyroid follicular cells in the mutants is dilated and occupies most of the cytoplasm. The results of this study demonstrate for the first time that Jimpy-Tabby mice exhibit abnormalities outside the Central Nervous System. The neonatal changes observed in the endocrine system are the basis for continued studies to determine if they are responsible for the myelin deficit.     

Differential expression of apoptotic markers in jimpy and in Plp overexpressors: evidence for different apoptotic pathways

Point mutations and duplications of proteolipid protein (PLP) gene in mammals cause dysmyelination and oligodendrocyte cell death. The jimpy mouse, which has a lethal Plp point mutation, is the best characterized of the mutants; transgenic mice, which have additional copies of Plp gene, are less characterized. While oligodendrocyte death is a prominent feature in jimpy, the pathways leading to death have not been investigated in jimpy and Plp overexpressors. Using immunohistochemistry and immunobloting, we examined expression of cleaved caspase-3, Poly (ADP-ribose) polymerase (PARP), caspase-12, and mitochondrial apoptotic markers in spinal cord in jimpy males and Plp overexpressors. Compared to controls, cleaved caspase-3 is increased 10× in jimpy white matter spinal cord, and 3× in Plp overexpressor. In jimpy, the number of cleaved caspase-3 cells far exceeds the number of TUNEL⁺ cells. The majority of cleaved caspase-3⁺ cells were not TUNEL⁺ and these cells exhibited staining in perikarya and in processes. Only 30% of the cleaved caspase-3⁺ cells were TUNEL⁺ and exhibited both nuclear and perinuclear staining. This observation suggests that activation of caspase-3 begins earlier and overlaps for a period of time with DNA fragmentation. In both Plp mutants, quantitative immunobloting of PARP showed a 45% increase in total as well as cleaved form, indicating that oligodendrocytes die via apoptosis. Most interestingly, cleavage of caspase-12, a caspase associated with unfolded protein response, is dramatically increased in jimpy but not at all in Plp overexpressors. Mitochondrial markers cytochrome c and Bcl-X_L are upregulated in both Plp mutants but levels of expression are different between mutants, suggesting that apoptosis in these two Plp mutants follows different pathways. In jimpy, mitochondrial apoptotic markers may play a role in amplifying the apoptotic signal. Our data shows for the first time, in vivo, that mutations in Plp gene increase oligodendrocyte death by activating the caspase cascade but the trigger to upregulate this cascade follows different pathways.