Myelin basic protein deficit in the PNS of mld mutant mice recovers during development

Myelination was studied between 15 and 135 days postnatally in peripheral nerves of myelin deficient (mld) mice and in unaffected littermates. The nerve weights were not affected by the mutation and showed a 4-fold increase during the developmental period studied. The amounts of myelin present in peripheral nerves, as shown by biochemical and morphological techniques, were slightly reduced in mld in comparison to control mice. In controls, the concentration of myelin doubled during the investigation period. The increase of myelin basic protein (MBP) in total nerve homogenate paralleled the deposition of myelin, but the MBP concentration remained constant in normal myelin. In contrast, in mld myelin MBP concentrations were extremely low until 60 days of age and increased thereafter to reach almost normal values at 135 days. Similarly, the amounts of myelin isolated at 85 and 135 days were normal. 2',3'-Cyclic nucleotide 3'-phosphodiesterase (CNP; EC 3.1.4.37), the myelin-specific enzyme, showed normal specific activities in mld nerves. In mld and control myelin, CNP-specific activities decreased during development suggesting a preferential localization of CNP in Schwann cell plasma membranes. In contrast to the central nervous system, other myelin proteins were not altered in mld peripheral nervous system (PNS) and the very low MBP content had no severe repercussions on the composition and structure of the myelin sheath. Furthermore, Schwann cells appeared normal in mld PNS. Nevertheless, more subtle alterations could be detected. Slightly decreased amounts of myelin were observed in young mld mice and preliminary results indicate discrete alterations of the myelin periodicity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytoskeletal changes during development and aging in the cortex of neurofilament light protein knockout mice

The neurofilament light (NFL) subunit is considered as an obligate subunit polymer for neuronal intermediate filaments comprising the neurofilament (NF) triplet proteins. We examined cytoskeletal protein levels in the cerebral cortex of NFL knockout (KO) mice at postnatal day 4 (P4), 5 months, and 12 months of age compared with age‐matched wild‐type (WT) mice of a similar genetic background (C57BL/6). The absence of NFL protein resulted in a significant reduction of phosphorylated and dephosphorylated NFs (NF‐P, NF‐DP), the medium NF subunit (NFM), and the intermediate filament α‐internexin (INT) at P4. At 5 months, NF‐DP, NFM, and INT remained significantly lower in knockouts. At 12 months, NF‐P was again significantly decreased, and INT significantly increased, in KOs compared with wild type. In addition, protein levels of class III neuron‐specific β‐tubulin and microtubule‐associated protein 2 were significantly increased in NFL KO mice at P4, 5 months, and 12 months, whereas β‐actin levels were significantly decreased at P4. Immunocytochemical studies demonstrated that NF‐DP accumulated abnormally in the perikarya of cortical neurons by 5 months of age in NFL KO mice. Neurons that lacked NF triplet proteins, such as calretinin‐immunolabeled nonpyramidal cells, showed no alterations in density or cytoarchitectural distribution in NFL KO mice at 5 months relative to WT mice, although calretinin protein levels were decreased significantly after 12 months in NFL KO mice. These findings suggest that a lack of NFL protein alters the expression of cytoskeletal proteins and disrupts other NF subunits, causing intracellular aggregation but not gross structural changes in cortical neurons or cytoarchitecture. The data also indicate that changes in expression of other cytoskeletal proteins may compensate for decreased NFs. J. Comp. Neurol. 521:1817–1827, 2013. © 2012 Wiley Periodicals, Inc.     

Fibrinogen and albumin synthesis during fetal development in mice

The hepatic synthesis of fibrinogen and albumin in mice during fetal development (12 to 20 days gestation) was determined. Fetal hepatic synthesis of fibrinogen matures relatively rapidly and reaches adult levels by the 16th day of gestation. In contrast, albumin production develops more slowly, attaining 80% of adult values immediately prior to birth at 20 days. Autoradiography of fetal hepatocytes cultured in agar established that, in the earliest obtainable hepatocytes (12 days gestation), all cells were producing fibrinogen but a fraction of hepatocytes (about 8%) were not yet producing albumin.     

Abnormal neocortical development in mice lacking cGMP-dependent protein kinase I

Cyclic GMP-dependent protein kinase type I (cGKI) is a key signaling intermediate important for synaptic potentiation in the hippocampus and cerebellum, but its expression and function in cortical development have not been elucidated. The expression of cGKI in the developing mouse neocortex was evaluated by immunofluorescence labeling, and effect of cGKI deletion on cortical development was studied in adult cGKI knockout mice. cGKI was expressed at highest levels at embryonic stages in young neurons and radial glial fibers, corresponding to the major period of radial migration and laminar development of pyramidal neurons (embryonic day E13.5-E14.5), declining upon maturation (E17.5-postnatal day P28). The cerebral cortex of homozygous null mutant mice lacking cGKI exhibited heterotopic collections of neurons in the upper cortical layers and abnormal invaginations of layer I, in accord with a neuronal migration or positioning defect. Some cGKI mutant mice displayed defects in midline development resulting in partial fusion of cerebral hemispheres with adjacent neuronal heterotopias. Apical dendrites of cortical pyramidal neurons were misoriented in the cerebral cortex of cGKI null mutants, as shown in reporter mice expressing yellow fluorescent protein in layer V pyramidal neurons and by Golgi impregnation. These results demonstrate a role for cGKI signaling in cortical development related to neuronal migration/positioning that is important for dendritic orientation and connectivity.     

The role of nutritional factors in behavioural development in laboratory mice.

This paper addresses the importance of considering nutritional factors as a source of variability in studies of behavioural development in mice. Work in our laboratory, using a standardised developmental scale that allows quantitative comparisons among different studies, indicates that nutritional factors do have the propensity to influence behavioural development to a degree similar to that seen with some genotypic manipulations. These nutritional factors encompass both undernutrition, which entails an overall reduction in nutrient and caloric intake, and malnutrition, which refers to a dietary imbalance, i.e. a deficiency (or excess) of specific macro- or micronutrients. As an example of malnutrition, we describe investigations in mice that address the role of the essential fatty acids in brain and behavioural development. These show that manipulations of dietary lipid composition that are in the same range that one would find among commercial laboratory diets influence not only behavioural development, but also performance on other behavioural tasks. This suggests that detailed dietary information may be useful in the attempt to characterise the sources of variation in the behavioural phenotypes of mice.     

Isoforms changes of tau protein during development in various species

Tau protein is one of the major microtubule-associated proteins of the vertebrate nervous system. Some kinds of isoforms, for example, six isoforms in humans, are generated from a single gene by alternative mRNA splicing. The expression of tau protein is widely believed to be developmentally and pathologically regulated. We examined developmental changes in tau protein from humans, rats, mice, and guinea pigs to determine the universal function of each isoform. Tau isoforms, composed of variants in the amino terminal and carboxyl terminal regions, gradually shifted through development in protein. The developmental changes in the carboxyl terminal region were found to be conserved in all species in which three-repeat tau isoforms were dominant in the fetus or neonate, while four-repeat tau isoforms were dominant in adult brain. On the other hand, the changes in the amino terminal region were not identical in these species. These observations were confirmed using isoform-specific antibodies which could discriminate the numbers of amino-terminus insertions and carboxy-terminus repeat insertions. Developmental regulation of 3- and 4-repeat tau isoforms may contribute to axonal development and neural plasticity.     

Changes in hippocampal synaptic functions and protein expression in monosodium glutamate‐treated obese mice during development of glucose intolerance

Glucose is the sole neural fuel for the brain and is essential for cognitive function. Abnormalities in glucose tolerance may be associated with impairments in cognitive function. Experimental obese model mice can be generated by an intraperitoneal injection of monosodium glutamate (MSG; 2 mg/g) once a day for 5 days from 1 day after birth. MSG‐treated mice have been shown to develop glucose intolerance and exhibit chronic neuroendocrine dysfunction associated with marked cognitive malfunctions at 28–29  weeks old. Although hippocampal synaptic plasticity is impaired in MSG‐treated mice, changes in synaptic transmission remain unknown. Here, we investigated whether glucose intolerance influenced cognitive function, synaptic properties and protein expression in the hippocampus. We demonstrated that MSG‐treated mice developed glucose intolerance due to an impairment in the effectiveness of insulin actions, and showed cognitive impairments in the Y‐maze test. Moreover, long‐term potentiation (LTP) at Schaffer collateral–CA1 pyramidal synapses in hippocampal slices was impaired, and the relationship between the slope of extracellular field excitatory postsynaptic potential and stimulus intensity of synaptic transmission was weaker in MSG‐treated mice. The protein levels of vesicular glutamate transporter 1 and GluA1 glutamate receptor subunits decreased in the CA1 region of MSG‐treated mice. These results suggest that deficits in glutamatergic presynapses as well as postsynapses lead to impaired synaptic plasticity in MSG‐treated mice during the development of glucose intolerance, though it remains unknown whether impaired LTP is due to altered inhibitory transmission. It may be important to examine changes in glucose tolerance in order to prevent cognitive malfunctions associated with diabetes.     

Effects of protein malnutrition during development on protein synthesis in brain and peripheral tissues

Rats born of mothers fed a low protein diet (8% casein versus a normal 25% casein diet) starting 5 weeks prior to mating showed a 50–100% increase in protein synthesis in the brain and kidney on the day of birth. This effect was due to a 50–100% increase in the uptake of IP injected ¹⁴C-leucine in the malnourished rats. The proportion of total tissue radioactivity in the trichloroacetic acid-protein precipitates was the same in the 8% and 25% casein groups. For the most part, there were no significant diet related changes in uptake or incorporation of ¹⁴C-leucine in the brain, liver or kidney in the 8% and 25% casein groups on Days 5, 10–11 and 21. While the physiological basis of the diet related changes seen on the day of birth is unknown, the present data represent a previously undescribed effect of prenatal protein malnutrition.     

Degeneration of pontine mossy fibres during cerebellar development in weaver mutant mice

In weaver mutant mice, substitution of an amino acid residue in the pore region of GIRK2, a subtype of the G-protein-coupled inwardly rectifying K+ channel, changes the properties of the homomeric channel to produce a lethal depolarized state in cerebellar granule cells and dopaminergic neurons in substantia nigra. Degeneration of these types of neurons causes strong ataxia and Parkinsonian phenomena in the mutant mice, respectively. On the other hand, the mutant gene is also expressed in various other brain regions, in which the mutant may have effects on neuronal survival. Among these regions, we focused on the pontine nuclei, the origin of the pontocerebellar mossy fibres, projecting mainly into the central region of the cerebellar cortex. The results of histological analysis showed that by P9 the number of neurons in the nuclei was reduced in the mutant to about one half and by P18 to one third of those in the wild type, whereas until P7 the number were about the same in wild-type and weaver mutant mice. Three-dimensional reconstruction of the nuclei showed a marked reduction in volume and shape of the mutant nuclei, correlating well with the decrease in neuronal number. In addition, DiI (a lipophilic tracer dye) tracing experiments revealed retraction of pontocerebellar mossy fibres from the cerebellar cortex after P5. From these results, we conclude that projecting neurons in the pontine nuclei, as well as cerebellar granule cells and dopaminergic neurons in substantia nigra, strongly degenerate in weaver mutant mice, resulting in elimination of pontocerebellar mossy fibres during cerebellar development.     

NR3 protein expression in trigeminal neurons during postnatal development

The N-methyl-d-aspartate (NMDA) receptor plays an important role in the generation of rhythmical oral motor activities. To compliment our previous studies, we examined the developmental regulation of NR3A and NR3B expression in trigeminal motoneurons (Mo5) and mesencephalic trigeminal neurons (Me5). NR3A-immunoreactive neurons were observed at all ages in both nuclei, decreasing in Mo5 and caudal Me5 after P14, and increasing in rostral Me5. NR3B protein expression only emerged in Mo5 after P21-23. Results indicate that NR3A and NR3B expression is differentially regulated between Mo5 and Me5 coincident with the transition from suckling to chewing.     

RNA concentration and protein synthesis in rat brain during development

Type I cells of embryonic rabbit carotid bodies were cultured under normoxic (21% O2, 10% CO2, 69% N2) and hypoxic (5% O2, 10% CO2, 85% N2) conditions for two days. The mean membrane potential in the hypoxic cultivated type I cells (-27 mV) was significantly higher than in normoxic cultivated cells (-10 mV). The mean input resistance also had the tendency to increase under hypoxic conditions, from 19 m omega to 48 M omega. Results suggest that variations in membrane potential of type I cells due to oxygen pressure changes are an expression of the important role of these cells in oxygen sensing by the carotid body.     

Regional distribution of myelin basic protein in the central nervous system of quaking, jimpy, and normal mice during development and aging

Myelin basic protein (MBP) was quantified using a RIA technique in the spinal cord, cerebellum, diencephalon plus brainstem region and cerebral hemispheres of two dysmyelinating murine mutants, quaking (qk) and jimpy (jp) mice. Comparison was made with normal control values. The whole life-span has been investigated: ie, ages ranging from 0 to 26 days for the jp, O to one year for the qk, and prenatal stage to three years for the control animals. Assays in the mutants at early ages were rendered feasible by the use of marker genes, which has allowed the diagnosis of the mutation at birth, 12 days before the expression of their typical tremor phenotype. Special care was given to the period of early myelinogenesis in order to clarify the dysynchrony between the various parts of the central nervous system. In normal mice, MBP was already detected in the brain of 19-day-old embryos. During development, rapid accumulation of MBP first occurred in the spinal cord then in the diencephalon, the brainstem, the cerebellum, and finally in the cerebral hemispheres. In the 25-day-old jimpy mutant, levels of MBP were found dramatically decreased, never exceeding 6% of the normal controls in any of the areas investigated. The situation for the quaking mouse was quite different. This mutant could be investigated up to one year old. At that age, a high discrepancy was observed between the values found in the brain and in the spinal cord (respectively, 10% and 35%) compared to normal controls. In both mutants, not only were the levels of MBP decreased, but also its appearance during development was delayed. Nevertheless, in both mutants the caudo-rostral timing of myelination as assayed by MBP levels was maintained. Furthermore, the later myelination occurred, the stronger weas the deficit in MBP. Interestingly, in the quaking mutant, the specific plasticity of the spinal cord was exemplified by its ability to reduce constantly, even at an advanced age, its initial deficit of MBP.     

Huntingtin is localized in the nucleus during preimplanatation embryo development in mice

Huntington's disease (HD) is a dominant neurodegenerative disorder caused by the expansion of a CAG repeat in the gene encoding huntingtin. Moreover, the nuclear targeting of mutant huntingtin increases cellular toxicity, whereas normal huntingtin resides mainly in the cytoplasm, and is associated with membranes or microtubules. Huntingtin is enriched in neurons and its expression is increased during neural development. The inactivation of the HD gene results in embryonic lethality before nervous system development. Thus, huntingtin is critical during early embryonic development. Nevertheless, the function of huntingtin at this stage is unknown, even the distribution of the protein has not been described. The present study was undertaken to elucidate the distribution of huntingtin during the early developmental period in the mouse embryo. At the preimplantation stage, huntingtin was detected in nuclei up to 2.5 days post coitum (dpc), but disappeared from nuclei during the blastocyst stage (3.5 dpc). Following this stage, huntingtin was mainly localized in the cytoplasm and co-localized with mitotic spindles. These data suggest that the nuclear targeting of normal huntingtin is required during early embryo development in mice.     

Myelin/oligodendrocyte glycoprotein expression during development in normal and myelin-deficient mice

The myelin/oligodendrocyte glycoprotein (MOG) is identified by monoclonal antibody 8-18C5. MOG is localized on the surface of myelin and oligodendrocyte processes. Recently, several studies have shown that MOG plays an important role as a target for antibody-induced demyelination. In the present study, we investigated MOG expression in the brains of normal and myelin-deficient (mld) mutant mice during development. By gel electrophoresis and immunoblotting, we observed the developmental pattern of two closely migrating bands, with apparent molecular masses of 26 and 28 kilodaltons. Their concentrations increased coordinately during the most active phase of myelin and myelin basic protein (MBP) synthesis. Between 20 and 25 days of age, the MOG developmental pattern superimposed that of MBP as well as myelin yields. In mld mutant mice, which are affected by a severe deficit of MBP synthesis, MOG was present at reduced levels (40% of controls at 60 days of age). At 85 days of age, mld mice exhibited increased concentrations of MBP, and myelin was better compacted. At this age, MOG concentrations increased and reached 70% of controls. These results suggest that MOG could play a role in the maintenance or completion of the myelin sheath. Its expression level may be modulated by the presence of compact myelin and/or MBP in the myelin sheath.     

IL1RAPL1 controls inhibitory networks during cerebellar development in mice

Abnormalities in the formation and function of cerebellar circuitry potentially contribute to cognitive deficits in humans. In the adult, the activity of the sole output neurons of the cerebellar cortex – the Purkinje cells (PCs) – is shaped by the balance of activity between local excitatory and inhibitory circuits. However, how this balance is established during development remains poorly understood. Here, we investigate the role of interleukin-1 receptor accessory protein-like 1 (IL1RAPL1), a protein linked to cognitive function which interacts with neuronal calcium sensor 1 (NCS-1) in the development of mouse cerebellum. Using Il1rapl1 -deficient mice, we found that absence of IL1RAPL1 causes a transient disinhibition of deep cerebellar nuclei neurons between postnatal days 10 and 14 (P10/P14). Upstream, in the cerebellar cortex, we found developmental perturbations in the activity level of molecular layer interneurons (MLIs), resulting in the premature appearance of giant GABAA-mediated inhibitory post-synaptic currents capable of silencing PCs. Examination of feed-forward recruitment of MLIs by parallel fibres shows that during this P10/P14 time window, MLIs were more responsive to incoming excitatory drive. Thus, we conclude that IL1RAPL1 exerts a key function during cerebellar development in establishing local excitation/inhibition balance.     

Environmental change during postnatal development alters behaviour, cognitions and neurogenesis of mice

Four groups of male C57BL/6 mice were reared differing combinations of the two environments from 3 to 11 weeks after birth. At 12 and 13 weeks they were assessed by measures of behaviour and learning: open-field activity, auditory startle reflex and prepulse inhibition, water maze learning, and passive avoidance. Another four groups of mice reared under these varying conditions were examined for generation of neurons in hippocampus and cerebral cortex using bromodeoxyuridine (BrdU) at 12 weeks. Enriched (EE) and impoverished (PP) groups were housed in their respective environment for 8 weeks, enriched-impoverished (EP) and impoverished-enriched (PE) mice respectively were reared for 6 weeks in the first-mentioned environment and then for 2 weeks in the second. PP and EP mice showed hyperactivity, greater startle amplitude and significantly slower learning in a water maze than EE or PE animals, and also showed a memory deficit in a probe test, avoidance performance did not differ. Neural generation was greater in the EE and PE than PP and EP groups, especially in the hippocampus. These results suggest that environmental change critically affects behavioural and anatomic brain development, even if brief. In these mice, the effect of unfavourable early experience could be reversed by a later short of favourable experience.     

Maternal hypoxia during pregnancy delays the development of motor reflexes in newborn mice

Prenatal hypoxic-ischemic brain injury is believed to cause permanent neurological deficits in newborns. We investigated the possibility that maternal hypoxia during pregnancy leads to offspring brain damage and its prevention by i.p. administration of MgSO4. Pregnant mice at gestation day 17 were exposed to hypoxia or air following pretreatment with saline or Mg. Newborn mice to mothers exposed to hypoxia demonstrated faster development of morphogenic parameters such as eyelid opening, hair growth and teeth eruption. In addition, hypoxia delayed the development of motor reflexes. Pretreatment with Mg compensates for hypoxia-induced impairment and in some cases accelerates the development of these functions. In conclusion, maternal hypoxia significantly modifies the developmental process of newborn mice. In our study, pretreatment with Mg showed significant prophylactic action against motor impairments.