Changes during development of mouse brain in the activities and subcellular distributions of creatine and adenylate kinases

Effects of creatine and β-guanidinopropionic acid and alterations in creatine transporter and creatine kinases expression in acute seizure and chronic epilepsy models

Background

In order to confirm the roles of creatine (Cr) in epilepsy, we investigated the anti-convulsive effects of Cr, creatine transporter (CRT) and creatine kinases (CKs) against chemical-induced acute seizure activity and chronic epileptic seizure activity.

Results

Two hr after pilocarpine (PILO)-seizure induction, ubiquitous mitochondrial CK (uMtCK) immunoreactivity was unaltered as compared to control level. However, brain-type cytoplasm CK (BCK) immunoreactivity was decreased to 70% of control level. CRT immunoreactivity was decreased to 60% of control level. Following Cr or Tat-CK treatment, uMtCK or CRT immunoreactivity was unaffected, while BCK immunoreactivity in Cr treated group was increased to 3.6-fold of control levels. β-Guanidinopropionic acid (GPA, a competitive CRT inhibitor) reduced BCK and CRT expression. In addition, Cr and tat-BCK treatment delayed the beginning of seizure activity after PILO injection. However, GPA treatment induced spontaneous seizure activity without PILO treatment. In chronic epilepsy rats, both uMtCK and CRT immunoreactivities were reduced in the hippocampus. In contrast, BCK immunoreactivity was similar to that observed in control animals. Cr-, GPA and tat-BCK treatment could not change EEG.

Conclusion

Cr/CK circuit may play an important role in sustaining or exacerbating acute seizure activity, but not chronic epileptic discharge.

Opposite transitions of chick brain catalytically active cytosolic creatine kinase isoenzymes during development

Postnatally the rat brain synthesizes catalytic forms of muscle type (MM) and heart type (MB) creatine kinase (CK), besides the supposedly sole type vertebrate brain-specific (BB) CK. We intended to demonstrate that in Rhode Island chicken brain, cytosolic (c) CK isoenzymatic transitions. (for example BB-CK is followed by the appearance of MB-CK and MM-CK during muscle differentiation), can also occur during development and aging. Cytosolic post 125000 x g, mitochondrial CK-free, brain samples were obtained for zone electrophoresis separation and identification of catalytically active cCK isoforms. BB-CK was never found during chicken brain ontogeny. Against the accepted view, an opposite isoenzyme transition pattern from MM through BB-CK was found in the chicken embryonic brain from the very early stages of development up to day 2 post-hatching. At very early stages of chicken brain ontogeny constitutive MM- and MB-CK isoenzymes were present before the advent of creatine. It seems to be that typical and atypical brain MM- and MB-CK could be working as ATPases in the absence of creatine before embryonic stage 28 (day 5.5) and/or such CK isoforms may begin to form part of the slow component b in developing early neurons and later in the nuclei of glial cells to be used by the CK/phosphocreatine (PC) system as the neural tissues mature. The post-hatching transition pattern showed simultaneous expression of more than one CK isoenzyme within the same neural sample as in post-natal rat brain, presumably due to regional differential transphosphorylation requirements. Strain-dependent enzymatic specific activities have been reported in several species. Since equivalent values of brain CK specific activity were obtained previously from the embryonic plateau phase of CK activity during White Leghorn development, and those from Rhode Island brain neurons cultured 11 days, we compared if, in vivo, a similar brain CK specific activity pattern was physiologically equivalent during Rhode Island and White Leghorn chicken ontogeny. We found quantitatively different strain-specific CK specific activity patterns during this period. Rhode Island brain CK activity values were approximately 4.5-fold those of White Leghorn ones. This indicates that production of energy from anaerobic metabolism and transphosphorylation by the CK/PC system to synthesize ATP more efficiently is strain-specific. In Rhode Islands, there was an age-dependent increase of CK specific activity, mostly in older animals (440% above the value found during the embryonic plateau), when the Krebs cycle and glycolysis lose capacity. During adult life and aging, under physiological conditions, the three CK isoenzymes may participate in diverse functions of the different cell compartments of brain glia and neurons with regard to their high and fluctuating energy demands that are not completely covered by anaerobic and aerobic glycolisis.

Identification of a novel adenylate kinase system in the brain: cloning of the fourth adenylate kinase

We identify a novel subtype of adenylate kinase, which is the 4th adenylate kinase (AK4), in the vertebrate. AK4 mRNA is expressed in the mammalian central nervous system in a region-specific manner from the middle stage of embryogenesis to the adulthood in the rodent. The presence of three isozymes of adenylate kinase (AK1, AK2 and AK3) that maintains the homeostasis of adenine and guanine nucleotide composition has been reported in the vertebrate. Obtained mouse AK4 cDNA is 3667 bp in size. The predicted open reading frame consists of 223 amino acid residues. Rat AK4 cDNA is also obtained, and the predicted open reading frame is the same length as that of the mouse. The predicted rat AK4 molecule shows 97.8% homology with mouse AK4. Rat AK4 protein is distinct from rat AK3, 53.8% homologous with rat AK3, although the adenylate kinase signature and the mitochondrial energy transfer protein signature are found in both sequences. Interestingly, rat AK4 is 89.2% homologous with the human AK3 over 223 amino acid residues and rat AK3 is 53.7% homologous with the human AK3 indicating that the reported human AK3 actually belongs to the AK4 group (therefore, it should be referred to as human AK4). Although the sequence of AK4 is most similar to that of AK3 among the AK isozymes, its in vivo expression is completely different from AK3; AK4 mRNA is expressed in the pyramidal cells in the hippocampus (mainly in the subfield CA3), the granular cells in the cerebellum, nasal neuroepithelium and the liver while AK3 mRNA is expressed ubiquitously in the body. It is probable that AK4 acts on the specific mechanism of energy metabolism rather than control of the homeostasis of the ADP pool ubiquitously.

Expression of brain-type creatine kinase and ubiquitous mitochondrial creatine kinase in the fetal rat brain: evidence for a nuclear energy shuttle

To test the hypothesis that embryonic brain cells utilize a creatine phosphate energy shuttle, we examined the pattern of creatine kinase (CK) isoform expression and localization in the fetal rat brain. Moderate levels of CK activity are present at embryonic day 14 (7 U/mg protein) and decrease slightly until 3 days postpartum followed by a rapid, fourfold up-regulation to adult levels by 1 month (18 U/mg protein). In parallel with changes in enzyme activity, there is a biphasic and coordinate pattern of expression of brain-type CK (BCK) and ubiquitous mitochondrial CK (uMtCK) determined by nondenaturing electrophoresis and immunoblot analysis. The localization of CK isoforms was examined by immunocytochemistry, and, during the fetal period, BCK and uMtCK immunoreactivity was detected throughout the central and peripheral nervous system, especially in neuroepithelial regions of the cerebral vesicles and spinal cord. In large cells within the olfactory neuroepithelium and ventral spinal cord, differential compartmentation of CK isoforms was evident, with BCK localized primarily in cell nuclei, whereas uMtCK immunoreactivity was present in the cell body (but not within nuclei). In olfactory bulb neuroepithelium, both isoforms were expressed in the middle zone of the germinal layer associated with DNA synthesis. In embryonic skeletal and cardiac muscle, which also express BCK, the same compartmentation of BCK was seen, with BCK localized primarily in the cell nucleus of cardiac and skeletal myoblasts. These results demonstrate a coordinate pattern of expression and compartmentation of BCK and uMtCK isoforms in the fetal brain that, in some cells, provides the anatomic basis for a nuclear energy shuttle.

Brain creatine kinase activity during ontogeny of the cichlid fish oreochromis mossambicus and the clawed toad Xenopus laevis, influence of gravity?

The development of creatine kinase (CK) activity was studied in the brain of cichlid fish and clawed toads. The activity of CK in the whole brain of the fish decreases immediately after hatching (stage 6) from values of about 135 nmol substrate cleaved/mg protein/min to a value of about 105 at stage 8 (5 days post hatch at 20 degrees C). With the exception of a significant peak (125 nmol) between stages 9 and 10 (7 and 9 days respectively, post hatch at 20 degrees C) and a small intermediate peak at stages 12 and 13 (about 10 days post hatch at 20 degrees C) a constant level of about 100 nmol cleaved substrate is maintained until maturity. In contrast, CK activity was determined to be 3-fold higher in the whole brain of the clawed toad. With the exception of two significant peaks at stages 47 and 49 (5 and 12 days respectively, post fertilization at 23 degrees C) a value of about 360 nmol was found during larval development and metamorphosis, as well as in the adult brain. In investigating the possible influence of gravity on CK activity during early ontogeny of the brain both animal species were exposed to hyper-gravity (3 +/- 1 g) for 7 days. A significant decrease of total CK activity of 20% was found in the fish brain and of about 5% in the toad.(ABSTRACT TRUNCATED AT 250 WORDS)

Creatine kinase activity in postnatal rat brain development and in cultured neurons, astrocytes, and oligodendrocytes

The development and distribution of cytosolic creatine kinase (CK) activity was studied in rat brain and in cell culture. The activity of CK in whole brain increased almost fivefold during the period from birth to day 40 when adult levels of 18-19 U/mg of protein were attained. The distribution of CK activity was examined in dissected regions of the adult brain and was nonuniform; the cerebellum, the striatum, and the pyramidal tracts contained significantly higher CK activity than did whole brain. The cellular compartmentation of CK was investigated using primary cultures of purified neurons, astrocytes, and oligodendrocytes. The CK activity in neurons increased fourfold greater than that measured at the time of isolation to 4 U/mg of protein. The CK activity in astrocytes cultured for 20 days was 3.5 U/mg of protein and was 1.5-fold greater than that measured at the time of isolation. In contrast, the CK activity in cultured oligodendrocytes (day 20) was three- to fourfold higher than that determined in astrocytes and almost sevenfold higher than the activity measured at the time the cells were isolated. The high levels of CK in cultured oligodendrocytes suggest a role for this enzyme in oligodendrocyte function and/or myelinogenesis.

Rat brain synaptosomal ATP:AMP-phosphotransferase activity

Adenylate kinase activity (ATP:AMP-phosphotransferase; EC 2.7.4.3) was studied in various subcellular fractions of rat brain tissues. Because of the presence of other adenosine nucleotide-utilizing enzymes, adenylate kinase activity was assayed in both the forward and reverse directions by using coupled enzyme systems and by using a specific adenylate kinase inhibitor, P1,P5-di(adenosine-5') pentaphosphate. As expected, the highest specific adenylate kinase activity (2.89 mumol/min/mg of protein) was detected in the cytosolic brain fraction. However, substantial enzyme activity (0.68 mumol/min/mg) was also found in the intact synaptosomal fraction isolated on Percoll/sucrose gradients. The increased specific enzyme activity of purified synaptosomes and the differences found between the kinetic parameters of the membrane-bound and cytosolic enzyme forms suggest that the synaptosomal adenylate kinase activity cannot be attributed to the small amount of contaminating cytosol present in our preparations. The adenylate kinase enzyme adhered to purified synaptic plasma membranes and was not released by washings with isoosmotic sucrose medium. The facts that the adenylate kinase enzyme activity could be measured in intact synaptosomal preparations and that both its substrates and its inhibitors do not cross intact plasma membranes support the possibility that the synaptosomal adenylate kinase is an ecto-enzyme.

On the ontogeny of aldolase isozymes and their interactions with cellular structure

In an endeavour to extend the available information on the biological significance of the interactions between aldolase and cellular ultrastructure, the extent of association has been studied in the tissues of the mouse during the major stages of development from embryo to adult. Analysis of the isozyme status in these compartments and the latency of the enzyme during tissue differentiation was also effected. In all tissues investigated, a considerable variation in the degree of association of aldolase with structure was evident during development. Binding was particularly extensive in the early embryonic stages, but regardless of the tissue or the stage of differentiation, binding preference was directed towards A-type activity over the B- and C-type of enzyme. Substantial latent activity of aldolase was evident only in brain in the postnatal stages of development, and not in the other tissues or early stages of ontogeny. The significance of these ontogenic phenomena have been discussed, along with the physiological variations in individual tissues during maturation.

Studies on the mitochondrially bound form of rat brain creatine kinase

1. The development of the total rat brain creatine kinase was studied in brain homogenates. Until approx. 14-15 days after birth, the activity remains less than one-third that of the adult activity (207+/-6 units/g wet wt. s.d.; n=3). Over the next 10 days the activity increases markedly to the adult value and thereafter remains essentially constant. 2. In the adult brain, approx. 5% (11.9+/-2.2 units/g wet wt. s.d.; n=5) of the total creatine kinase is associated with the mitochondrial fraction. This creatine kinase could not be solubilized by sodium acetate solutions of up to 0.8m concentration, whereas 66% of the hexokinase associated with brain mitochondria was released under these conditions. 3. Rat brain mitochondria incubated in the presence of various concentrations of creatine (1, 5 and 10mm) and ADP (100mum) synthesized phosphocreatine at rates of approx. 4.5, 11 and 17.5nmol/min per mg of mitochondrial protein. Atractyloside (50mum) or oligomycin (1.5mug/mg of mitochondrial protein) completely inhibited the synthesis of phosphocreatine. 4. The apparent K(m) and V(max.) values of the mitochondrially bound rat brain creatine kinase were determined in both directions. The V(max.) in the direction of phosphocreatine synthesis is 237nmol/min per mg of mitochondrial protein, with an apparent K(m) for creatine of 1.67mm and for MgATP(2-) of 0.1mm, and in the reverse direction V(max.) is 489nmol/min per mg of mitochondrial protein, with an apparent K(m) for phosphocreatine of 0.4mm and for MgADP(-) of 27mum. 5. The results are discussed with reference to the role that the mitochondrially bound creatine kinase may play in the development of brain energy metabolism.