Effect of fasting on glycogen metabolism and activities of glycolytic and gluconeogenic enzymes in the mudskipper Boleophthalmus boddaerti

During starvation, muscle glycogen in Boleophthalmus boddaerti was utilized preferentially over liver glycogen. In the first 10 days of fasting, the ratio of the active‘a’form of glycogen phosphorylase to total phosphorylase present in the liver was small. During this period, the active‘I’form of glycogen synthetase increased in the same tissue. In the muscle, the phosphorylase‘a’activity declined during the first 7 days and increased thereafter while the total glycogen synthetase activity showed a drastic decline during the first 13 days of fasting. The glycogen level in the liver and muscle of mudskippers starved for 21 days increased after refeeding. After 6 and 12 h refeeding, liver glycogen level was 8·5 ± 2·3 and 6·9 ± 4·5 mg·g wet wt ¹, respectively, as compared to 5·8 ± l·6mg·g wet wt ¹ in unfed fish. Muscle glycogen level after 6 and 12 h refeeding was 0·96±0·76 and 0·82 ± 0·50 mg·g wet wt ¹, respectively, as opposed to 0·21 ± 0·12 mg·g wet wt ¹ in the 21-days fasted fish. At the same time, activities of glycogen phosphorylase in the muscle and liver increased while the active‘I’form of glycogen synthetase showed higher activity in the liver. Since glycogen was resynthesized upon refeeding, this eliminated the possibility that glycogen depletion during starvation was due to stress or physical exhaustion after handling by the investigator. Throughout the experimental starvation period, the body weight of the mudskipper decreased, with a maximum of 12% weight loss after 21 days. Liver lipid reserves were utilized at the onset of fasting but were thereafter resynthesized. Muscle proteins were also metabolized as the fish were visibly thinner. However, no apparent change in protein content expressed as per gram wet weight was detected as the tissue hydration state was maintained constant. The increased degradation of liver and muscle reserves was coupled to an increase in the activities of key gluconeogenic enzymes in the liver (G6Pase, FDPase, PEPCK, MDH and PC). The increase in glucose synthesis was possibly necessary to counteract hypoglycemia brought about by starvation in B. boddaerti.     

The expression of T cell receptor-associated proteins during T cell ontogeny in man

The expression of TCR-associated molecules was examined in human fetal and postnatal tissues. From gestational wk 7 onward in the fetal liver, putative prothymocytes have been identified with cytoplasmic CD3 positivity (cCD3+). These immature cells are TdT- and do not express membrane CD3 (mCD3-) or TCR beta identified by beta F1, but show CD7 and CD45 positivity without CD1, CD2, CD5, CD4, CD8, CD10, and class II Ag. Their high proliferative activity is indicated by greater than 85% Ki67 positivity. After the 10th wk, beta F1+, mCD3+ cells also appear in the liver and these are mostly Ki67- but no TCR gamma delta-bearing cells can be identified at such an early stage of extrathymic development. In the mCD3- TdT-fetal thymus (10 1/2 to 18th wk) cCD3+, mCD3- CD1-blasts proliferate (Ki67+) and lack TCR-beta or TCR-gamma delta. The TdT-, CD1+ cortical thymocytes develop into TCR-beta + and WT31-positive (TCR-alpha beta +) cells. Subsequently TdT-positive thymocytes become detectable around 19 to 20 wk, and in such glands the peak of proliferative activity is seen among TdT+, cCD3+ cells which appear to acquire, in a regular sequence, cytoplasmic beta F1 (TCR-beta), mCD3, and TCR-alpha beta (WT31 positivity) together with the loss of TdT and Ki67 positivity. A newly described transitional population of cells is TdT-, beta F1+ but exhibits no detectable WT31 positivity. These cells correspond to the CD1+, mCD3+ thymocytes and are probably the targets of thymic selection. The cells of the TCR-gamma delta lineage, detected by mAb TCR-delta-1 and delta TCS1, are rare (0.02 to 0.5%) among thymocytes from gestational wk 10 1/2 onward through the whole span of thymic development, but these cells include a proportion (18 to 59%) of cells expressing CD1 Ag, suggesting that these TCR-gamma delta cells differentiate in the thymus. Among the CD1+, TCR-gamma delta + thymocytes, no TdT positivity can be detected.     

Active ammonia excretion in the giant mudskipper, Periophthalmodon schlosseri (Pallas), during emersion

The main objective of this study was to determine whether active NH(4) (+) excretion occurred in the giant mudskipper, Periophthalmodon schlosseri, during emersion. Our results demonstrated that continual ammonia excretion in P. schlosseri during 24 hr of emersion resulted in high concentrations ( approximately 30 mmol l(-1)) of ammonia in fluid collected from the branchial surface. For fish injected intraperitoneally with 8 mumol g(-1) ammonium acetate (CH3COONH4) followed by 24 hr of emersion, the cumulative ammonia excreted was significantly greater than that of the control injected with sodium acetate. More importantly, the ammonia excretion rate at hour 2 in fish injected with CH3COONH4 followed by emersion was greater than that in fish immersed in water as reported elsewhere, with the greatest change in the ammonia excretion rate occurring at hour 2. Assuming that the rate of endogenous ammonia production remained unchanged, 33% of the exogenous ammonia was excreted through the head region, presumably through the gills, during the first 6 hr of emersion. Indeed, at hour 6, the ammonia concentration in the branchial fluid increased to an extraordinarily high concentration of >90 mmol l(-1). Therefore, our results confirm for the first time that P. schlosseri can effectively excrete a high load of ammonia on land, and corroborate the proposition that active NH(4) (+) excretion through its gills contributes in part to its high tolerance of aerial exposure. Only 4.6% of the exogenous ammonia was detoxified to urea. The glutamate contents in the muscle and liver also increased significantly, but the glutamine contents remained unchanged.     

Cyclin-Dependent Kinase 5 Links Extracellular Cues to Actin Cytoskeleton During Dendritic Spine Development

Emerging evidence has indicated a regulatory role of cyclin-dependent kinase 5 (Cdk5) in synaptic plasticity as well as in higher brain functions, such as learning and memory. However, the molecular and cellular mechanisms underlying the actions of Cdk5 at synapses remain unclear. Recent findings demonstrate that Cdk5 regulates dendritic spine morphogenesis through modulating actin dynamics. Ephexin1 and WAVE-1, two important regulators of the actin cytoskeleton, have both been recently identified as substrates for Cdk5. Importantly, phosphorylation of these proteins by Cdk5 leads to dendritic spine loss, revealing a potential mechanism by which Cdk5 regulates synapse remodeling. Furthermore, Cdk5-dependent phosphorylation of ephexin1 is required for the ephrin-A1 mediated spine retraction, pointing to a critical role of Cdk5 in conveying signals from extracellular cues to actin cytoskeleton at synapses. Taken together, understanding the precise regulation of Cdk5 and its downstream targets at synapses would provide important insights into the multi-regulatory roles of Cdk5 in actin remodeling during dendritic spine development.Excitatory synaptic transmission occurs primarily at dendritic spines, small protrusions that extend from dendritic shafts. Emerging studies have shown that dendritic spines are dynamic structures which undergo changes in size, shape and number during development, and remain plastic in adult brain.¹ Regulation of spine morphology has been implicated to associate with changes of synaptic strength.² For example, enlargement and shrinkage of spines was reported to associate with certain forms of synaptic plasticity, i.e., long-term potentiation and long time depression, respectively.³ Thus, understanding the molecular mechanisms underlying the regulation of spine morphogenesis would provide insights into synapse development and plasticity. Receptor tyrosine kinases (RTKs) such as the Ephs are known to play critical roles in regulating spine morphogenesis. Eph receptors are comprised of 14 members, which are classified into EphAs and EphBs according to their sequence homology and ligand binding specificity. With a few exceptions, EphAs typically bind to A-type ligands, whereas EphBs bind to B-type ligands. During development of the central nervous system (CNS), ephrin-Eph interactions exert repulsive/attractive signaling, leading to regulation of axon guidance, topographic mapping and neural patterning.⁴ Activated Ephs trigger intracellular signaling cascades, which subsequently lead to remodeling of actin cytoskeleton through tyrosine phosphorylation of its target proteins or interaction with various cytoplasmic signaling proteins. Intriguingly, emerging studies have revealed novel functions of Ephs in synapse formation and synaptic plasticity.⁵ Specific Ephs expressed in dendritic spines of adult brain are implicated in regulating spine morphogenesis, i.e., EphBs promote spine formation and maturation, while EphA4 induces spine retraction.^6,7In the adult hippocampus, EphA4 is localized to the dendritic spines.^7,8 Activation of EphA4 at the astrocyte-neuron contacts, triggered by astrocytic ephrin-A3, leads to spine retraction and results in a reduction of spine density.⁷ It has been well established that actin cytoskeletal rearrangement is critical for spine morphogenesis, and is controlled by a tight regulation of Rho GTPases including Rac1/Cdc42 and RhoA. Antagonistic regulation of Rac1/Cdc42 and RhoA has been observed to precede changes in spine morphogenesis, i.e., activation of Rac1/Cdc42 and inhibition of RhoA is involved in spine formation, and vice versa in spine retraction.⁹ Rho GTPases function as molecular switches that cycle between an inactive GDP-bound state and an active GTP-bound state. The activation status of GTPase is regulated by an antagonistic action of guanine-nucleotide exchange factors (GEFs) which enhance the exchange of bound GDP for GTP, and GTPase-activating proteins (GAPs) which increase the intrinsic rate of hydrolysis of bound GTP.¹⁰ Previous studies have implicated that Rho GTPases provides a direct link between Eph and actin cytoskeleton in diverse cellular processes including spine morphogenesis.¹¹ In particular, EphBs regulate spine morphology by modulating the activity of Rho GTPases, thereby leading to rearrangement of actin networks.^12–14 Although EphA4 activation results in spine shrinkage, the molecular mechanisms that underlie the action of EphA4 at dendritic spines remain largely unclear.Work from our laboratory recently demonstrated a critical role of cyclin-dependent kinase 5 (Cdk5) in mediating the action of EphA4 in spine morphogenesis through regulation of RhoA GTPase.¹⁵ Cdk5 is a proline-directed serine/threonine kinase initially identified to be a key regulator of neuronal differentiation, and has been implicated in actin dynamics through regulating the activity of Pak1, a Rac effector, during growth cone collapse and neurite outgrowth.¹⁶ We found that EphA4 stimulation by ephrin-A ligand enhances Cdk5 activity through phosphorylation of Cdk5 at Tyr15. More importantly, we demonstrated that ephexin1, a Rho GEF, is phosphorylated by Cdk5 in vivo. Ephexin1 was reported to transduce signals from activated EphA4 to RhoA, resulting in growth cone collapse during axon guidance.^17,18 Interestingly, we found that ephexin1 is highly expressed at the post-synaptic densities (PSDs) of adult brains.¹⁵ Loss of ephexin1 in cultured hippocampal neurons or in vivo perturbs the ability of ephrin-A to induce EphA4-dependent spine retraction. The loss of ephexin1 function in spine morphology can be rescued by reexpression of wild-type ephexin1, but not by expression of its phosphorylation-deficient mutant. Our findings therefore provide important evidence that phosphorylation of ephexin1 by Cdk5 is required for the EphA4-dependent spine retraction.Molecular mechanisms underlying the action of Cdk5/ephexin1 on actin networks in EphA4-mediated spine retraction is just beginning to be unraveled. It was reported that activation of EphA4-signaling induces tyrosine phosphorylation of ephexin1 through Src family kinases (SFKs), and promotes its exchange activity towards RhoA.¹⁷ Interestingly, mutation of the Cdk5 phosphorylation sites of ephexin1 attenuates the Src-dependent tyrosine phosphorylation of ephexin1 at Tyr⁸⁷ upon EphA4 activation. These findings suggest that Cdk5 is the “priming” kinase for ephexin1. We propose that EphA4 activation by ephrin-A ligand increases Cdk5 activity, leading to phosphorylation and priming of ephexin1 for the subsequent phosphorylation of ephexin1 by Src kinase at Tyr⁸⁷, resulting in an increase of its exchange activity towards RhoA. Thus, regulation of Cdk5 activity might indirectly control the phosphorylation of ephexin1 by Src. It is tempting to speculate that phosphorylation of ephexin1 by Cdk5 at the amino-terminal region leads to a conformational change of protein, thus facilitating the access of Tyr⁸⁷ site on ephexin1 to Src kinase. Whereas accumulating evidence have pointed to a pivotal role of various GEFs including Tiam1, intersectin and kalirin in regulating spine morphogenesis, the involvement of GAPs is not clear. For example, oligophrenin-1, a Rho GAP, is implicated in maintaining the spine length through repressing RhoA activity.¹⁹ Thus, it is conceivable that a specific GAP is involved in EphA4-dependent spine retraction. Recently, we found that α2-chimaerin, a Rac GAP, regulates EphA4-dependent signaling in hippocampal neurons (Shi and Ip, unpublished observations). Taken into consideration that α2-chimaerin is enriched in the PSDs, α2-chimaerin is a likely candidate that cooperates with ephexin1 during EphA4-dependent spine retraction.In addition to stimulation of the RTK signaling cascade following EphA4 receptor activation, clustering of EphA4 signaling complex is required for eliciting maximal EphA4 function.²⁰ It is tempting to speculate that Cdk5 also regulates the formation of EphA4-containing clusters in neurons. Indeed, Cdk5^-/- neurons show reduced size of EphA4 clusters upon ephrin-A treatment, suggesting that Cdk5 regulates the recruitment of downstream signaling proteins to activate EphA4. Moreover, since ephrinA-EphA4 interaction stimulates the activity of Cdk5 at synaptic contacts, it is possible that Cdk5 might play additional roles at the post-synaptic regions through phosphorylation of its substrates. For example, PSD-95, the major scaffold protein in the PSDs, and NMDA receptor subunit NR2A are both substrates for Cdk5. Interestingly, phosphorylation of these proteins by Cdk5 has been implicated in regulating the clustering of neurotransmitter receptors as well as synaptic transmission.^21,22 Consistent with these observations, spatial distribution of neurotransmitter receptors at neuromuscular synapses is altered and abnormal neurotransmission is observed in Cdk5^-/- mice.²³ Thus, further analysis to delineate the precise roles of Cdk5 in EphA4-dependent synapse development, including regulation of neurotransmitter receptor clustering, is required.Recently, Cdk5 was shown to regulate dendritic spine density and shape through controlling the phosphorylation status of Wiskott-Aldrich syndrome protein-family verprolin homologous protein 1 (WAVE-1), a critical component of actin cytoskeletal network.²⁴ In particular, phosphorylation of WAVE-1 by Cdk5 prevents actin from Arp2/3 complex-dependent polymerization and leads to a loss of dendritic spines at basal state, while reduced Cdk5-dependent phosphorylation of WAVE-1 through cAMP-dependent dephosphorylation leads to an enhanced actin polymerization and increased number of spines. It is interesting to note that phosphorylation of ephexin1 and WAVE-1 by Cdk5 both results in a reduction of spine density. Whether a concerted phosphorylation of these proteins at synapses by Cdk5 plays a role in synaptic plasticity awaits further studies. Precise regulation of Cdk5 activity is unequivocally important to maintain its proper functions at synaptic contacts. Activation of Cdk5 is mainly dependent on its binding to two neuronal-specific activators, p35 or p39, and its activity can be enhanced upon phosphorylation at Tyr¹⁵.While the signals that lie upstream of Cdk5 have barely begun to be unraveled, Cdk5 has been demonstrated to be a key downstream regulator of signaling pathways activated by extracellular cues such as neuregulin, BDNF and semaphorin. To the best of our knowledge, ephrin-EphA4 signaling is the first extracellular cue that has been identified to phosphorylate Cdk5 and promote its activity at CNS synapses.^15,25 Since BDNF-TrkB and semaphorin3A-fyn signaling have also been implicated in synapse/ spine development, it is of importance to examine whether Cdk5 is the downstream integrator of these signaling events at synapses during spine morphogenesis.^26,27Although accumulating evidence highlights a role of Cdk5 in spatial learning and synaptic plasticity, the molecular mechanisms underlying the action of Cdk5 are largely unclear.^28,29 With the recent findings that reveal the critical involvement of Cdk5 in the regulation of Rho GTPases to affect spine morphology, it can be anticipated that precise regulation of actin dynamics by Cdk5 at synapses will be an important mechanism underlying synaptic plasticity in the adult brain.? Open in a separate windowFigure 1Phosphorylation of actin regulators by Cdk5 during dendritic spine morphogenesis. (A) In striatal and hippocampal neurons, phosphorylation of WAVE-1 by Cdk5 at basal condition prevents WAVE-1-mediated actin polymerization and leads to a loss of dendritic spines. However, activation of cyclic AMP-dependent signaling by neurotransmitter such as dopamine, reduces the Cdk5-dependent phosphorylation of WAVE-1 in these neurons. Dephosphorylation of WAVE-1 promotes actin polymerization and results in an increased number of mature dendritic spines. (B) In mature hippocampal neurons, activation of EphA4 by ephrin-A increases Cdk5-dependent of ephexin1. The phosphorylation of ephexin1 by Cdk5 facilitates its EphA4-stimulated GEF activity towards RhoA activation and leads to spine retraction.     

The African lungfish (Protopterus dolloi): ionoregulation and osmoregulation in a fish out of water

Although urea production and metabolism in lungfish have been thoroughly studied, we have little knowledge of how internal osmotic and electrolyte balance are controlled during estivation or in water. We tested the hypothesis that, compared with the body surface of teleosts, the slender African lungfish (Protopterus dolloi) body surface was relatively impermeable to water, Na(+), and Cl(-) due to its greatly reduced gills. Accordingly, we measured the tritiated water ((3)H-H(2)O) flux in P. dolloi in water and during air exposure. In water, (3)H-H(2)O efflux was comparable with the lowest measurements reported in freshwater teleosts, with a rate constant (K) of 17.6% body water h(-1). Unidirectional ion fluxes, measured using (22)Na(+) and (36)Cl(-), indicated that Na(+) and Cl(-) influx was more than 90% lower than values reported in most freshwater teleosts. During air exposure, a cocoon formed within 1 wk that completely covered the dorsolateral body surface. However, there were no disturbances to blood osmotic or ion (Na(+), Cl(-)) balance, despite seven- to eightfold increases in plasma urea after 20 wk. Up to 13-fold increases in muscle urea (on a dry-weight basis) were the likely explanation for the 56% increase in muscle water content observed after 20 wk of air exposure. The possibility that muscle acted as a "water reservoir" during air exposure was supported by the 20% decline in body mass observed during subsequent reimmersion in water. This decline in body mass was equivalent to 28 mL water in a 100-g animal and was very close to the calculated net water gain (approximately 32 mL) observed during the 20-wk period of air exposure. Tritiated water and unidirectional ion fluxes on air-exposed lungfish revealed that the majority of water and ion exchange was via the ventral body surface at rates that were initially similar to aquatic rates. The (3)H-H(2)O flux declined over time but increased upon reimmersion. We conclude that the slender lungfish body surface, including the gills, has relatively low permeability to water and ions but that the ventral surface is an important site of osmoregulation and ionoregulation. We further propose that an amphibian-like combination of ventral skin water and ion permeability, plus internal urea accumulation during air exposure, allows P. dolloi to extract water from its surroundings and to store water in the muscle when the water supply becomes limited.     

Functional coordination of alternative splicing in the mammalian central nervous system

Background

Alternative splicing (AS) functions to expand proteomic complexity and plays numerous important roles in gene regulation. However, the extent to which AS coordinates functions in a cell and tissue type specific manner is not known. Moreover, the sequence code that underlies cell and tissue type specific regulation of AS is poorly understood.

Results

Using quantitative AS microarray profiling, we have identified a large number of widely expressed mouse genes that contain single or coordinated pairs of alternative exons that are spliced in a tissue regulated fashion. The majority of these AS events display differential regulation in central nervous system (CNS) tissues. Approximately half of the corresponding genes have neural specific functions and operate in common processes and interconnected pathways. Differential regulation of AS in the CNS tissues correlates strongly with a set of mostly new motifs that are predominantly located in the intron and constitutive exon sequences neighboring CNS-regulated alternative exons. Different subsets of these motifs are correlated with either increased inclusion or increased exclusion of alternative exons in CNS tissues, relative to the other profiled tissues.

Conclusion

Our findings provide new evidence that specific cellular processes in the mammalian CNS are coordinated at the level of AS, and that a complex splicing code underlies CNS specific AS regulation. This code appears to comprise many new motifs, some of which are located in the constitutive exons neighboring regulated alternative exons. These data provide a basis for understanding the molecular mechanisms by which the tissue specific functions of widely expressed genes are coordinated at the level of AS.     

Both seawater acclimation and environmental ammonia exposure lead to increases in mRNA expression and protein abundance of Na⁺:K⁺:2Cl⁻ cotransporter in the gills of the climbing perch, Anabas testudineus

The freshwater climbing perch, Anabas testudineus, is an obligatory air-breathing teleost which can acclimate to seawater, survive long period of emersion, and actively excrete ammonia against high concentrations of environmental ammonia. This study aimed to clone and sequence the Na⁺:K⁺:2Cl⁻ cotransporter (nkcc) from the gills of A. testudineus, and to determine the effects of seawater acclimation or exposure to 100 mmol l⁻¹ NH₄Cl in freshwater on its branchial mRNA expression. The complete coding cDNA sequence of nkcc from the gills of A. testudineus consisted of 3,495 bp, which was translated into a protein with 1,165 amino acid residues and an estimated molecular mass of 127.4 kDa. A phylogenetic analysis revealed that the translated Nkcc of A. testudineus was closer to fish Nkcc1a than to fish Nkcc1b or Nkcc2. After a progressive increase in salinity, there were significant increases in the mRNA expression and protein abundance of nkcc1a in the gills of fish acclimated to seawater as compared with that of the freshwater control. Hence, it can be concluded that similar to marine teleosts, Cl⁻ excretion through basolateral Nkcc1 of mitochondrion-rich cells (MRCs) was essential to seawater acclimation in A. testudineus. Exposure of A. testudineus to 100 mmol l⁻¹ NH₄Cl for 1 or 6 days also resulted in significant increases in the mRNA expression of nkcc1a in the gills, indicating a functional role of Nkcc1a in active ammonia excretion. It is probable that NH₄ ⁺ enter MRCs through basolateral Nkcc1a before being actively transported across the apical membrane. Since the operation of Nkcc1a would lead to an increase in the intracellular Na⁺ concentration, it can be deduced that an upregulation of basolateral Na⁺/K⁺-ATPase (Nka) activity would be necessary to compensate for the increased influx of Na⁺ into MRCs during active NH₄ ⁺ excretion. This would imply that the main function of Nka in active NH₄ ⁺ excretion is to maintain intracellular Na⁺ and K⁺ homeostasis instead of transporting NH₄ ⁺ directly into MRCs as proposed previously. In conclusion, active salt secretion during seawater acclimation and active NH₄ ⁺ excretion during exposure to ammonia in freshwater could involve similar transport mechanisms in the gills of A. testudineus.