Phosphorylation of bovine neurofilament proteins by protein kinase FA (glycogen synthase kinase 3).

A highly purified preparation of protein kinase FA (where FA is the activating factor for phosphatase 1)/glycogen synthase kinase 3 from rabbit muscle readily phosphorylated bovine neurofilaments. All three neurofilament proteins, the high, middle, and low molecular proteins (NF-H, NF-M, and NF-L), were phosphorylated when intact filaments were incubated with the kinase. Experiments with individual proteins showed that NF-M was the best substrate. At protein concentrations of 0.13 mg/ml, the initial rate of NF-M phosphorylation was 30% of that observed for glycogen synthase. Km values were 0.24 mg/ml (7 x 10(-7) M tetramer) for glycogen synthase and 0.10 mg/ml (5 x 10(-7) M dimer) for NF-M. Vmax values were 0.36 mumol/min/mg for glycogen synthase and 0.035 mumol/min/mg for NF-M. Dephosphorylated NF-M was phosphorylated only half as much as native NF-M; this is consistent with the known substrate specificity of the kinase. The possible involvement of FA/GSK-3 in the phosphorylation of neurofilaments in vivo is discussed.     

Dephosphorylation of neurofilament proteins enhances their susceptibility to degradation by calpain.

The degradation of phosphorylated and dephosphorylated neurofilament proteins by the Ca2+-activated neutral proteinase calpain was studied. Neurofilaments were isolated from bovine spinal cord, dephosphorylated by alkaline phosphatase (from Escherichia coli) and radioiodinated with [125I]-Bolton-Hunter reagent. The radioiodinated neurofilament proteins (untreated and dephosphorylated) were incubated in the presence and absence of calpain from rabbit skeletal muscle, and the degradation rates of large (NF-H), mid-sized (NF-M) and small (NF-L) neurofilament polypeptides were analysed by SDS/polyacrylamide-gel electrophoresis and autoradiography. The degradation of dephosphorylated neurofilament proteins occurred at a higher rate, and to a greater extent, than did that of the phosphorylated (untreated) neurofilament proteins. The dephosphorylated high-molecular-mass neurofilament (NF-HD) was proteolyzed 6 times more quickly than the untreated NF-H. The degradation rate of the NF-M and NF-L neurofilament proteins was also enhanced after dephosphorylation, but less than that of NF-H. This indicates that the dephosphorylation of neurofilament proteins can increase their sensitivity to calpain degradation.     

Effects of metal ions and catalytic loop sequences on the complex formation of a deoxyribozyme and its RNA substrate

A deoxyribozyme is a catalytic DNA that catalyzes a site-specific RNA cleavage activity and requires various divalent cations. Earlier we have reported that by downsizing the catalytic loop of a deoxyribozyme from 15-mer to 11-mer it resulted in a short and novel Ca2+-dependent deoxyribozyme. In this paper, we investigate the complex formation of deoxyribozymes with their RNA substrates by using surface plasmon resonance (SPR) in order to determine quantitatively the effect of Ca2+ or Mg2+ on the recognition step between a deoxyribozyme and its RNA substrate. The results indicate that both the association and dissociation rate constants (k(a) and k(d)) for the deoxyribozyme-RNA complex depends on metal ions as well as the loop size of the deoxyribozyme. Metal ions with high RNA cleavage activity induced an increase in k(a) and a decrease in k(d). On the basis of the results, we propose that Ca2+ ions may play a role in the rearrangement of the 11-mer catalytic loop of the short Ca2+-dependent deoxyribozyme.     

Aluminum Alters the Electrophoretic Properties of Neurofilament Proteins: Role of Phosphorylation State

Exposure of each of the three neurofilament proteins (NFPs) to AlCl3 resulted in their failure to migrate into sodium dodecyl sulfate (SDS)-containing gels. This effect was dependent on length of incubation (minimum, 2 h) and AlCl3 concentrations (minimum, 50 microM) and was not reversed by 20% SDS, 6 M urea, freeze-thawing, boiling, or extensive dialysis. The migration of vimentin and glial fibrillary acidic protein was not affected by AlCl3. The high-molecular-weight neurofilament subunit (NF-H) entered SDS-containing gels after exposure to aluminum lactate but migrated aberrantly as a long high-molecular-weight streak. Migration of the 160-kDa alpha-chymotryptic cleavage product of NF-H, which contains the higher phosphorylated tail domain, was also prevented from migrating into SDS-containing gels by AlCl3. Dephosphorylation of NF-H and the middle-molecular-weight neurofilament subunit (NF-M) eliminated these effects on gel migration. EDTA, EGTA, MgCl2, CaCl2, or FeCl3 had no effect on NF-H or NF-M migration; furthermore, preincubation with, or simultaneous exposure to, CaCl2 or FeCl3 did not alter the effect of AlCl3. One interpretation of these results is that Al3+ interacts with phosphate groups on extensively phosphorylated C-terminal sidearms of NFPs, resulting in intermolecular cross-linking. These findings demonstrate a direct effect of aluminum on NFPs and provide a possible mechanism for neurofilament accumulation in perikarya during aluminum intoxication.     

The Differential Role of Protein Kinase C Isozyme in the Rapid Induction of Neurofilament Phosphorylation by Nerve Growth Factor and Phorbol Esters in PC12 Cells

We examined the short-term regulation of the phosphorylation of the mid-sized neurofilament subunit (NF-M) by kinases which were activated in rat pheochromocytoma (PC12) cells by nerve growth factor (NGF) and/or 12-O-tetradecanoylphorbol 13-acetate (TPA). We found that NGF and TPA, alone or in combination, increased (a) the incorporation of [32P]Pi into NF-M and (b) the rate of conversion of NF-M from a poorly phosphorylated to a more highly phosphorylated form. This was not due to increased synthesis of NF-M, because NGF alone did not increase NF-M synthesis and TPA alone or TPA and NGF together inhibited the synthesis of NF-M. Further, an increase in calcium/phospholipid-dependent kinase (PKC) activity resulting from the treatment of PC12 cells with NGF and TPA was observed concomitant with the increased phosphorylation of NF-M. This PKC activity was determined to be derived from the PKC alpha and PKC beta isozymes. Finally, when PC12 cells were rendered PKC-deficient by treatment with 1 muM TPA for 24 h, NGF maintained the ability to induce an increase in NF-M phosphorylation, though not to the level attained in cells which were not PKC-deficient. These data suggest that NGF with or without TPA stimulates NF-M phosphorylation as a result of a complex series of events which include PKC-independent and PKC-dependent pathways.     

外源钙、磷、氮对铝胁迫下杉木幼苗生长影响的调控研究

为缓解Al胁迫对杉木人工林更新的影响,本文采用水培模拟Al胁迫,引入Ca、P、NH₄⁺-N、NO₃^--N营养调控因子,探讨Al胁迫对杉木幼苗根茎生长的影响.结果表明,增加Ca或P浓度,能促进根、茎的正常生长发育,根系的形态特征明显变化,降低组织内MDA含量和POD活性.增加NH₄⁺-N浓度只能促进茎的生长,对根系发育影响不明显.增加NO₃^--N浓度对根茎生长均无明显的规律性影响.增加NH₄⁺-N和NO₃^--N浓度,能抑制MDA含量增加,并在一定范围内降低POD活性,但效果不及Ca或P明显.经回归方程拟合,得出本试验条件下营养因子有效缓解Al胁迫的阈值是:Ca/Al≥2.8,P/Al≥4.4,NH₄⁺-N/Al≥4.5(摩尔比).     

Hypophosphorylated neurofilament subunits undergo axonal transport more rapidly than more extensively phosphorylated subunits in situ

Axonal transport of neurofilaments (NFs) has long been considered to be regulated by phosphorylation. We present evidence that in optic axons of normal mice, the rate of NF axonal transport is inversely correlated with the NF phosphorylation state. In addition to 200 kDa NF-H and 145 kDa NF-M, axonal cytoskeletons from CNS contained a range of phospho-variants of NF-H migrating between 160-200 kDa, and of NF-M migrating at 97-145 kDa. While 160 kDa phospho-variants of NF-H have been well characterized, we confirmed the identity of the previously-described 97 kDa species as a hypophospho-variant of NF-M since (1) pulse-chase metabolic labeling confirmed the 97 kDa species to be a new synthesis product that was converted by phosphorylation over time into a form migrating at 145 kDa, (2) the 97 kDa protein reacted with multiple NF-M antibodies, including one specific for hypophosphorylated NF-M, and (3) dephosphorylation converted NF-M isoforms to 97 kDa. Autoradiographic analyses following metabolic radiolabeling demonstrated that hypophosphorylated NF-H and NF-M isoforms underwent substantially more rapid transport in situ than did extensively phosphorylated isoforms, while NF-H subunits bearing a developmentally delayed C-terminal phospho-epitope transported at a rate slower than that of total 200 kDa NF-H. Differential transport of phospho-variants also highlights that these variants are not homogeneously distributed among NFs, but are segregated to some extent among distinct, although probably overlapping, NF populations, indicating that axonal NFs are not homogeneous with respect to phosphorylation state.     

The circular dichroism of ribosomal ribonucleic acids.

1. The c.d. (circular dichroism) of Drosophila melanogaster rRNA (42% G+C) and of G+C-rich fragments (78% G+C) obtained by partial hydrolysis of rabbit L-rRNA (the largest RNA species isolated from the large subribosomal particle) were measured and found to differ substantially. 2. To interpret these spectra a relation between c.d. of bihelical RNA and % G+C was derived, namely delta epsilonfG = AFG2+bfG+c, where deltaepsilonfG is the c.d. of RNA characterized by a mole fraction, fG, of guanine nucleotides and a, b and c are constants. 3. A frame of reference was established by studying the c.d. of a range of rRNA species, including S-rRNA (the RNA species isolated from the smaller subribosomal particle) and L-rRNA of Escherichia coli. 4. It was found for the rRNA species studied that 0.60+/-0.05 of residues appear to form bihelical secondary structure. 5. A higher helical content, 0.66+/-0.05, was found for the G+C-rich fragment of L-rRNA. The difference in the c.d. of rabbit L-rRNA and of D. melanogaster rRNA is attributable to the dependence of c.d. of the bihelical parts on %G+C. 6. The minimum in c.d. at 295 nm increases with increasing %G+C. The c.d. of rRNA was compared with that of the parent subparticle in this region of the spectrum, where high precision may be attained.     

Tau inhibits anterograde axonal transport and perturbs stability in growing axonal neurites in part by displacing kinesin cargo: neurofilaments attenuate tau-mediated neurite instability

Overexpression of tau compromises axonal transport and induces retraction of growing neurites. We tested the hypothesis that increased stability provided by neurofilaments (NFs) may prevent axonal retraction. NB2a/d1 cells were differentiated for 3 days, at which time phosphorylated NFs appear and for 14 days, which induces continued neurite elongation and further phospho-NF accumulation. Cultures were transfected with a construct that expresses full-length, 4-repeat tau. Consistent with prior studies, overexpression of tau induced retraction of day three axonal neurites even following treatment with the microtubule-stabilizing drug taxol. Axonal neurites of day 14 cells were more resistant to tau-mediated retraction. To test whether or not this resistance was derived from their additional NF content, day 3 cultures were co-transfected with constructs expressing tau and NF-M (which increases overall axonal NFs). Overexpression of NF-M attenuated tau-mediated retraction of day 3 axonal neurites. By contrast, co-transfection with constructs expressing tau and vimentin (which increases axonal neurites length) did not attenuate tau-mediated neurite retraction. Co-precipitation experiments indicate that tau is a cargo of kinesin, and that tau overexpression may displace other kinesin-based cargo, including both critical cytoskeletal proteins and organelles. However, cultures simultaneously transfected with constructs expressing NF-M and tau, the level of examined vesicles was maintained. These collectively indicate that NFs stabilize developing axonal neurites and can counteract the destabilizing force resulting from overexpression of tau, and underscore that the development and stabilization of axonal neurites is dependent upon a balance of cytoskeletal elements.     

Phosphorylation of neurofilament H subunit at the tail domain by CDC2 kinase dissociates the association to microtubules

We sought the mammalian neurofilament tail domain-specific kinase. Several well known kinases including cAMP-dependent protein kinase, protein kinase C, Ca(2+)-calmodulin-dependent protein kinase II, casein kinase I, and casein kinase II phosphorylated the high (NF-H) and middle molecular mass subunit (NF-M) of bovine neurofilaments, but they did not reduced the electrophoretic mobility of the dephosphorylated form of NF-M and NF-H by phosphorylation nor was the amount of phosphorylation increased by dephosphorylation of NF proteins, indicating that the phosphorylation sites by these kinases are not major in vivo phosphorylation sites at the tail domain. In contrast, cdc2 kinase phosphorylated specifically the dephosphorylated form of NF-H. 4 mol of phosphates were incorporated per mol of NF-H and this phosphorylation returned the electrophoretic mobility of the dephosphorylated form of NF-H to the position of the isolated, fully phosphorylated form of NF-H. Furthermore, the phosphorylation by cdc2 kinase dissociated the binding of dephosphorylated NF-H to microtubules. Phosphorylation sites were located at the carboxyl-terminal tail domain. The KSPXK motif, but not KSPXX, in the repetitive sequence was suggested to be the phosphorylation site by using synthetic peptides.     

The systematic study of aluminium speciation in medium concentrated aqueous solutions.

Industrial applications and environmental problems involving the aqueous chemistry of aluminium require an understanding of the speciation of this metal ion at a wide range of concentrations. The formation of polynuclear species is of special interest due to the complexity of the hydrolysis mechanisms and the diversity of the hydrolysis products. Kinetic aspects of speciation are also important considering the different stability ranges of polycationic species formed during the hydrolysis process. In the present paper we report results of systematic studies on the formation of aluminium polycations at room temperature. Automated potentiometric titrations have been used to study the hydrolysis of aluminium-ions in solutions (0.01-0.2 M) on a short time scale (2 min between titrant additions). (27)Al NMR spectroscopy and dynamic light scattering have been used for investigations on a longer time scale (24 h). The effects of alkali strength (KOH, NH(4)OH and KHCO(3)) and concentration (0.45-2.0 M), counterion identity (Cl(-), NO(3)(-), SO(4)(2-)) and ionic strength have been investigated. Optimum conditions for the generation of Al(13)-mer are proposed on short and long time scales. On a short time scale, aluminium chloride and nitrate should be used as starting materials, KOH and KHCO(3) should be used for hydrolysis and experiments conducted at low ionic strength. For solutions that have been left to age, there is a considerable hydrolysis window that can be used to generate significant quantities of the Al(13)-mer that vary little with the alkali used. Al(13)-mer species are not generated from alum as the precursor. The presence of sulphate ions alters the pathway of aluminium polymerisation to form polymeric and solid materials. On the basis of the potentiometric titration data, dynamic light scattering and (27)Al NMR measurements evidence is provided for the detrimental role of sulphate-ions in the formation of Al(13)-mer and an alternative mechanism of aluminium ion polycondensation is proposed, based on the increased stability of monomeric and oligomeric species (dimer and trimer) in the presence of sulphate-ions.     

Behavior of the Ca2+ transport sites linked with the phosphorylation reaction of ATPase purified from the sarcoplasmic reticulum.

Both the formation and decay of phosphorylated ATPase, and Ca2+ release from and rebinding to transport sites alpha sites) on the enzyme have been investigated in the pre- and post-steady states by means of rapid mixing acid quench technique and a stopped flow technique, respectively. At a relatively high concentration of enzyme (10 muM protein) and a low concentration of free Ca2+ (1.42 muM), rapid changes in the Ca2+ affinity of the transport sites could be monitored with the use of a Ca2+ indicator dye, Arsenazo III. As the enzyme becomes phosphorylated, Ca2+ is released. In the early stages, the ratio of Ca2+ released to acid-stable phosphoenzyme is less than 2, while at the maximum of Ca2+ release, which occurs later than the maximum phosphorylation, it is greater than 2. Assuming that phosphorylation of the enzyme releases both Ca2+ bound to it (Ikemoto, N. (1975) J. Biol. Chem. 250, 7219), these data are consistent with the sequential formation of two acid-stable intermediates differing in Ca2+ affinity and a third acid-labile phosphorylated species of low Ca2+ affinity. The changes in Ca2+ affinity are probably related to changes in the structure of the ATPase transport protein that are involved in the Ca2+ translocation in the intact sarcoplasmic reticulum. As the ATP is being used up, Ca2+ rebinding occurs concomitantly with the decay of phosphoenzyme. The comparison of the time courses of Ca2+ rebinding with that of dephosphorylation in the post-steady state suggests that interactions among phosphorylated and nonphosphorylated ATPase molecular may also be involved in the Ca2+ affinity changes.     

Microsomal Ca2+ flux modulation as an indicator of heavy metal toxicity

Inositol 1,4,5-trisphosphatee (IP3), an intracellular messenger, releases Ca2+ from microsomes. Ca2+ plays a major role in regulating various cellular events like neural transmission and regulation of hormones and growth factors. Aluminum (Al), lead (Pb) and mercury (Hg) were reported to alter Ca(2+)-regulated events thereby causing neurotoxicity. Hence, an attempt was made characterize IP3 mediated Ca2+ release from rat brain microsomes under the influence of Al, Pb and Hg. Different concentrations of metals were tested over a designated time scale and their effects on IP3 mediated Ca2+ release from microsomes were monitored using Fura-2 technique. All the three metals inhibited IP3 mediated Ca2+ release, Pb being more potent. The order of potency of these three metals was Pb>Hg>Al. Except for Al, both Hg and Pb independently released Ca2+ from microsomes. Re-uptake of Ca2+ into microsomes was inhibited by all the three metals, Pb being more potent. Microsomal Ca(2+)-ATPase activity was also inhibited by all the three metals. These results suggest that neurotoxicity exerted by Al, Pb and Hg may be due to the interference of these metals with IP3 mediated calcium release and also interfering with the microsomal Ca2+ sequestration mechanism. Differential effects of heavy metal induced changes in Ca2+ flux can be used as an index of relative toxicity.     

Phosphorylation of the amino-terminal head domain of the middle molecular mass 145-kDa subunit of neurofilaments. Evidence for regulation by second messenger-dependent protein kinases

To begin to understand the regulation and roles of neurofilament phosphorylation, we localized the phosphorylated domains on the 140-145-kDa neurofilament subunit (NF-M) and identified the protein kinases that may specifically phosphorylate the sites within these domains in vivo. Mouse retinal ganglion cells were labeled in vivo by injecting mice intravitreally with [32P]orthophosphate, and neurofilament-enriched fractions were obtained from the optic axons. Two-dimensional phosphopeptide map analysis of NF-M after digestion with alpha-chymotrypsin and trypsin revealed seven major (M8-M14) and at least eight minor (M1-M7 and M15) phosphopeptides. Two-dimensional phosphopeptide map analyses of NF-M phosphorylated in vitro by individual purified or endogenous axonal cytoskeleton-associated protein kinases showed that five peptides (M9-M13) were substrates for the heparin-sensitive second messenger-independent protein kinase(s). Protein kinase A and/or protein kinase C phosphorylated eight other peptides (M1-M8). Two alpha-chymotryptic peptides (C1 and C2) that were phosphorylated by protein kinase A but not by the endogenous independent kinase(s) were isolated by high performance liquid chromatography on a reverse-phase C8 column. Partial sequence analysis of peptides C1 (S R V S G P S ...) and C2 (S R G S P S T V S ...) showed that the peptides were localized on the head domain of NF-M at 25 and 41 residues from the amino terminus, respectively. Tryptic digest of peptide C1 (less than 12 kDa) generated the phosphopeptides M1-M6. Peptide C2 was a breakdown product of peptide C1. Since the polypeptide sites targeted by second messenger-independent kinase(s) associated with neurofilaments are localized on the carboxyl-terminal domain, separate aspects of NF-M function appear to be regulated by separate kinase systems that selectively phosphorylate head or tail domains of the polypeptide.     

Inositol 1,4,5-trisphosphate and the endoplasmic reticulum Ca2+ cycle of a rat insulinoma cell line

Regulation of endoplasmic reticulum (ER) Ca2+ cycling by inositol 1,4,5-trisphosphate (IP3) was studied in saponin-permeabilized RINm5F insulinoma cells. Cells were incubated with mitochondrial inhibitors, and medium Ca2+ concentration established by nonmitochondrial pool(s) (presumably the ER) was monitored with a Ca2+ electrode. IP3 degradation accounted for the transience of the Ca2+ response induced by pulse additions of the molecule. To compensate for degradation, IP3 was infused into the medium. This resulted in elevation of [Ca2+] from about 0.2 microM to a new steady state between 0.3 and 1.0 microM, depending on both the rate of IP3 infusion and the ER Ca2+ content. The elevated steady state represented a bidirectional buffering of [Ca2+] by the ER, as slight displacements in [Ca2+], by small aliquots of Ca2+ or the Ca2+ chelator quin 2, resulted in net uptake or efflux of Ca2+ to restore the previous steady state. When IP3 infusion was stopped, [Ca2+] returned to its original low level. Ninety per cent of the Ca2+ accumulated by the ER was released by IP3 when the total Ca2+ content did not exceed 15 nmol/mg of cell protein. Above this high Ca2+ content, Ca2+ was accumulated in an IP3-insensitive, A23187-releasable pool. The maximal amount of Ca2+ that could be released from the ER by IP3 was 13 nmol/mg of cell protein. The data support the concept that in the physiological range of Ca2+ contents, almost all the ER is an IP3-sensitive Ca2+ store that is capable of finely regulating [Ca2+] through independent influx (Ca2+-ATPase) and efflux (IP3-modulated component) pathways of Ca2+ transport. IP3 may continuously modulate Ca2+ cycling across the ER and play an important role in determining the ER Ca2+ content and in regulating cytosolic Ca2+ under both stimulated and possibly basal conditions.     

Analysis of 13NH4+ Efflux in Spruce Roots (A Test Case for Phase Identification in Compartmental Analysis)

13NH4+-efflux analyses were conducted with roots of intact Picea glauca (Moench) Voss. seedlings at external NH4+ concentrations of 100 [mu]M and 1.5 mM. Three kinetically distinct phases were identified with half-lives of exchange of approximately 2 s, 30 s, and 14 min. The presumed identities of the subcellular compartments corresponding to these phases were confirmed by several techniques, including pretreatment of roots (a) at 75[deg]C or with SDS, (b) with [alpha]-keto-glutarate or L-methionine-DL-sulfoximine, (c) at elevated levels of Ca2+, and (d) at low pH or with Al3+ at low pH. Treatments a and b selectively influenced phase III without affecting phases I and II. Similarly, treatment c selectively perturbed phase II, and treatment d affected phases II and III. Based on these findings and the assumption of an in-series arrangement of root cell compartments, it was concluded that phase III corresponded to the cytoplasm, phase II corresponded to the Donnan free space, and phase I corresponded to a film of solution adhering to the root surface.     

Aluminum Effects on Calcium (45Ca2+) Translocation in Aluminum-Tolerant and Aluminum-Sensitive Wheat (Triticum aestivum L.) Cultivars (Differential Responses of the Root Apex versus Mature Root Regions)

The influence of Al exposure on long-distance Ca2+ translocation from specific root zones (root apex or mature root) to the shoot was studied in intact seedlings of winter wheat (Triticum aestivum L.) cultivars (Al-tolerant Atlas 66 and Al-sensitive Scout 66). Seedlings were grown in 100 [mu]M CaCl2 solution (pH 4.5) for 3 d. Subsequently, a divided chamber technique using 45Ca2+-labeled solutions (100 [mu]M CaCl2 with or without 5 or 20 [mu]M AlCl3, pH 4.5) was used to study Ca2+ translocation from either the terminal 5 to 10 mm of the root or a 10-mm region of intact root approximately 50 mm behind the root apex. The Al concentrations used, which were toxic to Scout 66, caused a significant inhibition of Ca2+ translocation from the apical region of Scout 66 roots. The same Al exposures had a much smaller effect on root apical Ca2+ translocation in Atlas 66. When a 10-mm region of the mature root was exposed to 45Ca2+, smaller genotypic differences in the Al effects effects on Ca2+ translocation were observed, because the degree of Al-induced inhibition of Ca2+ translocation was less than that at the root apex. Exposure of the root apex to Al inhibited root elongation by 70 to 99% in Scout 66 but had a lesser effect (less than 40% inhibition) in Atlas 66. When a mature root region was exposed to Al, root elongation was not significantly affected in either cultivar. These results demonstrate that genotypic differences in Al-induced inhibition of Ca2+ translocation and root growth are localized primarily in the root apex. The pattern of Ca2+ translocation within the intact root was mainly basipetal, with most of the absorbed Ca2+ translocated toward the shoot. A small amount of acropetal Ca2+ translocation from the mature root regions to the apex was also observed, which accounted for less than 5% of the total Ca2+ translocation within the entire root. Because Ca2+ translocation toward the root apex is limited, most of the Ca2+ needed for normal cellular function in the apex must be absorbed from the external solution. Thus, continuous Al disruption of Ca2+ absorption into cells of the root apex could alter Ca2+ nutrition and homeostasis in these cells and could play a pivotal role in the mechanisms of Al toxicity in Al-sensitive wheat cultivars.     

Lithium Chloride Inhibits the Phosphorylation of Newly Synthesized Neurofilament Protein, NF-M, in Cultured Chick Sensory Neurons

The middle and high molecular weight members of the neurofilament triplet, NF-M and NF-H, undergo extensive posttranslational polyphosphorylation, a process requiring 24 h or more for completion. We have investigated ways of perturbing this process in intact cells and have found that phosphorylation of newly synthesized NF-M in cultured chick sensory neurons is inhibited by Li+. [35S]Methionine pulse-chase experiments were carried out with pure neuronal cultures, and the phosphorylation of newly synthesized NF-M was monitored by following the accompanying change, with chase time, in apparent size and charge of the polypeptide. Addition of LiCl to the medium inhibited this mobility shift in a dose-dependent manner over concentrations between 2 and 25 mM. Incorporation of 32P into NF-M, as well as NF-H, was also inhibited, whereas incorporation into the low molecular weight neurofilament protein, beta-tubulin, and total protein was unaffected. Protein synthesis was not altered. Exposure to 25 mM LiCl for up to 72 h was not toxic, and the inhibition of NF-M phosphorylation was completely reversible. When 25 mM Li+ was added after NF-M had become partially phosphorylated, further progression was blocked, but there was no net dephosphorylation or degradation of NF-M. Additional experiments suggest that this action of Li+ is probably not due to effects on second messenger levels or to effects on tubulin metabolism and assembly state presented in our accompanying article, but rather to interference by Li+ itself, with the phosphorylation of NF-M and NF-H by specific neurofilament kinase(s).     

Interactive effects of Al, Ca and other cations on root elongation of rice cultivars under low pH

BACKGROUND AND AIMS: As with other crop species, Al tolerance in rice (Oryza sativa) is widely different among cultivars, and the mechanism for tolerance is unknown. The Ca2+-displacement hypothesis, that is, Al displaces Ca2+ from critical sites in the root apoplast, was predicted to be the essential mechanism for causing Al toxicity in rice cultivars. If displacement of Ca is an essential cause of Al toxicity in rice, Al toxicity may show the same trend as toxicities of elements such as Sr and Ba that are effective in displacing Ca. METHODS: The interactive effects of Al, Ca, Sr and Ba on root elongation of rice cultivars with different Al tolerances were evaluated in hydroponic culture. Al and Ca accumulation in root tips was also investigated. KEY RESULTS AND CONCLUSIONS: Not only Al but also Sr and Ba applications inhibited root growth of rice cultivars under low Ca conditions. As expected, rice cultivars more tolerant of Sr and Ba were also tolerant of Al (japonica > indica). Although Mg application did not affect Sr or Ba toxicity, Mg alleviated Al toxicity to the same level as Ca application. In addition, Ca application decreased the Al content in root tips without displacement. These results suggest that Ca does not have a specific, irreplaceable role in Al toxicity, unlike Sr and Ba toxicities. Alleviation of Al toxicity with increasing concentrations of Ca in rice cultivars is due to increased ionic strength, not due to decreased Al activity. The difference in Al tolerance between indica and japonica cultivars disappears under high ionic strength conditions, suggesting that different electrochemical characteristics of root-tip cells are related to the significant difference in Al tolerance under low ionic strength conditions.     

Quantification of the calcium-induced secondary structural changes in the regulatory domain of troponin-C.

The backbone resonance assignments have been completed for the apo (1H and 15N) and calcium-loaded (1H, 15N, and 13C) regulatory N-domain of chicken skeletal troponin-C (1-90), using multidimensional homonuclear and heteronuclear NMR spectroscopy. The chemical-shift information, along with detailed NOE analysis and 3JHNH alpha coupling constants, permitted the determination and quantification of the Ca(2+)-induced secondary structural change in the N-domain of TnC. For both structures, 5 helices and 2 short beta-strands were found, as was observed in the apo N-domain of the crystal structure of whole TnC (Herzberg O, James MNG, 1988, J Mol Biol 203:761-779). The NMR solution structure of the apo form is indistinguishable from the crystal structure, whereas some structural differences are evident when comparing the 2Ca2+ state solution structure with the apo one. The major conformational change observed is the straightening of helix-B upon Ca2+ binding. The possible importance and role of this conformational change is explored. Previous CD studies on the regulatory domain of TnC showed a significant Ca(2+)-induced increase in negative ellipticity, suggesting a significant increase in helical content upon Ca2+ binding. The present study shows that there is virtually no change in alpha-helical content associated with the transition from apo to the 2Ca2+ state of the N-domain of TnC. Therefore, the Ca(2+)-induced increase in ellipticity observed by CD does not relate to a change in helical content, but more likely to changes in spatial orientation of helices.