Cesar H. Casale

Cholinesterase, acid phosphatase, and phospholipase C ofPseudomonas aeruginosa under hyperosmotic conditions in a high-phosphate medium

The presence of low choline or betaine concentrations in a culture medium containing succinate, NH4Cl, and inorganic phosphate (Pi) as the carbon, nitrogen, and phosphate sources, respectively, permits the growth ofPseudomonas aeruginosa in a hyperosmolar medium. Dimethylglycine, acetylcholine, and phosphorylcholine were less effective as osmoprotectants than choline or betaine. Other alkylammonium compounds tested were virtually ineffective in this capacity. Bacterial growth was also observed in a hyperosmolar medium when choline was the sole carbon and nitrogen source. Choline could act as an osmoprotectant under all the conditions tested. However, the production of cholinesterase (ChE), acid phosphatase (Ac. Pase) and phospholipase C (PLC) took place only when choline was the carbon and nitrogen source. This fact confirms that the synthesis of PLC may occur even in the presence of a high Pi concentration in the medium. Inasmuch as in a high-Pi medium the synthesis of PLC and Ac. Pase (phosphorylcholine phosphatase) is dependent only on choline metabolism, it is postulated that both enzymes are involved in a set of reactions coordinated to produce the breakdown of the membrane phospholipids of the host cell in a hyperosmotic medium.

Tubulin must be acetylated in order to form a complex with membrane Na + ,K + -ATPase and to inhibit its enzyme activity

In cells of neural and non-neural origin, tubulin forms a complex with plasma membrane Na+,K+-ATPase, resulting in inhibition of the enzyme activity. When cells are treated with 1 mM L-glutamate, the complex is dissociated and enzyme activity is restored. Now, we found that in CAD cells, ATPase is not activated by L-glutamate and tubulin/ATPase complex is not present in membranes. By investigating the causes for this characteristic, we found that tubulin must be acetylated in order to associate with ATPase and to inhibit its catalytic activity. In CAD cells, the acetylated tubulin isotype is absent. Treatment of CAD cells with deacetylase inhibitors (trichostatin A or tubacin) caused appearance of acetylated tubulin, formation of tubulin/ATPase complex, and reduction of membrane ATPase activity. In these treated cells, addition of 1 mM L-glutamate dissociated the complex and restored the enzyme activity. Cytosolic tubulin from trichostatin A-treated but not from non-treated cells inhibited ATPase activity. These findings indicate that the acetylated isotype of tubulin is required for interaction with membrane Na+,K+-ATPase and consequent inhibition of enzyme activity.

Activation of the plasma membrane H+‐ATPase of Saccharomyces cerevisiae by glucose is mediated by dissociation of the H+‐ATPase–acetylated tubulin complex

In the yeast Saccharomyces cerevisiae, plasma membrane H+‐ATPase is activated by d‐glucose. We found that in the absence of glucose, this enzyme forms a complex with acetylated tubulin. Acetylated tubulin usually displays hydrophilic properties, but behaves as a hydrophobic compound when complexed with H+‐ATPase, and therefore partitions into a detergent phase. When cells were treated with glucose, the H+‐ATPase–tubulin complex was disrupted, with two consequences, namely (a) the level of acetylated tubulin in the plasma membrane decreased as a function of glucose concentration and (b) the H+‐ATPase activity increased as a function of glucose concentration, as measured by both ATP‐hydrolyzing capacity and H+‐pumping activity. The addition of 2‐deoxy‐d‐glucose inhibited the above glucose‐induced phenomena, suggesting the involvement of glucose transporters. Whereas total tubulin is distributed uniformly throughout the cell, acetylated tubulin is concentrated near the plasma membrane. Results from immunoprecipitation experiments using anti‐(acetylated tubulin) and anti‐(H+‐ATPase) immunoglobulins indicated a physical interaction between H+‐ATPase and acetylated tubulin in the membranes of glucose‐starved cells. When cells were pretreated with 1 mm glucose, this interaction was disrupted. Double immunofluorescence, observed by confocal microscopy, indicated that H+‐ATPase and acetylated tubulin partially colocalize at the periphery of glucose‐starved cells, with predominance at the outer and inner sides of the membrane, respectively. Colocalization was not observed when cells were pretreated with 1 mm glucose, reinforcing the idea that glucose treatment produces dissociation of the H+‐ATPase–tubulin complex. Biochemical experiments using isolated membranes from yeast and purified tubulin from rat brain demonstrated inhibition of H+‐ATPase activity by acetylated tubulin and concomitant increase of the H+‐ATP ase–tubulin complex.

De novo heterozygous mutations in SMC3 cause a range of Cornelia de Lange syndrome-overlapping phenotypes.

Cornelia de Lange syndrome (CdLS) is characterized by facial dysmorphism, growth failure, intellectual disability, limb malformations, and multiple organ involvement. Mutations in five genes, encoding subunits of the cohesin complex (SMC1A, SMC3, RAD21) and its regulators (NIPBL, HDAC8), account for at least 70% of patients with CdLS or CdLS‐like phenotypes. To date, only the clinical features from a single CdLS patient with SMC3 mutation has been published. Here, we report the efforts of an international research and clinical collaboration to provide clinical comparison of 16 patients with CdLS‐like features caused by mutations in SMC3. Modeling of the mutation effects on protein structure suggests a dominant‐negative effect on the multimeric cohesin complex. When compared with typical CdLS, many SMC3‐associated phenotypes are also characterized by postnatal microcephaly but with a less distinctive craniofacial appearance, a milder prenatal growth retardation that worsens in childhood, few congenital heart defects, and an absence of limb deficiencies. While most mutations are unique, two unrelated affected individuals shared the same mutation but presented with different phenotypes. This work confirms that de novo SMC3 mutations account for ∼1%–2% of CdLS‐like phenotypes.

Submembraneous microtubule cytoskeleton: regulation of ATPases by interaction with acetylated tubulin

The ATP‐hydrolysing enzymes (Na+,K+)‐, H+‐ and Ca2+‐ATPase are integral membrane proteins that play important roles in the exchange of ions and nutrients between the exterior and interior of cells, and are involved in signal transduction pathways. Activity of these ATPases is regulated by several specific effectors. Here, we review the regulation of these P‐type ATPases by a common effector, acetylated tubulin, which interacts with them and inhibits their enzyme activity. The presence of an acetyl group on Lys40 of α‐tubulin is a requirement for the interaction. Stimulation of enzyme activity by different effectors involves the dissociation of tubulin/ATPase complexes. In cultured cells, acetylated tubulin associated with ATPase appears to be a constituent of microtubules. Stabilization of microtubules by taxol blocks association/dissociation of the complex. Membrane ATPases may function as anchorage sites for microtubules.

Carnitine resembles choline in the induction of cholinesterase, acid phosphatase, and phospholipase C and in its action as an osmoprotectant in Pseudomonas aeruginosa

The present study demonstrates that under conditions of iso or hyperosmolarity, P. aeruginosa utilized carnitine as the carbon, nitrogen or carbon and nitrogen sources. As occurred in the case of choline, the bacteria synthesized cholinesterase (ChE), acid phosphatase (Ac.Pase) and phospholipase C (PLC) under any of these conditions and in the presence of high or low Pi concentrations.Carnitine acted as an osmoprotectant when the cells were grown in the presence of preferred carbon and nitrogen sources and high NaCl concentrations. Under these conditions the three enzyme activities were not produced.The osmotically stressed bacteria grown under any of the above conditions accumulated betaine. Its presence indicated that carnitine may be metabolized by P. aeruginosa to produce betaine which could account for the induction of the three enzyme activities or its action as an osmoprotectant.The phosphatidylcholine encountered in the host cell membranes allows the bacteria to obtain free choline by the coordinated action of PLC and Ac.Pase. Since the consequence of this action may be cell disruption, the increase of free carnitine in the natural environment of the bacteria is also possible. These two compounds, choline and carnitine, acting in conjunction or separately, may increase the production of PLC and Ac.Pase activities by P. aeruginosa and thus enhance the degradative effect upon the host cells.

Acetylated tubulin associates with the fifth cytoplasmic domain of Na+/K+-ATPase: possible anchorage site of microtubules to the plasma membrane

We showed previously that NKA (Na(+)/K(+)-ATPase) interacts with acetylated tubulin resulting in inhibition of its catalytic activity. In the present work we determined that membrane-acetylated tubulin, in the presence of detergent, behaves as an entity of discrete molecular mass (320-400 kDa) during molecular exclusion chromatography. We also found that microtubules assembled in vitro are able to bind to NKA when incubated with a detergent-solubilized membrane preparation, and that isolated native microtubules have associated NKA. Furthermore, we determined that CD5 (cytoplasmic domain 5 of NKA) is capable of interacting with acetylated tubulin. Taken together, our results are consistent with the idea that NKA may act as a microtubule-plasma membrane anchorage site through an interaction between acetylated tubulin and CD5.

Differential HMG-CoA lyase expression in human tissues provides clues about 3-hydroxy-3-methylglutaric aciduria

Abstract3-Hydroxy-3-methylglutaric aciduria is a rare human autosomal recessive disorder caused by deficiency of 3-hydroxy-3-methylglutaryl CoA lyase (HL). This mitochondrial enzyme catalyzes the common final step of leucine degradation and ketogenesis. Acute symptoms include vomiting, seizures and lethargy, accompanied by metabolic acidosis and hypoketotic hypoglycaemia. Such organs as the liver, brain, pancreas, and heart can also be involved. However, the pathophysiology of this disease is only partially understood. We measured mRNA levels, protein expression and enzyme activity of human HMG-CoA lyase from liver, kidney, pancreas, testis, heart, skeletal muscle, and brain. Surprisingly, the pancreas is, after the liver, the tissue with most HL activity. However, in heart and adult brain, HL activity was not detected in the mitochondrial fraction. These findings contribute to our understanding of the enzyme function and the consequences of its deficiency and suggest the need for assessment of pancreatic damage in these patients.

High glucose levels induce inhibition of Na,K-ATPase via stimulation of aldose reductase, formation of microtubules and formation of an acetylated tubulin/Na,K-ATPase complex

Our previous studies demonstrated that acetylated tubulin forms a complex with Na(+),K(+)-ATPase and thereby inhibits its enzyme activity in cultured COS and CAD cells. The enzyme activity was restored by treatment of cells with l-glutamate, which caused dissociation of the acetylated tubulin/Na(+),K(+)-ATPase complex. Addition of glucose, but not elimination of glutamate, led to re-formation of the complex and inhibition of the Na(+),K(+)-ATPase activity. The purpose of the present study was to elucidate the mechanism underlying this effect of glucose. We found that exposure of cells to high glucose concentrations induced: (a) microtubule formation; (b) activation of aldose reductase by the microtubules; (c) association of tubulin with membrane; (d) formation of the acetylated tubulin/Na(+),K(+)-ATPase complex and consequent inhibition of enzyme activity. Exposure of cells to sorbitol caused similar effects. Studies on erythrocytes from diabetic patients and on tissues containing insulin-insensitive glucose transporters gave similar results. Na(+),K(+)-ATPase activity was >50% lower and membrane-associated tubulin content was >200% higher in erythrocyte membranes from diabetic patients as compared with normal subjects. Immunoprecipitation analysis showed that acetylated tubulin was a constituent of a complex with Na(+),K(+)-ATPase in erythrocyte membranes from diabetic patients. Based on these findings, we propose a mechanism whereby glucose triggers a synergistic effect of tubulin and sorbitol, leading to activation of aldose reductase, microtubule formation, and consequent Na(+),K(+)-ATPase inhibition.

Activation of PMCA by calmodulin or ethanol in plasma membrane vesicles from rat brain involves dissociation of the acetylated tubulin/PMCA complex

We have recently shown that acetylated tubulin interacts with plasma membrane Na+,K+‐ATPase and inhibits its enzyme activity in several types of cells. H+‐ATPase of Saccharomyces cerevisiae is similarly inhibited by interaction with acetylated tubulin. The activities of both these ATPases are restored upon dissociation of the acetylated tubulin/ATPase complex. Here, we report that in plasma membrane vesicles isolated from brain synaptosomes, another P‐type ATPase, plasma membrane Ca2+‐ATPase (PMCA), undergoes enzyme activity regulation by its association/dissociation with acetylated tubulin. The presence of acetylated tubulin/PMCA complex in membrane vesicles was demonstrated by analyzing the behavior of acetylated tubulin in a detergent partition, and by immunoprecipitation experiments. PMCA is known to be stimulated by ethanol and calmodulin at physiological concentrations. We found that treatment of plasma membrane vesicles with these reagents induced dissociation of the complex, with a concomitant restoration of enzyme activity. Conversely, incubation of vesicles with exogenous tubulin induced the association of acetylated tubulin with PMCA, and the inhibition of enzyme activity. These findings indicate that activation of synaptosomal PMCA by ethanol and calmodulin involves dissociation of the acetylated tubulin/PMCA complex. This regulatory mechanism was shown to also operate in living cells.