Response of three enzymes to oleic acid, trypsin, and calmodulin chemically modified with a reactive phenothiazine

Calmodulin was covalently modified with 10-(1-propionyloxysuccinimide)-2-trifluoromethylphenothiazine++ + to stoichiometries between 0 and 2 mol/mol in the presence of Ca2+. The modified calmodulins, oleic acid, and trypsin were assayed for their ability to activate pea plant NAD kinase, bovine brain 3',5'-cAMP phosphodiesterase, and human erythrocyte Ca2+-ATPase. All modified calmodulins activated both phosphodiesterase and Ca2+-ATPase; at the highest concentration assayed, calmodulin modified with 2 mol of reagent/mol activated phosphodiesterase and Ca2+-ATPase to 53% and 100%, respectively, of the activation obtained with unmodified calmodulin. However, higher concentrations of the modified calmodulins were required to observe the same activation; at least 900-fold and 100-fold higher concentrations were required for the two enzymes, respectively. NAD kinase was not activated by any calmodulin labeled to a stoichiometry greater than 1 mol/mol even when a concentration equal to 17,000 times the apparent dissociation constant of calmodulin for NAD kinase was assayed. Therefore, the modified protein (and not some fraction resistant to labeling) is active toward the mammalian enzymes but inactive toward plant NAD kinase. The different response of the three enzymes to the chemical modification suggests that the enzymes may utilize different binding domains on calmodulin. NAD kinase also was not activated by other known activators of the two mammalian enzymes, namely lipids and limited proteolysis. In parallel experiments using the same agents on each enzyme, NAD kinase was the only enzyme of the three that was not activated by oleic acid and several other lipids or by limited trypsin digestion. These results show that NAD kinase possesses several attributes which would not be predicted by current models of the mechanism of activation of enzymes by calmodulin.     

Amyloid fibril formation requires a chemically discriminating nucleation event: studies of an amyloidogenic sequence from the bacterial protein OsmB.

The sequence of the Escherichia coli OsmB protein was found to resemble that of the C-terminal region of the beta amyloid protein of Alzheimer's disease, which seems to be the major determinant of its unusual structural and solubility properties. A peptide corresponding to residues 28-44 of the OsmB protein was synthesized, and its conformational properties and aggregation behavior were analyzed. The peptide OsmB(28-44) was shown to form amyloid fibrils, as did two sequence analogs designed to test the sequence specificity of fibril formation. These fibrils bound Congo red, and two of the peptides showed birefringence. The peptide fibrils were analyzed by electron microscopy and Fourier transform infrared spectroscopy. Subtle differences were observed which were not interpretable at the molecular level. The rate of fibril formation by each peptide was followed by monitoring the turbidity of supersaturated aqueous solutions. The kinetics of aggregation were characterized by a delay period during which the solution remained clear, followed by a nucleation event which led to a growth phase, during which the solution became viscous and turbid due to the presence of insoluble fibrils. The observation of a kinetic barrier to aggregation is typical of a crystallization event. The delay period could be eliminated by seeding the supersaturated solution with previously formed fibrils. Each peptide could be nucleated by fibrils formed from that same peptide, but not by fibrils from closely related sequences, suggesting that fibril growth requires specific hydrophobic interactions. It appears likely that this repeated sequence motif, which comprises most of the OsmB protein sequence, dictates the structure and possibly the function of that protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Some viral and protozool diseases in the European wildcat (Felis silvestris).

Ten European wildcats (Felis silvestris) were examined at necropsy and an additional 23 were examined clinically for evidence of viral diseases in Scotland. Two plasma samples taken from live free-living wildcats showed positive ELISA reactions to feline leukemia antigen. A feline leukemia virus of subgroup A was isolated from one of these samples, taken from a wildcat in north-western Scotland. No antibodies to feline coronavirus or feline immunodeficiency virus were detected in any sample. Three of the live wildcats and one of the dead had chronic mucopurulent rhinotracheitis suggestive of "cat flu." One other dead wildcat had diffuse enlargement of anterior lymph nodes. The findings indicated that feline leukemia virus infection can occur in free-living Felis silvestris. It is possible that the disease exists as a sustained infection in some wildcat populations, although the close interaction between wildcat and the domestic cat means that the latter could act as a continual source of infection.     

The effects of deletions in the central helix of calmodulin on enzyme activation and peptide binding

Using site-directed mutagenesis we have expressed in Escherichia coli three engineered calmodulins (CaM) containing deletions in the solvent-exposed region of the central helix. These are CaM delta 84, Glu-84 removed; CaM delta 83-84, Glu-83 and Glu-84 removed; and CaM delta 81-84, Ser-81 through Glu-84 removed. The abilities of these proteins to activate skeletal muscle myosin light chain kinase, plant NAD kinase, and bovine brain calcineurin activities were determined, as were their abilities to bind a synthetic peptide based on the calmodulin-binding domain of skeletal muscle myosin light chain kinase. Similar results were obtained with all three deletion proteins. Vm values for enzymes activated by the deletion proteins are all within 10-20% of those values obtained with bacterial control calmodulin. Relative to bacterial control values, changes in Kact or Kd values associated with the deletions are all less than an order of magnitude: Kact values for NAD kinase and myosin light chain kinase are increased 5-7-fold, Kd values for binding of the synthetic peptide are increased 4-7-fold, and Kact values for calcineurin are increased only 1-3-fold. In assays of NAD kinase and myosin light chain kinase activation some differences between bovine calmodulin and bacterial control calmodulin were observed. With NAD kinase, Kact values for the bacterial control protein are increased 4-fold relative to values for bovine calmodulin, and Vm values are increased by 50%; with myosin light chain kinase, Kact values are increased 2-fold and Vm values are decreased 10-15% relative to those values obtained with bovine calmodulin. These differences between bacterial control and bovine calmodulins probably can be attributed to known differences in postranslational processing of calmodulin in bacterial and eucaryotic cells. No differences between bovine and control calmodulins were observed in assays of calcineurin activation or peptide binding. Our observations indicate that contacts with the deleted residues, Ser-81 through Glu-84, are not critical in the calmodulin-target complexes we have evaluated. Formation of these calmodulin-target complexes also does not appear to be greatly affected by the global alterations in the structure of calmodulin that are associated with the deletions. In models in which the central helix is maintained in the altered calmodulins, each deleted residue causes the two lobes of calmodulin to be twisted 100 degrees relative to one another and brought 1.5 A closer together.(ABSTRACT TRUNCATED AT 400 WORDS)     

Feline leukemia virus envelope gp70 of subgroups B and C defined by monoclonal antibodies with cytotoxic and neutralizing functions

Nine murine monoclonal antibodies (MAb) to the envelope proteins of feline leukemia virus (FeLV) are described. Eight MAb are directed to epitopes of the same molecular species of gp70 and the other MAb is directed to the p15E moiety. Six of the gp70 epitopes are discrete; two are closely associated or overlapping. Four anti-gp70 MAb (2 of IgG2A and 2 of IgG2B subclasses) were directly cytotoxic for FeLV-producer lymphoma cells with cat or with rabbit complement (C). Another MAb (IgG2B), which was not cytotoxic alone, specifically and synergistically increased the cytotoxic effects of both IgG2A MAb. Cytotoxic anti-gp70 MAb also had virus-neutralizing capacity; one MAb recognized a determinant common to all FeLV subgroups (A, B, and C), the others recognized gp70 epitopes not present on subgroup A but common to both B and C subgroups. Competitive inhibition of MAb binding was employed to map spatial distributions of the epitopes, and the results fitted a molecule shaped as an incomplete loop. According to the model, epitopes involved with cytotoxic and virus neutralizing antibody functions were closely associated; the region involved is approximately in the center of the molecule, and it contains epitopes that are variably expressed among individual isolates of FeLV derived from different cat lymphoma cell lines.     

STIM1-Ca(2+) signaling is required for the hypertrophic growth of skeletal muscle in mice

Immediately after birth, skeletal muscle must undergo an enormous period of growth and differentiation that is coordinated by several intertwined growth signaling pathways. How these pathways are integrated remains unclear but is likely to involve skeletal muscle contractile activity and calcium (Ca(2+)) signaling. Here, we show that Ca(2+) signaling governed by stromal interaction molecule 1 (STIM1) plays a central role in the integration of signaling and, therefore, muscle growth and differentiation. Conditional deletion of STIM1 from the skeletal muscle of mice (mSTIM1(-/-) mice) leads to profound growth delay, reduced myonuclear proliferation, and perinatal lethality. We show that muscle fibers of neonatal mSTIM1(-/-) mice cannot support the activity-dependent Ca(2+) transients evoked by tonic neurostimulation, even though excitation contraction coupling (ECC) remains unperturbed. In addition, disruption of tonic Ca(2+) signaling in muscle fibers attenuates downstream muscle growth signaling, such as that of calcineurin, mitogen-activated protein (MAP) kinases, extracellular signal-regulated kinase 1 and 2 (ERK1/2), and AKT. Based on our findings, we propose a model wherein STIM1-mediated store-operated calcium entry (SOCE) governs the Ca(2+) signaling required for cellular processes that are necessary for neonatal muscle growth and differentiation.     

Characterization of late acyltransferase genes of Yersinia pestis and their role in temperature-dependent lipid A variation

Yersinia pestis is an important human pathogen that is maintained in flea-rodent enzootic cycles in many parts of the world. During its life cycle, Y. pestis senses host-specific environmental cues such as temperature and regulates gene expression appropriately to adapt to the insect or mammalian host. For example, Y. pestis synthesizes different forms of lipid A when grown at temperatures corresponding to the in vivo environments of the mammalian host and the flea vector. At 37 degrees C, tetra-acylated lipid A is the major form; but at 26 degrees C or below, hexa-acylated lipid A predominates. In this study, we show that the Y. pestis msbB (lpxM) and lpxP homologs encode the acyltransferases that add C12 and C(16:1) groups, respectively, to lipid IV(A) to generate the hexa-acylated form, and that their expression is upregulated at 21 degrees C in vitro and in the flea midgut. A Y. pestis deltamsbB deltalpxP double mutant that did not produce hexa-acylated lipid A was more sensitive to cecropin A, but not to polymyxin B. This mutant was able to infect and block fleas as well as the parental wild-type strain, indicating that the low-temperature-dependent change to hexa-acylated lipid A synthesis is not required for survival in the flea gut.