Capacity For Self-association Research Articles

Protein Kinase C-Dependent Phosphorylation of Human Pleckstrin Reduces its Capacity for Self-Association and Impairs its Ability to Bind Phosphoinositide

Pleckstrin is a major substrate of protein kinase C in lymphocytes, macrophages, monocytes, granulocytes and platelets. In these cells, pleckstrin is expressed at high levels and represents approximately 1 % of total cellular protein. Pleckstrin plays an important role in protein kinase C-dependent secretion, and abberant pleckstrin phosphorylation has been associated with disease. The mechanism, however, by which phosphorylation regulates pleckstrin function is unknown. Here, we show that native pleckstrin self-associates to form dimers that reduce its binding capacity to phosphoinositides. Phosphomimetic amino acid substitutions at residues normally phosphorylated by protein kinase C result in significantly reduced pleckstrin dimerization. Although phosphomimetic forms of pleckstrin exhibit subtle conformational changes they retain most of their phosphoinositide binding properties. These findings suggest that phosphorylation regulates pleckstrin interaction with membranes via a dimerization-dependent mechanism.

Biophysical Characterization of Pro-apoptotic BimBH3 Peptides Reveals an Unexpected Capacity for Self-Association

Bcl-2 proteins orchestrate the mitochondrial pathway of apoptosis, pivotal for cell death. Yet, the structural details of the conformational changes of pro- and antiapoptotic proteins and their interactions remain unclear. Pulse dipolar spectroscopy (double electron-electron resonance [DEER], also known as PELDOR) in combination with spin-labeled apoptotic Bcl-2 proteins unveils conformational changes and interactions of each protein player via detection of intra- and inter-protein distances. Here, we present the synthesis and characterization of pro-apoptotic BimBH3 peptides of different lengths carrying cysteines for labeling with nitroxide or gadolinium spin probes. We show by DEER that the length of the peptides modulates their homo-interactions in the absence of other Bcl-2 proteins and solve by X-ray crystallography the structure of a BimBH3 tetramer, revealing the molecular details of the inter-peptide interactions. Finally, we prove that using orthogonal labels and three-channel DEER we can disentangle the Bim-Bim, Bcl-xL-Bcl-xL, and Bim-Bcl-xL interactions in a simplified interactome.

Remarkable Functional Constraints on the Antigen Receptors of CLL Stereotyped Subset #2: High-Throughput Immunogenetic Evidence

Subset #2 is the largest subset carrying stereotyped B cell receptor immunoglobulin (BcR IG) in chronic lymphocytic leukemia (CLL). This particular BcR IG is composed of heavy (HC) and light (LC) chains encoded by the IGHV3-21 and the lambda IGLV3-21 gene, respectively. The clonotypic IGHV3-21 genes display a variable load of somatic hypermutation (SHM), being mostly classified as mutated (M-CLL) but also including unmutated (U-CLL) cases. Subset #2 cases, independently of the SHM status, have a particularly dismal clinical outcome similar to that of patients with TP53 aberrations, although lacking such aberrations. Subset #2 BcR IG display a series of distinctive features, including conservation at certain VH and VL CDR3 positions and recurrent SHMs; as well as a capacity for self-association leading to cell autonomous signaling that is critically dependent on a substitution of Arginine (R) for Glycine (G) introduced by SHM at the lambda VL-CL linker region. These features implicate antigen selection in CLL subset #2 ontogeny. However, the available molecular evidence derives from low throughput immunogenetic analysis, precluding comprehensive assessment of antigenic impact on (sub)clonal composition. Here, we sought to overcome this limitation by performing next-generation sequencing (NGS) of HC and LC gene rearrangements of 20 subset #2 patients. RT-PCR products amplified by the IGHV3-21/IGHJ6 and IGLV3-21/IGLC primer pairs, respectively, were subjected to NGS on the MiSeq Illumina Platform. NGS data was analyzed by a validated bioinformatics pipeline. Rearrangements with identical CDR3 amino acid (aa) sequences were defined as clonotypes, whereas clonotypes with different aa substitutions within the V-domain were defined as subclones. Starting with HCs, we obtained 3,340,508 (mean: 291,751, range: 101,231-186,055) productive reads. On average, each analyzed sample carried 92 distinct clonotypes (range: 71-152), with the dominant clonotype having a mean frequency of 96% (range: 67-99%): in all cases the dominant clonotype was identical to that determined by Sanger sequencing. The dominant clonotype displayed considerable intraclonal heterogeneity with a mean of 5,082 subclones/sample (range: 2,946-11,041). Turning to LCs, we obtained 5,094,045 (mean: 231,547, range: 38,036-507,949) productive reads. LCs carried a higher number of distinct clonotypes/sample compared to their partner HCs (mean 222, range: 156-306). The dominant clonotype had a mean frequency of 96% (range: 74-98%); similar to HCs, it was identical to that determined by Sanger sequencing. Intraclonal heterogeneity was observed in the LCs as well, with a mean of 7,382 subclones/sample (range: 1,946-11,866), hence more pronounced vs their partner HCs. Viewing the entire subset #2 VH or VL CDR3 dataset (i.e. the CDR3 aa sequences from all clonotypes of all cases) as a single entity branching through diversification enabled the identification of 2 distinct VH CDR3 sequences present at varying frequencies in 16 and 13 cases, respectively; and, 3 distinct VL CDR3 sequences present at varying frequencies in all 20 cases: these results allude to important constraints on the composition of the antigen binding site. Focusing on SHM, the following notable observations could be made. (i) The G-to-R substitution at the VL-CL linker was a clonal event in all cases with R being degenerately encoded by different nucleotide sequences; altogether, these findings underscore the seminal role of this recurrent SHM, likely due to mediating self-association. (ii) A recurrent 3-nucleotide deletion was detected in the VH CDR2 of all cases, strongly supporting functional pressure. This change, previously identified by Sanger sequencing as a recurrent SHM in subset #2 (albeit at a frequency of only 25%), was clonal in 4 cases and subclonal in the remainder, where it was present in an average of 105 subclones/sample (range: 1-369). (iii) Certain positions in both the VH and VL domain bore the same aa substitution, mostly at subclonal level: the prime example concerned the G for Serine (S) substitution within the VL CDR3, detected in all samples at a mean frequency of 44.2% (range: 6.3-87%). In conclusion, we provide compelling immunogenetic evidence for functional pressure in the ontogeny of CLL subset #2. On this evidence, subset #2 emerges as perhaps the most striking example of antigen-driven leukemogenesis reported thus far. DisclosuresGemenetzi:Gilead: Research Funding. Agathangelidis:Gilead: Research Funding. Stamatopoulos:Abbvie: Honoraria, Research Funding; Gilead: Honoraria, Research Funding; Janssen: Honoraria, Research Funding. Hadzidimitriou:Abbvie: Research Funding; Gilead: Research Funding; Janssen: Honoraria, Research Funding.

Structural Insights into the Intrinsic Self-Assembly of Par-3 N-Terminal Domain

Par-3, the central organizer of the Par-3/Par-6/atypical protein kinase C complex, is a multimodular scaffold protein that is essential for cell polarity establishment and maintenance. The N-terminal domain (NTD) of Par-3 is capable of self-association to form filament-like structures, although the underlying mechanism is poorly understood. Here, we determined the crystal structure of Par-3 NTD and solved the filament structure by cryoelectron microscopy. We found that an intrinsic "front-to-back" interaction mode is important for Par-3 NTD self-association and that both the lateral and longitudinal packing within the filament are mediated by electrostatic interactions. Disruptions of the lateral or longitudinal packing significantly impaired Par-3 NTD self-association and thereby impacted the Par-3-mediated epithelial polarization. We finally demonstrated that a Par-3 NTD-like domain from histidine ammonia-lyase also harbors a similar self-association capacity. This work unequivocally provides the structural basis for Par-3 NTD self-association and characterizes one type of protein domain that can self-assemble via electrostatic interactions.

Control of Erythrocyte Membrane-Skeletal Cohesion by the Spectrin-Membrane Linkage

Spectrin tetramer is the major structural member of the membrane-associated skeletal network of red cells. We show here that disruption of the spectrin-ankyrin-band 3 link to the membrane leads to dissociation of a large proportion of the tetramers into dimers. Noncovalent perturbation of the linkage was induced by a peptide containing the ankyrin-binding site of the spectrin beta-chain, and covalent perturbation by treatment with the thiol reagent, N-ethylmaleimide (NEM). This reagent left the intrinsic self-association capacity of the spectrin dimers unaffected and disturbed only the ankyrin-band 3 interaction. The dissociation of spectrin tetramers on the membrane into functional dimers was confirmed by the binding of a spectrin peptide directed against the self-association sites. Dissociation of the tetramers resulted, we infer, from detachment of the proximal ends of the constituent dimers from the membrane, thereby reducing their proximity to one another and thus weakening their association. The measured affinity of the interaction of the peptides with the free dimer ends on the membrane permits an estimate of the equilibrium between intact and dissociated tetramers on the native membrane. This indicates that in the physiological state the equilibrium proportion of the dissociated tetramers may be as high as 5-10%. These findings enabled us to identify an additional important functional role for the spectrin-ankyrin-band 3 link in regulating spectrin self-association in the red cell membrane.

Biochemical and cellular characteristics of the 3' -> 5' exonuclease TREX2

TREX2 is an autonomous nonprocessive 3′ → 5′ exonuclease, suggesting that it maintains genome integrity. To investigate TREX2's biochemical and cellular properties, we show that endogenous TREX2 is expressed widely in mouse tissues and human cell lines. Unexpectedly, endogenous human TREX2 is predominantly expressed as a 30-kDa protein (not 26 kDa, as previously believed), which is likely encoded by longer isoforms (TREX2L1 and/or TREX2L2) that possess similar capacity for self-association, DNA binding and catalytic activity. Site-directed mutagenesis analysis shows that the three functional activities of TREX2 are distinct, yet integrated. Mutation of amino acids putatively important for homodimerization significantly impairs both DNA binding and exonuclease activity, while mutation of amino acids (except R163) in the DNA binding and exonuclease domains affects their corresponding activities. Interestingly, however, DNA-binding domain mutations do not impact catalytic activity, while exonuclease domain mutations diminish DNA binding. To understand TREX2 cellular properties, we find endogenous TREX2 is down regulated during G2/M and nuclear TREX2 displays a punctate staining pattern. Furthermore, TREX2 knockdown reduces cell proliferation. Taken together, our results suggest that TREX2 plays an important function during DNA metabolism and cellular proliferation.

Xyloglucan–cellulose interaction depends on the sidechains and molecular weight of xyloglucan

Recent papers have brought evidence against the hypothesis that the fucosyl branching of primary wall xyloglucans (Xg) are responsible for their higher capacity of binding to cellulose. Reinforcement of this questioning has been obtained in this work where we show that the binding capacity was improved when the molecular weight (MW) of the Xg polymers is decreased by enzymatic hydrolysis. Moreover, the enthalpy changes associated with the adsorption process between Xg and cellulose is similar for Xgs with similar MW (but differing in the fine structure such as the presence/absence of fucose). On the basis of these results, we suggest that the fine structure and MW of Xg determines the energy and amount of binding to cellulose, respectively. Thus, the occurrence of different fine structural domains of Xg (e.g. the presence of fucose and the distribution of galactoses) might have several different functions in the wall. Besides the structural function in primary wall, these results might have impact on the packing features of storage Xg in seed cotyledons, since the MW and absence of fucose could also be associated with the self-association capacity.

Interaction of Surfactin with Membranes: A Computational Approach

Modeling analysis was used to understand the molecular mechanisms of the biological activities of surfactin, in particular, its hemolytic activity. This study highlights the importance of the fatty acid chain hydrophobicity of the surfactin on its activities, the C15 homologue being the most active. This is related to its self-association capacity. The detergent effect is the predominant mechanism involved in the hemolytic activity. A two-step mechanism is suggested, depending on the surfactin concentration. Other mechanisms (cationic channel, mobile carrier) can also be involved in particular conditions.

Identification of Residues within Two Regions Involved in Self-association of Viral Histone-like Protein p6 from Phage Ø29

Protein p6 of Bacillus subtilis phage theta29 is involved in the initiation of viral DNA replication and transcription by forming a multimeric nucleoprotein complex with the phage DNA. Based on this, together with its abundance and its capacity to bind to the whole viral genome, it has been proposed to be a viral histone-like protein. Protein p6 is in a monomer-dimer-oligomer equilibrium association. We have identified protein p6 mutants deficient in self-association by testing random mutants obtained by degenerated polymerase chain reaction in an in vivo assay for dimer formation. The mutations were mainly clustered in two regions located at the N terminus, and the central part of the protein. Site-directed single mutants, corresponding to those found in vivo, have been constructed and purified. Mutant p6A44V, located at the central part of the protein, showed an impaired dimer formation ability, and a reduced capacity to bind DNA and to activate the initiation of O29 DNA replication. Mutant p6I8T has at least 10-fold reduced self-association capacity, does not bind DNA nor activate O29 DNA initiation of replication. C-terminal deletion mutants showed an enhanced dimer formation capacity. The highly acidic tail, removed in these mutants, is proposed to modulate the protein p6 self-association.

The influence of alkyl substituents on the chromatographic indicator of self-association ofN-containing heterocyclic compounds

The chromatographic indicator of the ability of substances to form associates in a pure liquid δT b.p. proposed in our previous study was used to estimate the capacity for self-association of alkyl-substituted imidazoles, pyrazoles, pyrroles, oxazoles, isoxazoles, pyridazines, pyrimidines, pyrazines, and pyridines. Alkyl substituents introduced in heterocyclic compounds decrease the δT b.p. values, which is consistent with the data on the heats of self-association of heterocyclic compounds in pure liquids. The reasons for the difference between the boiling point of a compound at standard pressure and its “gas-chromatographic boiling point” are discussed.

Self-association of the C-terminal domain of the hepatitis-C virus core protein.

The N-terminal region of the hepatitis-C virus (HCV) core protein is rich in basic residues, while the C-terminal end of the protein comprises of a stretch of hydrophobic amino acids. Between these two extremes is an amphipathic region with two predicted alpha-helical segments. This region embodies Leu or hydrophobic residues in positions of heptad repeats and is possibly capable of self-association. To investigate this possibility, the core sequence was divided into two fragments and expressed separately as recombinant proteins. Recombinant proteins with the N-terminal fragment remained as monomers even at high concentrations in SDS/PAGE. Recombinant protein with the C-terminal fragment appeared largely monomeric on denaturing gels but some oligomers were also detected. Furthermore, proline mutations in either one of the predicted alpha helices adversely affected the observed oligomerization. The self-association capacity of the core protein C-terminal region was further supported by results from a yeast two-hybrid system. To affirm our conclusion, a peptide covering the heptad repeats and the predicted alpha helices was synthesized. Data from mass spectrometry and gel-filtration chromatography concluded that this peptide readily self-associated into the homodimer. Therefore, our results suggest that the oligomerization motifs of the HCV core protein may not be limited to the previously suggested N-terminal region.

Insulin lispro: a review of its pharmacological properties and therapeutic use in the management of diabetes mellitus.

Insulin lispro, a recombinant insulin analogue, is identical to human insulin except for the transposition of proline and lysine at positions 28 and 29 in the C-terminus of the B chain. The resultant reduced capacity for self-association in solution translates into more rapid absorption of insulin lispro than human regular insulin from subcutaneous sites. Maximum insulin concentrations are higher and are reached earlier with insulin lispro than with human regular insulin, and insulin concentrations return to baseline values more quickly with insulin lispro; consequently, insulin lispro has a more rapid onset and a shorter duration of glucose-lowering activity. These pharmacological properties provided the rationale for comparative clinical trials of subcutaneous insulin lispro (administered within 15 minutes before meals, preferably immediately before meals) and subcutaneous human regular insulin (administered 20 to 45 minutes before meals) in patients with type 1 diabetes (insulin-dependent diabetes mellitus) or type 2 diabetes (non-insulin-dependent diabetes mellitus) requiring premeal insulin therapy plus basal insulin therapy. Available clinical trials are well designed and results suggest that 1- and 2-hour postprandial blood glucose levels with insulin lispro are similar to or lower than those with human regular insulin; 1- and 2-hourpostprandial glucose excursions are similar to or less pronounced than those with human regular insulin. Glycated haemoglobin A values were generally similar with both agents. Continuous subcutaneous insulin infusion was associated with greater improvements in postprandial blood glucose levels and glycated haemoglobin A1 values with insulin lispro than with human regular insulin. Confirmatory data are required. The incidence of hypoglycaemia with insulin lispro was similar to or lower than that with human regular insulin. In particular insulin lispro appears to be associated with a lower incidence of night-time and severe hypoglycaemic episodes. Evidence also suggests that patients perceive their quality of life to be improved with insulin lispro compared with human regular insulin, and that satisfaction with treatment is greater with the insulin analogue. Thus, in patients with type 1 or 2 diabetes requiring premeal insulin therapy, insulin lispro appears to provide greater postprandial glycaemic control than human regular insulin without increasing the risk of hypoglycaemia. Furthermore, the reduced injection-meal interval with this agent offers greater convenience for the patient than regular human insulin. If longer term clinical experience supports these promising results it is likely that insulin lispro will offer important advantages over human regular insulin.

Lys(B28), Pro(B29)]-human insulin: Effect of injection time on postprandial glycemia

[Lys(B28), Pro(B29)]-human insulin (lispro) is an insulin analogue with a reduced capacity for self-association and faster absorption from subcutaneous injection sites. We hypothesized that administration of lispro closer to a meal would result in better glucose control than that achieved with regular insulin. This trial used a randomized crossover design that consisted of a period of metabolic stabilization lasting 9 days followed by an evaluation period lasting 5 days. The patients received weight-maintenance diets, and insulin doses were adjusted as needed. Calorie intake, insulin dose, and activities were kept constant once the evaluation period began. During the evaluation period, we varied the time between insulin injection and mealtime and assessed glucose control. During the evaluation period, the lowest mean glucose concentrations were 117.9 mg/dl for lispro and 119.8 mg/dl (p = 0.817) for regular insulin. To obtain these, we gave lispro, on average, 22.5 minutes before meals and regular insulin 63.8 minutes before meals (p = 0.006). A similar pattern was evident throughout the glucose control parameters. The exception was mean amplitude of glucose excursion, which was lower after lispro (59 versus 75 mg/dl; p = 0.007) compared with regular insulin. We achieved equal or slightly better glucose control, as reflected by mean amplitude of glucose excursion, with insulin lispro given much closer to meal time than that achieved with regular insulin. As a result of these findings, we propose that a rapidly absorbed analogue of insulin is capable of achieving better control of postprandial glucose at a more convenient injection time.

Fluorescence studies on the interactions of myelin basic protein in electrolyte solutions

This paper examines the influence of electrolytes on fluorescence spectral properties of the single tryptophanyl residue, Trp-115, within the 18.5-kDa species of myelin basic protein from bovine brain. Steady-state fluorescence spectra and intensities and time-correlated fluorescence lifetimes increased in the presence of increasing concentrations of mono- and divalent electrolytes (Li+, Na+, K+, Mg2+, Ca2+, Cl-, ClO4-, SO4(2-), and PO4(3-)). In all cases, the increases closely paralleled the ionic strength of the bulk aqueous medium and resembled that observed upon immersion of the protein in solutions of urea. This behavior was therefore concluded to reflect changes in the solution conformation of myelin basic protein. Bimolecular quenching of Trp-115 by acrylamide was rapid (10(9) M-1 s-1), approaching the diffusion limitation, and markedly dependent on the viscosity of the bulk aqueous medium. Rotational depolarization of myelin basic protein was rapid (phi less than or equal to 1 ns), occurring at rates exceeding those predicted for a rigid particle of revolution, and markedly dependent on the viscosity of the surrounding medium. Whereas the bimolecular quenching constants were unaltered in the presence of electrolytes, rotational depolarization of myelin basic protein underwent substantial slowing as indicated by the appearance of an additional decay component characterized by a correlation time of 5-10 ns. These studies indicate that Trp-115 of myelin basic protein is readily accessible to the bulk aqueous medium and is associated with a highly mobile segment of the protein. The slowing of rotational depolarization upon immersion of myelin basic protein in electrolyte solutions is consistent with an electrolyte-induced self-association of myelin basic protein molecules and indicates a relationship between the lability of solution conformation on the one hand and the capacity for self-association on the other.

Low-frequencyPublishing vibrational spectra and capacity for self-association of organomercury derivatives of thiols

1. The low-frequency IR and Raman spectra (150–400 cm−1) of the phenylmercury derivatives of a series of aliphatic and aromatic thiols have been studied in the condensed phase and in solution. The influence of intermolecular coordination interactions on the frequency and half-width of the stretching vibrations of S-Hg has been examined. 2. The capacity for self-association of phenylmercury derivatives of aliphatic thiols is lower than for substituted thiophenol, and for substituted aliphatic thiols the capacity for self-association falls with increase in the carbon chain length, and especially with branching. 3. Phenylmercury derivatives of aromatic and aliphatic thiols are more prone to selfassociation than to coordination with pyridine.

Study of the thermal and viscoelastic properties of phosphorus-containing urethane block copolymers

A series of phosphorus-containing block copolyurethanes distinguished by the structure of the rigid blocks has been studied by DTA, thermomechanical analysis, stress relaxation on constant deformation and X-ray diffraction at low scatter angles. It is shown that the inhomogeneity of structure and flexibility of the chain of the block copolymer predetermines the development of processes of microphase ply separation which, in turn, influence the formation of the macroproperties of the block copolyurethanes. Phosphorus-containing chain elongators of rigid blocks reduce their capacity for self-association into rigid domains although by changing the structure and polarity of the other fragments of rigid blocks one may change in a directed way the character of the microphase ply separation in the system. A model of the rigid domain is proposed for the phosphorus-containing block copolyurethanes studied.

IR spectroscopic study of the structure and capacity for intermolecular coordination of organomercury, organolead, and organotin derivatives of p-carbonyl-containing phenols

1. We have examined the spectral characteristics of the absorption bands in the 1550–1750 cm−1 region of p-carbonyl-containing phenols and the corresponding organometallic derivatives in nonpolar and polar solvents. 2. The capacity for self-association of p-carbonyl-containing compounds falls in the order H > SnPh3 > PbPh3 > HgPh for different classes of compounds. 3. When conjugation between the R3SnO group and the CH3CO substituent is possible self-association of p-R3SnOC6H4COCH3 is more facile than association of R3SnOAr and ArCOCH3. 4. These compounds have the benzenoid structure in polar and nonpolar solvents. The intensity of the benzene ring modes varies in an order corresponding to the change in the electron-donating properties of the RnM groups: Ph3Pb ≥ SnEt3 > HgPh > SnPh3 > H. 5. The magnitudes of σ R o of these groups calculated from thev Ar intensity by Katritzky's method are not constant but depend on the p-substituent and the solvent.

Molecular structure of elongated forms of electric eel acetylcholinesterase

Molecular forms of acetylcholinesterase extracted from fresh electric organ tissue of the electric eel are elongated structures in which a multi-subunit head is connected to a fibrous tail. The principal form, 18 S acetylcholinesterase, is of molecular weight approximately 1,050,000, contains about 12 catalytic subunits in its head, has a tail approximately 500 Å long, and aggregates reversibly at low ionic strength. Trypsin converts it to an 11 S globular tetramer devoid of the tail and lacking the capacity to aggregate in low-salt solutions. Amino acid analysis shows that elongated forms of acetylcholinesterase contain significant amounts of hydroxyproline and hydroxylysine, characteristic components of collagen, which are absent from 11 S acetylcholinesterase. Collagenase converts 18 S acetylcholinesterase to a 20 S form which no longer aggregates in low salt. Purified 20 S acetylcholinesterase has about half the hydroxyproline and hydroxylysine contents of the 18 S enzyme, and physicochemical measurements indicate the formation of a more symmetrical molecular structure without marked reduction in molecular weight. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis without reducing agent shows that in 18 S acetylcholinesterase half the catalytic subunits are present as dimers linked by disulfide bonds. The remaining subunits migrate as larger molecular species which contain significant amounts of hydroxylysine, are specifically modified by collagenase and are converted to dimers and monomers by trypsin. Sodium dodecyl sulfate/acrylamide gel electrophoresis with reducing agent reveals, in 18 S acetylcholinesterase, two polypeptides of molecular weights 45,000 and 47,000 which are absent in the 11 S tetramer. They are readily digested by collagenase under conditions which do not affect the catalytic subunits, with concomitant formation of a new 30,000 polypeptide. The above data can be rationalized by a model in which 18 S acetylcholinestorase contains three subunit tetramers, each linked by disulfides to one strand of a collagen triple helix. Sodium dodecyl sulfate detaches those subunit dimers which are not covalently linked to the tail; trypsin attacks the distal portion of the collagen triple helix releasing discrete tetramers, and collagenase specifically attacks the triple helix near its midpoint, producing a shortened structure in which the residual tail still holds the tetramers together, but destroying the capacity for self-association at low ionic strength. This latter property may be related to the postulated role of the tail in anchoring acetylcholinesterase to the fibrillar matrix of the basement membrane.

RNA viruses: stabilization of brome mosaic virus.

The relative importances of protein-protein and RNA-protein interactions in stabilizing the architecture of brome mosaic virus particles are discussed in the light of the following experimental evidence: (a) disassembly pathways of the virus particles, (b) reassembly of the virus and self-association capacity of the protein moiety, and (c) the role of divalent cations in virus stabilization, and their relevance to localization of the RNA in the virus particles. Evidence is given that the capsid of BMV is primarily stabilized by hydrophobic bonds at low pH, but not around and above neutrality where RNA-protein electrostatic interactions are essential to the integrity of the virus particles. A model is proposed for the structure of BMV in the different configurational states.

N‐Acetylglutamate 5‐Phosphotransferase of Pseudomonas aeruginosa

Some kinetic properties of N‐acetylglutamate 5‐phosphotransferase (ATP: N‐acetyl‐l‐glutamate 5‐phosphotransferase EC 2.7.2.8) purified approx. 2000‐fold from Pseudomonas aeruginosa have been studied. The enzyme required Mg2+ for activity. Mn2+, Zn2+, Co2+, and Ca2+, in this order, could replace Mg2+ partially. The substrate specificity was narrow: N‐carbamoyl‐l‐glutamate and N‐formyl‐l‐glutamate were phosphorylated, but at a lower rate than N‐acetyl‐l‐glutamate; N‐propionyl‐l‐glutamate was almost inactive as a substrate. dATP, but neither GTP nor ITP, could be used instead of ATP. The enzyme had a broad pH optimum from pH 6.5 to 9. Feedback inhibition by l‐arginine was markedly dependent on pH. Above pH9 no inhibition was observed. l‐Citrulline was three times less potent an inhibitor than l‐arginine.The enzyme showed Michaelis‐Menten kinetics, even at low concentration of the second substrate. The apparent Km was 2 mM for N‐acetyl‐l‐glutamate (at 10 mM ATP) and approx. 3 mM for ATP (at 40 mM N‐acetyl‐l‐glutamate). In the presence of l‐arginine the rate‐concentration curves for N‐acetyl‐l‐glutamate became sigmoidal, while no cooperativity was detected for ATP.A method was developed allowing the determination of N‐acetyl‐l‐glutamate in the nanomolar range by means of purified enzyme.