Block Magnetic Excitations in the Orbitally Selective Mott Insulator BaFe_{2}Se_{3}.

Iron pnictides and selenides display a variety of unusual magnetic phases originating from the interplay between electronic, orbital, and lattice degrees of freedom. Using powder inelastic neutron scattering on the two-leg ladder BaFe_{2}Se_{3}, we fully characterize the static and dynamic spin correlations associated with the Fe_{4} block state, an exotic magnetic ground state observed in this low-dimensional magnet and in Rb_{0.89}Fe_{1.58}Se_{2}. All the magnetic excitations of the Fe_{4} block state predicted by an effective Heisenberg model with localized spins are observed below 300 meV and quantitatively reproduced. However, the data only account for 16(3)µ_{B}^{2} per Fe^{2+}, approximatively 2/3 of the total spectral weight expected for localized S=2 moments. Our results highlight how orbital degrees of freedom in iron-based magnets can conspire to stabilize an exotic magnetic state.

Single site alpha-tubulin mutation affects astral microtubules and nuclear positioning during anaphase in Saccharomyces cerevisiae: possible role for palmitoylation of alpha-tubulin.

We generated a strain of Saccharomyces cerevisiae in which the sole source of alpha-tubulin protein has a cys-to-ser mutation at cys-377, and then we examined microtubule morphology and nuclear positioning through the cell cycle. During G1 of the cell cycle, microtubules in the C377S alpha-tubulin (C377S tub1) mutant were indistinguishable from those in the control (TUB1) strain. However, mitotic C377S tub1 cells displayed astral microtubules that often appeared excessive in number, abnormally long, and/or misoriented compared with TUB1 cells. Although mitotic spindles were always correctly aligned along the mother-bud axis, translocation of spindles through the bud neck was affected. In late anaphase, spindles were often not laterally centered but instead appeared to rest along the sides of cells. When the doubling time was increased by growing cells at a lower temperature (15 degrees C), we often found abnormally long mitotic spindles. No increase in the number of anucleate or multinucleate C377S mutant cells was found at any temperature, suggesting that, despite the microtubule abnormalities, mitosis proceeded normally. Because cys-377 is a presumptive site of palmitoylation in alpha-tubulin in S. cerevisiae, we next compared in vivo palmitoylation of wild-type and C377S mutant forms of the protein. We detected palmitoylated alpha-tubulin in TUB1 cells, but the cys-377 mutation resulted in approximately a 60% decrease in the level of palmitoylated alpha-tubulin in C377S tub1 cells. Our results suggest that cys-377 of alpha-tubulin, and possibly palmitoylation of this amino acid, plays a role in a subset of astral microtubule functions during nuclear migration in M phase of the cell cycle.

Amino-terminal cysteine residues of RGS16 are required for palmitoylation and modulation of Gi- and Gq-mediated signaling.

RGS proteins (Regulators of G protein Signaling) are a recently discovered family of proteins that accelerate the GTPase activity of heterotrimeric G protein alpha subunits of the i, q, and 12 classes. The proteins share a homologous core domain but have divergent amino-terminal sequences that are the site of palmitoylation for RGS-GAIP and RGS4. We investigated the function of palmitoylation for RGS16, which shares conserved amino-terminal cysteines with RGS4 and RGS5. Mutation of cysteine residues at residues 2 and 12 blocked the incorporation of [3H]palmitate into RGS16 in metabolic labeling studies of transfected cells or into purified RGS proteins in a cell-free palmitoylation assay. The purified RGS16 proteins with the cysteine mutations were still able to act as GTPase-activating protein for Gialpha. Inhibition or a decrease in palmitoylation did not significantly change the amount of protein that was membrane-associated. However, palmitoylation-defective RGS16 mutants demonstrated impaired ability to inhibit both Gi- and Gq-linked signaling pathways when expressed in HEK293T cells. These findings suggest that the amino-terminal region of RGS16 may affect the affinity of these proteins for Galpha subunits in vivo or that palmitoylation localizes the RGS protein in close proximity to Galpha subunits on cellular membranes.

Posttranslational modification of tubulin by palmitoylation: II. Identification of sites of palmitoylation.

As shown in the companion article, tubulin is posttranslationally modified in vivo by palmitoylation. Our goal in this study was to identify the palmitoylation sites by protein structure analysis. To obtain quantities of palmitoylated tubulin required for this analysis, a cell-free system for enzymatic [3H]palmitoylation was developed and characterized in our companion article. We then developed a methodology to examine directly the palmitoylation of all 451 amino acids of alpha-tubulin. 3H-labeled palmitoylated alpha-tubulin was cleaved with cyanogen bromide (CNBr). The CNBr digest was resolved according to peptide size by gel filtration on Sephadex LH60 in formic acid:ethanol. The position of 3H-labeled palmitoylated amino acids in peptides could not be identified by analysis of the Edman degradation sequencer product because the palmitoylated sequencer products were lost during the final derivatization step to phenylthiohydantoin derivatives. Modification of the gas/liquid-phase sequencer to deliver the intermediate anilinothiozolinone derivative, rather than the phenylthiohydantoin derivative, identified the cycle containing the 3H-labeled palmitoylated residue. Therefore, structure analysis of peptides obtained from gel filtration necessitated dual sequencer runs of radioactive peptides, one for sequence analysis and one to identify 3H-labeled palmitoylated amino acids. Further cleavage of the CNBr peptides by trypsin and Lys-C protease, followed by gel filtration on Sephadex LH60 and dual sequencer runs, positioned the 3H-labeled palmitoylated amino acid residues in peptides. Integration of all the available structural information led to the assignment of the palmitoyl moiety to specific residues in alpha-tubulin. The palmitoylated residues in alpha-tubulin were confined to cysteine residues only. The major site for palmitoylation was cysteine residue 376.

Posttranslational modification of tubulin by palmitoylation: I. In vivo and cell-free studies.

It is well established that microtubules interact with intracellular membranes of eukaryotic cells. There is also evidence that tubulin, the major subunit of microtubules, associates directly with membranes. In many cases, this association between tubulin and membranes involves hydrophobic interactions. However, neither primary sequence nor known posttranslational modifications of tubulin can account for such an interaction. The goal of this study was to determine the molecular nature of hydrophobic interactions between tubulin and membranes. Specifically, I sought to identify a posttranslational modification of tubulin that is found in membrane proteins but not in cytoplasmic proteins. One such modification is the covalent attachment of the long chain fatty acid palmitate. The possibility that tubulin is a substrate for palmitoylation was investigated. First, I found that tubulin was palmitoylated in resting platelets and that the level of palmitoylation of tubulin decreased upon activation of platelets with thrombin. Second, to obtain quantities of palmitoylated tubulin required for protein structure analysis, a cell-free system for palmitoylation of tubulin was developed and characterized. The substrates for palmitoylation were nonpolymerized tubulin and tubulin in microtubules assembled with the slowly hydrolyzable GTP analogue guanylyl-(alpha, beta)-methylene-diphosphonate. However, tubulin in Taxol-assembled microtubules was not a substrate for palmitoylation. Likewise, palmitoylation of tubulin in the cell-free system was specifically inhibited by the antimicrotubule drugs Colcemid, podophyllotoxin, nocodazole, and vinblastine. These experiments identify a previously unknown posttranslational modification of tubulin that can account for at least one type of hydrophobic interaction with intracellular membranes.

Transcriptional regulation of the albumin gene in cultured rat hepatocytes. Role of basement-membrane matrix.

The expression of tissue-specific functions by hepatocytes in primary culture is enhanced in the presence of an extracellular matrix. A basement membrane-like substratum, derived from the Engelbreth-Holm-Swarm mouse sarcoma (EHS) and termed EHS gel, supports synthesis and secretion of albumin for at least three weeks, in contrast to a conventional substratum (plastic or collagen-coated plastic), on which cells rapidly lose this function. The presence of an EHS matrix (as a substratum or added to the medium as a dilute gel) supports transcriptional activity at 30 to 35% and specific mRNA at 70 to 80% of initial values after five days of culture, at a time when transcription in cells plated in conventional culture is undetectable. For examining the cis elements required for transcriptional regulation by EHS matrix, we are utilizing recombinant adenoviruses to introduce DNA into hepatocytes, as an alternative to transfection of DNA fragments. Initial studies are presented, in which hepatocytes are cultured on either collagen-coated plastic or on EHS gel. At various times after plating, the cultures are infected with an adenovirus containing the proximal 5' regulatory region (to -441 base-pair) of the albumin gene. The results indicate no effect of EHS gel on this proximal promoter region, implying that matrix-responsive element(s) lie further upstream, possibly within the previously described enhancer at about -10,000 base-pairs.

Induction of albumin gene transcription in hepatocytes by extracellular matrix proteins.

Transcriptional activity of the albumin gene was induced in primary cultures of hepatocytes by adding dilute concentrations of basement membrane-like proteins derived from the EHS mouse sarcoma tumor to established type I collagen cultures. By immunofluorescence microscopy with antialbumin antibody, the population of cells responded uniformly to dilute EHS. Of the three major components of EHS, purified laminin was as effective as unfractionated EHS at inducing an increase in albumin mRNA levels and albumin secretion; type IV collagen and heparan sulfate proteoglycan were ineffective.

Alteration of microtubule physiology in hepatocytes by insulin.

Incubation of primary cultures of rat hepatocytes with insulin caused an alteration in several parameters of microtubule physiology. There was a transient decrease in total cellular tubulin levels and, at the same time, an apparent stabilization of microtubule polymers which was also transient. The level of microtubule polymer, however, was not altered, which indicated that an insulin-inducible decrease in the level of nonpolymerized tubulin was responsible for the decrease in total cellular tubulin. These changes were followed by an increase in tubulin mRNA levels and, shortly thereafter, by an increase in tubulin protein synthesis. This study demonstrates that microtubule physiology in hepatocytes is modulated by insulin and, further, suggests a model by which insulin-induced changes in microtubule physiology may play a role in regulating other insulin responses.

Dynamic interactions between microtubules and artificial membranes.

We report that extensive adsorption of microtubule protein to liposomes occurs above the transition temperature of the phospholipid bilayer, occurs to phosphatidylcholine (PC) or phosphatidylserine (PS) vesicles, and is not affected by preincubation of microtubule protein with colchicine. Most importantly, we show that 51-63% of the tubulin adsorbed onto neutral (PC) phospholipid vesicles can be desorbed to form microtubules when buffer conditions are adjusted to favor microtubule assembly. By contrast, no microtubule assembly occurred with preadsorption of microtubule protein onto acidic (PS) phospholipid vesicles, suggesting irreversible binding.

Autoregulation of tubulin synthesis in hepatocytes and fibroblasts.

Microtubule polymer levels in mouse 3T6 fibroblasts and primary cultures of rat hepatocytes can be manipulated by treatment of cells with long term, low doses of colcemid. Such treatment produces a rather uniform population of cells with microtubules of reduced lengths. Using this system, we demonstrate (a) that the rate of tubulin synthesis is sensitive to small changes (10%) in microtubule polymer mass and (b) that the percent of inhibition of synthesis is proportional to the level of soluble tubulin. Experiments with hepatocytes indicate that not only synthesis but the stability of tubulin protein was also regulated to maintain a specific level of tubulin. Treatment of hepatocytes with colcemid or other microtubule-depolymerizing drugs reduced the half-life of tubulin from 50 to 2 h, whereas taxol, which stabilizes microtubules, increased the half-life. To assess the consequences of altering microtubule polymer mass, we have analyzed the effect of controlled depolymerization of microtubules in rat hepatocytes on the processing of endocytosed ligands and found it sensitive to small changes in microtubule polymer levels.

Autoregulation of tubulin synthesis in enucleated cells.

The effects on tubulin messenger RNA levels and tubulin protein synthesis of treating cells with microtubule-depolymerizing drugs or directly microinjecting cells with tubulin have suggested that non-polymerized tubulin depresses its own synthesis. The precise level of this control is unclear. It has been shown that enucleated cells, termed cytoplasts, retain many properties of the original cell, including maintenance of cell shape, pinocytic activity and locomotion as well as biosynthetic activities such as protein synthesis and replication of cytoplasmic viruses. Furthermore, cytoplasts retain most of the components of the cytoskeleton including the centrioles. If cytoplasmic activities alone are responsible for regulating tubulin biosynthesis, cytoplasts should contain the necessary components. To distinguish between regulation which would occur in the nucleus, that is, alterations in mRNA synthesis or modifications of the mRNA, from alterations in mRNA stability and/or translatability which would take place in the cytoplasm, we examined the autoregulation of tubulin synthesis in enucleated cells. Here, we report that enucleated mouse fibroblasts retain the ability to turn off tubulin protein synthesis in response to microtubule depolymerization, the reduction in tubulin synthesis being accompanied by a corresponding decrease in tubulin mRNA levels. Thus, transcription, processing and transport of tubulin mRNA from the nucleus are not likely to be the loci of regulation. Instead, tubulin must reduce, either directly or indirectly, the translatability of its own mRNA.

Interaction of microtubule proteins with phospholipid vesicles.

We have examined the interaction of unilamellar dimyristoyl phosphatidylcholine liposomes with the high-speed supernate of brain homogenate and with tubulin purified through one or two cycles of microtubule assembly-disassembly. Tubulin and certian high molecular weight proteins are selectively adsorbed from these mixtures onto liposomes. The composition of adsorbed proteins is similar to that obtained during corresponding cycles of microtubule assembly, suggesting the equivalency of these processes. Adsorption induces stacking and/or fusion of liposomes into multilamellar structures indicating strong protein-lipid interaction. In addition, liposome-adsorbed tubulin forms extensive intermolecular disulfide bridges that are inert to reducing agents in the aqueous medium. The observations form a basis for further study of the distribution, function, and properties of membrane-bound tubulin.