Stabilization and improvement of catalytic activity of a low molar mass cellobiase by cellobiase-sucrase aggregation in the culture filtrate of Termitomyces clypeatus

The extracellular cellobiase (EC 3.2.1.21) of Termitomyces clypeatus separated in two protein fractions when culture filtrate or ammonium sulfate precipitated proteins were chromatographed on BioGel P-200 column. During purification of cellobiase (CBS) from the lower molar mass (LMM) protein fraction, the enzyme behaved like a low molecular weight multimeric protein. The purified enzyme gave a single 56 kDa band in SDS-PAGE but ladderlike bands (14, 28, 42, and 56 kDa) on denaturation by reducing-SDS and urea. The protein, however, dissociated on dilution and protomeric (14 kDa) and multimeric forms (28 and 60 kDa) were eluted separately during HPGPLC. Specific activity of CBS gradually decreased as the molar mass of the enzyme was lowered in different eluted peaks. Protein present in all CBS pool fractions had the same amino acid composition and all displayed the same, single protein peak in reverse-phase HPLC and 56 kDa band in SDS-PAGE. Thus, T. clypeatus CBS was a multimeric 14 kDa protein that was optimally active as a tetramer. CBS purified from the higher molar mass fraction (HMM) as a SDS-PAGE homogeneous 110-kDa protein did not dissociate on dilution or by SDS-urea. The purified protein was a protein aggregate as CBS consistently contained 20 +/- 5% sucrase (SUC) Units in the preparation. The aggregate resolved during reverse-phase chromatography on a C(4) column, and an additional protein peak other than CBS was detected. The aggregated CBS had a higher temperature optimum and was more stable toward thermal and chemical denaturations than SUC-free CBS. Increase of stability and catalytic activity of CBS by aggregation with SUC was much higher than those by the multimerization of CBS itself. All of these observations for the first time suggested that the heterologous protein-protein aggregation, observed for a long time for fungal enzymes, might have a significant role in modulating physicochemical properties of the extracellular enzyme.     

Regulation of cellobiase secretion in Termitomyces clypeatus by co-aggregation with sucrase

Regulated secretory proteins are sorted via selective co-aggregation in eukaryotes. Cellobiase (C) of the filamentous fungus Termitomyces clypeatus remained co-aggregated with sucrase (S), and only one isoform of each of the enzymes was present in intra- and extracellular extracts. Kinetics of secretion of sucrase increased in vivo and in vitro in secreting (Sc) medium and decreased under non-secreting (NSc) conditions similar to those observed for cellobiase. In the Sc condition, total enzyme production and activity ratios of cellobiase and sucrase (C/S) in cell-bound, extra- and intracellular preparations increased with time and were significantly higher from those obtained in non-secretory media. It was concluded that secretion of sucrase in culture medium is under same cellular regulation as that of cellobiase, and sucrase is involved in regulating extracellular release of cellobiase through co-aggregation in the fungus. Received: 27 August 2001 / Accepted: 1 November 2001     

Removal of carboxymethyl cellulase activity from the culture filtrate of Termitomyces clypeatus producing xylanase

Termitomyces clypeatus produced 450 IU xylanase ml^–1 in a medium containing starch-free wheat bran powder as the carbon source. Carboxymethyl cellulase (CMCase) activity in the culture filtrate was removed by keeping the filtrate at pH 10 for 60 min followed by a change to pH 6. Treatment of Kraft pulp (bamboo) with the filtrate at pH 7 decreased the kappa number from 10.5 to 5 with release of reducing groups equivalent to 0.15 mg glucose g^–1 pulp.     

Secretion of cellobiase is mediated via vacuoles in Termitomyces clypeatus

The majority of cellobiase activity in Termitomyces clypeatus was localized in vacuolar fractions of the fungus under secretory and nonsecretory conditions of growth. Activities of marker proteins for subcellular organelles, e.g., vacuoles, cytosol, ER, and mitochondria, in mycelial extracts from the secreting conditions increased by approximately 20, 12, 5, and 2.5 times, respectively, as compared to those obtained from mycelium grown in nonsecreting conditions. The average size and concentration of vacuoles visualized by electron microscopy were also increased in secreting conditions in the fungus. The specific activity of cellobiase in vacuoles isolated in Ficoll-sucrose gradient, as obtained from mycelial growth in secretory medium, was more than 40 times higher in comparison to that found from nonsecretory medium. The results indicated that subcellular localization of cellobiase in vacuoles is regulated by the cellular signaling prevailing in the fungus. Mycelial extraction of intracellular proteins by hand grinding and by bead-beater from cells frozen in the presence or absence of liquid nitrogen was also compared. Maximum recovery of intracellular protein was obtained with the bead-beater under aerobic conditions in the absence of nitrogen. Highest recovery of vacuoles up to 85% was obtained by single-step ultracentrifugation of the mycelial extract of the fungus in Ficoll-sucrose gradient. The method appeared to be useful for separation of other subcellular organelles in filamentous fungi.     

Regulation (alteration) of activity and conformation of sucrase by coaggregation with cellobiase in culture medium of Termitomyces clypeatus

Extracellular sucrase (S) of Termitomyces clypeatus was aggregated with cellobiase (C) in culture filtrate and coaggregates of sucrase to cellobiase with different activity ratios (S/C) were obtained during purification. Specific activity of the enzyme decreased significantly, after purification of sucrase free from cellobiase. Purified sucrase was characterized as a glycoprotein of molar mass around 55kDa as indicated by SDS-PAGE and HPGPLC. K(m) and V(max) of the purified enzyme were determined as 34.48 mM and 13.3 U/mg, respectively, at optimum temperature (45 degrees C) and pH (5.0). Substrate affinity and reaction velocity of the purified enzyme, free from cellobiase, was lowered by approximately 3.5 and 55 times, respectively, than that of the enzyme obtained from culture filtrate. The instant regain of sucrase activity up to the extent of 41% was obtained on in vitro addition of cellobiase (free from sucrase) to the enzyme in incubation mixture. Conformation of the enzyme free from cellobiase appeared to be significantly different from that of the coaggregate, as analyzed by circular dichroic and light scattering spectroscopy. It was concluded that activity and conformation of sucrase is regulated (altered) by heteroaggregation with cellobiase in the fungus.     

In situ reversible aggregation of extracellular cellobiase in the filamentous fungus Termitomyces clypeatus

Cellobiase (E.C. 3.2.1.21), is a widely exploited industrial glycosidase with a major role in biofuel industry. Its stability and shelf life are major bottlenecks in achieving a superior formulation for industry. In the filamentous fungus Termitomyces clypeatus, the enzyme is secreted in a co-aggregated form with sucrase; the separation of this co-aggregation results in substantial loss of the enzyme??s activity. The aim of the present study was to examine the mode of aggregation of the secreted cellobiase-sucrase coaggregate and its role in the stabilization of cellobiase. Transmission electron microscopy and dynamic light scattering of purified co-aggregates revealed reversible, concentration driven self-aggregation of the extracellular enzymes to form larger entities. However, the intracellular enzyme aggregates were rigid, non-interacting, and possessed a higher percentage of disulphide bonds. Circular dichroic spectra of the two coaggregates indicated no significant difference in secondary structures. Self-association increased the stability of extracellular aggregates towards heat by 1.5 fold, SDS by 4 ?? 7 fold, and chaotropic agents, by 1.5 ?? 2 fold, than the intracellular counterpart. The K_m of extracellular aggregate varied between 0.29 and 0.45 mM as a result of spontaneous aggregation and disaggregation, whereas that of intracellular aggregate was 0.22 mM irrespective of its concentration status. In situ detection of cellobiase in native PAGE revealed two activity bands of the extracellular enzyme, which indicated a minimum of two active dissociated aggregate species, as compared to a single band for the intracellular enzyme. These studies are believed to improve the understanding of aggregation of the fungal glycosidases, which remains to be a blackbox, to increase the efficacy of these enzymes.     

RPA stabilizes the XPA-damaged DNA complex through protein-protein interaction

The xeroderma pigmentosum group A complementing protein (XPA) and eukaryotic replication protein A (RPA) are among the major damage-recognition proteins involved in the early stage of nucleotide excision repair (NER). XPA and RPA are able to bind damaged DNA independently, although RPA interaction stimulates XPA binding to damaged DNA [Li, L., Lu, X., Peterson, C. A., and Legerski, R. J. (1995) Mol. Cell. Biol. 15, 5396-5402 (1); Stigger, E., Drissi, R., and Lee, S.-H. (1998) J. Biol. Chem. 273, 9337-9343 (2)]. In this study, we used surface plasmon resonance (SPR) analysis to investigate the interaction of XPA and RPA with two major types of UV-damaged DNA: the (6-4) photoproduct and the cis-syn cyclobutane dimer of thymidine. Both XPA and RPA preferentially bind to (6-4) photoproduct-containing duplex DNA over cis-syn cyclobutane dimer-containing DNA. The binding of XPA to (6-4) photoproduct was weak (K(D) = 2.13 x 10(-)(8) M), whereas RPA showed a very stable interaction with (6-4) photoproduct (K(D) = 2. 02 x 10(-)(10) M). When XPA and RPA were incubated together, the stability of the XPA-damaged DNA interaction was significantly enhanced by wild-type RPA. On the other hand, mutant RPA (RPA:p34Delta33C) defective in its interaction with XPA failed to stabilize XPA-damaged DNA complex. Taken together, our results suggest that a role for RPA in UV-damage recognition is to stabilize XPA-damaged DNA complex through protein-protein interaction.     

Evidence of an alternative route of cellobiase secretion in the presence of brefeldin A in the filamentous fungus Termitomyces clypeatus

Secretion of cellobiase occurred in a brefeldin A (BFA) uninhibited manner in the filamentous fungus Termitomyces clypeatus. Fluorescence confocal microscopy revealed that application of the drug at a concentration of 50 microgram/ml caused arrest of Spitzenkorper assembly at the hyphal tip. This resulted in greater than 30% inhibition of total protein secretion in the culture medium. However, the cellobiase titer increased by 17%, and an additional 13% was localized in the vacuolar fraction en route secretion. The secretory vacuoles formed in the presence of the drug were also found to be bigger (68 nm) than those in the control cultures (40 nm). The enzyme secreted in the presence and absence of BFA revealed a single activity band in both cases in native PAGE and had similar molecular masses (approx. 120 kDa) in SDS-PAGE. The BFA enzyme retained 72% of native glycosylation. It also exhibited a higher stability and retained 98% activity at 50°C, 93.3% activity at pH 9, 63.64% activity in the presence of 1M guanidium hydrochloride, and 50% activity at a glucose concentration of 10 mg/ml in comparison to 68% activity, 75% activity, 36% activity, and 19% activity for the control enzyme, respectively. The observations collectively aimed at the operation of an alternative secretory pathway, distinct from the target of brefeldin A, which bypassed the Golgi apparatus, but still was able to deliver the cargo to the vacuoles for secretion. This can be utilized in selectively enhancing the yield and stability of glycosidases for a successful industrial recipe.     

Regulation of protein secretion by mycelial culture of the mushroom Termitomyces clypeatus

Termitomyces clypeatus secreted a 24-kDa xylanase constitutively in xylan medium, but required a gluconeogenic amino acid or Krebs cycle acid for the secretion of a 56-kDa amyloglucosidase in dextrin medium. Aspartate, glutamate, succinate and fumarate all increased secretion of amyloglucosidase from 50% to >90% and enzyme production by 10-fold with little effect on xylanase production. Glutamate or succinate stimulated in vitro release of intracellular amyloglucosidase from washed mycelia in the presence of cycloheximide. Amyloglucosidase accumulated in the absence of glutamate was a high-molecular-mass protein that did not migrate in PAGE. Cellular regulation by the fungus of the secretion of amyloglucosidase is indicated.     

Hypothesis: a glycoprotein-degradation complex formed by protein-protein interaction involves cytoplasmic peptide:N-glycanase

A cytoplasmic peptide:N-glycanase has been implicated in the proteasomal degradation of newly synthesized misfolded glycoproteins that are exported from the endoplasmic reticulum to the cytosol. Recently, the gene encoding this enzyme (Png1p) was identified in yeast and shown to bind to the 26S proteasome through its interaction with a component of the DNA repair system, Rad23p. Moreover, a mouse homologue of Png1p (mPng1p), which has an extended N-terminal domain, was found to bind not only to the Rad23 protein, but also to various proteins related to the ubiquitin/proteasome pathway. An extended N-terminus of mPng1p, which is not found in yeast, contains a potential site of protein-protein interaction called the PUB/PUG domain. The PUB/PUG domain is predicted to be helix-rich and is found in various proteins that may be involved in the ubiquitin/proteasome-related pathway. This review will discuss the consequence of the deglycosylation reaction by peptide:N-glycanase in cellular processes. In addition, the potential importance of the PUB/PUG domain for the formation of a putative "glycoprotein-degradation complex" will be discussed.     

A nonhistone protein-protein interaction required for assembly of the SIR complex and silent chromatin

Budding yeast silent chromatin, or heterochromatin, is composed of histones and the Sir2, Sir3, and Sir4 proteins. Their assembly into silent chromatin is believed to require the deacetylation of histones by the NAD-dependent deacetylase Sir2 and the subsequent interaction of Sir3 and Sir4 with these hypoacetylated regions of chromatin. Here we explore the role of interactions among the Sir proteins in the assembly of the SIR complex and the formation of silent chromatin. We show that significant fractions of Sir2, Sir3, and Sir4 are associated together in a stable complex. When the assembly of Sir3 into this complex is disrupted by a specific mutation on the surface of the C-terminal coiled-coil domain of Sir4, Sir3 is no longer recruited to chromatin and silencing is disrupted. Because in sir4 mutant cells the association of Sir3 with chromatin is greatly reduced despite the partial Sir2-dependent deacetylation of histones near silencers, we conclude that histone deacetylation is not sufficient for the full recruitment of silencing proteins to chromatin and that Sir-Sir interactions are essential for the assembly of heterochromatin.     

Discovering functional interaction patterns in protein-protein interaction networks

Background  

In recent years, a considerable amount of research effort has been directed to the analysis of biological networks with the availability of genome-scale networks of genes and/or proteins of an increasing number of organisms. A protein-protein interaction (PPI) network is a particular biological network which represents physical interactions between pairs of proteins of an organism. Major research on PPI networks has focused on understanding the topological organization of PPI networks, evolution of PPI networks and identification of conserved subnetworks across different species, discovery of modules of interaction, use of PPI networks for functional annotation of uncharacterized proteins, and improvement of the accuracy of currently available networks.     

乳杆菌对数生长期培养基滤液核酸组分分析

目的通过对乳杆菌对数生长期培养基滤液中核酸组分的分析,阐明乳杆菌DM9811对数生长期培养基滤液中核酸的性质。方法应用核酸的分离、纯化及电泳分析技术。结果乳杆菌对数生长期培养基滤液中核酸组分为RNA,其片段大小为100 bp左右。乳杆菌对数生长期培养基滤液中核酸组分为RNA,为对数期产生且呈时间依赖关系。结论核酸组分不仅仅是遗传信息的载体,还可能作为有效的信息分子。     

Phytochrome phosphorylation modulates light signaling by influencing the protein-protein interaction

Plant photoreceptor phytochromes are phosphoproteins, but the question as to the functional role of phytochrome phosphorylation has remained to be elucidated. We investigated the functional role of phytochrome phosphorylation in plant light signaling using a Pfr-specific phosphorylation site mutant, Ser598Ala of oat (Avena sativa) phytochrome A (phyA). The transgenic Arabidopsis thaliana (phyA-201 background) plants with this mutant phyA showed hypersensitivity to light, suggesting that phytochrome phosphorylation at Serine-598 (Ser598) in the hinge region is involved in an inhibitory mechanism. The phosphorylation at Ser598 prevented its interaction with putative signal transducers, Nucleoside Diphosphate Kinase-2 and Phytochrome-Interacting Factor-3. These results suggest that phosphorylation in the hinge region of phytochromes serves as a signal-modulating site through the protein-protein interaction between phytochrome and its putative signal transducer proteins.     

Mapping of protein-protein interaction sites by the 'absence of interference' approach

Protein-protein interactions are critical to most biological processes, and locating protein-protein interfaces on protein structures is an important task in molecular biology. We developed a new experimental strategy called the ‘absence of interference’ approach to determine surface residues involved in protein-protein interaction of established yeast two-hybrid pairs of interacting proteins. One of the proteins is subjected to high-level randomization by error-prone PCR. The resulting library is selected by yeast two-hybrid system for interacting clones that are isolated and sequenced. The interaction region can be identified by an absence or depletion of mutations. For data analysis and presentation, we developed a Web interface that analyzes the mutational spectrum and displays the mutational frequency on the surface of the structure (or a structural model) of the randomized protein†. Additionally, this interface might be of use for the display of mutational distributions determined by other types of random mutagenesis experiments. We applied the approach to map the interface of the catalytic domain of the DNA methyltransferase Dnmt3a with its regulatory factor Dnmt3L. Dnmt3a was randomized with high mutational load. A total of 76 interacting clones were isolated and sequenced, and 648 mutations were identified. The mutational pattern allowed to identify a unique interaction region on the surface of Dnmt3a, which comprises about 500-600 Å². The results were confirmed by site-directed mutagenesis and structural analysis. The absence-of-interference approach will allow high-throughput mapping of protein interaction sites suitable for functional studies and protein docking.     

Grafting of protein-protein interaction epitope

Transferring the biological function of one protein to another is a key issue in understanding the structure and function relationship of proteins. We have developed a strategy for grafting protein-protein interaction epitopes. As a first step, residues at the interface of the ligand protein which strongly interact with the receptor protein were identified. Then protein scaffolds were docked onto receptor protein based on geometric complementarity. Only high docking score matches were saved. For each saved match, the scaffold protein was accepted if it had suitable positions for grafting key interaction residues of the ligand protein. These candidate residues were mutated to corresponding residues in the ligand protein at each relevant position and the mutated scaffold protein was co-minimized with receptor protein. Finally, the minimized complexes were evaluated by a scoring function deduced from statistical analysis of rigid binding data sets. As a test case, the binding epitope of barstar, the inhibitor of barnase, was grafted onto smaller proteins. Pheromone Er-1 (PDB entry 1erc) has been found to be a good scaffold. The calculated binding free energy for mutated Pheromone Er-1 is equivalent to that of barstar.