Iridovirus CARD Protein Inhibits Apoptosis through Intrinsic and Extrinsic Pathways.

Grouper iridovirus (GIV) belongs to the genus Ranavirus of the family Iridoviridae; the genomes of such viruses contain an anti-apoptotic caspase recruitment domain (CARD) gene. The GIV-CARD gene encodes a protein of 91 amino acids with a molecular mass of 10,505 Daltons, and shows high similarity to other viral CARD genes and human ICEBERG. In this study, we used Northern blot to demonstrate that GIV-CARD transcription begins at 4 h post-infection; furthermore, we report that its transcription is completely inhibited by cycloheximide but not by aphidicolin, indicating that GIV-CARD is an early gene. GIV-CARD-EGFP and GIV-CARD-FLAG recombinant proteins were observed to translocate from the cytoplasm into the nucleus, but no obvious nuclear localization sequence was observed within GIV-CARD. RNA interference-mediated knockdown of GIV-CARD in GK cells infected with GIV inhibited expression of GIV-CARD and five other viral genes during the early stages of infection, and also reduced GIV infection ability. Immunostaining was performed to show that apoptosis was effectively inhibited in cells expressing GIV-CARD. HeLa cells irradiated with UV or treated with anti-Fas antibody will undergo apoptosis through the intrinsic and extrinsic pathways, respectively. However, over-expression of recombinant GIV-CARD protein in HeLa cells inhibited apoptosis induced by mitochondrial and death receptor signaling. Finally, we report that expression of GIV-CARD in HeLa cells significantly reduced the activities of caspase-8 and -9 following apoptosis triggered by anti-Fas antibody. Taken together, these results demonstrate that GIV-CARD inhibits apoptosis through both intrinsic and extrinsic pathways.

Effects of C-terminal domain truncation on enzyme properties of Serratia marcescens chitinase C.

A chitinase gene (SmChiC) and its two C-terminal truncated mutants, SmChiCG426 and SmChiCG330 of Serratia marcescens, were constructed and cloned by employing specific polymerase chain reaction (PCR) techniques. SmChiCG426 is derived from SmChiC molecule without its C-terminal chitin-binding domain (ChBD) while SmChiCG330 is truncated from SmChiC by its C-terminal deletion of both ChBD and fibronectin type III domain (FnIII). To study the role of the C-terminal domains of SmChiC on the enzyme properties, SmChiC, SmChiCG426, and SmChiCG330 were expressed in Escherichia coli by using the pET-20b(+) expression system. The His-tag affinity-purified SmChiC, SmChiCG426, and SmChiCG330 enzymes had a calculated molecular mass of 51, 46, and 36 kDa, respectively. Certain biochemical characterizations indicated that the enzymes had similar physicochemical properties, such as the optimum pH (5), temperature (37 °C), thermostability (50 °C), and identical hydrolyzing product (chitobiose) from both the soluble and insoluble chitin substrates. The overall catalytic efficiency k cat /K M was higher for both truncated enzymes toward the insoluble α-chitin, whereas the binding abilities toward the insoluble α-chitin substrate were reduced moderately. The fluorescence and circular dichroism (CD) spectroscopy data suggested that both mutants retained a similar folding conformation as that of the full-length SmChiC enzyme. However, a CD-monitored melting study showed that the SmChiCG330 had no obvious transition temperature, unlike the SmChiC and SmChiCG426.

Effect of C-terminal truncation on enzyme properties of recombinant amylopullulanase from Thermoanaerobacter pseudoethanolicus.

The smallest and enzymatically active molecule, TetApuQ818, was localized within the C-terminal Q818 amino acid residue after serial C-terminal truncation analysis of the recombinant amylopullulanase molecule (TetApuM955) from Thermoanaerobacter pseudoethanolicus. Kinetic analyses indicated that the overall catalytic efficiency, k (cat)/K (m), of TetApuQ818 was 8-32% decreased for the pullulan and the soluble starch substrate, respectively. Changes to the substrate affinity, K (m), and the turnover rate, k (cat), were decreased significantly in both enzymatic activities of TetApuQ818. TetApuQ818 exhibited less thermostability than TetApuM955 when the temperature was raised above 85°C, but it had similar substrate-binding ability and hydrolysis products toward various substrates as TetApuM955 did. Both enzymes showed similar spectroscopies of fluorescence and circular dichroism, suggesting the active folding conformation was maintained after this C-terminal Q818 deletion. This study suggested that the binding ability of insoluble starch by TetApuM955 did not rely on the putative C-terminal carbohydrate binding module family 20 (CBM20) and two FnIII regions of TetApu, though the integrity of the AamyC module of TetApuQ818 was required for the enzyme activity.

Biochemical characterization of two truncated forms of amylopullulanase from Thermoanaerobacterium saccharolyticum NTOU1 to identify its enzymatically active region.

The enzymatically active region of amylopullulanase from Thermoanaerobacterium saccharolyticum NTOU1 (TsaNTOU1Apu) was identified by truncation mutagenesis. Two truncated TsaNTOU1Apu enzymes, TsaNTOU1ApuM957 and TsaNTOU1ApuK885, were selected and characterized. Both TsaNTOU1ApuM957 and TsaNTOU1ApuK885 showed similar specific activities toward various substrates. The overall catalytic efficiency (k (cat)/apparent K (m)) for the soluble starch or pullulan substrate, however, was 20-25% lower in TsaNTOU1ApuK885 than in TsaNTOU1ApuM957. Both truncated enzymes exhibited similar thermostability and substrate-binding ability against the raw starch. The fluorescence and circular dichroism spectrometry studies indicated that TsaNTOU1ApuK885 retained an active folding conformation similar to that of TsaNTOU1ApuM957. These results indicate that a large part of the TsaNTOU1Apu, such as the C-terminal carbohydrate-binding module family 20, the second fibronectin type III, and a portion of the first FnIII motifs, could be removed without causing a serious aberrant structural change or a dramatic decrease in hydrolysis of soluble starch and pullulan.

Characterization of a salt-tolerant xylanase from Thermoanaerobacterium saccharolyticum NTOU1.

A xylanase gene was PCR-cloned from Thermoanaerobacterium saccharolyticum and expressed in Escherichia coli. The xylanase (XynA) consisted of a signal peptide, glycoside hydrolase family 10 domains, carbohydrate-binding modules, and surface layer homology domains. It was optimally active at 70-73°C and at pH 5-7. It had enhanced activity with NaCl with optimal activity at 0.4 M but was tolerant up to 2 M NaCl. The thermostable and salt-tolerant properties of this xylanase suggest that it may be useful for industrial applications.

Effects of C-terminal amino acids truncation on enzyme properties of Aeromonas caviae D1 chitinase.

C-terminal truncation mutagenesis was used to explore the functional and structural significance of the C-terminal region of Aeromonas caviae D1 chitinase (AcD1ChiA). Comparative studies between the engineered full-length AcD1ChiA and the truncated mutant (AcD1ChiAK606) included initial rate kinetics, fluorescence and circular dichroism (CD) spectrometric properties, and substrate binding and hydrolysis abilities. The overall catalytic efficiency, k(cat)/K(M), of AcD1ChiAK606 with the 4MU-(GlcNAc)(2) and the 4MU-(GlcNAc)(3) chitin substrates was 15-26% decreased. When compared with AcD1ChiA, the truncated mutant AcD1ChiAK606 maintained 80% relative substrate-binding ability and about 76% of the hydrolyzing efficiency against the insoluble alpha-chitin substrate. Both fluorescence and CD spectroscopy indicated that AcD1ChiAK606 retained the same conformation as AcD1ChiA. These results indicated that removal of the C-terminal 259 amino acid residues, including the putative chitin-binding motif and the A region (a motif of unknown function) of AcD1ChiA, did not seriously affect the enzyme structure integrity as well as activity. The present study provided evidences illustrating that the binding and hydrolyzing of insoluble chitin substrates by AcD1ChiA were not absolutely dependent on the putative C-terminal chitin-binding domain and the function-unknown A region.

Biochemical characterization of engineered amylopullulanase from Thermoanaerobacter ethanolicus 39E-implicating the non-necessity of its 100 C-terminal amino acid residues.

The functional and structural significance of the C-terminal region of Thermoanaerobacter ethanolicus 39E amylopullulanase (TetApu) was explored using C-terminal truncation mutagenesis. Comparative studies between the engineered full-length (TetApuM955) and its truncated mutant (TetApuR855) included initial rate kinetics, fluorescence and CD spectrometric properties, substrate-binding and hydrolysis abilities, thermostability, and thermodenaturation kinetics. Kinetic analyses revealed that the overall catalytic efficiency, k (cat)/K (m), was slightly decreased for the truncated enzymes toward the soluble starch or pullulan substrate. Changes to the substrate affinity, K (m), and turnover rate, k (cat), varied in different directions for both types of substrates between TetApuM955 and TetApuR855. TetApuR855 exhibited a higher thermostability than TetApuM955, and retained similar substrate-binding ability and hydrolyzing efficiency against the raw starch substrate as TetApuM955 did. Fluorescence spectroscopy indicated that TetApuR855 retained an active folding conformation similar to TetApuM955. A CD-melting unfolding study was able to distinguish between TetApuM955 and TetApuR855 by the higher apparent transition temperature in TetApuR855. These results indicate that up to 100 amino acid residues, including most of the C-terminal fibronectin typeIII (FnIII) motif of TetApuM955, could be further removed without causing a seriously aberrant change in structure and a dramatic decrease in soluble starch and pullulan hydrolysis.

Biochemical characteristics of C-terminal region of recombinant chitinase from Bacillus licheniformis: implication of necessity for enzyme properties.

The functional and structural significance of the C-terminal region of Bacillus licheniformis chitinase was explored using C-terminal truncation mutagenesis. Comparative studies between full-length and truncated mutant molecules included initial rate kinetics, fluorescence and CD spectrometric properties, substrate binding and hydrolysis abilities, thermostability, and thermodenaturation kinetics. Kinetic analyses revealed that the overall catalytic efficiency, k(cat)/K(m), was slightly increased for the truncated enzymes toward the soluble 4-methylumbelliferyl-N-N'-diacetyl chitobiose or 4-methylumbelliferyl-N-N''-N'''-triacetyl chitotriose or insoluble alpha-chitin substrate. By contrast, changes to substrate affinity, K(m), and turnover rate, k(cat), varied considerably for both types of chitin substrates between the full-length and truncated enzymes. Both truncated enzymes exhibited significantly higher thermostabilities than the full-length enzyme. The truncated mutants retained similar substrate-binding specificities and abilities against the insoluble substrate but only had approximately 75% of the hydrolyzing efficiency of the full-length chitinase molecule. Fluorescence spectroscopy indicated that both C-terminal deletion mutants retained an active folding conformation similar to the full-length enzyme. However, a CD melting unfolding study was able to distinguish between the full-length and truncated mutant molecules by the two phases of apparent transition temperatures in the mutants. These results indicate that up to 145 amino acid residues, including the putative C-terminal chitin-binding region and the fibronectin (III) motif of B. licheniformis chitinase, could be removed without causing a seriously aberrant change in structure and a dramatic decrease in insoluble chitin hydrolysis. The results of the present study provide evidence demonstrating that the binding and hydrolyzing of insoluble chitin substrate for B. licheniformis chitinase was not dependent solely on the putative C-terminal chitin-binding region and the fibronectin (III) motif.

Iridovirus Bcl-2 protein inhibits apoptosis in the early stage of viral infection.

The grouper iridovirus (GIV) belongs to the family Iridoviridae, whose genome contains an antiapoptotic B-cell lymphoma (Bcl)-2-like gene. This study was carried-out to understand whether GIV blocks apoptosis in its host. UV-irradiated grouper kidney (GK) cells underwent apoptosis. However, a DNA fragmentation assay of UV-exposed GK cells after GIV infection revealed an inhibition of apoptosis. The UV- or heat-inactivated GIV failed to inhibit apoptosis, implying that a gene or protein of the viral particle might contribute to an apoptosis inhibitory function. The DNA ladder assay for GIV-infected GK cells after UV irradiation confirmed that apoptosis inhibition was an early process which occurred as early as 5 min post-infection. A GIV-Bcl sequence comparison showed distant sequence similarities to that of human and four viruses; however, all possessed the putative Bcl-2 homology (BH) domains of BH1, BH2, BH3, and BH4, as well as a transmembrane domain. Northern blot hybridization showed that GIV-Bcl transcription began at 2 h post-infection, and the mRNA level significantly increased in the presence of cycloheximide or aphidicolin, indicating that this GIV-Bcl is an immediate-early gene. This was consistent with the Western blot results, which also revealed that the virion carries the Bcl protein. We observed the localization of GIV-Bcl on the mitochondrial membrane and other defined intracellular areas. By immunostaining, it was proven that GIV-Bcl-expressing cells effectively inhibited apoptosis. Taken together, these results demonstrate that GIV inhibits the promotion of apoptosis by GK cells, which is mediated by the immediate early expressed viral Bcl gene.

New role of C-terminal 30 amino acids on the insoluble chitin hydrolysis in actively engineered chitinase from Vibrio parahaemolyticus.

A chitinase (VpChiA) and its C-terminal truncated G589 mutant (VpChiAG589) of Vibrio parahaemolyticus were cloned by polymerase chain reaction (PCR) techniques. To study the role of the C-terminal 30 amino acids of VpChiA in the enzymatic hydrolysis of chitin, both the recombinant VpChiA and VpChiAG589 encoded in 1,881 and 1,791 bp DNA fragments, respectively, were expressed in Escherichia coli using the pET-20b(+) expression system. The His-Tag affinity purified VpChiA and VpChiAG589 enzymes had a calculated molecular mass of 65,713 and 62,723 Da, respectively. The results of biochemical characterization including kinetic parameters, spectroscopy of fluorescence and circular dichroism, chitin-binding and hydrolysis, and thermostability, both VpChiA and VpChiAG589, had very similar physicochemical properties such as the optimum pH (6), temperature (40 degrees C), and kinetic parameters of Km and kcat against the 4MU-(GlcNAc)(2) or 4MU-(GlcNAc)(3) soluble substrates. The significant increase of thermostability and the drastic decrease of the hydrolyzing ability of VpChiAG589 toward the insoluble alpha-chitin substrate suggested that a new role could be played by the C-terminal 30 amino acids.

Solution structure of the ligand binding domain of the fibroblast growth factor receptor: role of heparin in the activation of the receptor.

The three-dimensional solution structure of the ligand binding D2 domain of the fibroblast growth factor receptor (FGFR) is determined using multidimensional NMR techniques. The atomic root-mean-square distribution for the backbone atoms in the structured region is 0.64 A. Secondary structural elements in the D2 domain include 11 beta-strands arranged antiparallely into two layers of beta-sheets. The structure of the D2 domain is characterized by the presence of a short flexible helix that protrudes out of the layers of beta-sheets. Results of size exclusion chromatography and sedimentation velocity experiments show that the D2 domain exists in a monomeric state both in the presence and in the absence of bound sucrose octasulfate (SOS), a structural analogue of heparin. Comparison of the solution structure of the D2 domain with the crystal structure of the protein (D2 domain) in the FGF signaling complex reveals significant differences, suggesting that ligand (FGF) binding may induce significant conformational changes in the receptor. SOS binding sites in the D2 domain have been mapped on the basis of the 1H-15N chemical shift perturbation data. SOS binds to the positively charged residues located in beta-strand III and the flexible helix. Isothermal titration calorimetry data indicate that the ligand (hFGF-1) binds strongly (Kd approximately 10(-9) M) to the D2 domain even in the absence of SOS. Binding of SOS to either the D2 domain or hFGF-1 does not seem to be the driving force for the formation of the D2-hFGF-1 binary complex. The function of SOS binding appears to stabilize the preformed D2-FGF binary complex.

Cloning, expression, and characterization of thermostable region of amylopullulanase gene from Thermoanaerobacter ethanolicus 39E.

The bifunctional activities of alpha-amylase and pullulanase are found in the cloned recombinant amylopullulanase. It was encoded in a 2.9-kb DNA fragment that was amplified using polymerase chain reaction from the chromosomal DNA of Thermoanaerobacter ethanolicus 39E. An estimated 109-kDa recombinant protein was obtained from the cloned gene under the prokaryotic expression system. The optimum pH of the recombinant amylopullulanase was 6.0. The most stable pH for the alpha-amylase and pullulanase activity was 5.5 and 5.0, respectively. The optimum temperature for the alpha-amylase activity was 90 degrees C, while its most stable temperature was 80 degrees C. Regarding pullulanase activity, the optimum temperature and its most stable temperature were found to be 80 and 75 degrees C, respectively. Pullulan was found to be the best substrate for the enzyme. The enzyme was activated and stabilized by the presence of Ca2+, whereas EDTA, N-bromosuccinimide, and alpha-cyclodextrin inhibited its bifunctional activities. A malto-2-4-oligosaccharide was the major product obtained from the enzymatic reaction on soluble starch, amylose, amylopectin, and glycogen. A single maltotriose product was found in the pullulan hydrolysis reaction using this recombinant amylopullulanase. Kinetic analysis of the enzyme indicated that the Km values of alpha-amylase and pullulanase were 1.38 and 3.79 mg/mL, respectively, while the Vmax values were 39 and 98 micromol/(min x mg of protein), respectively.