Proteolytic processing of foot-and-mouth disease virus polyproteins expressed in a cell-free system from clone-derived transcripts

All picornaviral genes are expressed as a single, large polyprotein, which is proteolytically processed into the system produces functional proteins, including viral protease 3C, which plays a major role in processing the precursor proteins. To study the function of the two putative proteases 3C and leader (L) in processing, we constructed several cDNA plasmids encoding various regions of the FMDV type A12 genome. These plasmids, containing FMDV cDNA segments under the control of the T7 promoter, were transcribed in vitro by using T7 RNA polymerase and then translated in rabbit reticulocyte lysates. The expressed FMDV gene products were identified by immunoprecipitation with specific antisera and analyzed by gel electrophoresis. The results demonstrate the following: (i) the leader protein, L, is processed from the structural protein precursor, P1, in the absence of any P2 or P3 region proteins; (ii) protein 2A remains associated with the structural protein precursor, P1, rather than the precursor, P2; (iii) the processing of the P1-2A/P2 junction is not catalyzed by 3C or L; (iv) the proteolytic processing of polyproteins from the structural P1 region (except VP4/VP2) and the nonstructural P2 and P3 region is catalyzed by 3C.     

Leader protein of foot-and-mouth disease virus is required for cleavage of the p220 component of the cap-binding protein complex.

Suppression of host protein synthesis in cells infected by poliovirus and certain other picornaviruses involves inactivation of the cap-binding protein complex. Inactivation of this complex has been correlated with the proteolytic cleavage of p220, a component of the cap-binding protein complex. Since picornaviral RNA is not capped, it continues to be translated as the cap-binding protein complex is inactivated. The cleavage of p220 can be induced to occur in vitro, catalyzed by extracts from infected cells or by reticulocyte lysates translating viral RNA. Expression of polioviral protease 2A is sufficient to induce p220 cleavage, and the presence in 2A of an 18-amino-acid sequence representing a putative cysteine protease active site correlates with the ability of different picornaviruses to induce p220 cleavage. Foot-and-mouth disease virus (FMDV) infection induces complete cleavage of p220, yet the FMDV genome codes for a 2A protein of only 16 amino acids, which does not include the putative cysteine protease active site. Using cDNA plasmids encoding various regions of the FMDV genome, we have determined that the leader protein is required to initiate p220 cleavage. This is the first report of a function for the leader protein, other than that of autocatalytic cleavage from the FMDV polyprotein.     

Production of cellulase using a mutant strain of Trichoderma reesei growing on lactose in batch culture

The production of cellulases in batch culture was studied using a mutant strain of Trichoderma reesei C-5 growing on lactose. Growth kinetic parameters on 2% lactose were studied and the comparative results for growth and enzyme productivities at two different lactose levels are discussed. The cellulase synthesis rate depended on the lactose concentration in the medium. Although growth was favoured at a higher lactose level, the volumetric enzyme productivity did not increase in proportion and the specific enzyme productivity decreased to a certain extent, indicating that partial catabolic inhibition at higher lactose concentrations may be possible. However, it was noted that the mutant strain was highly depressed and capable of synthesising active cellulases on lactose.     

Detection and identification of ferricrocin produced by ectendomycorrhizal fungi in the genusWilcoxina

The ectendomycorrhizal fungiWilcoxina mikolae isolates CSY-14 and RMD-947 andW. rehmii isolate CSY-85 were grown in pure culture under iron-limiting conditions. All three isolates tested positive for siderophore formation using both the ferric perchlorate assay and a sensitive HPLC iron-binding assay. A peptide siderophore was isolated from the culture medium by HPLC and shown to contain the amino acids serine, glycine and ornithine in a 1:2:3 ratio. This siderophore was identified as ferricrocin on the basis of electrospray mass spectroscopy and its co-chromatography in two different HPLC systems with ferricrocin isolated fromAspergillus fumigatus. Ferricrocin was the only siderophore isolated from theseWilcoxina cultures. This is the first report of siderophore formation by ectendomycorrhizal fungi.     

Reversed-phase boronate chromatography for the separation of O-methylribose nucleosides and aminoacyl-tRNAs

Boronate forms an anionic complex with the cis-2′,3′ hydroxyls of unsubstituted ribonucleosides and the 3′-terminal adenosine of unacylated tRNAs, but not with ribosesubstituted nucleosides such as 2′-O-methylnucleosides and aminoacyl-tRNAs. We have synthesized phenyl boronates with hydrophobic side chains of about 1-nm-long and coated inert 10-μm solid beads of polychlorotrifluoroethylene with this material. This matrix complexes easily with compounds containing free cis-hydroxyls, but not with their O-alkyl or O-acyl derivatives. This permits the separation of mammalian and bacterial amino-acyl-tRNAs from uncharged tRNAs and O-methyl nucleosides from ribose-unsubstituted nucleosides in one chromatographic step, as the substituted members of each group do not undergo boronate complex formation and are thus not as much retarded in passing through the column. Complex formation between ribofuranoses and the boronate matrix appears to be enhanced by the hydrophobic “tail” of the boronate compound, by the high ionic environment of the solvent, and by the hydrophobic nature of the inert support. This method of one-step purification of tRNAs on reversed-phase boronate columns has been tested for several tRNAs specific for amino acids of different hydrophobicity and ionic character. The results indicate that each tRNA tested can be purified with appreciable purity (70–95%) and high yield (80%). However, recovery of the queuine base containing aminoacyl-tRNAs is only about 6% of the applied material. Several other boronate matrices have also been synthesized using cellulose, agarose. Sepharose, or porous glass beads as the inert support with different lengths of the spacer arm. Cellulose with a 1-nm-long spacer arm is satisfactory not only for the separation of aminoacyl-tRNAs and O-methylribose nucleosides, but also for the separation as a group of tRNAs containing the base of Q, queuine. However, other inert supports are unsatisfactory because of a non-specific binding of the tRNAs.     

Malabarase,a serine protease with anticoagulant activity from Trimeresurus malabaricus venom

In the present study we describe the purification and characterization of Malabarase, a serine protease from Trimeresurus malabaricus venom. Purification was achieved by gel-permeation chromatography on Sephadex G-75 followed by ion-exchange chromatography on CM Sephadex C-25. Homogeneity of Malabarase was confirmed by RP-HPLC. Malabarase is a monomer that migrated as a single protein band on SDS-PAGE under both reducing and non-reducing conditions. The molecular mass of Malabarase was determined to be 23.4 kDa using MALDI-TOF mass spectrometry. Malabarase is the first serine protease purified from T. malabaricus venom and is selective for fibrinogen. Malabarase hydrolyzes Aα and Bβ but not γ-chains of fibrinogen similar to the metalloproteases, Malabarin and Trimarin, isolated from the same venom. However, the action of Malabarase on plasma coagulation is opposite than those of Malabarin, Trimarin and the whole venom. Malabarase significantly prolonged plasma coagulation time from 152–341 s; whereas Malabarin, Trimarin, and whole venom, greatly reduce plasma clotting time from 152 to 12, 48, and 14 s, respectively. Malabarase did not show hemorrhagic or myotoxic activity. In contrast, Malabarin, Trimarin and whole venom are highly hemorrhagic and myotoxic. These observations support the specificity of Malabarase towards fibrinogen and its non-toxic nature. In conclusion, Malabarase is a fibrinogen-specific, anti-coagulant, and non-toxic serine protease. Its selective action and non-toxic nature might make it useful for treating thrombotic disorders.     

Nitrate signals determine the sensing of nitrogen through differential expression of genes involved in nitrogen uptake and assimilation in finger millet

In order to understand the molecular basis of high nitrogen use efficiency of finger millet, five genes (EcHNRT2, EcLNRT1, EcNADH-NR, EcGS, and EcFd-GOGAT) involved in nitrate uptake and assimilation were isolated using conserved primer approaches. Expression profiles of these five genes along with the previously isolated EcDof1 was studied under increased KNO₃ concentrations (0.15 to 1,500 μM) for 2 h as well as at 1.5 μM for 24 h in the roots and shoots of 25 days old nitrogen deprived two contrasting finger millet genotypes (GE-3885 and GE-1437) differing in grain protein content (13.76 and 6.15 %, respectively). Time kinetics experiment revealed that, all the five genes except EcHNRT2 in the leaves of GE-3885 were induced within 30 min of nitrate exposure indicating that there might be a greater nitrogen deficit in leaves and therefore quick transportation of nitrate signals to the leaves. Exposing the plants to increasing nitrate concentrations for 2 h showed that in roots of GE-3885, NR was strongly induced while GS was repressed; however, the pattern was found to be reversed in leaves of GE-1437 indicating that in GE-3885, most of the nitrate might be reduced in the roots but assimilated in leaves and vice-versa. Furthermore, compared with the low-protein genotype, expression of HNRT2 was strongly induced in both roots and shoots of high-protein genotype at the least nitrate concentration supplied. This further indicates that GE-3885 is a quick sensor of nitrogen compared with the low-protein genotype. Furthermore, expression of EcDof1 was also found to overlap the expression of NR, GS, and GOGAT indicating that Dof1 probably regulates the expression of these genes under different conditions by sensing the nitrogen fluctuations around the root zone.