Deletion analysis of the SUP35 gene of the yeast Saccharomyces cerevisiae reveals two non-overlapping functional regions in the encoded protein

SUP35is an omnipotent suppressor gene of Saccharomyces cerevisiae coding for a protein consisting of a C-terminal part similar to the elongation factor EF-1α and a unique N-terminal sequence of 253 amino acids. Twelve truncated versions of the SUP35 gene were generated by the deletion of fragments internal to the coding sequence. Functional studies of these deletion mutants showed that: (i) only the EF-1α-like C-terminal part of the Sup35 protein is essential for the cell viability; (ii) overexpression of either the N-terminal part of the Sup35 protein or the full-length Sup35 protein decreases translational fidelity, resulting in omnipotent suppression and reduced growth of [psi⁺] strains; (iii) expression of the C-terminal part of the Sup35 protein generates an antisuppressor phenotype; and (iv) both the N- or C-terminal segments of the Sup35 protein can bind to 80S ribosomes. Thus, the data obtained define two domains within the Sup35 protein which are responsible for different functions.     

Identification of sequences important for recognition of vnf genes by the VnfA transcriptional activator in Azotobacter vinelandii

Abstract To analyze regulation of the vanadium-dependent nitrogenase of Azotobacter vinelandii , plasmids carrying vnfE-, vnfH- , or vnfD-lacZ fusions were transferred to Escherichia coli . These genes were expressed only if VnfA was present. Deletions of the vnfE upstream region were constructed and comparison of a region necessary for expression with sequences upstream of other vnf genes indicated a substantially conserved motif, GTAC-N6-GTAC, hypothesized to be the binding site for VnfA. This motif was duplicated with 17 or 18 bases lying between each in the vnfH and vnfD promoters. Deletion analysis of the vnfH promoter indicated that both motifs were necessary for full expression. In footprinting experiments, VnfA significantly protected from methylation the guanine residues within or immediately adjacent to the proposed VnfA recognition motifs. The active form of VnfA is probably interacting dimers, a tetramer, or a higher order oligomer since two regions of dyad symmetry are required for its interaction with the DNA.     

Effect of N- and C-terminal deletions on the RNA N-glycosidase activity and the antigenicity of karasurin-A, a ribosome-inactivating protein from Trichosanthes kirilowii var. japonica

Karasurin-A, from root tubers of Trichosanthes kirilowii var. japonica, is a type I ribosome-inactivating protein (RIP) that displays activity of RNA N-glycosidase to remove an adenine in the conserved sarcin/ricin loop of the largest RNA in the ribosome. We expressed recombinant proteins of karasurin-A and its various mutants with N- or C-terminal deletions in Escherichia coli as fusion proteins with maltose-binding protein (MBP), and compared their enzymatic activities and antigenicities. Muteins of karasurin-A generated by deleting either the first 100 N-terminal or the last 30 C-terminal amino acid residues lost activity of RNA N-glycosidase. The mutant proteins whose 80 N-terminal or 20 C-terminal amino acids were deleted could depurinate rRNA although the activities were decreased drastically. The antigenicities of the recombinant proteins were considerably reduced by deleting 20 amino acid residues from either N- or C-terminal regions.Revisions requested 30 September 2004; Revisions received 22 October 2004     

Sequence and molecular analysis of the nifL gene of Azotobacter vinelandii

In both Klebsiella pneumoniae and Azotobacter vinelandii the nifL gene, which encodes a negative regulator of nitrogen fixation, lies immediately upstream of nifA. We have sequenced the A. vinelandii nifL gene and found that it is more homologous in its C-terminal domain to the histidine protein kinases (HPKs) than Is K. pneumoniae NifL. In particular A. vinelandii NifL contains a conserved histidine at a position shown to be phosphorylated in other systems. Both NifL proteins are homologous in their N-termini to a part of the Halobacterium halobium bat gene product; Bat is involved in regulation of bacterio-opsin, the expression of which is oxygen sensitive. The same region showed homology to the haembinding N-terminai domain of the Rhizobium meliloti fixL gene product, an oxygen-sensing protein. Like K. pneumoniae NifL, A. vinelandii NifL is shown here to prevent expression of nif genes in the presence of NH⁺₄ or oxygen. The sequences found homologous in the C-terminal regions of NifL, FixL and Bat might therefore be involved in oxygen binding or sensing. An in-frame deletion mutation in the nifL coding region resulted in loss of repression by NH⁺₄ and the mutant excreted high amounts of ammonia during nitrogen fixation, thus confirming a phenotype reported earlier for an insertion mutation. In addition, nifLA are cotranscribed in A. vinelandii as in K. pneumoniae, but expression from the A. vinelandii promoter requires neither RpoN nor NtrC.     

Subunit dissociation and stability alteration of <Emphasis Type="SmallCaps">d</Emphasis>-hydantoinase deleted at the terminal amino acid residue

Two variants of d-hydantoinase (HYD), created by deletion of one amino acid residue of at either the N- or C-terminus, were expressed in Escherichia coli and purified by two-step chromatography. Compared with HYD, HYDc1 with the C-terminal Arg deletion retained 43% activity, while HYDn1 with the N-terminal Ser deletion had no activity using dl-Hydantoin as substrate. Based on HYD dimer with a molecular weight of 103 kDa, HYDc1 is a monomer of 52 kDa and HYDn1 is a mixture of dimer and monomer. Moreover, HYDc1 displayed higher pH stability and lower thermal stability compared to HYD. In addition, the secondary and tertiary structures of HYDc1 were not significantly changed in contrast to the ones of HYDn1. All data imply that the C-terminal Arg of the HYD is crucial for homodimeric architecture of the enzyme, but non-essential for catalysis, while the N-terminal Ser is required for both conformation and catalysis of the enzyme.     

Functional domains of theEscherichia coli ferric uptake regulator protein (Fur)

The functions of N- and C-terminal domains of the Fur repressor ofEscherichia coli in promoter recognition and dimerization were studied. We investigated the ability of fusion proteins containing the N- or C-terminal domain of Fur to dimerize and to repress a Fur-regulatedlacZ fusion gene. The N-terminal domain, when fused to the C-terminal domain of the repressor C1857, repressed a Fur-regulatedlacZ fusion. However, the Fur-CI857 fusion was unable to complement the growth defect of anE. coli fur mutant on fumarate and succinate. The C-terminal domain of Fur, when fused to the N-terminus of CI857, repressed a P, -regulatedlacZ fusion, indicating dimerization of the chimeric protein, which is a prerequisite for Cl activity. Both fusion proteins were fully active under both iron-rich and iron-poor growth conditions. We conclude that the N-terminal domain of Fur is involved in recognition of the Fur-responsive promoter and the C-terminus mediates oligomerization of the repressor.     

Characterization of mutations in divlB of Bacillus subtilis and cellular localization of the DivlB protein

Four temperature-sensitive mutations in the divlB gene of Bacillus subtilis have been localized to the region corresponding to the C-terminal half of the 263-residue DivlB protein. Antiserum was raised to the 80%C-terminal portion lying on one side of a putative transmembrane (hydrophobic) segment, and used to examine aspects of the nature and localization of the DivIB protein in the cell. A single DivIB species of a size equal to the full-length protein encoded by the divIB gene was detected in wild-type cells. Cell fractionation studies established that DivIB is associated preferentially with the cell envelope (membrane plus cell wall), with approximately 50% being released into solution upon treatment of cells with lysozyme under conditions that yield protoplasts. Of the remaining 50%, approximately half remained firmly associated with the membrane fraction. On the basis of the‘positive-inside rule’of von Heijne (1986) it is suggested that the topology of membrane-bound DivlB is such that the long C-terminal portion is directed to the outside and the smaller N-terminal portion to the inside of the cell. DivlB in protoplasts was rapidly degraded by proteinase K under conditions where there was no general proteolysis of the cytoplasmic proteins. This is consistent with its absence from the cytoplasm, and with the predicted membrane topology. Septum positioning in a divIB null mutant, which grows as filaments at temperatures of 30^°C and below, was found to be normal. It appears that DivlB is needed for achieving the appropriate rate of initiation of septum formation at normal division sites. It is proposed that the C-terminal portion of DivlB, localized on the exterior surface of the membrane and in juxtaposition to the peptidoglycan, normally interacts with another protein (or proteins) to initiate septum formation.     

Effects of <Emphasis Type="Italic">N</Emphasis>- and <Emphasis Type="Italic">C</Emphasis>-terminal truncation of HP (2-20) from <Emphasis Type="Italic">Helicobacter pylori</Emphasis> ribosomal protein L1 (RPL1) on its anti-microbial activity

HP (2-20) [derived from the N-terminal region of Helicobacter pylori Ribosomal Protein L1 (RPL1)], a 19-mer peptide, possesses broad-spectrum anti-microbial activity. As the N- (residues 2–3) and C-terminal (residues 14–20) residues can be deleted without affecting antimicrobial activity, we have now determined the minimum chain length necessary for the retention of antimicrobial activity, and its mode of action. The N- (residues 2–3) and C-terminal (residues 17–20) truncated fragments [HP (4–16)] induce increased antibiotic activity against several bacterial strains without hemolysis. Flow cytometric analysis, scanning electron microscopy and fluorescence confocal microscopy revealed that HP (4–16) acted rapidly on the plasma membranes of the fungal cells in a salt- and energy-independent manner.Revisions requested 16 September 2004/1 November 2004; Revisions received 29 October 2004/8 December 2004     

Fusion with maltose-binding protein (MBP) affects neither RNA N-glycosidase activity nor immunogenicity of karasurin-A, a ribosome-inactivating protein from Trichosanthes kirilowii var. japonica

A genomic clone encoding mature karasurin-A (KRNA), a ribosome-inactivating protein from Trichosanthes kirilowii var. japonica, was efficiently expressed in E. coli using an expression cassette vector pMAL-c2. The resultant recombinant KRNA fused with maltose-binding protein (MBP) was recovered from the soluble fraction of the bacterial cells and purified to near homogeneity after one round of the affinity chromatography. Neither the karasurin precursor retaining both N- and C-terminal peptides, nor the protein with the N-terminal peptide was successufully produced even as a MBP-fusion. The protein with its C-terminal peptide was over-produced but was recovered in an insoluble fraction. Both the recombinant MBP-KRNA fusion protein and recombinant KRNA with MBP removed were as active as the native KRNA from root tubers. The immunogenicity of the recombinant KRNA was also unaffected by fusion with MBP.